I

ABSTRACT

A Natural product is a chemical compound or substance

produced by a living organism found in nature that usually has a

Pharmacological/ Biological activity for use in Pharmaceutical Drug

discovery and drug design.

The main advantage of semi synthetic drug is they can act with

higher potency than their original natural products such as onset of

action, potency, site of action etc.

Based on the above facts Four Pharmacologically potential

compounds were selected. The various derivatives of this compound

were synthesized by using simple synthetic procedures. The total

Nineteen semi synthetic derivatives were synthsized and their

structures are conformed by physical and spectral analysis.

All the synthesized compounds were subjected for different

activities, the Anti-bacterial activity of the synthesized compounds were

performed against two Gram positive and Gram negative bacteria. The

compound II, IX and XIII has potent Anti-bacterial activity. Further more

studies on these derivatives for safer and potent Anti-bacterial drug.

The Anti-fungal activity of these derivatives compound I, IX, XV

and XVII has shown moderated activity, thus in future more works has

to be carried out on these derivatives to come up with potent moiety.

II

The compound III to XVIII showed good potent Anti-inflamatory

activity when compared with standard drug.

The acute toxicity studies showed that all theNineteen derivatives

were safe even up 1000mg/kg and thus a dose of 300mg/kg i.p. was

used as safer dose in experimental animals.

Based on the above it could be concluded that compound

III, IV, IX and XIII were found to have good potency in all activity

performed. Thus structure of these derivatives has to be optimized to

explore the desired Pharmacological activity

III

LIST OF ABBREVIATIONS

ALT - Alanine Amino Transferase

ACE - Angiotensin Converting Enzyme

ASA - Acetyl Salicylic Acid

AST - Aspartate Amino Transferase

COPD - Chronic Obstructive Pulmonary Disease

MeOH - Methanol

CDK - Cyclin Dependent Kinase

GABA - Gama Amino Butyric Acid

IC50 - 50% Inhibitory Concentration

gm - gram

FDA - Food Drug Administration

cfu - Colony Forming Units

TLC - Thin Layer Chromatography

DSB - Bromovanin-induced DNA double-strand breaks

FAH - Fumaryl Acetoacetate Hydro-Lase

MGYP - Maltose, glucose, yeast extract and peptone

DMSO - Dimethyl Sulfoxide

HDAC - Histone Deacetylase

HDL-C - High-Density Lipoprotein-Cholesterol

HPPD - p -Hydroxyphenylpyruvate Dioxygenase (HDL-C

HMG-CoA - 3-Hydroxy-3-Methylglutaryl Coenzyme A

IV

IMPDH - Inosine Monophosphate Dehydrogenase

LDL-C - Low-Density Lipoprotein-Cholesterol

d - Doublet

m - Multiplet

s - Singlet

Et2O - Diethyl Ether

Ar-H - Aromatic Protons

CAT - Catalase

GGT - Gamma – glutamyltransferase

GST - GLUTATHIONE-S-TRANSFERASE

GSH - Glutathione

MTT - MICROCULTURE TETRAZOLIUM

MRSA - Methicillin Resistant Staphylococcus Aureus

NCE - New Chemical Entity

FBS - Fetal Bovine Serum

ROS - Reactive Oxygen Species

PMR - Proton Magnetic Resonance

IR - Infrared

COX-2 - Cyclo-Oxygenase-2

PGE2 - Prostaglandin E2

NO - Nitric oxide

iNOS - Inducable Nitric Oxide Synthase

LSD - Lysergic Acid Diethylamide

V

LPS - Lipopolysaccharide

SOD - Superoxide Dismutase

ACE - Angiotensin Converting Enzyme

w/w - Weight/Weight

ml - Milli litre

conc. - Concentrated

mg/g - Milli gram / gram

mg/dl - Milli gram / deci litre

BUN - Blood Urea Nitrogen

MDA - Malondialdehyde

G - Gram

h - Hour

min - Minutes

mg / kg - Milli gram / kilogram

CMC - Carboxy Methyl Cellulose

b.w - Body Weight

TMS - Tetra Methyl Silane

mmol/L - Milli moles / litre

N - Normality

M - Molarity

TCA - Trichloro Acetic Acid

DPPH - 2, 2- Diphenyl 1-Picryl Hydrazyl

ABTS - 2, 2΄Azino Bis (3-Ethylbenzo- Thiazoline – 6-

Sulphuric Acid)

PBS - Phosphate Buffer Saline

VI

LIST OF TABLESTable No TITLE Page

No

1 Various uses of herbals in treatment and diagnosis 03

2 List of chemicals and their manufactures used for synthesis 80

3 List of Equipments used during the Experiments 81

4 Structure and nomenclature of Citral derivatives(Compound I, II) 94

5 Structure and nomenclature of Vanillin derivatives(Compound III - V) 95

6 Structure and nomenclature of Vanillin derivatives(Compound VI - VIII ) 96

7 Structure and nomenclature of Vanillin derivatives(Compound IX - XI) 97

8 Structure and nomenclature of Carvone derivatives(Compound XII -XIV ) 98

9 Structure and nomenclature of Carvone derivatives(Compound XV - XVI) 99

10 Structure and nomenclature of Camphor derivatives(Compound XVII - XIX) 100

11 Physical properties of the synthesized compounds (I-XIX) 101

12 TLC profile of the synthesized compounds (I – XIX) 102

13 Elemental analysis of novel semisynthetic compounds (I –XIX) 103

14 FT-IR Spectral Datas of the Semisynthetic Compounds (I –XIX) 104-07

15 1HNMR Spectral Datas of compounds (I – XIX) 108-111

16 Antibacterial Activity of the Compounds (I – IX) 187

17 Antifungal Activity of Compounds (I – IX). 188

18 Antioxidant activity of compounds (I-IX). 189

19 Anti-inflammatory activity of the compounds (I –XIX). 190

20 Analgesic activity of the compounds (I –XIX) 191

21 Anthelmintic activity of compounds (I –XIX) 192

22 List of the Newly Synthesized Derivatives along with theirIUPAC Name 219

VII

LIST OF FIGURES (INCLUDING FT-IR, HNMR AND MASS SPECTRAS).

FIGURENO. PARTICULARS PAGE

NO.1 Precursor and Derivative of Salicylic Acid. 9

2 Artemisinin 10

3 Cocaine and Quinine 11

4 Vincristine 12

5 New drugs from terrestrial plants 16

6 Plant-derived drug candidates. 19

7 New drugs from terrestrial microorganisms (2000 to2005). 23

8 Vincristine 33

9 Pictorial representation of various parts of Vanillin 34,35

10 Carvone 36

11 Camphor 37

12 Isomers of Citral 39

13 Schemes for synthesis of compound I-III 74

14 Schemes for synthesis of compound IV-VI 75

15 Schemes for synthesis of compound VII-IX 76

16 Schemes for synthesis of compound X – XII 77

17 Schemes for synthesis of compound XIII – XVI 78

18 Schemes for synthesis of compound XVII –XIX 79

19 FT-IR Spectrum of Compound I 112

20 HNMR Spectrum of Compound I 113

21 MASS Spectrum of Compound I 114

22 FT-IR Spectrum of Compound II 115

23 HNMR Spectrum of Compound II 116

24 MASS Spectrum of Compound II 117

25 FT-IR Spectrum of Compound III 118

VIII

26 HNMR Spectrum of Compound III 119

27 MASS Spectrum of Compound III 120

28 FT-IR Spectrum of Compound IV 121

29 HNMR Spectrum of Compound IV 122

30 MASS Spectrum of Compound IV 123

31 FT-IR Spectrum of Compound V 124

32 HNMR Spectrum of Compound V 125

33 MASS Spectrum of Compound V 126

34 FT-IR Spectrum of Compound VI 127

35 HNMR Spectrum of Compound VI 128

36 MASS Spectrum of Compound VI 129

37 FT-IR Spectrum of Compound VII 130

38 HNMR Spectrum of Compound VII 131

139 MASS Spectrum of Compound VII 132

40 FT-IR Spectrum of Compound VIII 133

41 HNMR Spectrum of Compound VIII 134

42 MASS Spectrum of Compound VIII 135

43 FT-IR Spectrum of Compound IX 136

44 HNMR Spectrum of Compound IX 137

45 MASS Spectrum of Compound IX 138

46 FT-IR Spectrum of Compound X 139

47 HNMR Spectrum of Compound X 140

48 MASS Spectrum of Compound X 141

49 FT-IR Spectrum of Compound XI 142

50 HNMR Spectrum of Compound XI 143

51 MASS Spectrum of Compound XI 144

52 FT-IR Spectrum of Compound XII 145

53 HNMR Spectrum of Compound XII 146

54 MASS Spectrum of Compound XII 147

55 FT-IR Spectrum of Compound XIII 148

IX

56 HNMR Spectrum of Compound XIII 149

57 MASS Spectrum of Compound XIII 150

58 FT-IR Spectrum of Compound XIV 151

59 HNMR Spectrum of Compound XIV 152

60 MASS Spectrum of Compound XIV 153

61 FT-IR Spectrum of Compound XV 154

62 HNMR Spectrum of Compound XV 155

63 MASS Spectrum of Compound XV 156

64 FT-IR Spectrum of Compound XVI 157

65 HNMR Spectrum of Compound XVI 158

66 MASS Spectrum of Compound XVI 159

67 FT-IR Spectrum of Compound XVII 160

68 HNMR Spectrum of Compound XVII 161

69 MASS Spectrum of Compound XVII 162

70 FT-IR Spectrum of Compound XVIII 163

71 HNMR Spectrum of Compound XVIII 164

72 MASS Spectrum of Compound XVIII 165

73 FT-IR Spectrum of Compound XIX 166

74 HNMR Spectrum of Compound XIX 167

75 MASS Spectrum of Compound XIX 168

76 A broad classification of reactive oxygen species 172

1

INTRODUCTION

Nature always stands as a golden mark to exemplify the

outstanding phenomenon of symbiosis. The history of herbal medicines

is as old as human civilization. The documents, many of which are of

great antiquity, revealed that plants were used medicinally in China,

India, Egypt and Greece long before the Christian era. The oldest

known herbal is Pen-t`sao written by emperor Shen nung around 300

B.C It contains 365 drugs, one for each day of the year (Satyajit D

Sarker, 2004).

Ancient Chinese and Egyptian papyrus writings describe

medicinal uses for plants. Indigenous cultures (such as African and

Native American) used herbs in their healing rituals, while others

developed traditional medical systems (such as Ayurveda and

Traditional Chinese Medicine) in which herbal therapies were used.

Researchers found that people in different parts of the world tended to

use the same or similar plants for the same purposes. In the early 19th

century, when chemical analysis first became available, scientists

began to extract and modify the active ingredients from plants. Later,

chemists began making their own version of plant compounds, and over

time, the use of herbal medicines declined in favor of drugs (Kokate C

K, 2007).

2

Herbal medicine also called botanical medicine or phytomedicine

refers to using a plant's seeds, berries, roots, leaves, bark, or flowers for

medicinal purposes. Herbalism has a long tradition of use outside of

conventional medicine. Herbs having Medicinal Properties in nature,

there are a huge variety of herbs, having medicinal properties and they

are used to prepare the herbal medicines. They can be used directly in

the form of extracts or tea, or used to produce the drugs. Herbs such as

St. John’s Wort, ginkgo, echinacea, and ginseng are among the most

popular herbs. In 1999, echinacea was reported to make up 38% of the

U.S. market, with ginkgo a close second at 34%. The efficacy of these

herbs is being investigated in many laboratories, and efforts are also

being made to isolate and identify any active constituents. It is

becoming more main stream as improvements in analysis and quality

control along with advances in clinical research show the value of

herbal medicine in the treating and preventing disease (Newman DJ,

2007).

Several herbs consist of powerful ingredients, which are helpful to

cure a number of health problems. They can be used safely, without

causing any side effects. Some of the commonly used herbs are

American ginseng, bee pollen, astragalus, cat's claw, black cohosh,

bladder wrack, chamomile, feverfew, damiana, dong quai, flaxseed,

ginger, garlic, ginkgo biloba, grape seed, green tea, licorice, muira

3

puama, saw palmetto, suma, schizandra, tea tree, turmeric, soy

isoflavones, white willow, etc (Dan Bensky, 2004).

Ephedra is an appetite suppressant. It is used to treat asthma or

bronchitis. Echinacea helps strengthen immune system and protects

from flu and common cold. Feverfew is used to prevent migraine

headache and also helps manage allergies, rheumatic disease and

arthritis. Kava-kava is used to treat stress, anxiety and restlessness.

Ginkgo increases oxygenation and blood circulation and helps improve

memory and concentration. Valerian is a muscle relaxant and a mild

sedative and helps deal with insomnia. Ginger decreases and prevents

vertigo, nausea and vomiting( Hernan Garcia, 1999).

Interest in the United States had been growing in the recent years

from the reported success stories from the use of herbs. For example,

St. John's Wort is widely used in the treatment of mild depression

without the need for Prozac. St. John's Wort does not have the side

effects such as that of Prozac. There are some Ayurvedic herbs that are

very useful for reducing cholesterol, diabetes etc. Similarly the

popularity of Ginseng and Ginkgo biloba (ginkgo) is rising due to its

beneficial effects ( El- Shemy HA, 2003).

From the review, it is obvious that there is growing economic

value of medicinal plants that the developing countries need to harness

in order to improve their economic and health care delivery systems.

4

The “pharmergeing” nations appear to understand this economic

dynamics and are living up to the challenges. In particular, developing

counties from African region need to put in more effort in order to face

these health and economic challenges especially in the face of

resurgence and emergency of resistint strains of pathogenic micro-

organisums and cancers that had become serious threat to our

collective survival (Bukata B. Bukar. May 2016).

Table No. 1 various uses of herbals in treatment and diagnosis

Plant Family Uses

Digitalis

purpurea

Scrophulariaceae As a cardiotonic

Chondrodendron

tomentosum

Loganiaceae Neuromuscular blocker

Panex ginseng Araliacea Immunomodulatory,

sedativeCinchona

officinalis

Rubiacea Antimalarial

Rauwolfia

serpentina

Apocynaceae Antihypertensive

Datura metel Solanaceae Anticholinergic

Papaver

somniferum

Papaveraceae Hypnotic,sedative,analgesic

Curcuma longa Zingiberaceae Anti-inflammatory,

condimentAloe

barbadensis

Liliaceae In cosmetic preparations

Catharanthus

roseus

Apocynaceae Anticancer herb

Areca catechu Palmae Respiratory, stimulant.

NtihelmenthicHolarrhena Apocynaceae Antiamoebic

Veratrum album Liliaceae Cardiac depressant

5

Advantages of Herbal Medicines

Allopathic medicines are very costly. In contrast, herbal medicines

are very cheap. This cost effectiveness makes them all the more

alluring. Herbal medicines can be brought without prescription

and they are available in all most all health stores. Some herbs

can even be grown at home.

For certain ailments, herbal medicines are considered to be more

effective than allopathic medicines.

Herbal medicines do not have any side effects, as they are free

from chemicals. They are also milder than allopathic medicines.

The natural detoxification process of the body is effectively

enhanced by herbal medicines. They can be used to cleanse the

colon, improve digestion and food absorption. Herbal medicines

are also very good in boosting the immune system.

Herbal medicines are very effective in curing various digestive

disorders like colitis, indigestion, peptic ulcers, and irregular

bowel movements.

These types of medicines are best for people who are allergic to

various types of drugs.

Herbal medicines are also effective in boosting the mental health.

6

Most of the ailments related to blood circulation like high blood

pressure, varicose ulcers, and many others can be controlled

through herbal medicine.

Some herbal medicines are very good in reducing the cholesterol

level in the blood stream. They are also used to treat coronary

artery diseases.

Herbal medicine can be used to reduce weight by regulating

appetite.

An example may be seen with herbs and alternative remedies

used to treat arthritis. Vioxx, a well-known prescription drug uses

to treat arthritis, was recalled due to increased risk of

cardiovascular complications. Alternative treatments for arthritis,

on the other hand, have few side effects. Adjusting the diet to

remove vegetables from the nightshade family, reducing white

sugar consumption, and adding simple herbs to the diet have few

side effects. Most herbal medicines are well tolerated by the

patient, with fewer unintended consequences than

pharmaceutical drugs.

Another advantage to herbal medicine is cost. Herbs cost much

less than prescription medications. Research, testing, and

marketing add considerably to the cost of prescription medicines.

Herbs tend to be inexpensive compared to drugs.

7

The chemical medicine prescribed by a pharmacist could have

certain negative side effects. However, many of the herbal

medicines and remedies do not have negative side effects. If any,

they are softer than allopathic medicine.

Herbal medicine can be effectively used for body’s natural

detoxification process. The herbs such as Plantago psyllium

seed, rhubarb juice powder, aloe vera, alfalfa juice, chlorella,

carrot concentrate and garlic can be used to cleanse the colon,

improve digestion and food absorption and boost your immune

system. Some digestive disorders such as colitis, indigestion,

peptic ulcers and irritable bowel syndrome can be cured using the

herbs.

Herbal medicine which includes herbs such as ginger, capsicum,

garlic and motherwort help to control the ailments related to blood

circulation such as high blood pressure, varicose ulcers and so

on. Many of the herbal medicines are used to treat coronary

artery disease and to reduce cholesterol level in the blood stream

and

Obesity is the cause of many of the health problems. Herbal

medicine can help reduce excess weight and regulate appetite.

8

Disadvantages of Herbal Medicine (Merrilield RB, 1975)

Herbs are not without some disadvantages. For sudden, serious

illnesses, mainstream medicine still reigns supreme. An herbalist

would not be able to treat serious trauma, such as a broken leg,

nor would be able to heal appendicitis or a heart attack as

effectively as a conventional doctor using modern diagnostic

tests, surgery, and drugs. Modern medicine treats sudden illness

and accidents much more effectively than herbal or alternative

treatments.

Herbal medicines take too much time to act. The entire process is

very slow.

There is also a remote chance that herbal medicine may not give

the desired result.

Some plant chemicals can be toxic to the body. In addition,

certain ingredients react differently with different people. So, it is

always necessary to test the herbal medicine to check that it is

not allergic to the body.

Some herbal medicines can cause negative side effects. These

side effects may also take a long time to revel.

Herbal medicines are also not properly regulated and so they do

not carry any quality assurance.

9

Herbal medicines require very good practitioners and these are

very few. Most of the ‘Doctors’ that populate the commercial

herbal remedy market are not qualified and so people must stay

away from them.

Another disadvantage of herbal medicine is the very real risks of

doing oneself harm through self-dosing with herbs. While one can

argue that the same thing can happen with medications, such as

accidentally overdosing on cold remedies, many herbs do not

come with instructions or package inserts. There’s a very real risk

of overdose. Harvesting herbs in the wild is risky, if not foolhardy,

yet some people try to identify and pick wild herbs. They run a

very real risk of poisoning themselves if they don’t correctly

identify the herb, or if they use the wrong part of the plant.

Herbal treatments can interact with medications. Nearly all herbs

come with some warning, and many, like the herbs used for

anxiety such as Valerian and St. John’s Wort, can interact with

prescription medication such as antidepressants. It’s important to

discuss your medications and herbal supplements with your

Doctor and

Because herbal products are not tightly regulated, consumers

also run the risk of buying inferior quality herbs. The quality of

herbal products may vary among batches, brands or

10

manufacturers. This can make it much more difficult to prescribe

the proper dose of an herb.

Phytochemicals which are chemicals derived from plants.

Specifically, phytochemistry describes the large number of

secondarymetabolic compounds found in plants. The

inconsistencies in chemicals are observed due to environmental

conditions like soil, temperature, light, rainfall and humidity.

Recently, the World Health Organization estimated that 80% of

people worldwide rely on herbal medicines for some part of their

primary health care. In Germany, about 600 - 700 plant-based

medicines are available and are prescribed by some 70% of German

physicians. In the last 20 years in the United States, public

dissatisfaction with the cost of prescription medications, combined with

an interest in returning to natural or organic remedies, has led to an

increase in herbal medicine use.

A natural product is a chemical compound or substance produced by

a living organism - found in nature that usually has a pharmacological or

biological activity for use in pharmaceutical drug discovery and drug

design. A natural product can be considered as such even if it can be

prepared by total synthesis.

Natural products are products from various natural sources, plants,

microbes and animals. Natural products can be an entire organism (e.g.

11

a plant, an animal or a micro-organism), a part of an organism (e.g.

leaves or flowers of a plant, an isolated animal organ), an extract of an

organism or part of an organism and an exudate, or pure compound

(e.g. alkaloids, coumarins, flavonoids, lignans, steroids and terpenoids)

isolated from plants, animals or micro-organisms. However, in practice,

the term natural product refers to secondary metabolites, small

molecules (molecular weight < 1500 amu), produced by an organism,

but not strictly necessary for the survival of the organism.

These small molecules provide the source of inspiration for the

majority of FDA- approved agents and continue to be one of the major

sources of inspiration for drug discovery. In particular, these compounds

are important in the treatment of life-threatening conditions.

Natural products may be extracted from tissues of terrestrial

plants, marine organisms or microorganism fermentation broths. A

crude (untreated) extract from any one of these sources typically

contains novel, structurally diverse chemical compounds, which the

natural environment is a rich source of Chemical diversity in nature is

based on biological and geographical diversity, so researchers travel

around the world obtaining samples to analyze and evaluate in drug

discovery screens or bioassays. This effort to search for natural

products is known as bioprospecting.

12

In the past, traditional peoples or ancient civilizations depended greatly

on local flora and fauna for their survival. They would experiment with

various berries, leaves, roots, animal parts or minerals to find out what

effects they had. As a result, many crude drugs were observed by the

local healer or shaman to have some medical use. Although some

preparations may have been dangerous, or worked by a ceremonial or

placebo effect, traditional healing systems usually had a substantial

active pharmacopoeia, and in fact most western medicines up until the

1920s were developed this way. Some systems, like traditional Chinese

medicine or Ayurveda were fully as sophisticated and as documented

systems as western medicine, although they might use different

paradigms.

As a result of rapid development of phytochemistry and

pharmacological testing methods in recent years, new plant drugs are

finding their way into medicine as purified phytochemicals, rather than in

the form of traditional galenical preparations.

The earliest pure compounds discovered were salicin (1), isolated

from the bark of the white willow, Salix alba, in 1825-26. It was

subsequently converted to salicylic acid (2) via hydrolysis and oxidation,

and proved as successful as an antipyretic (fever reducing) that it was

actively manufactured and used worldwide. The use of salicylic acid,

however, often led to severe gastrointestinal toxicity. This was

13

overcome when Felix Hoffmann of Bayer Company converted salicylic

acid into acetylsalicylic acid (3,ASA) via acetylation. Bayer then began

marketing ASA under the trade name aspirin in 1899. Today, aspirin is

still the most widely used analgesic and antipyretic drug in the world.

O

OOH

HH

OH

OH

HHH

OH

OH OH

OH O

OH

OAc O

Salicin(1) Salicylic Acid (2) Acetyl Salicylic Acid (3)

Fig. No. 1. Precursor and Derivative of Salicylic Acid.

Many of aqueous, ethanolic, distilled, condensed or dried extracts do

indeed have a real and beneficial effect, and a study of ethno botany

can give clues as to which plants might be worth studying in more

detail. Rhubarb root has been used as a purgative for many centuries.

In China, it was called "The General" because of its "galloping charge"

and was only used for one or two doses unless processed to reduce its

purgative qualities. (Bulk laxatives would follow or be used on weaker

patients according to the complex laxative protocols of the medical

system.) The most significant chemicals in rhubarb root are

anthraquinones, which were used as the lead compounds in the design

of the laxative dantron.

The extensive records of Chinese medicine about response to

Artemisia preparations for malaria also provided the clue to the novel

14

antimalarial drug, Artemisinin (4). The therapeutic properties of the

opium poppy (active principle morphine) were known in Ancient Egypt,

were those of the solanaceae plants in ancient Greece (active principles

atropine and hyoscine).

O

CH3

H

CH3H

CH3

H

OO

Fig.No.2. Artemisinin ( 4)

The snakeroot plant was well regarded in India (active principle

reserpine), and herbalists in medieval England used extracts from the

willow tree(salicin) and foxglove (active principle digitalis - a mixture of

compounds such as digitoxin, digitonin, digitalin). The Aztec and Mayan

cultures of Mesoamerica used extracts from a variety of bushes and

trees including the ipecacuanha root (active principle emetine), coca

bush (active principle cocaine ,5), and cinchona bark (active principle

quinine) (James J, Knittel, 2008).

O

N

CH3

OOCH3

O

N

NOH

H3CO

CH2

Cocaine(5) Quinine(6)

Fig.No.3. Cocaine and Quinine

15

Some of the natural drugs may not have potency to treat diseases. So

there the concept of semi synthetic chemistry araised and for the first

time in 1869 Brown and Fraser while working on relationship between

molecular structure and biological activity, identified that N-Methyl

morphine and N-Methylatropin are muscle relaxants instead their parent

natural compounds morphine is an analgesic and atropine is an

mydriatic agent. Then after working on the semi synthetic compounds

increased and further investigations were carried out ( El- Shemy HA et

al., 2003).

Not all natural products can be fully synthesized and many natural

products have very complex structures that are too difficult and

expensive to synthesize on an industrial scale. These include drugs

such as penicillin, morphine and paclitaxel (Taxol). Such compounds

can only be harvested from their natural source - a process which can

be tedious, time consuming, and expensive, as well as being wasteful

on the natural resource. For example, one yew tree would have to be

cut down to extract enough paclitaxel from its bark for a single dose.

Furthermore, the number of structural analogues that can be obtained

from harvesting is severely limited (Friedrich Wohler et al., 1828).

A further problem is that isolates often work differently than the

original natural products which have synergies and may combine, say,

antimicrobial compounds with compounds that stimulate various

16

pathways of the immune system. Many higher plants contain novel

metabolites with antimicrobial and antiviral properties. However, in the

developed world almost all clinically used chemotherapeutics have been

produced by in vitro chemical synthesis. Exceptions, like taxol and

vincristine, were structurally complex metabolites that were difficult to

synthesize in vitro. Many non-naturals, synthetic drugs produce severe

side effects that were not acceptable except as treatments of last resort

for terminal diseases such as cancer. The metabolites discovered in

medicinal plants may avoid the side effect of synthetic drugs, because

they must accumulate within living cells ( Merrilield RB, 1975).

Many higher plants contain novel metabolites with antimicrobial

and antiviral properties. However, in the developed world almost all

clinically used chemotherapeutics have been produced by in vitro

chemical synthesis. Exceptions, like Taxol and Vincristine, were

structurally complex metabolites that were difficult to synthesize in vitro.

Many non-natural, synthetic drugs produce severe side effects that

were not acceptable except as treatments of last resort for terminal

diseases such as cancer. The metabolites discovered in medicinal

plants may avoid the side effect of synthetic drugs, because they must

accumulate within living cells.

17

NH

N

OH C H 3

N

N C H 3

COOMe

COOMe

OH

CHOMeO H

Fig. No.4. Vincristine (7)

The antimicrobial activity of plants can sometimes be attributed to

the low molecular weight phenolic compounds that are present within

them.

Semi synthetic procedures can sometimes get around these problems.

This often involves harvesting a biosynthetic intermediate from the

natural source, rather than the final (lead) compound itself. The

intermediate could then be converted to the final product by

conventional synthesis. This approach can have two advantages. First,

the intermediate may be more easily extracted in higher yield than the

final product itself. Second, it may allow the possibility of synthesizing

analogues of the final product. The semi synthetic penicillins are an

illustration of this approach. Another recent example is that of paclitaxel.

It is manufactured by extracting 10-deacetylbaccatin III from the needles

of the yew tree, then carrying out a four-stage synthesis (Muthuswamy

Raghunathan, 2009).

18

The main advantage of the semi-synthetic drugs is they can act

with higher potency than their original natural compounds and also

helps in overcoming the problems of the natural products such as onset

of action , potency, site of action, etc,.

Natural product medicines have come from various source materials

including terrestrial plants, terrestrial microorganisms, marine

organisms, and terrestrial vertebrates and invertebrates (Newman DJ,

2000). The importance of natural products in modern medicine has

been discussed in recent reviews and reports (Jones WP, 2006). The

value of natural products in this regard can be assessed using 3 criteria:

(1) The rate of introduction of new chemical entities of wide structural

diversity, including serving as templates for semisynthetic and total

synthetic modification.

(2) The number of diseases treated or prevented by these substances.

(3) Their frequency of use in the treatment of disease.

An analysis of the origin of the drugs developed between 1981 and

2002 showed that natural products or natural product- derived drugs

comprised 28% of all new chemical entities (NCEs) launched onto the

market (Newman DJ, 2003). In addition, 24% of these NCEs were

synthetic or natural mimic compounds, based on the study of

pharmacophores related to natural products.11 This combined

percentage (52% of all NCEs) suggests that natural products are

19

important sources for new drugs and are also good lead compounds

suitable for further modification during drug development. The large

proportion of natural products in drug discovery has stemmed from the

diverse structures and the intricate carbon skeletons of natural

products. Since secondary metabolites from natural sources have been

elaborated within living systems, they are often perceived as showing

more “drug-likeness and biological friendliness than totally synthetic

molecules” (Koehn FE et al., 2005) making them good candidates for

further drug development (Drahl C, 2005).

Scrutiny of medical indications by source of compounds has

demonstrated that natural products and related drugs are used to treat

87% of all categorized human diseases (48/55), including as

antibacterial, anticancer, anticoagulant, antiparasitic, and

immunosuppressant agents, among others. There was no introduction

of any natural products or related drugs for 7 drug categories

(anesthetic, antianginal, anti histamine, anxiolytic, chelator and antidote,

diuretic, and hypnotic) during 1981 to 2002.2 In the case of antibacterial

agents, natural products have made significant contributions as either

direct treatments or templates for synthetic modification. Of the 90

drugs of that type that became commercially available in the United

States or were approved worldwide from 1982 to 2002, 79% can be

traced to a natural product origin.

20

Frequency of use of natural products in the treatment or

prevention of disease can be measured by the number or economic

value of prescriptions, from which the extent of preference and/or

effectiveness of drugs can be estimated indirectly. According to a study

by Grifo and colleagues (Friedrrich Wohler, 1828), 84 of a

representative 150 prescription drugs in the United States fell into the

category of natural products and related drugs. They were prescribed

predominantly as anti-allergy/ pulmonary/respiratory agents, analgesics,

cardiovascular drugs, and for infectious diseases. Another study found

that natural products or related substances accounted for 40%, 24%,

and 26%, respectively, of the top 35 worldwide ethical drug sales from

2000, 2001, and 2002. of these natural product-based drugs, paclitaxel

(ranked at 25 in 2000), a plant-derived anticancer drug, had sales of

$1.6 billion in 2000.10,11 The sales of categories of plant-derived

cancer chemotherapeutic agents were responsible for approximately

one third of the total anticancer drug sales worldwide, or just under $3

billion dollars in 2002; namely, the taxanes, paclitaxel and docetaxel,

and the camptothecin derivatives, irinotecan and topotecan (Thayer A et

al., 2003).

New drugs derived from natural sources launched in the 6-year

period from 2000 to 2005, and drug candidates from natural sources in

clinical trials during the same time period arranged according to their

21

origin (terrestrial plants, terrestrial microorganisms, marine organisms,

and other natural sources). For drug candidates in clinical trials (Butler

MS, 2005), only examples of new chemical templates of potential

cancer chemotherapeutic drugs will be mentioned.

Drug Discovery from Terrestrial Plants:

Terrestrial plants, especially higher plants, have a long history of

use in the treatment of human diseases. Several well-known species,

including Licorice (Glycyrrhiza glabra), Myrrh (Commiphora species),

and Poppy capsule latex (Papaver somniferum), were referred to by the

first known written record on clay tablets from Mesopotamia in 2600 BC,

and these plants are still in use today for the treatment of various

diseases as ingredients of official drugs or herbal preparations used in

systems of traditional medicine.11 Furthermore, morphine, codeine,

noscapine (narcotine), and papaverine isolated from P. somniferum

were developed as single chemical drugs and are still clinically used.

Hemisuccinate carbenoxolone sodium, a semi-synthetic derivative of

glycyrrhetic acid found in licorice, is prescribed for the treatment of

gastric and duodenal ulcers in various countries (Dewick PM, 2002).

22

Fig. No. 5. New drugs from terrestrial plants

Historical experiences with plants as therapeutic tools have

helped to introduce single chemical entities in modern medicine. Plants,

especially those with ethno- pharmacological uses, have been the

primary sources of medicines for early drug discovery. In fact, a recent

analysis by Fabricant and Farnsworth showed that the uses of 80% of

122 plant-derived drugs were related to their original

ethnopharmacological purposes (Fabricant DS et al., 2001). Current

drug discovery from terrestrial plants has mainly relied on bioactivity-

23

guided isolation methods, which, for example, have led to discoveries of

the important anticancer agents, paclitaxel from Taxus brevifolia and

camptothecin from Camptotheca acuminate (Kinghorn AD, 1994). Other

NCEs discovered or modified from terrestrial plants between 2000 –

2005 are summarized in Fig.No.5.

Approved Drugs:

Apomorphine hydrochloride(8), a short-acting dopamine D1 and

D 2 receptor agonist, is a potent dopamine receptor agonist used to

treat Parkinson ’s disease, a chronic neurodegenerative disease caused

by the loss of pigmented mesostriatal dopaminergic neurons linking the

substantia nigra (pars compacta) to the neostriatum (caudate nucleus

and putamen). Apomorphine is a derivative of morphine isolated from

poppy (Papaver somniferum). Subcutaneous apomorphine is currently

used for the management of sudden, unexpected and refractory

levodopa induced off states in fluctuating Parkinson’s disease (Deleu D

et al., 2004).

Tiotropium bromide (9) has been approved by the United States

Food and Drug Administration (FDA) for the treatment of bronchospasm

associated with (COPD). Tiotropium, a derivative of atropine from

Atropa belladonna (Solanaceae) and related tropane alkaloids from

other solanaceous plants, is a potent reversible nonselective inhibitor of

muscarinic receptors. Tiotropium is structurally analogous to

24

ipratropium, a commonly prescribed drug for COPD, but has shown

longer-lasting effects (Koumis T et al., 2005).

Nitisinone (10) is a derivative of leptospermone, an important new

class of herbicides from the bottlebrush plant (Callistemon citrinus), and

exerts an inhibitory effect for p -hydroxyphenylpyruvate dioxygenase

(HPPD) involved in plastoquinone synthesis (Hall MG, 2001). This drug

has been used successfully as a treatment of hereditary tyrosinaemia

type 1 (HT-1), a severe inherited disease of humans caused by a

deficiency of fumaryl acetoacetate hydrolase (FAH), leading to

accumulation of fumaryl and maleyl acetoacetate, and progressive liver

and kidney damage (Mitcnell G, 2001).

Galantamine hydrobromide (11) is an Amaryllidaceae alkaloid

obtained from Galanthus nivalis that has been used traditionally in

Bulgaria and Turkey for neurological conditions (Howes M-JR, 2003)

(Heinrich M, 2004), and was launched onto the market as a selective

acetylcholinesterase inhibitor for Alzheimer’s disease treatment, slowing

the process of neurological degeneration by inhibiting

acetylcholinesterase as well as binding to and modulating the nicotinic

acetylcholine receptor.

Arteether (11), an antimalarial agent, has been developed from

artemisinin, a sesquiterpene lactone isolated from Artemisia annua

(Asteraceae), a plant used in traditional Chinese medicine as a remedy

25

for chills and fevers. Other derivatives of artemisinin are in various

stages of clinical development as antimalarial drugs in Europe (Van

agtmael et al., MA, 1999).

Plant-derived Compounds Currently in Clinical Trials:

Plant derived secondary metabolites, several new chemical

entities (Fig.No.6) are undergoing clinical trials including four that are

derivatives of known anticancer drugs (camptothecin, paclitaxel,

epipodophyllotoxin, and vinblastine).In addition, combretastatin A4,

isolated from the South African medicinal tree, Combretum caffrum

(Combretaceae), was derivatized to combretastatin A4 phosphate (12)

and AVE-8062 ( 13) (Cirla A, 2003, Pinney KG 2005). These analogs

bind to tubulin leading to morphological changes and then disrupt tumor

vasculature, and are in phase II trials (West CML et al., 2004).

26

Fig.No.6. Plant-derived drug candidates.

Homoharringtonine (14), a cephalotaxus alkaloid from the tree,

Cephalotaxus harringtonia found in mainland China (Powell RG, 1970),

is an inhibitor of protein synthesis and is reported to have activity

against hematologic malignancies (Kantarjian HM et al., 2001). Ingenol

3-Oangelate

(15), an analog of the polyhydroxy diterpenoid, ingenol, which was

originally obtained from Euphorbia peplus (known as “ petty spurge ” in

England or “ radium weed ” in Australia), is a potential topical

27

chemotherapeutic agent for skin cancer and exhibits its action through

activation of protein kinase C (Kedei N, 2004). Phenoxodiol (16), a

synthetic analog of daidzein, a well known isoflavone from soybean

(Glycine max), is being developed as a therapy for cervical, ovarian,

prostate, renal, and vaginal cancers, and induces apoptosis through

inhibition of anti-apoptotic proteins including XIAP and FLIP. (Kamsteeg

M, 2003)Phenoxodiol is currently undergoing clinical studies in the

United States and Australia (Constantinou AI, 2003).

Protopanaxadiol (17), a derivative of a triterpene aglycone of

several saponins from ginseng (Panax ginseng), exhibits its apoptotic

effects on cancer cells through various signaling pathways, and is also

reported to be cytotoxic against multidrug resistant tumors (Shibata S,

1963). Triptolide, a diterpene triepoxide, was isolated from Tripterygium

wilfordii, and has been used for autoimmune and inflammatory diseases

in the People’s Republic of China (Kiviharju TM, et al., 2002). PG490 –

88 (18), 14-succinyl triptolide sodium salt), a semisynthetic analog of

triptolide, exerts antiproliferative and proapoptotic activities on primary

human prostatic epithelial cells as well as tumor regression of colon and

lung xenografts (Fidler JM et al., 2003).

Thus an attempt was done in this study to derive some semi

synthetic derivatives of well known compounds like citral, vanillin,

carvone and camphor.

28

Citral:Citral (C10H16O), is present in the oils of several plants, including

lemon myrtle (90-98%), Litsea citrata (90%), Litsea cubeba (70-85%),

lemongrass (65-85%), lemon tea-tree (70-80%), Ocimum gratissimum

(66.5%), Lindera citriodora (about 65%), Calypranthes parriculata

(about 62%), petitgrain (36%), lemon verbena (30-35%), lemon ironbark

(26%), lemon balm (11%), lime (6-9%), lemon (2-5%), and orange.

Citral also called 3,7-dimethyl-2,6-octadienal, a pale yellow liquid, with a

strong lemon odour, that occurs in the essential oils of plants. It is

insoluble in water but soluble in ethanol (ethyl alcohol), diethyl ether,

and mineral oil. It is used in perfumes and flavourings and in the

manufacture of other chemicals. Chemically, citral is a mixture of two

aldehydes that have the same molecular formula but different

structures. Citral is present as two isomers citral α (31, Geranial), and

Citral β ( 32, Neral).

Geranial(31) Neral (32)

Fig.No.12. Isomers of Citral

29

Lemongrass oil contains 70–80 percent citral, which may be

isolated by distillation. Other natural sources include the oils of verbena

and citronella. Citral can be synthesized from myrcene

Uses:Geranial (31) has a strong lemon odor. Neral (32) has a lemon

odor that is less intense, but sweeter. Citral is therefore an aroma

compound used in perfumery for its citrus effect. Citral is also used as a

flavor and for fortifying lemon oil. It also has strong anti- microbial

qualities140 and pheromonal effects in insects. Further it is used

topically as analgesic, and to relieve nasal obstructions. 141 Citral is

used in the synthesis of vitamin A, ionone, and methylionone, and to

mask the smell of smoke.

Vanillin:

Vanilla beans Vanilla plantifolia

30

Vanilla fragrans Dried Vanilla fruits

Fig.No.9. Pictorial representation of various parts of Vanillin

Vanillin is a single molecule, 4-hydroxy-3-methoxybenzaldehyde,

is a white crystalline solid, which melts at 81°C. Vanillin was first

isolated from vanilla pods family (Orchidaceae) by Nicholas-Theodore

Gobley in 1858. The biosynthetic pathway of vanillin starts with

phenylalanine. 90% of vanillin currently in use is synthetically produced

(nature identical) from lignin, eugenol or guaiacol.

Vanillin has generally recognized as safe status and is used as a

flavoring/ aroma compound in foods and fragrance industries. Currently,

approximately 50% of the worldwide production of synthetic vanillin is

used as an intermediate in the chemical and pharmaceutical industries

for the production of herbicides, antifoaming agents or drugs such as

papaverine, l-dopa, l-methyldopa and the antimicrobial agent,

trimethoprim. Moreover, vanillin exhibits strong antimicrobial properties

with activity demonstrated against a number of yeast and mould strains

in laboratory media, fruit-based agar systems, fruit purees and fruit

31

juices. However, no reports have yet detailed the mode of action of

vanillin inhibition. Vanillin was found to posses various pharmacological

activities like antimicrobial, antifungal, analgesic activity etc, thus vanillin

was chosen for the study.

Carvone:

Carvone (29) is a member of a family of chemicals called

terpenoids Carvone is found naturally in many essential oils, but is most

abundant in the oils from seeds of caraway (Carum carvi) and dill.

Fig.no. 10 Carvone (29)

Carvone forms two mirror image forms or enantiomers: S-(+)-carvone

smells like caraway. Its mirror image, R-(–)-carvone, smells like

spearmint. The fact that the two enantiomers are perceived as smelling

differently is proof that olfactory receptors must contain chiral groups,

allowing them to respond more strongly to one enantiomer than to the

other. Not all enantiomers have distinguishable odors. The two forms

are also referred to by older names, with dextro-, d- referring to S-

carvone, and laevo-, l- referring to R-carvone.

32

S-(+)-Carvone is the principal constituent (50-70%) of the oil from

caraway seeds (Carum carvi ) which is produced on a scale of about 10

tonnes per year It also occurs to the extent of about 40-60% in dill seed

oil (from Anethum graveolens), and also in mandarin orange peel oil. R-

(–)-Carvone is present at levels greater than 51% in spearmint oil

(Mentha spicata), which is produced on a scale of around 1500 tonnes

annually. This isomer also occurs in kuromoji oil. Some oils, like

gingergrass oil, contain a mixture of both enantiomers. Many other

natural oils, for example peppermint oil, contain lower concentrations of

carvones (Hernan Grarcia, 1999).

Uses:

Carvone are used in the food and flavor industry .Carvone is also

used for air freshening products and, like many essential oils, oils

containing carvone are used in aromatherapy and alternative medicine.

Further the compound was found to be used as analgesics,

antimicrobial agent, antifungal agent, and also relieves many respiratory

tract infections.

Camphor:

Camphor (30) is a waxy, white or transparent solid with a strong,

aromatic odor. It is a terpenoid with the chemical formula C10H16O. It is

found in wood of the camphor laurel (Cinnamomum camphora), a large

evergreen tree found in Asia (particularly in Borneo and Taiwan) and

33

also of Dryobalanops aromatica, a giant of the Bornean forests. It also

occurs in some other related trees in the laurel family, notably Ocotea

usambarensis. It can also be synthetically produced from oil of

turpentine.

O

CH3

Fig.No.11. Camphor (30)

Camphor is widely used in Hindu religious ceremonies. Hindus

worship a holy flame by burning camphor, which forms an important

part of many religious ceremonies. Camphor is used in the

Mahashivratri celebrations of Shiva, the Hindu god of destruction and

(re)creation. As a natural pitch substance, it burns cool without leaving

an ash residue, which symbolizes consciousness. Of late, most temples

in southern India have stopped lighting camphor in the main Sanctum

Sanctorium due to heavy deposits of carbon; however, open areas do

use camphor. It also acts as rubifacient, counter irritant for inflamed

joints, sprains, rheumatic and other inflamed conditions like cold. It may

be used as mild nasopharyngeal decongestant. It is also found in

clarifying masks used for skin.

34

In ancient and medieval Europe camphor was used as an

ingredient in sweets. It was also used as a flavoring in confections

resembling ice cream in China during the Tang dynasty (AD 618–907).

It was used in a wide variety of both savory and sweet dishes in

medieval Arabic language cookbooks, compiled in the 10th century and

An Anonymous Andalusian Cookbook of the 13th Century. And it

appears in sweet and savory dishes in a book written in the late 15th

century for the sultans of Mandu, the Ni'matnama. Currently, camphor is

used as a flavoring, mostly for sweets, in Asia. It is widely used in

cooking, mainly for dessert dishes, in India where it is known as Kachha

(raw/crude) karpooram ("crude camphor" in Tamil and is available in

Indian grocery stores where it is labeled as "Edible Camphor". It is also

used as preservatives, irritant, etc (Hirota N et al., 1967).

The structural activity relationship (SAR) is the relationship

between the chemical or 3D structure of a molecule and its biological

activity. The analysis of SAR enables the determination of the chemical

groups responsible for evoking a target biological effect in the organism.

This allows modification of the effect or the potency of a bioactive

compound by changing its chemical structure. Medicinal chemists use

the techniques of chemical synthesis to insert new chemical groups into

the biomedical compound and test the modifications for their biological

effects.

35

Antioxidant Activity (Blois MS, 1958)

A free radical exists with one or more unpaired electron in atomic

or molecular orbital. Free radicals are generally unstable, highly

reactive, and energized molecules. Normally it steals an electron from

weakly bonded structures. The molecule, which loses an electron, also

becomes a free radical giving rise to a self-perpetuating chain system.

Free radical often attack DNA, protein molecules, enzymes and cells

leading to alterations in genetic material and cell proliferation

Reactive oxygen species in biological systems are related to free

radicals, even though there are non-radical compounds in reactive

oxygen species such as singlet oxygen and hydrogen peroxide 242.

Reactive Species

Reactive Nitrogen Species Reactive Oxygen Species

●Nitric Oxide

●Nitric Dioxide Oxygen centered radical Oxygen Centered(NO2˙) non-radical

●Superoxide anion(˙O2). ●Hydrogen peroxide●Hydroxyl radical (˙OH) ●Singlet oxygen (O2)●alkoxyl radical (RO˙)●peroxyl radical (ROO˙)

Fig.No.76. A broad classification of reactive oxygen species.

Clinical studies reported that reactive oxygen species are

associated with many age related degenerative diseases, including

36

atherosclerosis, cancers, trauma, stroke, asthma, hyperoxia, arthritis,

heart attack, dermatitis, retinal damage, hepatitis and liver injury.

Sources of free radicals

a) Prooxidative enzymes such as lipoxygenase can generate free

radicals 45. Lipoxygenase can react with free forms of fatty acids,

which can be released from glycerides by membrane bound

phospholipase A2.

b) Environmental sources, such as ultraviolet (UV) irradiation,

ionizing irradiation and pollutants also produce reactive oxygen

species.

c) Injured cells and tissues can stimulate the generation of free

radicals.

d) Reactive oxygen species can be formed in foods through lipid

oxidation and photosensitizers exposed to light.

e) Non enzymatic lipid oxidation requires the presence of free forms

of bivalent metal ions such as copper and iron, which are not

common for healthy adults.

Defense systems against free radicals

The human body although continuously produces free radicals, it

possess several defense systems, which are constituted of enzymes

and radical scavengers. These are called “first – line antioxidant

defense system”, but are not completely efficient because almost all

37

components of living bodies, tissues, cells and genes undergo free

radical destructions.

The “second line defense systems” are constituted of repair

systems of bio molecules which are damaged by the attack of free

radicals. The functions of these enzymes involved in repairing directly

damaged biomolecules such as lipids, polysaccharides, proteins,

nucleic acids, etc., or in eliminating oxidized compounds are illustrated

below.

Antioxidants

Non-enzymatic Enzymatic

Fig.No.77. Classification of Antioxidants

Antioxidants are compounds which act as inhibitors of the

oxidative process. They are quite large in number and diverse in

Natural Compounds Synthetic Compounds

●Vitamin C ●Melatonin ●Superoxide

dismutase(SOD)

●Vitamin E ●Dihydroepiandrosterone ●Peroxidase

●β-carotene (DHEA) ●Catalase

●Uric acid ●Glutathionedisufide

reductase

●Ubiquinone ●Glutathione S transferase

●Methionine sulfoxide

Reductase

38

nature, which opposes the process of oxidation largely by neutralizing

free radicals. Antioxidants at relatively small concentration have the

potential to inhibit the oxidants chain reactions. Antioxidants are also of

paramount importance in pharmaceutical formulations because there

are innumerate medicinal agents possessing diverse chemical functions

and are known to undergo oxidative decomposition.

Reactive Oxygen Species (ROS)

Superoxide anion (.O2-)

It is a reduced form of molecular oxygen created by receiving one

electron. Superoxide anion is an initial free radical from mitochondrial

electron transport systems.

The superoxide anion plays an important role in the formation of

other reactive oxygen species such as hydrogen peroxide, hydroxyl

radical or singlet oxygen. The superoxide anion can react with nitric

oxide (NO˙) and form peroxynitrite (ONOO-) which can generate toxic

compounds such as hydroxyl radical and nitric dioxide.

(ONOO-+H+ OH +˙NO2).

Hydroxyl radical (.OH)

e- e- e- e-O2

H+ HO˙2 H+ H+

H2O2˙OH H2O

39

Hydroxyl radical is the most reactive free radical and can be

formed from superoxide anion and hydrogen peroxide in the presence

of metal ions such as copper or iron.

˙OH + OH- + O2 O2- + H2O2

In general, aromatic compounds or compounds with carbon-

carbon multiple bonds undergo addition reaction with hydroxyl radicals

resulting in the hydroxylated free radicals. In saturated compounds, a

hydroxyl radical abstracts a hydrogen atom from the weakest C-H bond

to yield a free radical. The resulting radicals can react with oxygen and

generate other free radicals.

Hydroxyl radicals react with lipid, polypeptides, proteins and DNA,

especially thiamine and guanosine. Hydroxyl radicals also add readily to

double bonds. When a hydroxyl radical reacts with aromatic

compounds, it can add on across a double bond, resulting in

hydroxycyclohexadienyl radical. The resulting radical can undergo

further reactions, such as reaction with oxygen, to give peroxyl radical

or decompose to phenoxyl-type radicals by water elimination.

Hydrogen peroxide (H2O2)

Hydrogen peroxide can be generated through a dismutation

reaction from superoxide anion by superoxide dismutase. Enzymes

such as amino acid oxidase and xanthine oxidase also produce

hydrogen peroxide from superoxide anion.

40

It is the least reactive molecule among reactive oxygen species and is

stable under physiological pH and temperature in the absence of metal

ions. It can generate the hydroxyl radical in the presence of metal ions

and superoxide anion

˙O2- +H2O2˙OH+OH-+O2

Singlet Oxygen

Singlet oxygen is a non - radical and excited status. Singlet

oxygen can be formed from hydrogen peroxide, which reacts with

superoxide anion or with HOCl or chloramines in cells and tissues.

Compared with other reactive oxygen species, singlet oxygen is rather

mild and non-toxic for mammalian tissue. However, singlet oxygen has

been known to be involved in cholesterol oxidation.

Peroxyl and alkoxy radicals.

Peroxyl radicals (ROO˙) are formed by a direct reaction of oxygen

with alkyl radical (R˙), for example the reaction between lipid radicals

and oxygen. Decomposition of alkyl peroxide (ROOH) also results in

peroxyl (ROO˙) and alkoxyl (RO˙) radicals. Irradiation of UV light or the

presence of transition metal ions can cause homolysis of peroxides to

produce peroxyl and alkoxyl radicals.

ROOH ROO˙ + H˙

ROOH + Fe3+ ROO˙ + Fe 2+ + H+

Reactive Nitrogen Species (RNS)

41

a. Nitric oxide (NO˙)

Nitric Oxide (NO˙) is a free radical with a single unpaired

electron. Nitric oxide is formed from L-arginine by NO synthase. Nitric

oxide itself is not a very reactive free radical, but the overproduction of

NO is involved in ischemia reperfusion and neurodegenerative and

chronic inflammatory diseases such as rheumatoid arthritis and

inflammatory bowel disease. Nitric oxide exposed in human blood

plasma, can deplete the concentration of ascorbic acid and uric acid

and initiate lipid peroxidation.

b. Nitrogen dioxide (NO2˙)

Nitrogen dioxide (NO2˙) is formed from the reaction of peroxyl

radical and NO, polluted air and smoking. Nitrogen dioxide adds to

double bonds and abstract liable hydrogen atoms initiating lipid

peroxidation and production of free radicals.

c. Peroxynitrite

Reaction of NO and superoxide anion can generate peroxynitrite

˙O2 - + NO˙ OONO –

Peroxynitrite is a cytotoxic species and cause tissue injury and oxidizes

low-density lipoprotein (LDL). Peroxynitrite appears to be an important

tissue-damaging species generated at the sites of inflammation and is

involved in various neurodegenerative disorders and several kidney

diseases.

42

In the present study, the antioxidant activity involved using three

standard methods. They are

Scavenging of ABTS radical cation

Scavenging of DPPH

Scavenging of Nitric oxide radical

43

REVIEW OF LITERATURE

Citral:

Annamaria Buschini et al., synthesized some new metal-

complexes with thio-semicarbazones derived from natural aldehydes

which showed peculiar biological activities. In particular, a nickel

complex [Ni(S-tcitr)2] (S-tcitr = S-citronellal thiosemicarbazonate) was

observed to induce an antiproliferative effect on U937, a human

histiocytic lymphoma cell line, at low concentrations (IC50 = 14.4 μM)

and suggest that [Ni(S-tcitr)2] could be a good model for the synthesis of

new metal thiosemicarbazones with specific biological activity

(Annamaria Buschini et al., 2009).

United States Patent 4547361 studied that improved stability

against discoloration upon aging comprising an unsaturated aldehyde

flavoring agent selected from the group consisting of cinnamic aldehyde

and citral and an effective amount in excess of 5% and preferably about

10-45% of a color stabilizer.

The Volatile Oils Vol1", by E. Gildemeister study revealed that

derivatives of citral with hydroxylamine, phenyl hydrazine, and ammonia

are liquid; they cannot be utilized for the characterization of citral. When

dehydrated with the aid of acetic acid anhydride, the oxime is converted

into the nitrile of geranic acid. When acted upon by semicarbazide, citral

yields several well crystallizable semicarbazones. Citrylidene cyanacetic

44

acid, C9H15CHC(CN)COOH, obtained bycondensation of citral with

cyanacetic acid, is another derivative melting at 122° that crystallizes

well and hence can be used for the identification of citral. Condensing

15.2 g. citral and 20 g. of acetyl acetone at room temperature with the

aid of piper dine obtained in light yellow wart-like crystals that melt at 46

to 48°). In small amounts of citral or other aldehydes, a-methyl-/i-

naphtho-cinchonic acid is formed by the interaction of pyrotartaric acid

and B-naphthylamine (Jildemeister E et al., 1994).

US Patent 7309795 study revealed that citral derivatives that

maintain the fragrance characteristics and lemony flavor of citral, while

lowering the allergic properties, providing a longer shelf-life than citral,

and/or increasing the odor intensity relative to citral are disclosed.

In one embodiment, the citral derivatives are prepared by

replacing one or more double bonds in the parent molecule with a

cyclopropyl group, which can be unsubstituted, or substituted with one

or two lower alkyl, preferably methyl groups. The alkyl groups can

optionally be substituted, for example, with electron donating groups,

electron withdrawing groups, groups which increase the hydrophilicity or

hydrophobocity, and in another embodiment, the derivatives are

prepared by replacing one or more aldehyde groups in citral with a nit

rile, methyl ether or acetal group. The acetal groups can provide the

45

compounds with a long lasting flavor or fragrance, where the acetals

slowly hydrolyze to provide the parent aldehyde compounds.

Hierro i. et al., Studied that In vivo larvicidal activity of monoterpenic

derivatives from aromatic plants against L3 larvae of Anisakis simplex.

The aldehydic monoterpene citral and the alcoholic citronellol, when

they are administered together to the larvae of the nematode at the

concentration of 46.90mg/0.5ml in olive oil, achieve 85.90% and

67.53% dead L3, respectively, and also stop rats suffering

gastrointestinal hemorrhages produced by the larvae.

Olga I. Yarovaya et al., study revealed 6, 7-epoxides of citral are

isomerization reactions, resulting in keto-aldehydes, substituted

tetrahydrofurans and dicyclic esters. Dicyclic ketals 4,8,8-trimethyl-7,9-

dioxabicyclo[4.2.1]non-4-ene and 2,2,6-trimethyl-3,9- di-oxa-bicyclo

[4.2.1]non-4-ene have obtained are in fact the structural counterparts of

the known pheromons products of acetal type have pleasant odour and

can be investigated as odorous substances (olga I Yaroveya et al.,

2002).

Xiao Xiao Jin et al., studied that the Schiff base of chitosan was

synthesized by the reaction of chitosan with citral working under high-

intensity ultrasound. The antimicrobial activities of chitosan and the

Schiff base of chitosan were investigated against E. coli, L aureus, and

46

A. Niger. The results indicate that the Schiff base of chitosan has better

antimicrobial activities than chitosan.

Grace O. Onawunmi, found that Citral showed appreciable

antimicrobial activity against Gram-positive and Gram-negative bacteria

as well as fungi. Media composition and inoculum size had no

observable effect on activity but alkaline pH increased citral activity. The

growth rates of Escherichia coli cultures were reduced at concentrations

of citral ≥0·01% v/v while concentrations ≥0·03% v/v produced rapid

reduction in viable cells followed by limited regrowth. In a non-growth

medium, 0·08% and 0·1% v/v showed rapid bactericidal effects. Citral

may therefore be of preservative use in addition to its other uses in the

food, soap and cosmetic industries.

Grace O. Onawunmi, et al., found that Cymbopogon citratus

(DC.) Stapf, commonly known as lemon grass and used, over many

years, for medicinal purposes in West Africa, produces a volatile oil on

steam extraction of its leaves. While the α-citral (geranial) and β-citral

(neral) components individually elicit antibacterial action on gram-

negative and gram-positive organisms, the third component, myrcene,

did not show observable antibacterial activity on its own.

Sang wan, Naresh. K et al., Nematicidal activity of the essential

oils of three Cymbopogon grasses (C. martini var. motia, C. flexuous

and C. winterianus) and their major constituents, geraniol, citral,

47

citronellol and citronellal was determined with second stage juveniles of

four nematodes, seed-gall nematode (Anguina tritici), citrus nematode

(Tylenchulus semipenetrans), root-knot nematode (Meloidogyne

javanica) and cereal cyst-nematode (Heterodera avenae). The essential

oils and their constituents were found to be nematicidal and their

activities (Sang Wang, 1985).

Hayes J. and Markovic B. Found that antimicrobial and

toxicological properties of the Australian essential oil, lemon myrtle,

(Backhousia citriodora) were investigated. Lemon myrtle oil was shown

to possess significant antimicrobial activity against the organisms

Staphylococcus aureus, Escherichia coli, Pseudomonas aeruginosa,

Candida albicans, methicillin-resistant S. aureus (MRSA), Aspergillus

Niger, Klebsiella pneumoniae and Propionibacterium acnes comparable

to its major component-citral.

Amna A. Saddiq and Suzan A. Khayyat found that 6, 7-Citral-

epoxy derivative (a mixture of E and Z isomers with respect to the

C2 = C3 double bond) could be react with DNA base producing a major

adduct. Antifungal and antibacterial studies were carried out on citral

and citral-epoxide. Studies on the antifungal especially Penicillium

italicum and Rhizopus stolonifer showed that citral and citral-epoxide

have good antibacterial action. Antimicrobial studies of P. italicum and

R. stolonifer explained also that citral and citral-epoxide have good

48

antimicrobial activity. Citral epoxide shows high activity against the

growth of bacteria methicillin resistant Staphylococcus aureus (MRSA)

and fungi comparing by citral(Amna A et al., 2005).

Nativ dudai et al., found that Lemongrasses (Cymbopogonspp,

Poaceae) are a group of commercially important C4tropical grasses. To

specifically locate the sites of citral accumulation in lemongrass we

employed Schiff's reagent, which reacts with aldehydes and gives a

purple-red coloration with citral and suggested that citral accumulation

takes place in individual oil cells within the leaf tissues (Nativ Dudai et

al., 1998).

Renu Sharma, Santosh K. et al., reported that the ligand cis-3, 7-

dimethyl-2, 6-octadiensemicarbazone Complexes yields: [ML2 Cl2] and

[ML2 Cl2] Cl type complexes, where M = CrIII, MnII, FeIII, CoII, NiII, CuII,

ZnII, CdII and HgII. All the newly synthesized metal complexes, as well as

the ligand, were screened for their antibacterial activity. All the

complexes exhibit strong inhibitory action against Gram (+) bacteria

Staphylococcus aureus and Gram (−) bacteria.

Francesca Di Renzo et al., found that the clinically used

antimycotic fluconazole (flu co) is teratogenic in rodents. Citral is a

retinoic acid synthesis inhibitor. The co-exposure to fluco + citral was

significantly effective in reducing bronchial arch and cranial nerve

49

defects; supporting the hypothesis that citral balances the fluco-induced

RA concentration increase.

P.A. Paranagama et al., found that Aspergillus flavus Link. Was

isolated from stored rice and identified as an aflatoxigenic strain.

Lemongrass oil was tested against A. flavus and the test oil was fungi

static and fungicidal against the test pathogen at 0·6 and 1·0 mg ml−1,

respectively. Aflatoxin production was completely inhibited at

0·1 mg ml−1. The results obtained from the thin layer chromatographic

bioassay and gas chromatography indicated citral a and b as the

fungicidal constituents in lemongrass oil (Parangama PA, 2003).

J.m. Kim, et al., study revealed that Carvacrol, citral and geraniol

showed potent antibacterial activity against Salmonella typhimurium and

its rifampicin-resistant (RifR) strain as determined in txyptic soy broth

and by zone of inhibition on agar-based medium.

Tamonud Modak and Abhilash Mukhopadhaya. The effect of citral

on adipose tissue. Representative stained sections of perinephric

adipose tissue from drug control group and experimental group. The

drug treated group shows smaller adipocyte than the drug control

(Indian J. Pharmacol.2011).

Vanillin:

Vanillin is an organic compound with the molecular formula

C8H8O3. Its functional groups include aldehyde, ether, and phenol. It is

50

the primary component of the extract of the vanilla bean. It is also found

in roasted coffee and the Chinese red pine. Synthetic vanillin, instead of

natural vanilla extract, is sometimes used as a flavoring agent in foods,

beverages, and pharmaceuticals.

Natural vanillin is extracted from the seed pods of Vanilla

planifola, a vining orchid native to Mexico, but now grown in tropical

areas around the globe. Madagascar is presently the largest producer

of natural vanillin.

Natural "vanilla extract" is a mixture of several hundred different

compounds in addition to vanillin. Artificial vanilla flavoring is a solution

of pure vanillin, usually of synthetic origin. Because of the scarcity and

expense of natural vanilla extract, there has long been interest in the

synthetic preparation of its predominant component.

The first commercial synthesis of vanillin began with the more

readily available natural compound eugenol. Today, artificial vanillin is

made from either guaiacol or from lignin, a constituent of wood which is

a byproduct of the paper industry.

Vanillin was first isolated as a relatively pure substance in 1858

by Nicolas-Theodore Gobley, who obtained it by evaporating a vanilla

extract to dryness, and recrystallizing the resulting solids from hot

water.

51

In 1874, the German scientists Ferdinand Tiemann and Wilhelm

Haarmann deduced its chemical structure, at the same time finding a

synthesis for vanillin from coniferin, a glycoside of isoeugenol found in

pine bark. Tiemann and Haarmann founded a company, Haarmann &

Reimer (now part of Symrise) and started the first industrial production

of Vanillin using their process in Holzminden (Germany).

In 1876, Karl Reimer synthesized vanillin from guaiacol.

OH

OCH3

HO

O

OH

CH3

Guaiacol Vanillin

KOH/CHCl3

Lignin-based artificial vanilla flavoring is alleged to have a richer

flavor profile than oil-based flavoring; the difference is due to the

presence of acetovanillone in the lignin-derived product, an impurity not

found in vanillin synthesized from guaiacol.

D.F. Taber et.al., given has recently been described, a very

convenient laboratory synthesis involving electrophilic bromination of 4-

hydroxybenzaldehyde, followed by copper-catalysed methoxylation

which is suitable for synthesysing vanillin in few grams (Taber DF et al.,

2007).

52

OH

OH

OH

OH

CH3

OH

OH

O

CH3

Br2

M eOH

NaOM e/CuBrEtOAc

4-hydroxybenzaldehyde 4-hydroxy-3-m ethylbenzaldehyde Vanillin

As far as large-scale industrial syntheses go, a classic early

method starts from eugenol, which occurs naturally in cloves, nutmeg

and cinnamon. This isomerises to isoeugenol in alkaline solution, and

this in turn can be oxidised (by nitrobenzene) to vanillin.

O H

O

C H 3

C H 2

O H

O

C H 3

C H 3

O H

O

C H 3

OH

E u g e n o l Iso e u g e n o l V a n i l l in

Today most of the vanillin was synthesized by reacting guaiacol

which is obtained from catechol with glyoxalic acid.

O H

O

C H 3

O H

O

C H 3

H

OHO H

O

O H

O

C H 3

OO H

O

O H

O

C H 3

O HH

OHC

COOH+

O H - O 2

C a ta lys t

H + -C O 2

V a n i l l in

53

The freshly harvested green vanilla pods do not smell "vanilla" as

the vanillin is locked up inside them as a β-D-glycoside. The pods have

to be cured, during which time they become deep brown, and enzymes

release the vanillin from the glycoside, along with over a hundred other

molecules, all of which contribute to the authentic vanilla aroma. Vanillin

itself makes up about 2% of the final mass of the "cured" beans.

Vanillin as β-D-glycoside

Vanillin has been used as a chemical intermediate in the

production of pharmaceuticals and other fine chemicals. In 1970, more

than half the world's vanillin production was used in the synthesis of

other chemicals, but as of 2004 this use accounts for only 13% of the

market for vanillin.

The vanilla plant, Vanilla planifola originates in subtropical forests

in Mexico and parts of Central America, and it was the Mayan and

Aztec civilisations which first realised the potential of vanilla, using it to

lighten up the flavour of the chocolate that they drank. The Aztec leader

Moctezuma hinted to Hernán Cortés (who led the Spanish invaders)

that the Aztecs' vanilla flavoured chocolate drinks were a very useful

54

aphrodisiac. After their conquest of these areas, the Spaniards brought

vanilla to Western Europe in the early 16th century.

Vanillin is in the class of vanilloids, that includes – surprisingly –

capsaicin (8-methy-N-vanillyl noneamide) from chile pepper and

eugenol from cloves, cinnamon and other spices, and zingerone from

ginger. The vanilloid receptors of the central and peripheral nervous

systems bind with these compounds, resulting in different sensory

effects. Thus, capsaicin can cause a burning sensation while eugenol

results in mild anesthesia; vanillin itself is neutral. Vanilla is an aromatic

stimulant, with a tendency towards the nervous system. It has also been

regarded as an aphrodisiac. It has been employed as a remedy in

hysteria, low fevers, impotency, etc.

Vanillin (4-hydroxy-3-methoxybenzaldehyde), a potent nuclear

factor-κB (NF-κB) inhibitor, was evaluated in mice with trinitrobenzene

sulfonic acid (TNBS)-induced colitis. Vanillin not only prevented TNBS-

induced colitis but also ameliorated the established colitis. Vanillin

reduced the expressions of proinflammatory cytokines [interleukin (IL)-

1β, IL-6, interferon-γ, and tumor necrosis factor-α] and stimulated the

expression of anti-inflammatory cytokine (IL-4) in colonic tissues.

Vanillin, the active ingredient in vanilla, has shown some

interesting anti-cancer properties. Not only does it prevent mutations,

the changes in the cell’s DNA that lead to cancer, but it also stops

55

growth of cancer cells in a laboratory setting. A study conducted on

mice showed that vanillin stopped the metastasis or spread of breast

cancer cells to the lungs and decreased their ability to invade new

tissue. Bromovanin, a derivative of vanillin, also shows some promise

for the treatment of cancer and could be used in the development of

new cancer treatments.

Vanillin, the active component of vanilla, has antioxidant activity

and appears to offset some of the oxidative damage that occurs in the

brains of patients with Alzheimer’s disease – particularly the formation

of a compound called peroxynitrite. Peroxynitrite plays a role in other

degenerative diseases of the brain such as Parkinson’s disease.

Although research in this area is still in its infancy, it may hold future

promise for people dealing with these debilitating diseases.

Studies have shown that vanillin can stop the sickling of red blood

cells that leads to problems for people with sickle cell anemia.

Unfortunately, vanilla can’t be used directly since it would be destroyed

by the acid in the stomach. Researchers are hoping that a drug using

vanillin can be developed to treat sickle cell disease in the near future.

Vanilla has been used historically as far back as the seventeenth

century to treat a variety of conditions including stomach ulcers and

sleep difficulties. The essential oil reportedly has sedative-like

properties. Some alternative practitioners use vanilla essential oil to

56

treat insomnia, anxiety, and depression. It’s also thought to be an

aphrodisiac although there’s little scientific evidence to support this.

Z. Yuxia et,al., synthesized some new Schiff bases from 4-

aminoantipyrine and vanillin and determining their antibacterial activity.

Literature survey shows that Schiff bases show bacteriostatic and

bactericidal activity. Antibacterial, antifungal, antitumor, anticancer

activity has been reported and they are also active against a wide range

of organisms, e.g. C. albicans, E. coli, S.aureus, B. polymyxa, P.

viticola, etc. Many Schiff bases are known to be medicinally important

and are used to design medicinal compounds (Yogesh Kumar, 2004).

Vanillin, a food additive, has been evaluated as a potential agent

to treat sickle cell anemia. Earlier studies indicated that vanillin had

moderate antisickling activity when compared with other aldehydes.

In particular the detection of volatile organic compounds in low

concentration, has become of interest, because they are widely used as

ingredients house-hold products. These compounds vaporize at normal

room temperature, sometimes causing adverse health effects. Abdullah

M. Asiri, et.al, synthesized six new dyes derived from vanillin and active

methylene have been prepared and these dyes were tested for use as

sensors for volatile organic compounds (VOCs namely Triethylamine

and diethyl amine). The electronic spectra of these dyes were examined

57

and gave color depending on the acceptor groups (Abdullah M et al.,

2009).

Potkin V, et.al, performed Reaction between 4-formyl -2 –

methoxy phenyl 4, 5-dichloro isothiazole -3-carboxylate with various

aromatic amines led to azomethins formation. By treatment of

azomethins with sodium triacetoxyborohydride corresponding amine

were obtained. During the bioassays of new vanillin derivatives in

mixtures with insecticides remarkable synergetic effect was discovered.

Currently, approximately 50% of the worldwide production of synthetic

vanillin is used as an intermediate in the chemical and pharmaceutical

industries for the production of herbicides, antifoaming agents or drugs

such as papaverine, l-dopa, l-methyldopa and the antimicrobial agent,

trimethoprim.

Sandra S, et,al stated Azomethines are of considerable interest

because of their chemistry and potentially beneficial biological activities,

such as antitumor, antibacterial, antiviral and antimalarial activities,

Considering this, the vanillin azomethines were synthesized and tested

for their antimicrobial activity. The antifungal activity of the obtained

compounds show that vanillin azomethines have enhanced the activity

more than intermediates due to C=N group.

Vanillin, a naturally occurring food component, has been reported

to have anti-mutagenic and anti-metastatic potentials, and to inhibit

58

DNA-PKcs activity. However, vanillin itself exhibits very weak

antiproliferative activity.

Yu-Qian Yan, et.al., studied effects of bromovanin (6-bromine-5-

hydroxy-4-methoxybenzaldehyde), a novel vanillin derivative, on

survival and cell-cycle progression of human Jurkat leukemia cells.

Treatment with >10 μM bromovanin significantly elicited apoptosis and

G2/M arrest in Jurkat cells in a dose- and timedependent manner.

Bromovanin-induced DNA double-strand breaks (DSB) were

demonstrated by means of comet assay as well as detection of

phosphorylated H2AX, a sensitive indicator of DNA DSBs.

CHO

O H

O

C H 3

CHO

O

OH

B r

CH 3 V a n il l in B ro m o v a n il l in

Vanillin can be iodinated in an aqueous solution of sodium

triiodide (NaI3.NaI), made in situ from sodium iodide and iodine, forming

5-iodovanillin. Refluxing 5-iodovanillin in a strong sodium hydroxide

solution produces 5-hydroxyvanillin, which is a useful precursor for 3, 4,

and 5-trimethoxy- benzaldehyde (used in the synthesis of mescaline) as

well as 3-methoxy-4, 5-methylenedioxy- benzaldehyde

(myristicinaldehyde, used in the synthesis of MMDA-2). 5-Iodovanillin

can also be treated with sodium methoxide to form syringaldehyde (4-

59

hydroxy-3, 5-dimethoxybenzaldehyde, used in the synthesis of escaline,

proscaline and other mescaline derivatives (Dikusar et al., 2006).

CHO

OH

OCH3

CHO

OH

OCH3

I

CHO

OH

OCH3

OH

1N NaOH

NaI3,H2SO4

NaOH

vanillin 5-iodo vanillin

5-hydroxy vanillin

Ortho-Vanillin is harmful if ingested, irritating to eyes, skin and

respiratory system, but has an unmistakable high LD50 of 1330 mg/kg in

mice. It is a weak inhibitor of tyrosinase, and displays both

antimutagenic and comutagenic properties in Escherichia Coli.

However, its net effect makes it a potent comutagen. Ortho-Vanillin

possesses moderate antifungal and antibacterial properties. Most ortho-

vanillin is used in the study of mutagenesis and as a synthetic precursor

for pharmaceuticals.

CHO

OH

OCH3

ortho-vanillin(2-hydroxy-3-methoxybenzaldehyde)

Condensed tannins can be detected by vanillic acid, as the tannin

will react and make a red complex. Any fluid has its own characteristic

absorption profile, which is recorded on a disc by VIS-

spectrophotometry. Tannin detenorates, the absorption profile due to

60

change in its physical characteristics. VIS-spectrophotometry is

therefore inapplicable for the identification of much detenorated tannins.

Shrinkage temperature (Ts) is an expression for the hydrothermal

stability of leather. A high shrinkage temperature indicates stable

leather, with lot of bindings between the collagen fibers.

Thiosemicarbazones of natural aldehydes and ketones are easily

characterized and very stable crystalline compounds which can be

valuable synthons, especially for heterocyclic synthesis.

Thiosemicarbazones are widely used as insecticides, inhibitors,

zoocides, and pharmaceuticals exhibiting antimicrobial, antiviral, and

antitumor activity. So new thiosemicarbazones are synthesized on the

basis of our previously prepared esters of natural aldehydophenols,

such as vanillin and vanilla.

Ethers and esters of oximes exhibit anti-inflammatory,

antimicrobial, pesticidal, insecticidal, fungicidal, and other types of

physiological activity. Oximes of plant phenols prepared from vanillin

and vanillal are convenient and available synthons for the synthesis of

new biologically active compounds and fragrances and can be used as

reagents for separating and concentrating chemical elements.

Douglass F Taber, Shweta Patel. Vanillin Synthesis from 4-

Hydroxybenzaldehyde. A simple and safe preparation of vanillin from 4-

hydroxybenzaldehyde is described (J. Chemical education 2012.)

61

Carvone:

Anand Akhila et al., worked on Biosynthesis of carvone in Mentha

spicata by degradation of, and measurement of isotope ratios in, (−)-

carvone that had been biosynthesized in Mentha spicata from 3H- and

14C-labelled geraniol and mevalonate. These results enable the

mechanisms for the introduction of the carbonyl group and for the

formation of the isopropenyl side-chain to be delimited (Anand Akhila et

al., 2008).

Gerardo C. Torres et al., worked on Hydrogenation of carvone on

Pt–Sn/Al2O3 catalysts the effect of Sn concentration in Pt–Sn/Al2O3

catalysts prepared by different procedures on the catalytic behavior in

the carvone hydrogenation in liquid phase was studied. Results

indicated that the increase of the Sn amount added to Pt modified the

catalytic behavior, favoring the formation of unsaturated ketones and

the simultaneous production of small quantities of unsaturated alcohols

as reaction intermediaries. On the other hand, Pt/Al2O3 catalyst only

produced carvomenthone as the main reaction intermediary (Gerar C et

al., 2009).

Kathleen McBride et al., assessed whether the enantiomers of

terpinen-4-ol, odorants that activate nearly identical areas of the

olfactory bulb, are more difficult to discriminate than those of carvone,

odorants that activate different areas of the olfactory bulb, and whether

62

olfactory bulb lesions that disrupt the pattern of bulbar activation

produced by these enantiomers degraded the ability of rats to

discriminate between them.

Richard A. Kjonaas et al., worked on Acid-Catalyzed

Isomerization of Carvone to Carvacrol this experiment demonstrates

several important concepts including (i) formation of a carbocation by

protonation of an alkene, (ii) rearrangement of a carbocation, (iii)

deprotonation of a carbocation, (iv) acid-catalyzed enolization, and (v)

aromaticity. The experiment is especially suitable for use with low-field

permanent-magnet FT–NMR (Richard A, 1984).

Goncalves Juan Carlos Ramos et al., worked on Antinociceptive

Activity of Carvone it is a monoterpene ketone that is the main active

component of Mentha plant species. This study aimed to investigate the

antinociceptive activity of carvone using different experimental models

of pain and to investigate whether such effects might be involved in the

nervous excitability elicited by others monoterpenes.

Mariet J. van der Werf et al., worked on a novel nicotinoprotein,

catalyzing the dichlorophenolindophenol-dependent oxidation of carveol

to carvone, was purified to homogeneity from Rhodococcus erythropolis

DCL14. The enzyme is specifically induced after growth on limonene

and carveol. Dichlorophenolindophenol-dependent carveol

dehydrogenase (CDH) is a homotetramer of 120 kDa with each subunit

63

containing a tightly bound NAD (H) molecule. The enzyme is optimally

active at pH 5.5 and 50 °C and displays broad substrate specificity with

a preference for substituted cyclohexanols.

Paul McGeady, et al., worked on Carvone and perillaldehyde

were shown to inhibit the transformation of Candida albicans to a

filamentous form at concentrations far lower and more biologically

relevant than the concentrations necessary to inhibit growth. This

morphological transformation is associated with C. albicans

pathogenicity; hence these naturally occurring monoterpenes are

potential lead compounds in the development of therapeutic agents

against C. albicans infection (Paul Mc Geady et al., 1999).

B. Slotnick et al., worked on Rats with lesions of dorsal and dorsolateral

bulbar sites known to be differentially responsive to carvone

enantiomers were tested for their ability to detect (+)-carvone, to

discriminate between (+)-carvone from (−)-carvone, and to discriminate

(+)-carvone from mixtures of both enantiomers after they had been pre-

trained or not pre-trained on these tasks prior to surgery. These results

indicate that removal of most bulbar sites known to be differentially

responsive to carvone enantiomers and the consequent disruption of

normal patterns of bulbar input produced in response to carvones are

largely without effect on the ability of rats to discriminate between these

odors.

64

Michael Schiendorfer et al., worked on provided the lower rim of

resorc[4]arenes with stereogenic centers as well as with functional

groups. For the synthesis of these lower rim functionalized chiral

resorc[4]arenes we have used aldehydes derived from citronellal and

carvone. In general, the functional group was introduced into the

aldehyde compound prior to the final cyclization step. Another strategy

is the introduction of the iodo group at the lower rim of a resorc[4]arene,

which can be easily substituted by good nucleophiles and mild bases

without protection of the upper rim (Micheal Schiendorfer, 2005) .

Fernando de Sousa Oliveira et al., studied on

hydroxydihydrocarvone (HC) is a monoterpene analog prepared as a

semi synthetic intermediate by hydration of the carvone monoterpene.

Recent reports from studies carried out on HC have demonstrated its

antinociceptive effect. HC exerts a central antinociceptive effect without

causing pharmacological tolerance, and no significant toxicological

alterations were observed during treatment.

Renata Zawirska-Wojtasiak et al., worked on Solid-phase micro

extraction was examined for its suitability for isolation of volatiles from

seeds of dill in comparison with the traditional steam distillation

procedure. Two main dill seeds volatiles, carvone and limonene, were

taken into consideration. Two Supelco SPME fibers were used for the

extraction: polyacrylic (PAc) and polydimethylsiloxane (PDMS). The

65

time required to saturate the fibers was 3 min, while distillation took 3 h.

Gas chromatography (GC) separation was reduced to 5 min by use of

microcapillary column HP-5 cross-linked 5% Ph Me Siloxan.

Diego S. Pisoni et al., worked on indium trichloride based on

Journal of the Brazilian Chemical Society Indium trichloride promotes

the chlorination of terminal olefins in the presence of sodium

hypochlorite with good results. Carvone was chosen as a model

compound to examine some of the general features of this reaction,

such as stoichiometry, temperature, reaction time and product

conversion. Treatment of b-pinene with sodium hypochlorite in the

presence of indium trichloride resulted in a facile rearrangement to

selectively yield perillyl chloride, which is an important precursor for C-7

oxygenated limonenes.

Anja A. Verstegen-Haaksma et al., worked on Application of S-

(+)-carvone in the synthesis of biologically active natural products using

chemical transformations and bioconversions.

Dohm Michlle et al., worked on Frequency-dependent, complex

refractive indices for carvone in the mid-infrared from 750 to 5000 cm-1

have been inverted from the Fourier transform extinction spectra of

laboratory-generated aerosols recorded at room temperature. Such

data can be used to elucidate the optical properties of a substance,

which are of critical importance in the interpretation of remote sensing

66

data and in the evaluation of how atmospheric particulate matter

consisting of organic compounds may affect climate change (Dohn

Michelle et al., 2003).

IsaTelci et al., worked on Agronomical and Chemical

Characterization of Spearmint Spicata Originating in Turkey and the

components were determined by using gas chromatography. Two

chemo types were identified; one high in carvone and the other is

pulegone. Agronomic and essential oil properties of cultivated landraces

of M. spicata were also investigated under field conditions.

Asturias JA, et al., worked on the evolutionary relationship of

biphenyl dioxygenase from gram-positive Rhodococcus globerulus P6

to multicomponent dioxygenases from gram-negative bacteria.

Jeronimo S. Costa et al., worked on the reactivity and

diastereoselectivity of conjugate addition of different nitronates ions to

(R)-carvone was systematically studied. The nitro adducts were

transformed via Nef reaction into (R)-carvone ketone derivatives and

nitro adducts led to (R)-carvone alkylated derivatives via a denitration

reaction.

T. J. Raphael et al., worked on the immunomodulatory activity of

some naturally occurring monoterpenes were studied in Balb/c mice.

Administration of various monoterpenes such as carvone, limonene and

perillic acid were found to increase the total white blood cells (WBC)

67

count in Balb/c mice. Administration of terpenoids increased the total

antibody production, antibody producing cells in spleen, bone marrow

cellularity and α-esterase positive cells significantly compared to the

normal animals indicating its potentiating effect on the immune system

(Raphael TJ et al., 2003).

Y. S. R. Krishnaiah, et al., worked on the purpose of this study

was to investigate the effect of carvone on the permeation of nicardipine

hydrochloride across the excised rat abdominal epidermis from 2% w/w

hydroxypropyl cellulose gel system. The results suggest that carvone

may be useful for enhancing the skin permeability of nicardipine

hydrochloride from transdermal therapeutic system containing HPC gel

as a reservoir (Krishnaiah Y, 19984).

Fatemeh Rafii et al, worked on Piperitone from plant essential oils

enhance bactericidal activities of nitrofurantoin and furazolidone against

bacteria from the family Enterobacteriaceae. In this study, the essential

oils of spearmint, dill and peppermint were screened for augmentation

of nitrofurantoin activity and the most active components were

determined. Pure carvone and piperitone equally increased the

bactericidal activity of nitrofurantoin. Other ingredients of essential oils,

including camphor, limonene and menthone, were less effective.

Paul McGeady, et al., worked on Carvone and perillaldehyde

were shown to inhibit the transformation of Candida albicans to a

68

filamentous form at concentrations far lower and more biologically

relevant than the concentrations necessary to inhibit growth. This

morphological transformation is associated with C. albicans

pathogenicity.

Camila M.S. Silva, Carlos W.S. Carvone (R )-(-) and (S)-(+)

enantiomers inhibits upper gastrointestinal motility in mice. These

effects were accompanied by a reduction of the propulsive behavior of

small intestine. The retarding effects of carvone on gastric pressure

waves (Flavour and Fragrance Journal. 2015)

Camphor:

Warren P, Bishop MD, Kathleen D and Sanders MD et al., worked

on hepato toxicity in a 2-month-old baby after a camphor-containing

cold remedy was applied dermally. Liver function tests returned to

normal after the application of the cold remedy was discontinued.

Ingestion of camphor can cause severe liver and central nervous

system injury, and neurotoxicity has been observed after exposure to

camphor through the skin. Hepato toxicity after dermal application of

camphor has never been reported. This report emphasizes the common

use of cold remedies that are usually not beneficial and may be

potentially dangerous.

N S Vostrikov, A V Abutkov et al., worked on new camphor

derivative functionalized by Base-catalyzed condensation of 10

69

methylene camphor with diethyl oxalate gave the corresponding (Z)-3-

ethoxycarbonyl (hydroxyl) methylene derivative which was converted

into methyl ether and acetate. The Z-methyl ether undergoes

isomerization into the E-methyl ether on treatment with N-

bromosuccinimide in the presence of radical initiator [azobis

(isobutyrodinitrile)]. (Z)-3-Ethoxycarbonyl (hydroxy) methylene-10-

methylenecamphor smoothly reacts with N-bromosuccinimide to afford

stereo isomeric 3-bromo derivatives.

Mauro L. Mellão L and Mario L A, Vasconcellos et al., worked on

new camphor derivatives for enantio selective syntheses. New 1,3 diols

3a→3c were efficiently prepared in the enantiopure form in 50–68%

yield (2 steps), from the available 1-(R)-(+)-camphor (Kumar M, et al.,

1995).

Uzi Ravid, Eli Putievsky, Irena Katzir, et all worked on the

enantiomeric differentiation of camphor isolated from natural essential

oils and samples from commercial sources was determined using a

fused-silica Lipodex E capillary column. Enantiomerically pure (S)(-)-

camphor was detected in Chrysanthemum parthenium (L.) Bernh. oil.

The (S)(-)-enantiomer, with high enantiomeric purity was detected in

two types of Salvia offtcinalis L., and (R)(+)-camphor with high

enantiomeric purity was detected in two other types of S. officinalis and

in S. glutinosa L (Medoff G et al., 1999),.

70

Chihliang Chang, Kwunmin Chen et al., worked on Practical and

convenient synthetic routes for the synthesis of a new class of

pyrrolidinyl-camphor derivatives. These novel compounds were

screened as catalysts for the direct Michael addition of symmetrical , -

disubstituted aldehydes to -nitro alkenes. When this asymmetric

transformation was catalyzed by organo catalyst, the desired Michael

adducts were obtained in high chemical yields, with high to excellent

stereo selectivities and 99 % enantiomeric excess. The synthetic

application was demonstrated by the synthesis of a tetrasubstituted-

cyclohexane derivative from (S)-citronellal, with high stereo selectivity.

Peter Weyerstahl Christian Gansau, Tilo Claußen et al., worked

on Studies on the patchouli character of camphor derivatives. From

camphor the ketones were prepared by -alkylation, and the tertiary

alcohols by Grignard reaction. The disubstituted (iso) borneols could be

obtained by Grignard reaction with MtMgI or allyl magnesium halide.

Reaction with EtMgl afforded the secondary alcohols by reduction.

Olfactive evaluation showed that the -monoalkylated camphor’s as well

as the 2-alkylisoborneols remained more or less within the camphor-

eucalyptus odour profile. However, and the disubstituted (iso) borneols

possess a strong patchouli scent.

V Z Vasiko and M S Miftakhov et al., worked on Synthetic routes

to precursors of tricyclic camphor derivatives fused at the 2, 10-

71

positions, the corresponding halohydrins and dimethyl acetal, are

discussed (Bishop, 2000).

Antonio García Martínez, Enrique Teso Vilar, Amelia García

Fraile, et al., worked on the new, general and straightforward method

for the enantiospecific synthesis of 9,10-dihalocamphors (including

mixed derivatives) is reported and exemplified for the preparation of (+)-

9,10-dibromocamphor (a well-known chiral intermediate) as well as (+)-

9-bromo-10-chlorocamphor and (+)-9-bromo-10-iodocamphor (novel

mixed dihalides). Our approach is based on a key stereo controlled

tandem electrophilic addition - Wagner-Meerwein rearrangement of

optically pure 3-endo-(halo methyl)-3-methyl-2-methylenenorbornan-1-

ols, which are easily obtained from readily accessible 9-halocamphors.

William J, Phelan M.D, et al., worked on Camphor Poisoning

Over-the-Counter Dangers. Intoxication from camphor has been

reported frequently in the literature for decades, most cases involving

the accidental ingestion of camphorated oil, mistaken for castor oil or

other similar products. Over 20 years ago, Smith and Margolis collected

130 nonfatal and 18 fatal cases from literature dating back to 1833.

Recent data from the National Clearinghouse for Poison Control

Centers reveal an increasing proportion of ingestions of other over-the-

counter camphor-containing preparations.

72

Julian A Peterson et al., worked on large-scale purification from

the bacterium Pseudomonas putida of two components of the camphor

methylene hydroxylase system, cytochrome P-450 and putidaredoxin.

The heme iron of cytochrome P-450 is in a high-spin state with five

unpaired electrons in the presence of camphor and a low-spin state with

one unpaired electron in the absence of camphor as determined by

magnetic susceptibility and electron paramagnetic resonance

measurements, respectively.

J L Urai and F J Humphreys, et al., worked on Thin polycrystalline

specimens of rhombohedra camphor in pure shear in the temperature

range 283–343K. The deformation processes, dynamic recrystallization

and the development of microstructure were followed by transmission

polarized light microscopy. The development of microstructure changed

drastically above 310–320K.This change, probably due to the

development of a marked anisotropy in grain boundary motilities, and

the activation of new slip systems made the development of shear

zones a more frequently occurring phenomenon above 310–320K.

ChanI Ping, chiu ShuPing, WuFu Ming, et al., worked on acute

camphor oil intoxicosis in cats. Three cats were treated with camphor oil

due to flea infestation 2 weeks prior to presentation. These cats showed

signs of depression, anorexia and lethargy. On physical examination, all

3 cats had symptoms of dehydration and jaundice. Moreover, they

73

smelled of camphor lightly or heavily. The 3 cats died from days 1 to 4

after hospitalization. One of the cats was subjected to necropsy.

Regeneration of the renal tubular epithelial cells and hepatic tissue was

observed from many areas, and urine bladder had severely damaging

lesions from the clinical signs, laboratory and histopathological findings,

a diagnosis of acute camphor oil intoxication was made.

Sonja Frölich, Carola Sch ubert et al., worked on In vitro

antiplasmodial activity of prenylted chalcone derivatives of hops

(Humulus lupulus) and their interaction with haemin. There is an urgent

need to discover new antimalarials, due to the spread of chloroquine

resistance and the limited number of available drugs. Chalcones are

one of the classes of natural products that are known to possess

antiplasmodial properties. Therefore, the in vitro antiplasmodial activity

of the main hop chalcone xanthohumol and seven derivatives was

evaluated. In addition, the influence of the compounds on glutathione

(GSH)-dependent haemi-n degradation was analysed.

Matherine, Achanta Geetha et al., worked on2.Anticancer

activityes odzelewska Aneta; Pettit C of novel chalcone and bis-

chalcone derivatives.A series of novel chalcones and bis-chalcones et

against the human breast cancer MDA-MB-231 (estrogen receptor-

negative) and MCF7 (estrogen receptor-positive) cell lines and against

two normal breast epithelial cell lines, MCF-10A and MCF-12A. These

74

molecules inhibited the growth of the human breast cancer cell lines at

low micromolar to nanomolar concentrations, with five of them (1-4, 9)

showing preferential inhibition of the human breast cancer cell lines.

Furthermore, bis-chalcone 8 exhibited a more potent inhibition of colon

cancer cells expressing wild-type p53 than of an isogenic cell line that

was p53-null (Selipe Herencia et al., 1996).

G.Thirunarayanan and G. Vanangamudiet al., worked on

Synthesis of Some Aryl Chalcones Using Silica-Sulphuric Acid Reagent

under Solvent Free Conditions.There are two series of unsaturated

ketones derived from Biphenyl and 9H-Fluorenyl, and ketones with

various substituted benzaldehydes under solvent free conditions using

silica-sulphuric acid as a reagent in an oven. The catalyst silica is

reusable and the yields of chalcones are more than 90%. These

chalcones are characterized by physical constants.

Y.K.Srivastava et al., worked on Ecofriendly microwave assisted

synthesis of some chalcone. Claisen –Schmidt condensation has been

carried out for the synthesis of some o-hydroxchalcone, using

microwave assisted solid phase, solvent free method. Instead of normal

bases like NaOH, KOH the condensation has been carried out in

presence of anhydrous K2CO3 as catalyst which makes the process

eco-friendly, economic and easy and becomes a part of e-chemistry.

75

P.M. Gurubasavaraja Swamy et al., worked on Synthesis and

Antimicrobial Activity of Some Novel Chalcones Containing 3-Hydroxy

Benzofuran.2-Acetyl-3-hydroxy benzofuran were allowed to react

separately with different aromatic aldehydes in presence of 50%

alkaline medium to yield the corresponding 3-hydroxy benzofuran

substituted chalcones. The compounds obtained were identified by

spectral data and screened for antimicrobial activity (Shivakumar PM et

al., 2005).

Jian Wang, Shaojie et al., worked on .Chalcone Derivatives Inhibit

Glutathione S-Transferase P1-1 Activity: Insights into theInteraction

Mode of a, b-Unsaturated CarbonylCompounds. Resistance to

chemotherapeutic drugs has long been a considerable barrier to

successful treatmentof many cancers and over-expression of

glutathioneS-transferase P1-1 is correlated tocarcinogenesis and

resistance of cancer cellsagainst chemotherapeutic agents. This study

throws light on the role of chalcone derivatives.

Bahar Ahmeda and Tawfeq.A et al., worked on Two New Hydroxy

Chalcone Derivatives from Thymus cilicicus. The aerial part of Thymus

cilicicus Linn. (Labiatae) has afforded two new hydroxy chalcone

derivatives, characterized as 4,2,4,6,7, 8-hexahydroxy-7 (8)-dihydro-

chalcone (1), and 3, 4, 2, 4, 6,7, 8-hepta hydroxy-7 (8)-diydro-chalcone

76

(2). The structures of the isolated compounds have beenelucidated

based on various spectral studies.

Ms. Rashmi Jain, O.P chourasia et al., worked on Synthetic and

Antimicrobial Studies of Some New Chalcones of 3-Bromo-4-(p-tolyl

sulphonamido)acetophenone.Eleven new chalcones have been

sysnthesised by condensing 3-bromo-4-(p-tolyl sulphonamido)

acetophenone with different aromatic aldehydesusing the method or

Rohrman et al. The antimicrobial activity of these chalconeshas been

tested by adopting “paper disc diffusion plate method”, against

variouspathogenic fungi(10) and bacteria (9). It has been found that the

chalcones haveconsiderable antifungal activity but less antibacterial

activity. The results showthat these chalcones may find use as

antifungal agents.

Li Feng, Saeed R. Khan et al., worked on Chalcones and their

derivatives have been shown to have potent anticancer activity.

However, the exact mechanisms of cytotoxic activity remain to be

established. In this study, we have evaluated a series of boronic

chalcones for their anticancer activity and mechanisms of action.

Among the eight chalcone derivatives tested, 3,5-bis-(4-boronic acid-

benzylidene)-1-methyl-piperidin-4-one (AM114) exhibited most potent

growth inhibitory activity with IC50 values of 1.5 and 0.6 μM in 3-(4,5-

dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay and colony

77

formation assay, respectively. The cytotoxic activity of AM114 was

shown to be associated with the accumulation of p53 and p21 proteins

and induction of apoptosis.

Y.Rajendra Prasad, A.lakshmana Rao et al., worked on Synthesis

and Antimicrobial Activityof Some Chalcone Derivatives.In an effort to

develop antimicrobial agents, a series of chalconeswere prepared by

Claisen-Schmidt condensation ofappropriate acetophenoneswith

appropriate aromatic aldehydes in the presence of aqueous solution

ofpotassium hydroxide andethanol at room temperature. The

synthesized compounds were characterized by means of their IR, 1H-

NMR spectral data and elemental analysis. All the compounds were

tested for their antibacterial and antifungal activities by the cup plate

method (Yamakawa T et al., 1990).

Beom-Tae and Kim, Kwang-Joong O et al., worked on Synthesis

of Dihydroxylated Chalcone Derivatives with Diverse Substitution

Patterns and Their Radical Scavenging Ability toward DPPH Free

Radicals. A series of dihydroxylated chalcone derivatives with diverse

substitution patterns on a phenyl ring B and the para-substituents on a

phenyl ring A were prepared, and their radical scavenging activities

were evaluated by simple DPPH test to determine quantitative

structure-activity relationship in these series of compounds. The

chalcone compounds with the ortho-(i.e. 2',3'- and 3',4'-) and para-(i.e.

78

2,5'-) substitution patterns show an excellent antioxidant activities (80-

90% of control at the concentration of 50 μM) which are comparable to

those of ascorbic acid and α-tocopherol as positive reference materials.

A Rahaman, Y Rajendra Pasad et al., worked on synthesis and

anti histamic activity of some novel pyrimidines. Novel Pyrimidines were

prepared by the condensation of Chalcones of 4΄-

piperazineacetophenone with guanidine HCl. The structures of the

synthesized compounds RP 1-5were assigned on the basis of

Elemental analysis, IR, 1H NMR and Mass spectroscopy. These

compounds were also screened for antihistaminic activity. The recorded

% of histamine inhibition showed significant antihistaminic activity when

compared to the reference antihistaminic drug mepiramine.

N Domínguez, Caritza León, Juan.Rodrigues et al., worked on

Synthesis and antimalarial activity of sulfonamide chalcone

derivatives.A series of sulfonamide chalcone derivatives were

synthesized and investigated for their abilities to inhibit beta-hematin

formation in vitro and their activity against cultured Plasmodium

falciparum parasites. Inhibition of beta-hematin formation was minimal

in the aromatic ring of the chalcone moiety as it appeared for

compounds 4b, 4d-f, and greatest with compounds 4g (IC50 0.48

microM) and 4k (IC50 0.50 microM) with a substitution of 3,4,5-

trimethoxyl and 3-pyridinyl, respectively. In this study, the most active

79

compound resulted 1[4'-N(2'',5''-dichlorophenyl) sulfonyl-amidephenyl]-

3-(4-methylphenyl)-2-propen-1-one 4i, effective as antimalarial by the

inhibition of cultured P. falciparum parasites (1 microM).

Li-Ping Guan, Ji-Xing Nan, Xue-Jun Jin et al., worked on

Protective Effects of Chalcone Derivatives for Acute Liver. The

hepatoprotective effects of chalcone derivatives were evaluated in D-

galactosamine/lipopolysaccharide (D-GalN/LPS)-induced fulminant

hepatic failure in mouse. Thirteen chalcone derivatives were

synthesized for study and their hepatoprotective effects were evaluated

by assessing aspartate amino transferase (AST) and alanine amino

transferase (ALT) levels inserum.

Pramod Singh, Jagmohan S. Negi et al., worked on5-(3-

Nitrophenyl)-3-phenyl-4,5-dihydro-1H-pyrazole-1-carbaldehyde.A novel

1-formyl-2-pyrazoline was synthesized by reaction of an α,β-

unsaturated ketone with hydrazine hydrate and formic acid. The

structure of the title compound was established by UV, IR, 1H NMR,

13C NMR and microanalysis.

Felipe Herencia, M. Pilar López-García et al., worked on Nitric

Oxide-Scavenging Properties of Some Chalcone Derivatives.The

implication of NO in many inflammatory diseases has been well

documented. We have previously reported that some chalcone

derivatives can control the iNOS pathway in inflammatory processes. In

80

the present study, we have assessed the NO-scavenging capacity of

three chalcone derivatives (CH8, CH11, and CH12) in a competitive

assay with HbO2, a well-known physiologically relevant NO scavenger.

Our data identify these chalcones as new NO scavengers. The

estimated second-order rate constants (ks) for the reaction of the three

derivatives with NO is in the same range as the value obtained for

HbO2, with CH11 exerting the greatest effect. These results suggest an

additional action of these compounds on NO regulation (Brogden KA et

al., 2005).

Rafie Hamidpour, Soheil Hamidpour. Camphor a traditional

remedy with the history of trating several diseases.our focus is on the

use of Camphor as a remedy for daily minor problems as well as

reporting some information about the new applications of this traditional

medicine to treat or prevent some serious life threatening diseases such

as cancer and diabetes (IJCRI. 2012)

81

NEED FOR THE STUDY

The compounds used as starting materials are, Citral, Vanillin, Carvone

and Camphor; these compounds are volatile in nature. Hence in this

study we synthesize non-volatile derivatives of these substances with

better Pharmacological activity. By which we derive good potent

moieties as well as we can save the compounds from vaporization.

The major drawback of drugs derived from natural products is that

we cannot produce in a bulk quantity. Since the compounds

synthesized in the present study are very simple structures these can

be synthesized easily by synthesis.

The starting materials of the study are used in day to day life so

the derivatives may not have any major side effects in long term use.

To convert from volatile compounds to non-volatile compound is

very difficult. They are mild in action.

Volatile compounds in pureform is difficult to get and it is very

costly. The Volatile compounds are unstable in nature.

Some compounds shows side effects on use.

82

OBJECTIVES AND HYPOTHESIS

The newly approved drugs mentioned in previous chapter were

derived from natural sources and have been launched on the market

during 2000 – 2005. These new drugs have been approved for the

treatment of cancer, neurological diseases, infectious diseases,

cardiovascular and metabolic diseases, immunological, inflammatory

and related diseases, and genetic disorders, which encompass many of

the common human diseases. Besides new drugs launched on the

market from 2000 to the present, there are a variety of new chemical

entities from natural sources undergoing clinical trials. Thus further

research on these compounds at industrial, governmental, and

academic institutions is seen as vital for the enhancement of human

health.

Based on this concept the present work was designed to synthesize

semisynthetic derivatives of some commonly used phytoconstituent’s. In

the present study semisynthetic derivatives of citral, carvone, camphor

and vanilla were synthesized. These derivatives are chosen due to their

wide pharmacological activity and are used in our day to day life.

Eventhough these compounds are safer but it is not used for their

pharmacological activity due to less potency. Thus the objective of the

present work is

83

To optimize the biological activity of the compounds selected in

the study.

The compounds selected for the study are volatile in nature,

formation of non volatile derivative with a better activity avoids

the wastage through vaporization and also increases the potency.

The compounds to be synthesized in this study are very simple

derivatives and follow one or two step reactions, thus there is very

less chance for the degradation of the starting compound.

The compounds synthesized in this study will be subjected for

TLC, physical and spectral analysis in order to identify purity, and

to interpret the structure of the derivatives synthesized.

The phytoconstituents used in this study has the following

biological activities in common, thus all the derivatives

synthesized in the study will be subjected for the below

mentioned biological activities.

1. Acute toxicity studies

2. Antibacterial activity

3. Antifungal activity

4. Anthelmintic activity

5. In-vitro antioxidant activity

6. Anti-inflammatory activity

7. Analgesic activity

84

METHADOLOGY ADOPTED

Latest trends in drug discovery focuses a lot on the semi synthetic

derivatives, synthesized from the intermediate or the final lead

compound in order to reduce the toxic side effects of synthetically

obtained organic compound or synthesize some complicated drugs like

Vincristine, Vinblatine, Taxols etc., or to optimize the pharmacological

activity, ADME properties of a drug obtained from a natural origin.

Even though lot’s of drugs are available for treating the infections

caused by various bacteria’s, viruses, and fungus. The synthetically

derived compounds gets resistance for these pathogens, thus there is a

need of new molecules in future to treat the infections caused by these

resistant pathogens.

The present study was designed to synthesize some novel

derivatives of some selected compounds. The compounds selected for

the present study are Vanillin, Camphor, Carvone, and Citral. The

above mentioned compound was reported for various pharmacological

activities. Various derivatives of the above mentioned compounds were

designed with a motto to optimize the pharmacological activity and

should be less expensive for synthesis of those compounds. The

derivatives which we have planned for synthesis are smaller molecules

with less chiral centres, thus the total synthesis of these compounds will

be quiet easier.

85

Since the above mentioned compounds are used regularly in day

to day life and derived from natural product it could be safer than the

other synthetically derived compounds.

Various derivatives of the above compounds are prepared by various

reactions like alkylation, benzoylation, mannich condensation reaction

etc. The schemes for the synthesis are represented in the next section

of this thesis. The derivatives synthesized above are subjected for thin

layer chromatography for identifying the purity of the derivatives. The

derivatives will be subjected for physical and spectral analysis like

melting point, FTIR, HNMR, MASS spectroscopy for structural

interpretation.

Further the derivatives will be subjected for pharmacological evaluation.

The pharmacological activities to be carried out are

1. Acute toxicity studies

2. Antibacterial activity.

3. Antifungal activity

4. Antihelmentic activity

5. In-vitro antioxidant activity

6. Anti-inflammatory activity

7. Analgesic activity

86

Schemes for synthesis of Citral Derivatives

Compound 1:

CHO

CH3

CH3CH3

NH2 NH C

O

NH2 C2H5OH

SHAKE

+

hydrazinecarboxamide

MeCOONa+

CH3

CH3CH3

N NH C

O

NH2

2-[(2Z)-3,7-dimethylocta-2,6-dien-1-ylidene]hydrazinecarboxamideCitralCompound I

Compound 2:

OHC

CH3

CH3

CH3

C2H5OH

PYRIDINE

N-hydroxy-1,1-diphenylmethanimine

+

NOH

(2Z)-N-(diphenylmethylidene)-3,7-dimethylocta-2,6-dienamide

Citral

CH3

CH3

O

CH3

Compound II

Synthesis of Vanillin derivatives

Compound 3:

CHO

OH

OCH3

NH2 NH2CH3COONa

OH

OCH3

N

NH2

+

4-[(E)-hydrazinylidenemethyl]-2-methoxyphenolVanillin

Hydrazine

Compound III

Fig.No.13. Schemes for synthesis of compound I-III

87

Compound 4:

CHO

OH

OCH3

+

NHNH2

CH3COONa

OH

OCH3

N

NH

2-methoxy-4-[(E)-(2-phenylhydrazinylidene)methyl]phenol

Vanillin

Phenylhydrazine

Compound IV

Compound 5:

CHO

OH

OCH3

NHNH2

O2N

NO2

OH

OCH3

N

NH

O2N NO2

+CH3COONa

Vanillin

4-{(E)-[2-(2,4-dinitrophenyl)hydrazinylidene]methyl}-2-methoxyphenol

2,4 Dinitro Phenyl Hydrazine

Compound V

Compound 6:

CHO

OCH3

OH

+NH2 NH

NH2

O

CH3COONa

OCH3

OH

N NH

O

NH2

N-[(Z)-(4-hydroxy-3-methoxyphenyl)methylidene]hydrazinecarboxamideVanillin Semicarbazide

Compound VI

Fig.No.14. Schemes for synthesis of compound IV-VI

88

Compound 7:

N N

OH

O

CH3

OH

O

CH3

4,4'-{benzene-1,2-diylbis[nitrilo(E)methylylidene]}bis(2-methoxyphenol)

NH2

NH2

benzene-1,2-diamine

+

CHO

OH

OCH3

Vanillin

Compound VIICompound 8:

HO

OH

O

CH3

+

CH3O

1-phenylethanone

O

O

OH CH3(2E)-3-(3-hydroxy-2-methylphenyl)-1-phenylprop-2-en-1-one

Compound VIIIVanillin

Compound 9:

OH

O

CH3OH

+CH3

OCH3

H

O

CH3OH

O

CH3

butan-2-one

(1Z)-1-(4-hydroxy-3-methoxyphenyl)pent-1-en-3-oneCompound IX

Vanillin

Fig.No.15. Schemes for synthesis of compound VII - IX

89

Compound 10:

HO

OH

O

CH3

+O

diphenylmethanoneOH

O

CH3

O

{3-[(Z)-(3-hydroxy-2-methoxycyclohexa-2,4-dien-1-ylidene)methyl]phenyl}(phenyl)methanone

Compound XVanillin

Compound 11:

OH

O

CH3OH

+

H

O

CH3OH

N

CH3 N

CH3

OH

(2Z,3E)-N,N'-dihydroxybutane-2,3-diimine

4-[(Z)-2-{[(2E,3Z)-3-(hydroxyimino)butan-2-ylidene]amino}ethenyl]-2-methoxyphenol

OH N

N

CH3

OH

CH3

VanillinCompound XI

Synthesis of Carvone derivatives

Compound 12:

CH3

CH3 CH2

O

CH4

CH3

CH3

CH2

N

NH

O2N

NO2

(2E)-1-(2,4-dinitrophenyl)-2-[2-methyl-5-(prop-1-en-2-yl)cyclohex-2-en-1-ylidene]hydrazine

Carvone

NHNH2

N+

O-

O

N+

O-

O

/ Ethanol

Warm

+

2,4 Dinitro Phenyl Hydrazine Compound XII

Fig.No.16. Schemes for synthesis of compound X - XII

90

Compound 13:

C H 3

CH 3 C H 2

O

Carvone

Sod.acetate

Ethanol

Warm

C H 3

CH 3 C H 2

N N H 2

(1 E )-[2 -m ethyl-5 -(p ro p -1 -en-2 -yl)cyc lo hex-2 -en-1 -ylid ene]hyd raz ine

+ NH 2 N H 2

Hydrazine

Compound XIII

Compound 14:

O

CARVONE

Sod.acetate

Shake

N NHCONH2

(2E)-2-[2-methyl-5-(prop-1-en-2-yl)cyclohex-2-en-1-ylidene]hydrazinecarboxamide

semicarbazide

NH2 NH

O

NH2+

Compound XIVCompound 15:

O

Carvone

+NH2

NH2

EthanolReflux

o'-Phenylenediamine

N NCH3

CH3 CH2 CH3CH2

N,N'-Bis[(1e)-2-Methyl-5-(Prop-1-En-2-Yl)Cyclohex-2-En-1-Ylidine]Benzene-1,2-DiamineCompound XV

Compound 16.:

CH3

O

CH3 CH2

+ EthanolPyridineWarm

CH3

N

CH3 CH2

OH

Carvone (1E)-N-hydroxy-2-methyl-5-(prop-1-en-2-yl)cyclohex-2-en-1-im ine

NH2 OH

hydroxylam ine

Compound XVI

91

Fig.No.17. Schemes for synthesis of compound X111 – XVI

Synthesis of Camphor Derivatives

Compound17:

CH3

O

CH3 CH3

1-methylbicyclo[2.2.1]heptan-2-one

+

NH2

NH2

benzene-1,2-diamine

CH3

N

N

CH3

CH3CH3

CH3CH3

N,N'-bis-[(2E)-1-methylbicyclo[2.2.1]hept-2-ylidene]benzene-1,2-diamine-ethane(1:1)

Compound XVII

Compound18:

+Anhydrous ether

CH3

O

CH3 CH3

CH3O

O

CH3 CH3

1-methylbicyclo[2.2.1]heptan-2-one

MgCl

Benzyl megnesium chloride Compound XVIII

2 - benzyl -1,7,7 -methyl[2.2.1]hept -2-ylbenzoate

Compound 19:

CH3

O

+

NH2

aniline

CH3

N

CamphorCompound XIX

N-[(2E)-1,7,7-trimethylbicyclo[2.2.1]hept-2-ylidene]aniline

Fig.No.18. Schemes for synthesis of compound XVII -XIX

The above mentioned derivatives are synthesized, purified using

Thin Layer Chromatography and Column chromatography. The purified

compounds are further processed for physical analysis like meking

92

point, solubility etc and spectral analysis using FTIR, MASS, HNMR for

confirming the structure of the compound.

MATERIALS AND METHODSTable No.2. List of chemicals and their manufactures used for

synthesis

S.No Chemicals required Manufacturers

1 Carvone Gift Sample from Director,OTRI-JNTUA

2 Citral Gift Sample from Director,OTRI-JNTUA

3 Vanillin S.D.Fine Chem Pvt.Ltd, Boisar.

4 Camphor Finar chemical limited ahmedabad

5 Sodium acetate S.d-fine Chem. Ltd, Mumbai

62,4-DinitroPhenylhydrazine S.d-fine Chem. Ltd, Mumbai

7 Hydrazine Sulphate IDPL, Hyderabad8 Semicarbazine Sisco research laboratories, Mumbai

9 O-phenyl diamine Oxford lab, Mumbai

10 Hydroxylamine Sisco research laboratories, Mumbai11 Pyridine Merck specialties pvt.ltd

12 Ethanol Changshu yang Yuan chemical ltdChina

13 Benzophenone S.d-fine Chem. Ltd, Mumbai

14 Phenylhydrazine .HCl S.D.Fine Chem. Pvt.Ltd, India.

15 Iodine S.D.Fine Chem. Pvt.Ltd, India.

16 Hydroxylamine.HCl Sisco research lab, India.

17 Aniline Finar chemical limited ahmedabad

18 Formaldehyde Merck limited Mumbai

19 Conc. Hcl Finar chemical limited ahmedabad

20 Acetone S.D-Fine Chem.Ltd, Mumbai

21 Phenyl acetylene S.D-Fine Chem.Ltd, Mumbai

22 Anhydrous ether Finar chemical limited, Ahmedabad

93

23 Magnesium Merck limited, Mumbai

24 Ammonium Chloride Finar chemical limited,Ahmedabad

25 Benzoyl Chloride Finar chemical limited AhmedabadTable No 3. List of Equipments used during the Experiments:

S.No Equipment MAKE

1. IR SpectroPhotometer

Thermo Nicolet nexus 670spectrophotometer and SHIMADZU, FTIR-8400S.

2. Mass spectrophotometer Micromass Quatro II

3. Elemental Analyser Carlo Erba EA 1108

4. 1H NMR Gemini 300 MHz

5. Melting pointapparatus Toshniwal and Cintex

Instrumentation and general methodology:

All the melting points recorded in this thesis were determined in

open capillaries, using Toshniwal and Cintex melting point apparatus,

expressed in 0C and are uncorrected. The elemental analysis of the

synthesized compounds were determined by using Carlo Erba EA 1108

elemental analyzer expressed in percentage found. The IR spectra of

the compounds were recorded on Thermo Nicolet nexus 670

spectrophotometer using KBr discs and SHIMADZU, FTIR-8400S

expressed in cm-1. 1H NMR spectra were recorded on a Gemini 300

MHz spectrophotometer using TMS as an internal standard and the

values are expressed in δ ppm. Mass spectra of the compounds were

94

recorded by Micromass Quatro II Mass Spectrophotometer operating in

the ESI mode expressed in m/z.

Ia.Synthesis of Citral Derivatives

Procedure for synthesis of compound 1 (2-[(2z)-3,7-dimethylocta-

2,6-dien-1-ylidene]hydrazine carboxamide ) from citral. (Furniss BS,

2008)

1gm of Semicarbazine and 1.5gm of crystallized sodium acetate

was dissolved in 8-10ml of water, to this 0.5gm of the citral was added

and shaken for a while. To the above solution alcohol was added until

the clear solution was obtained. The mixture was shaken for few

minutes and allowed to stand for some time. Semicarbazone

crystallized from the cold solution on standing. Filtered off the crystals

and washed with cold water and recrystalized from dilute ethanol.

Procedure for synthesis of compound II ((2z)-N-

Diphenylmethylidene-3,7-Dimethylocta-2,6-Dienamide ) from

citral.(Brain’s and Furniss, 2008)

A mixture of 0.5gm of citral, 0.5gm of benzophenone oxime, 5ml

of ethanol and 0.5ml of pyridine was refluxed on a water bath for

30minutes. Ethanol was removed by evaporation in a stream of air. 5ml

of water was added to the cooled residue and kept in an ice bath and

stirred until the oxime crystallized out. The solid was filtered and

95

washed with a little water and dried. The dried product was

recrystallized using ethanol.

The structure and nomenclature of citral derivatives are represented in

Table No.4.

Ib.Synthesis of Vanillin Derivatives

Procedure for synthesis of compound III (4[(E)-

Hydrazinylidenemethyl]-2-Methoxyphenol) from Vanillin.

4-[(E)-hydrazinylidenemethyl]-2-methoxyphenol ( Compound III)

was synthesized by dissolving 0.5 gm of hydrazine sulphate and 0.8 gm

of sodium acetate in 5 ml of water. To the above mixture a solution of 2-

5gm of aldehyde (vanillin) in ethanol free from aldehydes and ketones

was added. The solution was shaken until a clear solution is formed

(add little more ethanol if necessary), warm on a water bath for 10-15

minutes and cool until the crystals appear, filter off the crystals and

recrystallize from dilute ethanol.

Procedure for synthesis of compound IV (2-Methoxy-4-[(E)-(2-

Phenylhydraziny lidene ) Methyl]Phenol ) from Vanillin.

2-methoxy-4-[(E)-(2-phenylhydrazinylidene)methyl]phenol was

prepared by dissolving 0.5 gm of colourless phenylhydrazine

hydrochloride and 0.8 gm of sodium acetate in 5 ml of water. To the

above mixture a solution of 2-5gm of aldehyde (vanillin) in ethanol free

from aldehydes and ketones was added. The solution was shaken until

96

a clear solution is formed (add little more ethanol if necessary), warm on

a water bath for 10-15 minutes and cool until the crystals appear, filter

off the crystals and recrystallize from dilute ethanol.

Procedure for synthesis of compoundV(4-{(E)[2-(2,4-Dinitrophenyl)

Hydrazinyl idene]Methyl}-2-Methoxy Phenol) from Vanillin.

4-{(E)-[2-(2,4-dinitrophenyl)hydrazinylidene]methyl}-

2methoxyphenol was prepared by dissolving 0.5 gm of 2,4

dinitrophenyhydrazine hydrochloride and 0.8 gm of sodium acetate in 5

ml of water. To the above mixture a solution of 2-5gm of aldehyde

(vanillin) in ethanol free from aldehydes and ketones was added. The

solution was shaken until a clear solution is formed (add little more

ethanol if necessary), warm on a water bath for 10-15 minutes and cool

until the crystals appear, filter off the crystals and recrystallise from

dilute ethanol.

Procedure for synthesis of compoundVI N-[(Z)-(4-Hydroxy-3-

Methylphenyl) Methylidene]Hydrazinecarboxamide from Vanillin.

N-[(Z)-(4 - hydroxy - 3 - methoxy phenyl) methylidene] hydrazine

carboxamide was prepared by dissolving 1.0 gm of semicarbazine

hydrochloride and 10.5gm of crystalline sodium acetate in 8-10 ml of

water. To the above mixture a solution of 2-5gm of aldehyde (vanillin) in

ethanol free from aldehydes and ketones was added. The solution was

shaken until a clear solution is formed (add little more ethanol if

97

necessary), warm on a water bath for 10-15 minutes and cool until the

crystals appear, filter off the crystals and recrystallise from dilute

ethanol.

Procedure for synthesis of compound VII 4,4'-{benzene-1,2-

diylbis[nitrilo(E) methylylidene]}bis(2-methoxyphenol from Vanillin.

4,4'-{benzene-1,2-diylbis[nitrilo(E)methylylidene]}bis(2-

methoxyphenol) was prepared by the reaction of Vanillin (0.010mol) and

o-Phenylenediamine (0.005mol) in ethanol under reflux for 3 h. The

precipitated product was filtered and recrystallised from the ethanol and

dried in vacuum over CaCl2.

Procedure for synthesis of compound VIII (2E)-3-(3-Hydroxy-2-

Methylphenyl)-1-Phenylprop-2-en-1-One from Vanillin.

2gm of NaoH in 18ml of water and 9ml of rectified spirit was taken

in a 500ml of bolt head flask provide with a mechanical stirrer. The flask

was immersed in a bath of a crushed ice, then 4.8 ml of freshly distilled

acetophenone was added and the stirring was started, During stirring

add 4.2gm of pure vanillin and the temperature of mixture was

maintained at about 250C and vigorous stirring was continued until

mixture becomes so thick that stirring is no longer effective. The stirrer

was removed and left overnight in an ice chest. The product was filtered

with suction and washed with cold water until the washings are neutral

to litmus, and then with 20ml of ice cold rectified spirit.

98

Procedure for synthesis of compound IX (1Z)-1-(4-Hydroxy-3-

Methoxyphenyl) Pent-1-en-3-one from Vanillin.

2gm of NaoH in 18ml of water and 9ml of rectified spirit was taken

in a 500ml of bolt head flask provide with a mechanical stirrer. The flask

was immersed in a bath of a crushed ice, then 4.8 ml of freshly distilled

ethylmethylketone was added and the stirring was started, During

stirring add 4.2gm of pure vanillin and the temperature of mixture was

maintained at about 250C and vigorous stirring was continued until

mixture becomes so thick that stirring is no longer effective. The stirrer

was removed and left overnight in an ice chest. The product was filtered

with suction and washed with cold water until the washings are neutral

to litmus, and then with 20ml of ice cold rectified spirit.

Procedure for synthesis of compound X {3-[(Z)-(3-Hydroxy-2-

Methoxycyclohexa-2,4-Dien-1-Ylidene)MethylPhenyl}(Phenyl)

Methanone from Vanillin.

2gm of NaoH in 18ml of water and 9ml of rectified spirit was taken

in a 500ml of bolt head flask provide with a mechanical stirrer. The flask

was immersed in a bath of a crushed ice, then 4.8gms of pure

benzophenone was added and the stirring was started, During stirring

add 4.2gm of pure vanillin and the temperature of mixture was

maintained at about 250C and vigorous stirring was continued until

99

mixture becomes so thick that stirring is no longer effective. The stirrer

was removed and left overnight in an ice chest. The product was filtered

with suction and washed with cold water until the washings are neutral

to litmus, and then with 20ml of ice cold rectified spirit. The crude

chalcone after drying in the air weigh 2.7gms and melts at 950c.

Recrystallised using rectified spirit at to 50oC.

Procedure for synthesis of compound XI 4-[(Z)-2-{[(2e,3z)-3-

(Hydroxyimino) Butan-2-Ylidene]Amino}Ethenyl]-2-Methoxyphenol

from Vanillin.

2gm of NaoH in 18ml of water and 9ml of rectified spirit was taken

in a 500ml of bolt head flask provide with a mechanical stirrer. The flask

was immersed in a bath of a crushed ice, then 4.8 ml of freshly distilled

dimethyl aldehyde was added and the stirring was started, During

stirring add 4.2gm of pure vanillin and the temperature of mixture was

maintained at about 250C and vigorous stirring was continued until

mixture becomes so thick that stirring is no longer effective. The stirrer

was removed and left overnight in an ice chest. The product was filtered

with suction and washed with cold water until the washings are neutral

to litmus, and then with 20ml of ice cold rectified spirit. Recrystallised

using rectified spirit, m.p. 1000C

The Structure and nomenclature of vanillin derivatives are represented

in Table No.5 and 6.

100

Ic.Synthesis of Carvone Derivatives

Procedure for synthesis of compound XII (2E)-1-(2,4-

Dinitrophenyl)-2-[2-Methyl-5-(Prop-1-en-2-yl)cyclohex-2-en-1-

ylidene]Hydrazine from Carvone.

0.5gm 2,4-dinitro phenyl hydrazine and 0.8gm of sodium acetate

was dissolved in 5ml of water, and a solution of 0.2-0.4g of carvone in a

little ethanol was added and the mixture was stirred until clear solution

appears. Then warm on water bath for 10-15minutes and cooled to

obtain product. The product was filtered using Buchnaer funnel and

washed with cold water and dried. Recrystallize by using ethanol.

Procedure for synthesis of compound XIII (1E)-[2-Methyl-5-(Prop-1-

en-2-yl) cyclohex-2-en-1-ylidene]Hydrazine from Carvone.

0.5gm hydrazine and 0.8gm of sodium acetate was dissolved in

5ml of water, and a solution of 0.2-0.4g of carvone in a little ethanol was

added and the mixture was shaken until clear solution appears. Then

warm on water bath for 10-15minutes and cooled to obtain product. The

product was filtered using Buchnaer funnel and washed with cold water,

dried and recrystallized using ethanol.

Procedure for synthesis of compound XIV (2E)-2-[2-Methyl-5-(Prop-

1-en-2-yl)Cyclohex-2-en-1-Ylidene]Hydrazine Carboxamide from

Carvone.

101

1gm of semi carbazine and 1.5gm of crystallized sodium acetate

was dissolved in 8-10ml of water to this mixture, 0.5gm of the carvone

was added and shaken for a while, then minute quantity of alcohol was

added and continued shaking until a clear solution was obtained. Then

the mixture was allowed to stand for crystallization of semicarbazone.

The crystals were filtered and washed with cold water and recrystalized

from dilute ethanol.

Procedure for synthesis of compound XV N,N’-Bis[(1E)-2-Methyl-5-

(Prop-1-en-2-yl)cyclohex-2-En-1-ylidine]Benzene-1,2-Diamine from

Carvone.

Carvone and ortho phenylenediamine (0.005mol) in ethanol was

taken in a 250ml RBF and refluxed under for 3 hours. Allow the mixture

to cool. The precipitated product was filtered and recrystalized from the

ethanol and dried in vacuum over calcium chloride.

Procedure for synthesis of compound XVI (1E)-n-Hydroxy-2-

Methyl-5-(Prop-1-en-2-yl)cyclohex-2-en-1-Imine from Carvone.

A mixture of 0.5gm of carvone, 0.5gm of hydroxylamine, 5ml of

ethanol and 0.5ml of pyridine was refluxed on a water bath for

30minutes. Remove the ethanol by evaporation of the hot solution in a

stream of air, cool.. To the above mixture 5ml of water was added and

kept in an ice bath and stirred until the oxime crystallizes out. The solid

102

was filtered and washed with little water, dried and recrystalized using

ethanol.

The structure and nomenclature of carvone derivatives are represented

in Table No.7 and 8.

Id.Synthesis of Camphor Derivatives

Procedure for synthesis of compound XVII N,N’-Bis-[(2E)-1-

Methylbicyclo [2.2.1] Hept-2-ylidene]Benzene-1,2-Diamine-

Ethane(1:1) from Camphor.

1 gm of Orthophenylene diamine dissolved in 10ml of ethanol and

1gm of camphor was taken in a 50ml round bottom flask. The mixture

was heated for 3hrs on a water bath with occasional stirring. The

product precipitates out as fine crystals. The crystals were filtered out

and recrystallized using ethanol and dried in vacuum over calcium

chloride.

Procedure for synthesis of compound XVIII 2-Benzyl-1-

Methylbicyclo [2.2.1] Hept-2-Benzoate from Camphor

A solution of Chloro (phenyl) magnesium in 50ml of anhydrous

ether was prepared from 27.3gm of ethyl bromide and 6gm of

magnesium. After cooling, 25.5gms phenyl acetylene in 30ml of

anhydrous ether was added drop wise. The reaction mixture was gently

refluxed for 2hrs and cooled to room temperature. Then the mixture was

slowly stirred and a solution of 45gm of benzophenone in 50ml of

103

anhydrous ether was added and continued stirring at room temp for 1.5

hrs. Then the mixture was refluxed for 1hr and cooled in an ice bath.

55gm of ammonium chloride as a saturated agues solution was added

and the product starts liberating out, the residue oil was kept in ice and

triturate with light petroleum until the buttery phenyl propynol crystallizes

out. Recrystallize using a mixture of benzyl and light petroleum.

Procedure for synthesis of compound XIX N-[(2E)-1-

Methylbicyclo[2.2.1]Hept-2-Ylidene]Aniline from Camphor

5.3gm of dry aniline, 2gm of powdered paraformaldehyde and

6gm of camphor was taken in a 50ml round bottom flask attached to a

reflux condenser. 8ml of 95% ethanol to which 2-3 drops of Conc.HCl

acid have been added was introduced into the reaction mixture and

refluxed on a water bath for 1 hour. The reaction mixture was almost

clear and homogenous. The yellowish solution was filtered through a

pre heated Buchner funnel and the filterate was transfered to a 100ml

wide mouthed conical flask and still warm. 40ml of acetone was added

and allowed to cool room temperature and placed on an ice bath to

obtain crystals. Crystals are filtered at the pump and washed with 2-3ml

of acetone. Acetone was drained and crystals are dried in steam oven

for 30min. Crude product obtained was recrystallized using hot rectified

spirit and the yield of product was 7.4gm, m.p-153-1550C

104

The structure and nomenclature of camphor derivatives are represented

in Table No.4.

Identification and Characterization:

The identification and characterization of synthesized compounds

were carried out by the following procedure to ascertain that all

prepared compounds had different chemical nature than the respective

parent compounds. The yields of the synthesized derivatives are

represented in Table No.11.

Melting point

Solubility

Elemental analysis

Thin layer chromatography

Infrared spectroscopy

Nuclear Magnetic Resonance spectroscopy (N.M.R)

Mass spectroscopy

Melting point determination:

The melting points of the organic compounds were determined by

open capillary tube method. Melting point is a valuable criterion of purity

for an organic compound as a pure crystal is having definite and sharp

melting point. The purity should not be assumed but must be

established by observation of any changes in the melting point when the

compound is subjected to purification by recrystallisation. The

synthesized compounds showed a minute change in melting point after

105

recrystallisation. The melting points of the compounds were reported in

Table No.11.

Solubility:

The solubility of the synthesized compounds was tested in

various solvents. All the synthesized compounds are soluble in Dimethyl

sulphoxide, Dimethyl formamide, Chloroform and Methanol.

Elemental analysis:

The elemental analysis(C, H and N) of the synthesized

compounds were determined by using Carlo Erba EA 1108 elemental

analyzer. The calculated and found percentages of the elements are

presented in Table No.13.

Thin layer chromatography:

Chromatography is an important technique to identify the

formation of new compounds and also to determine the purity of the

compound. The Rf value is characteristic for each of the compound.

Preparation of chromatography plate:

Clean and dry glass plates were taken. Uniform slurry of silica

Gel-G in water was prepared in the ratio of 1:2. The slurry was then

poured into the chamber of the TLC applicator, which was fixed and the

thickness was set to 0.5mm, glass plates were moved under the

applicator smoothly to get uniform coating of slurry on the plates.

106

The plates dried first at room temperature and then kept for

activation at 110oC for 1 hour.

Preparation of solvent system and saturation of chamber:

The solvent system used for the development of chromatogram

was prepared carefully by mixing ethyl acetate: chloroform (0.5ml:

1.5ml).

Application of sample:

The solution of the parent compound and its derivatives were

taken in small bored capillary tube and spotted at 2 cm from the base

end of the plate. After spotting the plates were allowed to dry at room

temperature and plates were transferred to chromatographic chamber

containing solvent system for development.

Development of chromatogram:

Plates were developed by ascending technique when solvent

front had reached a distance of 10-12 cm. They were taken out and

dried at room temperature.

Detection of spots:

The developed spots were detected by exposing them to iodine

vapours.

Calculation of Rf values:

The Rf values of compounds were calculated using the formula.

107

Rf value = Distance moved by sample from origin line / Distance

moved by solvent front from origin line

In all these cases the distance traveled by the sample was found to be

different from that of the parent compound spotted along with it. Thus

confirming that the compound formed was entirely different from that of

the parent compound. Moreover since the entire sample gave a single

spot, the compounds were taken to be free from impurities. The Rf

values of compounds and solvent system used are presented in Table

No.12.

FT-IR Spectra:

The peaks in IR spectrum gives an idea about the probable

structure of the compound, IR region ranges between 4000-666cm-1

quanta of radiation from this region of the spectrum corresponds to

energy differences between different vibrational levels of molecules.

The compounds were recorded on Thermo Nicolet nexus 670,

and SHIMADZU, FTIR-8400S spectrophotometer by using KBr pellet

technique showed different vibration levels of molecules.

The characteristic absorption bands of the few of the

synthesized compounds are presented in Table No.14.

1H NMR spectra:

NMR spectroscopy enables us to record differences in magnetic

properties of the various magnetic nuclei present and to deduce in the

108

large measure about the position of these nuclei within the molecule.

We can deduce how many different kinds of environments are there in

the molecules and also which atoms are present in neighboring groups.

The proton NMR spectra enable us to know different chemical

and magnetic environments corresponding to protons in molecules.

The samples were analyzed on Gemini 300 MHz spectrometer.

The proton NMR spectrums of the synthesized compounds are

presented in Table No.15.

Mass spectroscopy:

Mass spectroscopy enables us to know;

a) Relative molecular masses (molecular weights) with very high

accuracy, from this exact molecular formula can be deduced.

b) To detect within the molecules the places at which it prefers

fragmentation, from this we can deduce the presence of

recognizable groups within the molecule.

c) As a method of identifying analytes by comparison of their mass

spectra with libraries of digitalized mass spectra of known

compounds.

Mass spectra of title compounds were recorded on Micromass Quatro II

MassSpectrophotometer.

109

Table No.4 Structure and nomenclature of Citral derivatives (Compound I, II)

S. No Compound Mol.formula Chemical name Structure

1 I C11H19N3O

2-[(2Z)-3,7-DIMETHYLOCTA-2,6-DIEN-1-

YLIDENE] HYDRA ZINE CARBOXAMIDE

CH3

CH3CH3

N NH C

O

NH2

2 II C23H25NO

(2Z)-N-DIPHENYLMETHYLIDENE-3,7-

DIMETHYLOCTA-2,6-DIENAMIDE N

CH3

CH3

CH3

O

110

Table No.5 Structure and nomenclature of Vanillin derivatives (Compound III - V).

S. No Compound Mol.formula Chemical name Structure

3 III C8H10N2O2

4[(E)-HYDRAZINYLIDENEMETHYL]-2-

METHOXY PHENOL

OH

OCH3

N

NH2

4 IV C14H14N2O2

2-METHOXY-4-[(E)-(2-

PHENYLHYDRAZINYLIDENE) METH

YL]PHENOL

OH

OCH3

N

NH

5 V C14H12N4O6

4-{(E)[2-(2,4-

DINITROPHENYL)HYDRAZINYLIDENE]

METH YL}-2-METHOXY PHENOL

OH

OCH3

N

NH

O2N NO2

111

Table No.6 Structure and nomenclature of Vanillin derivatives (Compound VI - VIII)

S. No Compound Mol.formula Chemical name Structure

6 VI C9H11N3O3

N-[(Z)-(4-HYDROXY-3-ETHYLPHENYL)

METHYLIDENE]HYDRA

ZINECARBOXAMIDE OCH3

OH

N NH

O

NH2

7 VII C22H20N2O4

4,4'-{BENZENE-1,2-DIYLBIS[NITRILO(E)

METHYLYLIDENE]}BIS (2-METHOXY

PHENOL)

N N

OH

O

CH3

OH

O

CH3

8 VIII C16H14O3

(2E)-3-(3-HYDROXY-2-

METHYLPHENYL)-1-PHENYLPROP-2-

EN-1-ONEO

O

OH CH3

112

Table No.7 Structure and nomenclature of Vanillin derivatives (Compound IX - XI)

S. No Compound Mol.formula Chemical name Structure

9 IX C12H14O3

(1Z)-1-(4-HYDROXY-3-

METHOXYPHENYL)PENT-1-EN-3-ONE

H

O

CH3OH

O

CH3

10 X C21H18O3

{3-[(Z)-(3-HYDROXY-2-

METHOXYCYCLOHEXA-2,4-DIEN-1-YL

IDENE) METHY PHENYL}(PHENYL)

METH ANONE OH

O

CH3

O

11 XI C13H16N2O3

4-[(Z)-2-{[(2E,3Z)-3-

(HYDROXYIMINO)BUTAN-2-YLIDENE]

AMINO}ETHENYL]-2-METHOXYPHENOL

H

O

CH3OH

N

CH3 N

CH3

OH

113

Table No.8 Structure and nomenclature of Carvone derivatives (Compound XII -XIV )

S. No Compound Mol.formula Chemical name Structure

12 XII C16H18N4O4

(2E)-1-(2,4-DINITROPHENYL)-2-[2-

METHYL-5-(PROP-1-EN-2-YL) CYCLOHEX-

2-EN-1-YLIDENE]HYDRAZINE

CH3

CH3

CH2

N

NH

O2N

NO2

13 XIII C10H16N2

(1E)-[2-METHYL-5-(PROP-1-EN-2-

YL)CYCLOHEX-2-EN-1-

YLIDENE]HYDRAZINE

CH3

CH3 CH2

N NH2

14 XIV C11H17N3O

(2E)-2-[2-METHYL-5-(PROP-1-EN-2-

YL)CYCLOHEX-2-EN-1-

YLIDENE]HYDRAZINE CARBOXAMIDE

N

CH3 CH2

CH3

NH NH2

O

114

Table No.9 Structure and nomenclature of Carvone derivatives (Compound XV - XVI)

S. No Compound Mol.formula Chemical name Structure

15 XV C25H30N2

N,N’-BIS[(1E)-2-METHYL-5-(PROP-1-EN-2-

YL)CYCLOHEX-2-EN-1-

YLIDINE]BENZENE-1,2-DIAMINE

N NCH3

CH3 CH2 CH3CH2

16 XVI C10H15NO

(1E)-N-HYDROXY-2-METHYL-5-(PROP-1-

EN-2-YL) CYCLO HEX -2-EN-1-IMINE

CH3

N

CH3 CH2

OH

115

Table No.10 Structure and nomenclature of Camphor derivatives (Compound XVII - XIX)

S. No Compound Mol.formula Chemical name Structure

17 XVII C26H40N2

N,N’-BIS-[(2E)-1,7,7-

TRIMETHYLBICYCLO[2.2.1]HEPT-2-

YLIDENE]BENZENE-1,2-DIAMINE-

ETHANE(1:1)

CH3

N

N

CH3

CH3CH3

CH3CH3

18 XVIII C24H30O2

2-BENZYL-1,7,7-

TRIMETHYLBICYCLO[2.2.1]HEPT-2-

BENZOATE

CH3O

O

CH3 CH3

19 XIX C16H23N

N-[(2E)-1,7,7-

TRIMETHYLBICYCLO[2.2.1]HEPT-2-

YLIDENE]ANILINE

CH3

N

CH3 CH3

116

Fig.No.19. FT-IR Spectrum of Compound

Fig. No.18. FT-IR of compound I

117

Fig.No.19. HNMR Spectrum of Compound I

CH3

CH3CH3

N NH C

O

NH2

118

Fig.No.21. MASS Spectrum of Compound I

Fig.No.20. MASS spectrum of compound I

CH3

CH3CH3

N NH C

O

NH2

119

Fig.No.21. FT-IR Spectrum of Compound II

120

Fig.No.22. HNMR Spectrum of Compound II

N

CH3

CH3

CH3

O

121

Fig.No.23. MASS Spectrum of Compound II

N

CH3

CH3

CH3

O

122

Fig.No.24. FT-IR Spectrum of Compound III

123

Fig.No.25. HNMR Spectrum of Compound III

OH

OCH3

N

NH2

124

Fig.No.26. MASS Spectrum of Compound III

OH

OCH3

N

NH2

125

Fig.No.27. FT-IR Spectrum of Compound IV

126

Fig.No.28. HNMR Spectrum of Compound IV

OH

OCH3

N

NH

127

Fig.No.29. MASS Spectrum of Compound IV

OH

OCH3

N

NH

128

Fig.No.30. FT-IR Spectrum of Compound V

129

Fig.No.31. HNMR Spectrum of Compound V

OH

OCH3

N

NH

O2N NO2

130

Fig.No.32. MASS Spectrum of Compound V

OH

OCH3

N

NH

O2N NO2

131

Fig.No.33. FT-IR Spectrum of Compound VI

132

Fig.No.34. HNMR Spectrum of Compound VI

OCH3

OH

N NH

O

NH2

133

Fig.No.35. MASS Spectrum of Compound VI

OCH3

OH

N NH

O

NH2

134

Fig.No.36.FT-IR Spectrum of Compound VII

135

Fig.No.37. HNMR Spectrum of Compound VII

N N

OH

O

CH3

OH

O

CH3

136

Fig.No.38. MASS Spectrum of Compound VII

N N

OH

O

CH3

OH

O

CH3

137

Fig.No.39. FT-IR Spectrum of Compound VIII

138

Fig.No.40. HNMR Spectrum of Compound VIII

O

O

OH CH3

139

Fig.No.41. MASS Spectrum of Compound VIII

O

O

OH CH3

140

Fig.No.42. FT-IR Spectrum of Compound IX

141

Fig.No.43. HNMR Spectrum of Compound IX

H

O

CH3OH

O

CH3

142

Fig.No.44. MASS Spectrum of Compound IX

H

O

CH3OH

O

CH3

143

Fig.No.45. FT-IR Spectrum of Compound X

144

Fig.No.46. HNMR Spectrum of Compound X

OH

O

CH3

O

145

Fig.No.47. MASS Spectrum of Compound X

OH

O

CH3

O

146

Fig.No.48. FTIR Spectrum of Compound XI

147

Fig.No.49. HNMR Spectrum of Compound XI

H

O

CH3OH

N

CH3 N

CH3

OH

148

Fig.No.50. MASS Spectrum of Compound XI

H

O

CH3OH

N

CH3 N

CH3

OH

149

Fig.No.51. FT-IR Spectrum of Compound XII

150

Fig.No.52. HNMR Spectrum of Compound XII

CH3

CH3

CH2

N

NH

O2N

NO2

151

Fig.No.53. MASS Spectrum of Compound XII

CH3

CH3

CH2

N

NH

O2N

NO2

152

Fig.No.54. FT-IR Spectrum of Compound XIII

153

Fig.No.55. HNMR Spectrum of Compound XIII

CH3

CH3 CH2

N NH2

154

Fig.No.56. MASS Spectrum of Compound XIII

CH3

CH3 CH2

N NH2

155

Fig.No.57. FT-IR Spectrum of Compound XIV

156

Fig.No.58. HNMR Spectrum of Compound XIV

N

CH3 CH2

CH3

NH NH2

O

157

Fig.No.59. MASS Spectrum of Compound XIV

N

CH3 CH2

CH3

NH NH2

O

158

Fig.No.60. FT-IR Spectrum of Compound XV

159

Fig.No.61. HNMR Spectrum of Compound XV

N NCH3

CH3 CH2 CH3CH2

160

Fig.No.62. MASS Spectrum of Compound XV

N NCH3

CH3 CH2 CH3CH2

161

Fig.No.63. FT-IR Spectrum of Compound XVI

162

Fig.No.64. HNMR Spectrum of Compound XVI

CH3

N

CH3 CH2

OH

163

Fig.No.65. MASS Spectrum of Compound XVI

CH3

N

CH3 CH2

OH

164

Fig.No.66. FT-IR Spectrum of Compound XVII

CH3

N

N

CH3

CH3CH3

CH3CH3

165

Fig.No.67. HNMR Spectrum of Compound VII

CH3

N

N

CH3

CH3CH3

CH3CH3

166

Fig.No.68. MASS Spectrum of Compound XVII

CH3

N

N

CH3

CH3CH3

CH3CH3

167

Fig.No.69. FT-IR Spectrum of Compound XVIII

168

Fig.No.70. HNMR Spectrum of Compound XVIII

CH3O

O

CH3 CH3

169

Fig.No.71. MASS Spectrum of Compound XVIII

CH3O

O

CH3 CH3

170

Fig.No.72. FT-IR Spectrum of Compound XIX

171

Fig.No.73. HNMR Spectrum of Compound XIX

CH3

N

CH3 CH3

172

Fig.No.74. MASS Spectrum of Compound XIX

CH3

N

CH3 CH3

173

PHARMACOLOGICAL SCREENING

Acute Toxicity Studies: (Anne monks, 19991) Healthy and adult male

albino swiss mice weighing between 20-25g were used in this

investigation. Animals were fasted for 24 hours and divided into groups

of six animals each. The test compounds, suspended in sodium

carboxymethyl cellulose (CMC) solution (0.1%) were administered

intraperitoneally in doses of 5mg to 1000mg per kg (b.w.). The control

groups of animals received only the vehicle (0.1% sodium CMC). The

animals were observed for 48 hours from the time of administration of

test compound to record the mortality. It is approved by Institutional

Animal Ethical Commite (SSRCP/41/2010/CPCSEA-6755, Date: 09-11-

2010), a copy of the same is enclosed at the end of the thesis.

Anti-bacterial activity:The compounds (I-XIX) synthesized were

evaluated for antibacterial activity as per the reported methods 238.

The antibacterial activity of synthesized compounds was

performed against two gram positive bacteria viz., B.subtilis and

S.aureus and two gram negative bacteria viz., E.coli and P. vulgaris by

using cup plate method. Ampicillin sodium was employed as standard

to compare the results.

Culture medium: Nutrient broth was used for the preparation of

inoculum of the bacteria and nutrient agar was used for the screening

method.

174

Composition of Nutrient agar medium

Peptone 5.0 gmSodium chloride 5.0 gmBeef extract 1.5 gmYeast extracts 1.5 gmAgar 15.0 gmDistilled water up to 1000 mlpH 7.4 ± 0.2

The test organisms were subcultured using nutrient agar medium.

The tubes containing sterilized medium were inoculated with respective

bacterial strain. After incubation at 37 ±1oC for 24 hours, they were

stored in refrigerator. The stock cultures were maintained. Bacteria

inoculum was prepared by transferring a loopful of stock culture to

nutrient broth (100 ml) in conical flasks (250 ml). The flasks were

incubated at 37oC ±1oC for 48 hours before the experimentation.

Solution of the test compounds were prepared by dissolving 10mg each

in dimethylformamide (10 ml, AR grade). A reference standard for both

gram positive and gram negative bacteria was made by dissolving

accurately weighed quantity of ampicillin sodium in sterile distilled

water, separately.

The nutrient agar medium was sterilized by autoclaving at 121oC

(15 lb/sq. inches) for 15 min. The petriplates, tube and flasks plugged

with cotton were sterilized in hot-air oven at 160oC, for an hour. Into

each sterilized petriplate (10 cm diameter), about 27 ml of molten

nutrient agar medium was poured and inoculated with the respective

175

strain of bacteria (6 ml of inoculum to 300 ml of nutrient agar medium)

was transferred aseptically. The plates were left at room temperature to

allow the solidification. In each plate, three cups of 6 mm diameter

were made with sterile borer. Then 0.1 ml of the test solution was

added to the respective cups aseptically and labeled, accordingly. The

plates were kept undisturbed for at least 2 hours in refrigerator to allow

diffusion of the solution properly into nutrient agar medium. After

incubation of the plates at 37o ± 1oC for 24 hours, the diameter of zone

of inhibition surrounding each of the cups was measured with the help

of an antibiotic zone reader. All the experiments were carried out in

triplicate. Simultaneously, controls were maintained employing 0.1 ml

of dimethyl formamide to observe the solvent effects. The results are

presented in Tables No.16.

Antifungal Activity:

The compounds (I-XIX) synthesized using the above mentioned

procedures were evaluated for antifungal activity as per the reported

methods (British pharmacopoeia, 1953)

All those compounds screened for antibacterial activity were also tested

for their antifungal activity. The fungi employed for screening were

A.niger, A.flavus, F.oxysporum and C.verticulata. The test organisms

were sub-cultured using potato-dextrose-agar medium. The tubes

containing sterilized medium were inoculated with test fungi and after

176

incubation at 25oC for 48 hours, they were stored at 4oC in refrigerator.

The inoculum was prepared by taking a loopful of stock culture to about

100 ml of nutrient broth, in 250 ml conical flasks. The flasks were

incubated at 25oC for 24 hours before use.

The solutions of test compounds were prepared by a similar

procedure described under the antibacterial activity. Reference

standard (1mg/ml conc.) was prepared by dissolving 10 mg of

clotrimazole in 10 ml of dimethylformamide (AR grade). Further, the

dilution was made with dimethylformamide itself to obtain a solution of

100 g/ml concentration.

The potato-dextrose-agar medium was sterilized by autoclaving at

121oC (15 lb/sq. inches) for 15 minutes. The petriplates, tubes and

flasks with cotton plugs were sterilized in hot-air oven at 150oC, for an

hour. In each sterilized petriplate, about 27 ml of molten potato-

dextrose-agar medium inoculated with respective fungus (6 ml of

inoculum in 300 ml of potato-dextrose medium) was added aseptically.

After solidification of the medium at room temperature three discs of 6

mm diameter were made in each plate with a sterile borer. Accurately

0.1 ml (100 g/disc) of test solution was transferred to the discs

aseptically and labeled, accordingly. The reference standard, 0.1ml (10

g/disc) was also added to the discs in each plate. The plates were

kept undisturbed at room temperature for 2 hours, at least to allow the

177

solution to diffuse properly into the potato-dextrose-agar medium. Then

the plates were incubated at 25oC for 48 hours. The diameter of the

zone of inhibition was read with the help of an antibiotic zone reader.

The experiments were performed in triplicate in order to minimize the

errors. The results are presented in Table.No.190.

Anthelmintic activity: (Dash GK, 2003)

The synthesized compounds were screened for Anthelmintic

activity by using earth worms. Six Indian adult earth worms (Pheretima

postuma) of nearly equal size 5-8 cm in length and 0.2-0.3cm in width

were placed in standard drug solution and test compound solutions at

room temperature. Normal saline was used as control. The standard

drug and test compounds were dissolved in minimum quantity of

dimethyl formamide (DMF) and adjusted the volume up to 15ml with

normal saline solution to get the concentration of 0.1%w/v, 0.2%w/v and

0.5%w/v. Albendazole was used as standard drug. The compounds

were evaluated for the time taken for complete paralysis and death of

earthworms. The mean lethal time for each test compound was

recorded and compared with standard drug. The time taken by worms

to become motionless was noted as paralysis time.

To ascertain the death of motionless worms, they were frequently

applied with external stimuli, which stimulate and induce movement in

the worms, if alive. The mean lethal time and paralysis time of the earth

178

worms for different test compounds and standard drug were tabulated in

Tables No.21.

The results of all the above mentioned experiments are discussed

in next chapter.

In – vitro antioxidant studies:

Chemicals and Reagents:

ABTS [2,2’-azino-bis (3-ethylbenzo-thiazoline-6-sulfonic acid)]

diammonium salt was obtained from Sigma Aldrich Co, St Louis,

USA.and p-nitroso dimethyl aniline (p-NDA) were obtained from Acros

Organics, New Jersey, USA. Ascorbic acid, Nitro blue tetrazolium (NBT)

were obtained from SD Fine Chemicals Ltd., Mumbai, India. 2-Deoxy –

D-ribose was obtained from Himedia Laboratories Pvt. Ltd., Mumbai,

India. All other chemicals used were of analytical grade.

The scavenging of DPPH was performed using 2, 2- Diphenyl 1-

picryl hydrazyl solution (DPPH, 100 μM): Accurately weighed 22 mg of

DPPH and dissolved in 100 ml 0f methanol. From this stock solution, 18

ml was diluted to 100 ml with methanol to obtain 100 μM DPPH

solutions.

The scavenging of nirtric oxide radicals was performed using

Sodium nitroprusside solution (10 Mm): Weighed accurately 0.30 g of

sodium nitroprusside and dissolved in dissolved in distilled water to

make up the volume to 100 ml in a volumetric flask.

179

Naphthyl ethylene diamine dihydrochloride (NEDD): Weighed

accurately 0.1 g of NEDD and dissolved in 60 ml of 50% glacial acetic

acid by heating and made up the volume to 100 ml with distilled water in

a volumetric flask.

Sulphanilic acid reagent (0.33% W/V): Weighed accurately 0.33 g

of sulphanilic acid and dissolved in 20% glacial acetic acid by heating

and made up the volume to 100 ml in a volumetric flask.

A. Scavenging of ABTS radical cation

This method involves the scavenging of ABTS [2, 2΄azino bis (3-

ethylbenzo- thiazoline – 6- sulphuric acid)] radical cation. The principle

behind the technique involves the reaction between ABTS and

potassium persulphate to produce the ABTS radical action, a blue green

chromogen. In the presence of antioxidant reductant the coloured

radical is converted back to colourless ABTS, the absorbance of which

is measured at 734 nm.

Preparation of standard solutions: Required amount of ascorbic acid

was accurately weighed and dissolved in distilled water to prepare 1

mM stock solution. Solutions of different concentrations of ascorbic

acid 10 nM, 30 nM, 100 nM, 300 nM, 1 M, 3 M, 100 M, 300 M, 1

mM were prepared from stock solution.

Preparation of test compound solutions: Required amount of test

compound was dissolved in methanol and 1mM stock solution was

180

prepared. Solutions of concentrations ranging from 100 nM to 1 mM

were prepared from the stock solution.

Preparation of ABTS solution:

ABTS (54.8 mg) was dissolved in 50 ml of distilled water to 2 mM

concentration and potassium persulphate (17 mM) 0.3 ml was added.

The reaction mixture was left to stand at room temperature overnight in

dark before usage.

Standard graph of ascorbic acid: 0.16 ml of ABTS solution and 1 ml

of DMSO was added to 2.8 ml of ascorbic acid solution in a test tube

wrapped with aluminium foil and its absorbance was read out at 517 nm

using UV-visible double beam spectrophotometer. The results were

plotted on a graph and IC50 value was determined.

ABTS Assay procedure for the test compounds:

To 0.2 ml of various concentrations of the test compounds, 1.0 ml of

distilled DMSO and 0.16 ml of ABTS solution was added to make a final

volume of 1.36 ml. Absorbance was measured spectrophotometrically,

after 20 min at 734 nm. The assay was performed in triplicates.

The IC50 values of test compounds were determined by the procedure

similar to ascorbic acid determination.

B. Scavenging of DPPH:

The DPPH free radical is reduced to a corresponding hydrazine when it

reacts with hydrogen donors. The DPPH radical is purple in colour and

181

upon reaction with hydrogen donor’s changes to yellow in colour. It is a

discoloration assay, which is evaluated by the addition of the antioxidant

to a DPPH solution in ethanol or methanol and the decrease in

absorbance was measured.

Preparation of standard ascorbic acid solutions: Required amount

of ascorbic acid was accurately weighed and dissolved in distilled water

to prepare 1 mM stock solution. Solutions of different concentrations of

ascorbic acid 10 nM, 30 nM, 100 nM, 300 nM, 1 M, 3 M, 100 M, 300

M, 1 mM were prepared from stock solution.

Preparation of test compound solutions: Required amount of test

compound was dissolved in methanol and 1mM stock solution was

prepared. Solutions of concentrations ranging from 100 nM to 1 mM

were prepared from the stock solution.

Preparation of DPPH solutions: 0.05 mM of DPPH was prepared by

dissolving 19.71 mg of DPPH in 100 ml of methanol. The solution was

protected from sunlight to prevent the oxidation of DPPH.

Standard graph of ascorbic acid: 0.2 ml of DPPH solution was added

to 2.8 ml of ascorbic acid solution in a test tube wrapped with aluminium

foil and its absorbance was read out at 517 nm using UV-visible double

beam spectrophotometer. The results were plotted on a graph and IC50

value was determined.

DPPH Assay procedure for the test compounds:

182

Aq. soln

0.2 ml of DPPH solution was added to 2.8 ml of the test compounds in a

test tube wrapped with aluminium foil and its absorbance was read out

at 517 nm using UV-visible double beam spectrophotometer. The

assay was performed in triplicates.

The IC50 values of test compounds were determined by the procedure

similar to ascorbic acid determination.

C. Scavenging of Nitric oxide radical

Sodium nitroprusside in aqueous solution at physiological pH,

spontaneously generates nitric oxide, which interacts with oxygen to

produce nitrite ions, which can be estimated by the use of modified

Griess Illosvay reaction251. In the present investigation, Griess Illovay

reagent is modified by using Naphthyl ethylene diamine dichloride

(0.1% W/V) instead of 1-naphthylamine (5%). Nitrite ions react with

Griess reagent, which forms a purple azo dye. In presence of test

components, likely to be scavengers, the amount of nitrites will

decrease. The degree of decrease in the formation purple azo dye will

reflect the extent of scavenging. The absorbance of the chromophore

formed was measured at 540 nm.

Sodium Nitroprusside NO (Nitric Oxide)

NO HNO3 + HNO2Nitric Acid Nitrous Acid

Preparation of standard ascorbic acid solutions: Required amount

of ascorbic acid was accurately weighed and dissolved in distilled water

Dissolved O2/ Water

183

to prepare 1 mM stock solution. Solutions of different concentrations of

ascorbic acid 10 nM, 30 nM, 100 nM, 300 nM, 1 M, 3 M, 100 M, 300

M, 1 mM were prepared from stock solution.

Preparation of test compound solutions: Required amount of test

compound was dissolved in methanol and 1mM stock solution was

prepared. Solutions of concentrations ranging from 100 nM to 1 mM

were prepared from the stock solution.

Standard graph of ascorbic acid: The reaction mixture (6 ml)

containing sodium nitroprusside (10 millimole, 4ml), phosphate buffer

saline (PBS, PH 7.4, 1 ml was added to 2.8 ml of the ascorbic acid

solution and incubated at 25 ºC for 15 min. After incubation, 0.5 ml of

the reaction mixture containing nitrite ion was removed, 1 ml of

sulphanilic acid reagent was added, mixed well and allowed to stand for

5 min for completion of diazotization. Then, 1 ml of NEDD was added,

mixed and allowed to stand for 30 min in diffused light. A pink coloured

chromophore was formed. The absorbance was measured at 540 nm

using UV-visible double beam spectrophotometer. The results were

plotted on a graph and IC50 value was determined.

Nitric Oxide Assay procedure for the test compounds:

The reaction mixture (6 ml) containing sodium nitroprusside (10

millimole, 4ml), phosphate buffer saline (PBS, PH 7.4, 1 ml was added

to 2.8 ml of the test compounds and incubated at 25 ºC for 15 min. After

184

incubation, 0.5 ml of the reaction mixture containing nitrite ion was

removed, 1 ml of sulphanilic acid reagent was added, mixed well and

allowed to stand for 5 min for completion of diazotization. Then, 1 ml of

NEDD was added, mixed and allowed to stand for 30 min in diffused

light. A pink coloured chromophore was formed. The absorbance was

measured at 540 nm using UV-Visible double beam spectrophotometer.

The assay was performed in triplicates.

The IC50 values of test compounds were determined by the

procedure similar to ascorbic acid determination. The datas of the

above performed antioxidant activities are represented in Table No.18.

The above mentioned methods are performed and the results are

discussed in the next chapter.

Anti-inflammatory studies:

Materials:

Polypropylene cages with paddy husk

Plethysmograph

Carrageenan

Diclofenac sodium

Test compounds

Normal saline and water

Animals:

185

All the experiments were carried out using male, Wistar rats (150-

200 g).On arrival the animals were placed at random and allocated to

treatment groups in polypropylene cages with paddy husk as bedding.

Animals were housed at a temperature of 24 ± 2oC and relative humidity

of 30 – 70 %. A 12:12 light: day cycle was followed. All animals were

allowed to free access to water and fed with standard commercial rat

chaw pallets. All the experimental procedures and protocols used in this

study were reviewed by the Institutional Animal Ethics Committee.

Drugs and Chemicals

The drugs and fine chemicals were purchased from Sigma-

Aldrich, India. All other chemicals and solvents were obtained from local

firms (India) and were of highest pure and analytical grade.

Vehicle

Test compounds and Diclofenac sodium were suspended in 0.5%

w/v CMC and administered orally to animals. Carrageenan diluted

separately in normal saline and injected.

Acute Anti-inflammatory Studies:(Saxena RS et al., 1987)

Carrageenan, induced rat paw edema model were used for

evaluating potential of test compounds on inflammation. For each

model, rats were divided in two groups (n = 6). 200-250 mg /kg of test

compound and diclofenac sodium (10 mg/kg) were administered orally

186

one hour before the sub plantar injection of edematogenic agent. The

control groups of animals were received vehicle (1 ml/kg) orally.

Plethysmograph used for measuring paw volume (mm) of rats. Edema

(T) was calculated as follows: T = Tt – T0 Where Tt is the right hind paw

volume (mm) at time‘t’, T0 is hind paw volume (mm) before subplantar

injection.

In this method, acute inflammation was produced by the

subplantar administration of 0.1 ml of 1% w/v carrageenan in the right

paw of the rat. The volume (mm) of the paw was measured immediately

and at 1, 2, 3 and 4 hr intervals after the administration of the

carrageenan. The results are presented in Table No.19..

Analgesic activity:

Materials:

Polypropylene cages with paddy husk

Eddy’s hot plate

Pentazocine lactate as standard

Test compounds

Normal saline and double distilled water

Animals:

All the experiments were carried out using male, swiss Albino

mice (25-30 g). On arrival the animals were placed at random and

allocated to treatment groups in polypropylene cages with paddy husk

187

as bedding. Animals were housed at a temperature of 24 ± 2oC and

relative humidity of 30 – 70 %. A 12:12 light: day cycle was followed. All

animals were allowed to free access to water with standard commercial

chaw pallets. All the experimental procedures and protocols used in this

study were reviewed by the Institutional Animal Ethics Committee.

Drugs and Chemicals:

The drugs and fine chemicals were purchased from Sigma-

Aldrich, India. All other chemicals and solvents were obtained from local

firms (India) and were of highest pure and analytical grade.

Hot Plate Method:

Each group of six mice’s was selected for the present study. One

group served as control and received the vehicle, and one group

received the standard drug pentazocine lactate (30 mg/kg, i.p.). The

drug concentration of 50 mg/kg suspended in acacia was administered

orally to other groups. The mice were placed on Eddy’s hot plate kept at

a temperature of 55 ± 0.5 o C for a maximum time of 15 sec. Reaction

time was recorded when the animals licked their fore-and hind paws

and jumped, at before 0 and 15, 30, 45, and 60 min after administration

of test drugs. In Statistical Analysis all the results were expressed as

mean ± standard error (SEM). Data was analyzed using one-way

ANOVA followed by Dunnett’s t-test. P-values < 0.05 were considered

188

as statistically significant. The results of analgesic activity of title

compounds are presented in Table No.20.

189

RESULTS

Table No.11. Physical properties of the synthesized compounds (I-

XIX)

Sl.No. Compound Meting

point (oC) % yield Molecularweight

Molecularformula

1 Compound No. I 112 43.06%. 209.3 C11H19N3O

2 Compound No. II 130 49.75%. 331.4 C23H25NO

3 Compound No. III 178 59% 166.1 C8H10N2O2

4 Compound No. IV 86 70.3%. 242.2 C14H14N2O2

5 Compound No. V 182 13.7% 332.2 C14H12N4O6

6 Compound No. VI 224 25 % 209.2 C9H11N3O3

7 Compound No.VII 182 14.91% 376.4 C22H20N2O4

8 Compound No.VIII 97 64.5 254.2 C16H14O3

9 Compound No. IX 130 63.4 206.2 C12H14O3

10 Compound No. X 100 55.6% 318.3 C21H18O3

11 Compound No. XI 220 69.6% 248.2 C13H16N2O3

12 Compound No.XII 195 59% 330.3 C16H18N4O4

13 Compound No.XIII 160 70.3% 330.3 C16H23N

14 Compound No.XIV 95 13.7 207.2 C11H17N3O

15 Compound No.XV 163 25 358.5 C25H30N2

16 Compound No.XVI 95 78 165.2 C10H15NO

17 Compound No.XVII 157 61.6 376.5 C26H40N2

18 CompoundNo.XVIII 79 67.7 348.4 C24H30O2

19 Compound No.XIX 176 50.6 227.3 C10H16N2

190

Table No.12. TLC Profile of the Synthesized compounds (I-XIX)

Sl.No Compound Solvent System Proportion Rf Value

1 Compound No. I Acetic Acid: N-Butanol: CCl4 4.5:0.2:0.3 0.33

2 Compound No. II N-Butanol: N-Hexane 4.5:0.5 0.66

3 Compound No. III Acetone: Carbontetrachloride 5:5 0.85

4 Compound No. IV Benzene: Chloroform 4:1 0.7

5 Compound No. V Benzene: Ethanol 2.5:2.5 0.78

6 Compound No. VI Ethanol: N-Hexane 4:1 0.48

7 Compound No. VII Benzene: Ether 4.5:0.5 0.79

8 Compound No. VIII Ethanol- N-Hexane 4.5:0.5 0.85

9 Compound No. IX Ethanol- N-Hexane 4.5:0.5 0.76

10 Compound No. X Ethanol-Water 4.5:0.5 0.63

11 Compound No. XI Ethanol- N-Hexane 4.5:1.5 0.73

12 Compound No. XII Benzene: Ethanol 4.5:0.5 0.8

13 Compound No. XIII Ether: Water :Acetic Acid 5:2.5:2.5 0.7

14 Compound No. XIV Acetone : Alcohol 2.5:2.5 0.70

15 Compound No. XV Ethanol: N-Hexane 4:1 0.48

16 Compound No. XVI Benzene: Ether 4.5:0.5 0.79

17 Compound No.XVII Ethanol: Water 1:4 0.95

18 CompoundNo.XVIII

n-Hexane:CarbonTetrachloride 4.5:0.5 0.89

19 Compound No. XIX Ether:Carbon Tetrachloride 4.5:0.5 0.96

191

Table 13: Elemental analysis of novel semisynthetic compounds (I– XIX)

Sl.No Compound Calculated FoundC% H% N% O% C% H% N% O%

1 CompoundNo. I 63.12 9.21 20.09 7.93 63.13 9.15 20.08 7.64

2 CompoundNo. II 83.32 7.56 4.21 4.12 83.34 7.60 4.23 4.83

3 CompoundNo. III 57.32 5.98 17.23 18.34 57.82 6.07 16.86 19.26

4 CompoundNo. IV 70.12 4.88 12.01 14.09 69.41 5.82 11.56 13.21

5 CompoundNo. V 51.12 4.12 17.09 27.12 50.61 3.64 16.86 28.89

6 CompoundNo. VI 51.78 5.23 20.04 22.89 51.67 5.30 20.09 22.94

7 CompoundNo. VII 70.15 5.87 7.43 17.08 70.20 5.36 7.44 17.00

8 CompoundNo. VIII 75.43 5.55 - 18.92 75.57 5.55 - 18.88

9 CompoundNo. IX 69.91 6.78 - 23.76 69.88 6.84 - 23.27

10 CompoundNo. X 79.21 5.74 - 15.04 79.22 5.70 - 15.08

11 CompoundNo. XI 63.01 6.49 - 19.23 62.89 6.50 - 19.33

12 CompoundNo. XII 58.19 5.32 16.96 19.34 58.17 5.49 16.96 19.37

13 CompoundNo. XIII 73.12 9.79 17.08 - 73.13 9.82 17.06 -

14 CompoundNo. XIV 63.75 8.54 20.19 7.79 63.74 8.27 20.27 7.72

15 CompoundNo. XV 83.78 8.45 7.82 - 83.75 8.43 7.81 -

16 CompoundNo. XVI 72.67 9.21 8.45 9.56 72.69 9.15 8.48 9.68

17 CompoundNo. XVII 82.98 8.89 7.42 - 82,93 9.64 7.44 -

18 CompoundNo.XVIII 82.88 8.03 - 9.18 82.72 8.10 - 9.18

19 CompoundNo. XIX 84.56 9.21 6.12 - 84.53 9.31 6.16 -

192

Table No.14. FT-IR Spectral Datas of the Semisynthetic Compounds (I –

XIX)

Compound Compound structure Spectralpeaks cm-1

Functionalgroups

CompoundNo. I

CH3

CH3CH3

N NH C

O

NH2

341232861686109615121379942

-NH2 stretching-NH stretching-C=O stretching-C-N stretching-C-H bending-C-C stretching-C-H bending

CompoundNo. II N

CH3

CH3

CH3

O 3248305516311076

-C=C stretching-C=C stretching-C=O stretching-C-N stretching

CompoundNo. III

OH

OCH3

N

NH2

3477.132928.551597.271507.80

- OH stretching-CH stretching-NH bending-CH stretching

CompoundNo. IV

OH

OCH3

N

NH

3493.593312.983043.562942.091599.541355.421159.941507.34

- OH stretching-CH stretching-CH stretching-C=N stretching-CH stretching-CH stretching-C-O stretching-NH bending

193

CompoundNo. V

OH

OCH3

N

NH

O2N NO2

3459.083320.613095.151582.601504.841414.121326.37

-OH stretching-CH stretching-CH stretching-C=N stretching-NH stretching-C=C stretching-NO2 (S)

Compound Compound structure Spectralpeaks cm-1

Functionalgroups

CompoundNo. VI

OCH3

OH

N NH

O

NH23515.903463.203294.841646.771605.021441.231350.76

-NH stretching-OH stretching-CH stretching-C=O stretching-C=N stretching-C=C stretching-C-H bending

CompoundNo. VII N N

OH

O

CH3

OH

O

CH3

3402.913000.582936.361599.931523.631456.901225.80

-OH stretching-CH stretching-CH stretching-C=N stretching-NH bending-C=C stretching

CompoundNo. VIII O

O

OH CH3

3256.271656.941317.10820.03

-OH stretching-C=O stretching-C-O stretching-C-H bending

194

CompoundNo. IX

H

O

CH3OH

O

CH3

3259.971656.981581.23819.48

-OH stretching-C=O stretching-C=C stretching-C-H bending

CompoundNo. X

OH

O

CH3

O

3249.781656.581580.97819.94

-OH stretching-C=O stretching-C=C stretching-C-H bending

Compound Compound structure Spectralpeaks cm-1

Functionalgroups

CompoundNo. XI

H

O

CH3OH

N

CH3 N

CH3

OH

3209.261581.031361.65755.59

-OH stretching-C=O stretching-C=C stretching-C-H bending

CompoundNo. XII

CH3

CH3

CH2

N

NH

O2N

NO2

3438.413321.522922.53

16441583.12 ,1329.20

-NH stretching-CH stretching-CH stretching-C=C stretching-N=O-N=O

CompoundNo. XIII

CH3

CH3 CH2

N NH2

3377.463101.811519.80

-NH stretching-CH stretching-C=C stretching

195

CompoundNo. XIV

N

CH3 CH2

CH3

NH NH2

O3456.583404.973206.722924.281688.851572.92

-NH stretching-CH stretching-CH bending-CH stretching-C=O stretching-C=C stretching

CompoundNo. XV

N NCH3

CH3 CH2 CH3CH2

3439.172810.011581.501497.66

-NH stretching-CH stretching-C=C stretching-C=C stretching

Compound Compound structure Spectralpeaks cm-1

Functionalgroups

CompoundNo. XVI

CH3

N

CH3 CH2

OH 3216.463080.032913.901643.65

-OH stretching-NH stretching-CH stretching-C=C stretching

CompoundNo. XVII

CH3

N

N

CH3

CH3CH3

CH3CH3

3430.631733.671497.00810.78

-NH stretching-C=O stretching-CH stretching-CH bending

196

CompoundNo.XVIII

CH3O

O

CH3 CH3

3455.123324.363085.131733.751497.27

-CH stretching-CH stretching-C=O stretching-CH stretching-C-O stretching

CompoundNo. XIX

CH3

N

CH3 CH3

3430.993236.841546.861418.20810.69

-NH stretching-CH stretching-C=O stretching-CH stretching-CH bending

197

Table No.15.1HNMR Spectral Datas of compounds (I – XIX)

Sl.No Compound1HNMRδppm Protons J Value

1 Compound No. I

7.5 s7.0 s6.0 s5.20 t2.0 d1.71 t

1H- CH1H-NH2H-NH21H-CH

4H -CH29H-CH3

7.12.51.27.16.86.4

2 Compound No.II

7.8 – 7.39m5.81s5.20s2.00t1.71

10 H – Ar-H1H - =CH1H- =CH4H-CH2

9H – CH3

5.96.96.96.86.4

3 Compound No.III

8.1s7.0m6.7 q5.0s

3.73s

2H- NH21H-Ar-H1H-Ar- H1H- OH3H-CH3

12.25.55.5

10.26.2

4 Compound No.IV

8.1s6.46-7.01m

5.0s4.0s

3.73s

1H-Ar- CH8H-Ar-H

1H- Ar- OH1H- NH

3H-OCH3

5.75.9

11.213.17.2

5 Compound No.V

8.87q8.33q8.1s7.0q

6.98q6.7q5.0s4.0s

3.73s

1H-Ar-H1H-CH

2H-Ar-H1H-Ar-H1H-Ar-H1H-Ar-H

1H- Ar- OH1H-NH3H-CH3

5.57.15.95.55.55.5

11.22.56.2

6 Compound No.VI

8.1s8.0s7.0q6.7q5.0s

3.73s2.0s

1H-CH1H-NH

2H-Ar-CH1H-Ar-CH1H-Ar-OH3H-OCH32H-NH2

7.18.55.95.5

13.18.18.6

198

7 Compound No.VII

8.39s7.3q

7.01q6.96q6.65q5.0s

3.73s

2H-CH4H-Ar-CH2H-Ar-CH2H-Ar-CH2H-Ar-CH2H-Ar-OH6H-OCH3

8.65.25.95.95.9

11.18.1`

8 Compound No.VIII

8.17t7.81m

7.45-7.54m7.39t6.75q6.60q6.50q5.0s

3.73s

1H-CH2H-Ar-CH3H-Ar-CH

1H-CH1H-Ar-CH1H-Ar-CH1H-Ar-CH1H-Ar-OH3H-OCH3

7.15.95.87.15.55.55.5

11.28.1

9 Compound No.IX

7.37t6.69q6.64q6.57q6.24t5.0s

3.73s2.98t1.11t

1H-=CH1H-Ar-CH1H-Ar-CH1H-Ar-CH1H-=CHIH-Ar-OH3H-OCH32H-CH23H-CH3

6.95.55.55.57.1

10.88.16.96.2

10 Compound No.X

13.9s7.74-7..36m

6.28q6.16t5.66t3.50s2.63d

1H-Ar-OH9H-Ar-CH1H-Ar-CH1H-=CH1H-=CH

3H-OCH32H- CH2

11.25.35.56.95.88.14.2

11 Compound No.XI

6.69q6.64q6.6t

6.57q5.2d5.0s

3.73s2.0s

1.90s

1H-Ar-CH1H-Ar-CH

1H-CH1H-Ar-CH1H-=CH

1H-Ar-OH3H-OCH31H-OH3H-CH3

5.55.57.15.55.8

11.28.19.03.9

199

12 Compound No.XII

8.87q8.33q7.0s

6.98q5.5q

4.88d4.63d2.2q

2.09-1.84m1.52-1.2m

1H-Ar-CH1H-Ar-CH

1H-NH1H-Ar-CH1H-=CH1H-=CH1H-=CH1H-CH2H-CH22H-CH2

5.55.51.45.56.96.97.17.14.24.2

13 Compound No.XIII

7.0s5.5q

4.88d4.63d2.2q

2.09-1.84m1.71d

1.5-1.2m

2H-NH21H-=CH1H-=CH1H-=CH1H-CH2H-CH26H-CH32H-CH2

1.25.85.85.86.94.26.76.8

14 Compound No.XIV

7.0s6.0s5.5d

4.88d4.63d2.2q

2.09-1.85m1.71d

1.52-1.2m

1H-NH2H-NH21H-=CH1H-=CH1H-=CH1H-CH2H-CH26H-CH32H-CH2

8.51.26.96.96.97.18.68.14.2

15 Compound No.XV

7.3q5.7q5.5q

4.88d4.63d2.2q

2.09-1.84m1.71d

1.5-1.2m

4H-Ar-CH1H-=CH1H-=CH2H-=CH2H-=CH2H-CH4H-CH29H-CH34H-CH2

12.16.96.96.86.88.66.84.26.8

16 Compound No.XVI

5.5q4.83d4.69d2.2q

2.09-1.84m1.71d

1.5-1.2m

1H-=CH1H-=CH1H-=CH1H-CH2H-CH26H-CH32H-CH2

6.96.96.97.14.24.84.2

200

17 Compound No.XVII

7.3q2.60-2.34m

1.5t1.4m

1.11m

1H-Ar-CH8H-CH22H-CH4H-CH2

18H-CH3

5.54.18.66.88.8

18 CompoundNo.XVIII

7.99d7.46d7.37d7.21d7.12d7.08d3.06m1.90q1.52q1.49q1.42d1.16s1.11t

2H-Ar-CH1H-Ar-CH2H-Ar-CH2H-Ar-CH2H-Ar-CH1H-Ar-CH2H-CH22H-CH22H-CH22H-CH21H-CH3H-CH36H-CH3

5.45.55.45.45.45.54.24.24.24.25.86.86.7

19 Compound No.XIX

7.3t1.9d1.5m1.4d1.1s

5H--Ar-CH4H-CH21H-CH2H-CH26H-CH3

13.16.85.84.26.7

201

Table No.16: Antibacterial Activity of the Compounds (I – XIX).

Standard: Ampicillin sodium

Compound Antibacterial Activity (Zone of inhibition in mm)B. Subtillis S. Aureus E. coli P. vulgaris

I 18 17 16 14

II 14 15 14 12

III 14 16 13 13

IV 13 17 13 11

V 14 14 14 12

VI 17 13 15 13

VII 15 14 14 11

VIII 16 15 15 13

IX 19 18 23 16

X 17 15 19 15

XI 14 16 20 14

XII 15 15 18 15

XIII 16 17 19 12

XIV 14 15 18 13

XV 17 12 13 11

XVI 15 11 14 10

XVII 16 12 13 11

XVIII 15 13 12 13

XIX 16 11 14 12

Standard(10 µg/cup) 22 20 18 17

*Concentration of Test Compound:100 µg/cup

202

Table No.17: Antifungal Activity of Compounds (I – XIX).

Standard: Clotrimazole

Compound Antifungal Activity (Zone of inhibition in mm)

A. niger C.verticulata

F.oxysporum A. flavus

I 19 16 12 10

II 15 13 10 08

III 16 15 09 09

IV 14 15 08 09

V 12 13 11 10

VI 13 12 10 07

VII 14 13 11 06

VIII 13 14 08 09

IX 17 16 13 11

X 14 14 06 10

XI 15 11 12 09

XII 15 12 13 10

XIII 16 13 12 08

XIV 12 14 09 09

XV 16 14 07 10

XVI 15 13 06 09

XVII 17 12 10 04

XVIII 14 13 08 09

XIX 14 12 10 03Standard

(10 µg/cup) 21 22 23 15

*Concentration of Test Compound:100 µg/cup

203

Table No.18: Antioxidant activity of compounds (I-XIX).

Standard: Ascorbic acid

CompoundIC50 Value (µM)

ABTS DPPH Nitric Oxide

Standard 4.83 5.87 4.02

I 11.93 10.44 9.45

II 8.52 8.21 8.24

III 6.98 7.78 7.01

IV 10.04 11.00 9.83

V 11.83 9.45 10.78

VI 9.73 10.45 9.68

VII 12.89 10.22 11.93

VIII 7.83 7.94 6.52

IX 6.95 7.87 5.96

X 8.73 7.45 7.04

XI 6.39 7.79 6.62

XII 8.05 7.88 8.15

XIII 6.89 7.76 6.93

XIV 9.32 7.99 8.83

XV 9.03 11.77 9.83

XVI 8.89 11.66 7.41

XVII 9.52 10.58 9.21

XVIII 8.43 10.75 9.67

XIX 9.12 9.25 9.54

204

Table No.19: Anti-inflammatory activity of the compounds (I –XIX).

*** p<0.0001, ** p<0.001, * p<0.05 compared to control at respective Time period.NA = Not Applicable. Standard = Diclofenac Sodium

Compound1hr 2hr 3hr 4hr

Mean±SD % red Mean±SD % red Mean±SD % red Mean±SD % redControl 3.32±0.18 NA 3.47±0.19 NA 3.57±0.17 NA 3.27±0.25 NA

Standard 2.33±0.16* 29.81 2.13±0.16* 38.61 2.07±0.1* 42.01 1.83±0.13 44.03I 3.17±0.15 4.51 3.02±0.13 12.96 2.93±0.1 17.92 2.78±0.11 14.98II 2.8±0.17 15.66 2.7±0.2 22.19 2.62±0.16* 26.61 2.48±0.18* 34.15III 2.73±0.16 17.77 2.63±0.15* 24.20 2.5±0.11* 29.97 2.37±0.15* 37.52IV 2.53±0.17* 23.79 2.42±0.09* 30.25 2.27±0.1* 36.41 2.12±0.09* 35.16V 2.65±0.21 20.18 2.45±0.21* 29.39 2.33±0.24* 34.73 2.2±0.25* 32.72VI 3.1±0.11 6.62 2.95±0.1 14.98 2.83±0.15 20.72 2.7±0.16 17.43VII 2.45±0.15* 26.20 2.25±0.19* 35.15 2.15±0.13* 39.77 2.02±0.04* 38.22VIII 2.87±0.16 13.55 2.73±0.10 21.32 2.83±0.11 20.72 2.52±0.09 22.93IX 2.52±0.19* 24.09 2.38±0.13* 31.41 2.22±0.11* 37.81 2.10±0.08* 35.78X 3.28±0.11 4.09 3.20±0.08 9.09 3.12±0.09 13.33 3.0±0.07 12.28XI 3.22±0.07 5.84 3.12±0.10 11.36 3.08±0.07 14.44 2.98±0.07* 32.86XII 3.15±0.10 7.89 3.07±0.12 12.78 2.93±0.08 18.61 2.9±0.11 15.20XIII 3.02±0.07 11.69 2.90±0.08 17.61 2.80±0.12 22.22 2.68±0.11 21.63XIV 2.9±0.07 15.20 2.80±0.08 20.45 2.72±0.11* 24.44 2.6±0.14* 33.97XV 3.18±0.07 7.01 3.10±0.08 11.93 3.0±0.07 16.66 2.9±0.07* 35.20XVI 2.68±0.07 21.63 2.55±0.08* 27.55 2.44±0.08* 32.22 2.3±0.08* 32.74XVII 3.10±0.16 9.35 3.0±0.12 14.77 3.0±0.11 16.66 2.92±0.11 14.61XVIII 2.77±0.05 19.00 2.62±0.07* 25.56 2.53±0.05* 29.72 2.43±0.05* 28.94XIX 2.72±0.09 20.46 2.55±0.05* 28.57 2.45±0.05* 32.50 2.25± 0.05* 35.15

205

Table No.20: Analgesic activity of the compounds (I –XIX).

*** p<0.0001, ** p<0.001, * p<0.05 compared to control at respective Time period,NA = Not Applicable, Standard = Pentazocine Lactate

Compound0.5hr 1hr 2hr

Mean ±SDTime (min) %Protection Mean ±SD %Protection Mean ±SD %Protection

Control 4.42 ± 0.16 NA 4.27± 0.19 NA 4.33 ± 0.11 NAStandard 11.1 ± 0.89* 159.25 12.1 ± 0.05* 183.37 13.2 ± 0.34* 204.89

I 4.95 ± 0.22 12 5.7 ± 0.45 33.48 6.15 ± 0.82 42.03II 5.13 ± 0.12 16 6.3 ± 0.53 47.54 7.2 ± 0.61 66.28III 5.38 ± 0.14 21.7 7.2 ± 0.12 68.61 8.72 ± 0.46* 101.38IV 7.23 ± 0.25 63.5 8.2 ± 0.23 92.03 9.12 ± 0.22* 110.62V 8.56 ± 0.09* 93.66 9.42 ± 0.22* 120.60 10.65 ± 0.43* 145.40VI 5.11 ± 0.43 15.6 5.83 ± 0.17 36.53 6.37 ± 0.51 47.11VII 9.00 ± 0.22* 103.61 10.02 ± 0.15* 134.6 11.50 ± 0.44* 165.58VIII 5.45 ± 0.51 23 6.27 ± 0.38 46.83 7.21 ± 0.21 66.51IX 7.09 ± 0.02 67.15 11.0 ± 0.51 57.6 11.80 ± 0.24* 172.5X 6.05 ± 0.15 36.87 6.17 ± 1.00 44.4 7.15 ± 0.32 65.12XI 5.01 ± 0.15 13.34 5.43 ± 0.23 27.16 6.11 ± 0.81 41.10XII 4.85 ± 0.05 9.72 5.31 ± 0.32 24.35 6.17 ± 0.28 42.49XIII 5.34 ± 0.16 20.8 5.81 ± 0.32 36.29 6.61 ± 0.51 52.65XIV 6.14 ± 0.19 38.91 6.37 ± 0.21 49.18 7.15 ± 0.43 65.12XV 5.63 ± 0.22 27.3 6.52 ± 0.11 52.69 7.91 ± 0.21 82.67XVI 7.67 ± 0.21 73.52 6.13 ± 0.79 43.55 5.91 ± 0.21 36.48XVII 5.65 ± 0.21 27.82 6.82 ± 0.23 59.7 7.75 ± 0.23 78.98XVIII 6.67 ± 0.16 50.90 7.56 ± 0.45 77.04 8.59 ± 0.34 98.38XIX 9.15 ± 0.19* 107.01 10.18 ± 0.14* 138.90 12.08 ± 0.23* 178.98

5.19 ± 0.29 17.42 6.89 ± 0.84 61.35 7.38 ± 0.21 70.43

206

Table No.21: Anthelmintic activity of compounds (I –XIX).

Compound Concentration%w/v

Time in Minutes Mean±SDFor paralysis For Death

Control 0.9% - -

Standard0.1% 49±0.56 68±0.210.2% 44±0.15 62±0.310.5% 38±0.21 53±0.24

I0.1% 60±0.18 158±0.190.2% 57±0.14 145±0.240.5% 53±0.32 139±0.34

II0.1% 49±0.26 152±0.170.2% 42±0.35 137±0.340.5% 39±0.29 128±0.21

III0.1% 57±0.34 162±0.180.2% 55±0.51 143±0.260.5% 52±0.28 135±0.27

IV0.1% 61±0.31 170±0.360.2% 58±0.25 157±0.150.5% 55±0.36 145±0.34

V0.1% 63±0.42 178±0.280.2% 59±0.25 162±0.310.5% 57±0.51 149±0.27

VI0.1% 65±0.24 182±0.540.2% 62±0.32 167±0.510.5% 60±0.29 151±0.34

VII0.1% 67±0.14 168±0.260.2% 63±0.51 149±0.190.5% 59±0.26 140±0.34

VIII0.1% 53±0.34 165±0.280.2% 51±0.31 152±0.350.5% 48±0.24 143±0.34

IX0.1% 42±0.52 142±0.210.2% 39±0.26 137±0.510.5% 30±0.41 125±0.18

X0.1% 52±0.52 167±0.340.2% 50±0.32 155±0.510.5% 47±0.42 149±0.42

207

Standard: Albendazole

XI0.1% 68±0.93 159±0.910.2% 64±0.82 152±0.880.5% 53±0.39 142±0.29

XII0.1% 71±0.72 171±0.220.2% 63±0.78 167±0.850.5% 61±0.64 157±0.87

XIII0.1% 66±0.16 162±0.980.2% 61±0.93 153±0.920.5% 53±0.99 143±0.31

XIV0.1% 59±0.03 149±0.960.2% 56±0.80 139±0.180.5% 53±0.17 127±0.61

XV0.1% 57±0.05 129±0.630.2% 51±0.09 118±0.080.5% 49±0.68 112±0.97

XVI0.1% 63±0.04 139±0.380.2% 59±0.20 124±0.290.5% 52±0.99 118±0.97

XVII0.1% 69±0.08 150±0.380.2% 59±0.96 134±0.760.5% 49±0.60 128±0.89

XVIII0.1% 69±0.09 149±0.950.2% 58±0.28 139±0.430.5% 55±0.03 129±0.92

XIX0.1% 53±0.42 134±0.630.2% 49±0.92 129±0.010.5% 43±0.97 120±0.11

208

DISCUSSIONS

Rapid development of phytochemistry and pharmacological testing methods

in recent years has introduced lot of medicinal plants and many of their active

constituents have been reported. The discovery of aspirin like semisynthetic

derivatives is playing a main role in drug dsiscovery. Based on this concept the

present study was performed to synthesize some novel semisynthetic

derivatives of some commonly used medicinal compounds isolated from the

natural origin.

The compounds selected in the present study are some essential oils with

very popular medicinal properties. The aim of the present study was to avoid the

wastage of these medicinal compounds through vaporization i.e. to convert these

medicinal compounds into their respective non-volatile derivatives.

The volatile substances used in the present study are citral, camphor,

carvone, and vanillin. All the four compounds are used in our day to day life and

were found to contain various medicinal properties, which were also proven

scientifically. In this present study the derivatives of citral, camphor, carvone, and

vanillin are synthesized and evaluated for the possible pharmacological activity.

The derivatives of the above mentioned compounds were synthesized as

per the scheme mentioned in earlier chapter. The compounds synthesized were

subjected for thin layer chromatography to identify the purity of the synthesized

compound.

209

The synthesized compound was subjected for physical analysis like

melting point, solubility, and elemental analysis; and was also subjected for

1HNMR spectroscopy, MASS spectroscopy and FT-IR spectroscopic studies for

characterizing the structure of the synthesized derivatives.

Physical, Analytical and Spectral datas of Citral derivatives

Compound I

Compound I was synthesized as per scheme I and recrystallize to obtain

pure compound. The purity was determined using TLC, the compound 1

exhibited Rf of about 0.8 using solvent system benzene: Ethanol (4.5:0.5). The

melting point was found to be 195oC. Percentage yield was found to be 59%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of N-H Stretching at 3438.41cm-1methyl

at 3321.52 cm-1, C-H stretching salicylic at 2922.53 cm-1, conjugate C=C at

1644.cm-1,NO2 at 1583.12 and 1329.20 cm-1.

1HNMR spectrum showed characteristic signals (δ ppm) at 7.5 s (1H –CH),

7.0 s (1H-NH), 6.0 s (2H -NH2), 5.20 t (1H-CH), 2.0 d (4H -CH2), 1.71 t (9H-CH3).

The mass spectrum of the compound showed its molecular ion peak (M+)

at m/z at 209. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound I

as 2-[(2Z)-3,7-dimethylocta-2,6-dien-1-ylidene]hydrazine carboxamide.

210

Compound II

Compound II was synthesized as per scheme II and recystallized to obtain

pure compound. The purity was determined using TLC; the compound exhibited

a Rf value of about 0.66 using solvent system N-butanol: n-hexane (4.5:0.5).

The melting point was found to be 195oC. Percentage yield was found to be 59%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of 3248(C=C stretching in aromatic

compound), 3055(C=C stretching in aromatic compound), 1631(C=O stretching

in amide), 1076(C-N stretching), 997.01, 918,766(C-H bending in alkenes),

488(C-C bending).

1HNMR spectrum showed characteristic signals (δ ppm) at 7.8 – 7.39m (10

H – Ar-H) 5.81s (1H - =CH), 5.20s (1H- =CH), 2.00t (4H-CH2), 1.71s (9H – CH3).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 331. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound II

as (2Z)-N-diphenylmethlidene -3, 7-dimethylocta-2,6-dienamide

Physical, Analytical and Spectral datas of Vanillin derivatives

Compound III

Compound III was synthesized as per scheme III and recystallized to

obtain pure compound. The purity was determined using TLC. The compound

211

showed Rf of about 0.85 using solvent system Acetone: carbon tetrachloride

(5:5). The melting point was found to be 178oC. Percentage yield was found to

be 59%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of phenolic OH(S) at 3477.13cm-1,

CH(S) at2928.55cm-1, C=N at 1597.27cm-1,NH(B) at 1507.80 cm-1,Aromatic

CH(B) deformation at 809.74&750.86cm-1

1HNMR spectrum showed characteristic signals (δ ppm) at 8.1s (2H- NH2),

7.0m (1H-Ar-H), 6.7 q (1H-Ar- H), 5.0s (1H- OH), 3.73s (3H-CH3).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 166. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound III

as 4[(E)-hydrazinylidenemethyl]-2-methoxyphenol.

Compound IV

Compound IV was synthesized as per scheme IV and recystallized to

obtain pure compound. The purity was determined using TLC; the compound

exhibited Rf of about 0.7 using solvent system Benzene: chloroform (4:1). The

melting point was found to be 86oC. Percentage yield was found to be 70.3%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound

212

showed characteristic absorbance peak of O-H(S) at3493.59 cm-1, C-H(S) at

3312.98 cm-1, two aromatic rings at 3043.56 cm-1& 2942.09 cm-1, C=N at

1599.54 cm-1, CH bending at 1355.42 cm-1, C-O (S) at 1159.94, NH(B) at

1507.34, Aromatic at 614.88 cm-1.

1HNMR spectrum showed characteristic signals (δ ppm) at 8.1s (1H-Ar-

CH) 6.46- 7.01m (8H-Ar-H) 5.0s (1H- Ar- OH), 4.0s (1H- NH), 3.73s(3H-OCH3)

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 242. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound IV

as 2-methoxy-4-[(E)-(2-phenylhydrazinylidene) methyl] phenol.

Compound V

Compound V was synthesized as per scheme V and recrystallize to obtain

pure compound. The purity was determined using TLC; the compound exhibited

Rf of about 0.78 using solvent system Benzene: Alcohol (2.5:2.5). The melting

point was found to be 182oC. Percentage yield was found to be 65.7%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of OH(B) at 3459.08cm-1, CH(B) at

3320.61cm-1, Aromatic ring at 3095.15cm-1,C=N at 1582.60cm-1, NH(B) at

1504.84cm-1, C=C aromatic (S) at 1414.12 cm-1, NO2 (S) at 1326.37 cm-1.

213

1HNMR spectrum showed characteristic signals (δ ppm) at 8.87q (1H-Ar-

H), 8.33q (1H-CH), 8.1s (2H-Ar-H), 7.0q (1H-Ar-H), 6.98q (1H-Ar-H), 6.7q (1H-

Ar-H), 5.0s (1H- Ar- OH), 4.0s (1H-NH), 3.73s (3H-CH3).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 332. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound V

as4-{(E)[2-(2,4-dinitrophenyl) hydrazinylidene]methyl}-2-methoxy phenol.

Compound VI

Compound VI was synthesized as per scheme VI and recystalized to

obtain pure compound. The purity was determined using TLC; exhibited Rf of

about 0.48 using solvent system Ethanol: n-hexane (4:1). The melting point was

found to be 224 oC Percentage yield was found to be 54%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of NH(S) at 3515.90cm-1,OH(S) at

3463.20 cm-1, CH aromatic (S) at 3294.84 cm-1, C=O(S) at 1646.77 cm-1 ,C=N(S)

at 1605.02 cm-1,C=C aromatic(S) at 1441.23 cm-1 , CH(B) at 1350.76 cm-1 .

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 209. It exhibited the fragmentation pattern characteristic of the

compound.

214

1HNMR spectrum showed characteristic signals (δ ppm) at 8.1s (1H-CH),

8.0s (1H-NH), 7.0q (2H-Ar-CH), 6.7q (1H-Ar-CH), 5.0s (1H-Ar-OH), 3.73s (3H-

OCH3), 2.0s (2H-NH2).

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound VI

as N-[(Z)-(4-hydroxy-3-methyl phenyl) methylidene] hydrazinecarboxamide.

Compound VII

Compound VII was synthesized as per scheme VII and recystallized to

obtain pure compound. The purity was determined using TLC; the compound

exhibited Rf of about 0.79 using solvent system Benzene: ether (4.5:0.5). The

melting point was found to be 182oC. Percentage yield was found to be 59%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound

showed characteristic absorbance peak OH(S) at 3402.91 cm-1, CH aromatic (S)

at 3000.58 cm-1, CH alkane (S) at 2936.36 cm-1, C=N (S) at 1599.93 cm-1, NH(B)

at 1523.63 cm-1, C=C aromatic (S) at 1456.90 cm-1, C-O (S) at 1225.80 cm-1 .

1HNMR spectrum showed characteristic signals (δ ppm) at 8.39s (2H-CH),

7.3q (4H-Ar-CH), 7.01q (2H-Ar-CH), 6.96q (2H-Ar-CH), 6.65q (2H-Ar-CH), 5.0s

(2H-Ar-OH), 3.73s (6H-OCH3).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 376. It exhibited the fragmentation pattern characteristic of the

compound. The analytical and spectral data proves the identity and the purity of

the compound. From the spectral datas it also confirms the structure of

215

compound VII as 4,4'-{benzene-1,2-diylbis[nitrilo(e)methylylidene]}bis(2-methoxy

phenol).

Compound VIII

Compound VIII was synthesized as per schemeVIII and recystallized to

obtain pure compound. The purity was determined using TLC; exhibited Rf of

about 0.85 using solvent system, Alcohol- n-hexane (4.5:0.5). The melting point

was found to be 97oC. Percentage yield was found to be 64.5%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of N-H stretching at 3256.27cm-1,C=0

bending at 1656.94cm1. Aromatic C-H bending at 820.03cm-1, Nitro group at

1317.10 cm-1.

HNMR spectrum showed characteristic signals (δ ppm) at 8.17t (1H-CH),

7.81m (2H-Ar-CH), 7.45-7.54m (3H-Ar-CH), 7.39t (1H-CH), 6.75q (1H-Ar-CH),

6.60q (1H-Ar-CH), 6.50q (1H-Ar-CH), 5.0s (1H-Ar-OH), 3.73s (3H-OCH3).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 254. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound

VIII as (2E)-3-(3-hydroxy-2-methylphenyl)-1-phenylprop-2-en-1-one.

216

Compound IX

Compound IX was synthesized as per scheme IX and recystallized to

obtain pure compound. The purity was determined using TLC; the compound

exhibited Rf of about 0.76 using solvent system, Alcohol- n-hexane (4.5:0.5).

The melting point was found to be 130oC. Percentage yield was found to

be 63.4%.

The percentage of elements (C, H, O, N) obtained from elemental analysis was

matching with the calculated percentage. FT-IR Spectrum of Compound showed

characteristic absorbance peak of N-H bending at 3259.97cm-1, C=0 stretching

at 1656.98cm-1, Aromatic C-H bending at 819.48cm-1,Nitro group at 1318.82 cm-

1. C=C stretching at1581.23cm-1.

1HNMR spectrum showed characteristic signals (δ ppm) at 7.37t (1H-=CH),

6.69q (1H-Ar-CH), 6.64q (1H-Ar-CH), 6.57q (1H-Ar-CH), 6.24t (1H-=CH), 5.0s

(IH-Ar-OH), 3.73s (3H-OCH3), 2.98t (2H-CH2), 1.11t (3H-CH3).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 206. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound IX

as (1Z)-1-(4-hydroxy-3-methoxyphenyl) pent-1-en-3-one.

Compound X

Compound X was synthesized as per scheme X and recystallized to obtain

pure compound. The purity was determined using TLC, the compound exhibited

217

Rf of about 0.63 using solvent system, Alcohol-water (4.5:0.5). The melting point

was found to be 100oC. Percentage yield was found to be 55.6 %.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of N-H stretching at 3249.78cm-1, C=0

bending at 1656.58cm-1, Aromatic C-H bending at 819.94cm-1,C=C at

1580.97cm-1. aromatic rings at 1460.55cm-1 .

1HNMR spectrum showed characteristic signals (δ ppm) at 13.9s (1H-Ar-

OH), 7.74-7.36m 9H-Ar-CH), 6.28q (1H-Ar-CH), 6.16t (1H-=CH), 5.66t (1H-=CH),

3.50s (3H-OCH3), 2.63d (2H- CH2).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 318. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound X

as {3-[(Z)-(3-hydroxy-2-methoxycyclohexa-2,4-dien-1-ylidene) methyl

phenyl}(phenyl) methanone.

Compound XI

Compound XI was synthesized as per scheme XI and recystallized to

obtain pure compound. The purity was determined using TLC; exhibited Rf of

about 0.73 using solvent system, Alcohol- n-hexane (4.5:1.5). The melting point

was found to be 220oC. Percentage yield was found to be 69.6%.

218

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound

showed characteristic absorbance peak of N-H bending at 3209.26cm-1, C=0

bending at 1581.03cm-1, Aromatic C-H bending at 755.59cm-1,C-H bending

acyclic at 1361.65cm-1.

1HNMR spectrum showed characteristic signals (δ ppm) at 6.69q (1H-Ar-

CH), 6.64q (1H-Ar-CH), 6.6t (1H-CH), 6.57q (1H-Ar-CH), 5.2d (1H-=CH), 5.0s

(1H-Ar-OH), 3.73s (3H-OCH3), 2.0s (1H-OH), 1.90s (3H-CH3).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 248. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound XI

as 4-[(Z)-2-{[(2E,3Z)-3-(hydroxyimino) butan-2-ylidene]amino}ethenyl]-2-

methoxyphenol.

Physical, analytical and spectral datas of carvone derivatives

Compound XII

Compound XII was synthesized as per scheme XII and recystallized to

obtain pure compound. The purity was determined using TLC, the compound

exhibited Rf of about 0.8using solvent system, Benzene: Ethanol (4.5:0.5). The

melting point was found to be 195oC. Percentage yield was found to be 59%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

219

showed characteristic absorbance peak of N-H Stretching at 3438.41cm-1methyl

at 3321.52 cm-1, C-H stretching alicyclic at 2922.53 cm-1, conjugate C=C at

1644.cm-1,NO2 at 1583.12 and 1329.20 cm-1.

1HNMR spectrum showed characteristic signals (δ ppm) at 8.87q (1H-Ar-

CH), 8.33q (1H-Ar-CH), 7.0s (1H-NH), 6.98q (1H-Ar-CH), 5.5q (1H-=CH), 4.88d

(1H-=CH), 4.63d (1H-=CH), 2.2q (1H-CH), 2.09-1.84m (2H-CH2), 1.52-1.2m (2H-

CH2).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 330. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound

XII as (2E)-1-(2, 4-dinitrophenyl)-2-[2-methyl-5-(prop-1-en-2-yl) cyclohex-2-en-1-

ylidene] hydrazine.

Compound XIII

Compound XIII was synthesized as per scheme XIII and recystallized to

obtain pure compound. The purity was determined using TLC, the exhibited Rf of

about 0.7 using solvent system; ether: water: acetic acid (5:2.5:2.5). The melting

point was found to be 160oC. Percentage yield was found to be 70.3%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of N-H stretching at 3377.46cm-1, C-H

cyclic stretching at 3101.81 cm-1, C=C at 1519.80 cm-1.

220

1HNMR spectrum showed characteristic signals (δ ppm) at 7.0s (2H-NH2),

5.5q (1H-=CH), 4.88d (1H-=CH), 4.63d (1H-=CH), 2.2q (1H-CH), 2.09-1.84m

(2H-CH2), 1.71d (6H-CH3), 1.5-1.2m (2H-CH2).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 164. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound

XIII as (1E)-[2-methyl-5-(prop-1-en-2-yl) cyclohex-2-en-1-ylidene]hydrazine.

Compound XIV

Compound XIV was synthesized as per scheme XIV and recystallized to

obtain pure compound. The purity was determined using TLC, the compound

exhibited Rf of about 0.70 using solvent system; Acetone: Alcohol (2.5:2.5). The

melting point was found to be 95oC. Percentage yield was found to be 53.3%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound

showed characteristic absorbance peak of N-H stretching at 3456.58 cm-1, C-H

stretching at 3404.97 cm-1, C-H bending methyl at 3206.72 cm-1, CH stretching

at 2924.28 cm-1, C=0 twisting at 1688.85 cm-1, C=C ring stretching at b1572.92

cm-1, CH bending acyclic at 1379.08 cm-1.

1HNMR spectrum showed characteristic signals (δ ppm) at 7.0s (1H-NH),

6.0s (2H-NH2), 5.5d (1H-=CH), 4.88d (1H-=CH), 4.63d (1H-=CH), 2.2q (1H-CH),

2.09-1.85m (2H-CH2), 1.71d (6H-CH3), 1.52-1.2m (2H-CH2).

221

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 207. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound

XIV as (2E)-2-[2-methyl-5-(prop-1-en-2-yl) cyclohex-2-en-1-ylidene] hydrazine

carboxamide.

Compound XV

Compound XV was synthesized as per scheme XV and recystallized to

obtain pure compound. The purity was determined using TLC, the compound

exhibited Rf of about 0.0.48 using solvent system; Ethanol: n-hexane :( 4:1). The

melting point was found to be 163oC. Percentage yield was found to be 57%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of N-H stretching at 3439.17 cm-1, C-H

stretching and methyl at 2810.01 cm-1, C=C ring stretching aromatic at 1581.50

cm-1, C=C ring aromatic at 1497.66 cm-1.

1HNMR spectrum showed characteristic signals (δ ppm) at 7.3q (4H-Ar-

CH), 5.7q (1H-=CH), 5.5q (1H-=CH), 4.88d (2H-=CH), 4.63d (2H-=CH), 2.2q (2H-

CH), 2.09-1.84m (4H-CH2), 1.71d (9H-CH3), 1.5-1.2m (4H-CH2).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 358. It exhibited the fragmentation pattern characteristic of the

compound.

222

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound

XV as N,N’-bis[(1E)-2-methyl-5-(prop-1-en-2-yl)cyclohex-2-en-1-ylidine]benzene-

1,2-diamine.

Compound XVI

Compound XVI was synthesized as per scheme XVI and recystallized to

obtain pure compound. The purity was determined using TLC; the compound

exhibited Rf value of about 0.8 using solvent system benzene: Ethanol (4.5:0.5).

The melting point was found to be 195oC. Percentage yield was found to be 59%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of N-H Stretching at 3438.41cm-1methyl

at 3321.52 cm-1, C-H stretching alicyclic at 2922.53 cm-1, conjugate C=C at

1644.cm-1,NO2 at 1583.12 and 1329.20 cm-1.

1HNMR spectrum showed characteristic signals (δ ppm) at 5.5q (1H-=CH),

4.83d (1H-=CH), 4.69d (1H-=CH), 2.2q (1H-CH), 2.09-1.84m (2H-CH2), 2.0s (1H-

OH), 1.71d (6H-CH3), 1.5-1.2m (2H-CH2).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 165. It exhibited the fragmentation pattern characteristic of the

compound. The analytical and spectral data proves the identity and the purity of

the compound. From the spectral datas it also confirms the structure of

compound XVI as (1E)-N-hydroxy-2-methyl-5-(prop-1-en-2-yl) cyclohex-2-en-1-

imine.

223

Physical, Analytical and Spectral datas of Camphor derivatives

Compound XVII

Compound XVII was synthesized as per scheme XVII and recystallized to

obtain pure compound. The purity was determined using TLC, the compound

exhibited Rf of about 0.79 using solvent system; Benzene: ether (4.5:0.5). The

melting point was found to be 95oC. Percentage yield was found to be 78%.

The percentage of elements (C, H, O, N) obtained from elemental analysis

was matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of N-H stretching at 3216.46 and

3080.03 cm-1, C-H stretching at 2913.90 cm-1, C=C ring aromatic at 1437.43 cm-

1, C=O 1643.65 cm-1.

1HNMR spectrum showed characteristic signals (δ ppm) at 7.3q (1H-Ar-

CH), 1.60-1.34m (8H-CH2), 1.5t (2H-CH), 1.4-1.2m (4H-CH2), 1.11m (18H-CH3).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 376. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound

XVII as N, N’-bis-[(2E)-1,7,7-trimethyl bicyclo[2.2.1]hept-2-ylidene]benzene-1,2-

diamine-ethane(1:1).

Compound XVIII

Compound XVIII was synthesized as per scheme XVIII and recystallized to

obtain pure compound. The purity was determined using TLC; the compound

224

exhibited Rf of about 0.89 using solvent system N-hexane: Carbon tetrachloride

(4.5:0.5).

The melting point was found to be 79oC. Percentage yield was found to be

67.7%w/w.

The percentage of elements (C, H, O, N) obtained from elemental analysis was

matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of N-H stretching at 3455.12cm-1,

Aromatic C-H bending at 3085.13cm-1, C=0 bending at 1733.75cm-1,C-H methyl

group at 3324.36, Aromatic C-H bending at 826.26cm-1, aromatic rings at

1497.27-1 cm-1.

1HNMR spectrum showed characteristic signals (δ ppm) at 7.99d (2H-Ar-

CH), 7.46d (1H-Ar-CH), 7.37d (2H-Ar-CH), 7.21d (2H-Ar-CH), 7.12d (2H-Ar-CH),

7.08d (1H-Ar-CH), 3.06m (2H-CH2), 1.90q (2H-CH2), 1.52q (2H-CH2), 1.49q

(2H-CH2), 1.42d (1H-CH), 1.16s (3H-CH3), 1.11t (6H-CH3).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 348. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound

XVIII as 2-benzyl-1,7,7-trimethylbicyclo [2.2.1] hept-2-benzoate.

Compound XIX

Compound XIX was synthesized as per scheme XIX and recystallized to

obtain pure compound. The purity was determined using TLC; the compound

225

exhibited Rf of about 0.96 using solvent system, Ether: Carbon tetrachloride

(4.5:0.5).

The melting point was found to be 176oC. Percentage yield was found to

be 50.6%.

The percentage of elements (C, H, O, N) obtained from elemental analysis was

matching with the calculated percentage. FT-IR Spectrum of Compound I

showed characteristic absorbance peak of N-H bending at 3441.99cm-1,

Aromatic C-H bending at 3061.84cm-1, C=0 stretching at 1733.75cm-1, Aromatic

C-H bending at 810.69cm-1,aromatic rings at 1497.12.cm-1.

1HNMR spectrum showed characteristic signals (δ ppm) at 7.3t (5H--Ar-

CH), 1.6d (4H-CH2), 1.5m (1H-CH), 1.4d (2H-CH2), 1,1s (6H-CH3).

The mass spectrum of the compound showed its molecular ion (M+) peak

at m/z at 227. It exhibited the fragmentation pattern characteristic of the

compound.

The analytical and spectral data proves the identity and the purity of the

compound. From the spectral datas it also confirms the structure of compound

XIX as N-[(2E)-1,7,7-trimethylbicyclo [2.2.1] hept-2-ylidene] aniline.

II. Pharmacological Screening.

The semisynthetic derivatives of citral, vanillin, carvone and camphor was

synthesized as per the scheme and procedures discussed in our earlier chapters.

The compounds synthesized were subjected for various pharmacological

activities and their datas were represented in the tables illustrated in previous

chapters. The pharmacological activities are acute toxicity studies, analgesic

226

activity, anti-inflammatory activity, anthelmintic activity, Antimicrobial activity,

antifungal activity, and invitro antioxidant activity.

Acute toxicity studies:

The acute toxicity studies were performed as per OECD guidelines 423. All

the compounds synthesized were administered intraperitonially for mice (20-25

gm) and monitored for the mortality rate for next 48hrs. There was no mortality

rate and there were no behavioral changes observed for 48hrs. This proved the

compounds synthesized were safe up to 2000mg/kg body weight.

Sl.No. Compounds LD50 Value (mg/kg body weight)

1 Compound No. I 2150

2 Compound No. II 2310

3 Compound No. III 2815

4 Compound No. IV 2620

5 Compound No. V 2885

6 Compound No. VI 2620

7 Compound No. VII 2410

8 Compound No. VIII 2765

9 Compound No. IX 2816

10 Compound No. X 2011

11 Compound No. XI 2620

12 Compound No. XII 928

13 Compound No. XIII 889

227

14 Compound No. XIV 1110

15 Compound No. XV 920

16 Compound No. XVI 967

17 Compound No. XVII 1240

18 Compound No.XVIII 1011

19 Compound No. XIX 1150

Antimicrobial activity:

The antibacterial activity of compounds synthesized was performed

against two gram positive bacteria viz., B.subtilis and S.aureus and two gram

negative bacteria viz., E.coli and P. vulgaris by using cup plate method.

Ampicillin sodium was used as standard. The compounds showed good to mild

antimicrobial activity.

The two citral derivatives synthesized in the study has shown antimicrobial

activity among them compound I has shown better antimicrobial activity with a

greater zone of inhibition of 18mm in comparison with 14mm of compound II. But

when compared with the standard drug Ampicillin, compound II has shown

moderate antibacterial activity. While comparing the structure of compound I and

compound II, both the compounds contain Nitrogen hetero atom where as the

compound II contains Keto group and the aromatic rings which are absent in

compoundI. This states that removal of keto group is essential for the

antimicrobial activity, attaching the aromatic ring substituted amine to the

228

aldehyde group will show better activity than attaching a nitrogen attached to a

aliphatic compounds.

Nine derivatives of vanillin have been subjected for antimicrobial activity,

all the compounds have shown mild to moderate antibacterial activity. Among

them compoundIX has shown good activity against both gram positive and gram

negative bacteria in comparison with other derivatives. But when compared with

standard except compound IX other derivatives has shown mild antibacterial

activity, compound IX has shown moderate to good antimicrobial activity against

gram positive and gram negative bacteria. The zone of inhibition of compound IX

was 19mm and 18mm against B. Subtillis and S. Aureus, whereas zone of

inhibition of Ampicillin (standard) was found to be 22 mm and 20mm respectively.

This clearly shows that compound IX has good antimicrobial activity. The

compound IX has shown excellent and better activity against gram negative

bacteria’s with zone of inhibition of 23mm and 16mm when compared with

ampicillin (standard) with zone of inhibition of 18mm and 17mm against E.Coli

and P.Vulgaris respectively. This proves compound IX is a better compound with

good and excellent antimicrobial activity against gram positive and gram negative

bacteria.

When comparing the structure of compoundIX with the other derivatives;

compound IX comes under the category of chalcones as reported earlier in the

literature chalcones has shown to have antimicrobial activity. Thus it could be

concluded that the presence of keto group in vanillin is essential for microbial

activity and also attachment of higher aromatic substances or heteroatom’s like

229

nitrogen will not increase the activity and also has not diminished the activity but

to get better activity it will be better to substitute the aldehyde group with smaller

alkyl chains to achieve more potent antimicrobial compounds.

Five derivatives of carvone were synthesized and all the compounds were

subjected for antimicrobial activity against both gram positive and gram negative

bacteria. All the five derivatives were found to posses’ mild to moderate

antimicrobial activity. In comparison with ampicillin (standard), compoundXIII was

found to have good antimicrobial activity against both gram positive and gram

negative bacteria. The zone of inhibition of compound XIII was found to be

16mm and 17mm, whereas ampicillin (Standard) showed zone of inhibition of 22

mm and 20mm against B.Subtilis and S.aureus respectively.

In Compound XIII, the oxygen of the keto group was replaced by hydrazyl

group whereas on other compounds the oxygen was replaced with other

substituents like aromatic rings and alkyl derivatives. The presence of the

hydrazyl group may be responsible for increase in the antimicrobial activity.

All the three camphor derivatives has shown mild to moderate

antimicrobial activity, but none of the derivatives showed comparatively good

antimicrobial activity in comparison with the standard drug (Ampicillin).

Antifungal activity:

Citral derivatives were subjected for antifungal activity against A.niger, C.

verticulata, F. oxysporum, A. flavus and compared with standard drug. Among

them compound I showed better activity with zone of inhibition of 19mm against

A.niger but was not comparative active against other organisms.

230

Various derivatives of vanillin were synthesized and subjected for

antifungal activity, all the derivatives showed mild antifungal activity with respect

to the standard drug. Among them compound IX was found to have a better

activity with zone of inhibition of 17mm, 16mm, 13mm and 11mm against A.niger,

C. verticulata, F. oxysporum, and A. flavus respectively

Even the carvone derivatives have not shown any comparative activity

against the organisms used. Still all the compounds were more or less with the

same potency it clearly shows that the activity of the parent compound has not

been affected much with the substitution. Thus more derivatives have to be

synthesized by modifying the structure or by substituting other substituents in

other suitable portions of the compound.

Carvone derivatives have shown mild to moderate antifungal activity.

Among the carvone derivatives compoundXV have shown moderate activity in

comparison with the standard drug. It has shown the zone of inhibition of 16mm,

14mm, 07 mm and 10mm against A.niger, C. verticulata, F. oxysporum, and A.

flavus respectively.

Camphor derivatives showed mild to moderate activity against the

organisms used for antifungal activity. CompoundXVII has shown better activity

when compared with the other derivatives of camphor. It has the zone of

inhibition of 17mm, 12mm, 10mm and 04mm against A.niger, C. verticulata, F.

oxysporum, and A. flavus respectively.

Thus it was concluded that the compounds synthesized was not very

effective against the fungus, since the parent compound has antifungal property

231

in future more works should be targeted on these derivatives to optimize the

structure and to come up with a potent and a safer drug.

Invitro antioxidant activity:

A.Scavenging of ABTS radical cation:

ABTS radical anion scavenging activity was performed for all the derivatives of

citral, vanillin, and carvone. The experiments were performed in triplicates and

their average was taken and the IC50 values were calculated. Ascorbic acid was

used as standard. The IC50 values of the synthesized compounds were compared

with IC50 of ascorbic acid.

The Ic50 values of citral are more when compared to that of ascorbic acid

which shows that both the derivatives have very less scavenging property.

Among the vanillin derivatives compounds IX and III had moderate radical

scavenging activity. They have shown IC50 of 6.39 and 6.98 respectively, which is

comparable with the IC50 value 4.83 of Ascorbic acid. Compounds (IV-VII) have

showed very poor radical scavenging activity.

The carvone derivatives subjected for ABTS radical scavenging activity showed

mild to moderate scavenging activity. Among them compounds XIII showed

moderate scavenging activity when compared with the IC50 value of ascorbic

acid. Next compound with better scavenging activity is compound XII with a IC50

value 8.05. The other compounds showed very poor or mild scavenging property.

All the camphor derivatives have shown the IC50 value around and above more

than 9 which show the derivatives have very poor radical scavenging activity.

232

B.DPPH radical scavenging activity

The compounds synthesized were subjected for DPPH radical scavenging

activity and the results were compared with Ascorbic acid. Both the citral

derivatives have shown IC50 at a higher concentration it clearly indicates that

citral derivatives have very less radical scavenging property.

Vanillin derivatives have shown mild to moderate scavenging property.

Compound III, VIII, IX, X, XI has shown IC50 values around seven which is less

than the IC50 value of standard. Thus it can be concluded that these compounds

has moderate radical scavenging activity. Whereas, other derivatives of vanillin

have shown IC50 value at a higher concentration.

Except compound XIII and XIV all other derivatives of carvone has the IC50

values at a very high concentration. Compound XIII and XIV have their IC50 of

7.76 and 7.99 respectively, which proves that both the compounds posses

moderate antioxidant property.

The results of camphor derivatives show the IC50 value at higher concentration

except compound XVII. The IC50 Compound XVII was 7.88 which can be

considered as moderate scavenging property when comparing with the IC50

value of standard.

C.Nitric oxide radical scavenging activity

The IC50 values of the derivatives were around 9μM which is high when

compared to the IC50 values of the standard drug. This proves that citral

derivatives have shown very mild antioxidant activity.

233

Vanillin derivatives showed mild to moderate antioxidant activity. Compound

III, VIII, IX and XI has shown good antioxidant activity with the IC50 values of 7.01,

6.52, 5.96 and 6.62μM respectively. Other derivatives had the IC50 values at

higher concentration i.e. above 9μM.

Compound XIII of carvone derivatives showed good nitric oxide scavenging

activity at IC50 value of about 6.93μM concentration. The other derivatives of

carvone have not shown satisfactory results in scavenging the nitric oxide

radical.

The camphor derivatives had the IC50 value above 9 μM concentration. This

proves that the camphor derivatives have very mild nitric oxide radical

scavenging activity.

Anti-inflammatory activity

The anti inflammatory activity of all the synthesized compounds was

carried out using Male, Wister rats. Anti-inflammatory activity was evaluated by

carrageenan induced paw edema model using the standard drug diclofenac

sodium (10mg/ml) and results are presented in Table NO. 19. The results

mentioned showed good significance value with P < 0.05.

As per the results represented in Table No.19., all the derivatives

synthesized showed anti-inflammatory activity. Among the two citral derivatives

compound II showed potent anti-inflammatory activity whereas compound I

showed moderate anti-inflammatory activity.

All the nine derivatives of vanillin have showed satisfactory anti-inflammatory.

Compound III, IV, V, VI, VII, VIII and IX showed good potent anti-inflammatory,

234

whereas compound X and XI showed moderate anti-inflammatory activity in

comparison with standard drug Diclofenac sodium (10μg/ml).

Among the derivatives of carvone, compoundXVI and XIV showed potent

anti-inflammatory activity in par with the standard drug. The other derivatives

showed moderate activity with 15 to 30 percentage reduction of inflammation

when compared with the standard drug.

The results of camphor derivatives states that they posses moderate to good

potent anti-inflammatory activity. Compound XIX and XVIII showed good potency

and were in par with the standard drug. The compound XVIII also showed good

moderate activity.

Analgesic Activity:

All the derivatives of citral, camphor, carvone and vanillin have been

evaluated for their analgesic activity by Eddy’s hot plate method. The results of

analgesic activity are presented in Table No.20. The data represents that none of

the tested compounds shown analgesic activity as good as the standard drug.

The citral derivatives showed less to moderate activity when compared with the

standard drug. Among the vanillin derivatives CompoundIII, IV, V, VII and IX

showed good activity when compared to the standard drug, whereas the other

vanillin derivatives i.e. compound VI, VIII, X, and XI showed less to moderate

analgesic activity in comparison with the standard drug.

The carvone derivatives (compound XII – XVI) showed moderate activity in

comparison to the standard drug. The datas prove that compound XIX of

camphor derivative showed good potent analgesic activity when compared with

235

the standard drug. The other two derivatives i.e. compound XVII and XVIII

showed moderate analgesic activity when compared with the standard drug.

Anthelmentic activity

All the compounds were screened for Anthelmintic activity by using Indian

adult earth worms (Pheretima postuma). The compounds were evaluated for the

time taken for complete paralysis and death of earthworms by taking albendazole

as the standard drug with 0.1, 0.2, and 0.5 % concentrations. The compounds

were evaluated and results are presented in Table No.21.

As per data’s recorded in Table No.20. Citral derivatives were found effective in

causing paralysis but have consumed more time to cause death. Among the two

derivatives compoundII was found to be more effective and the time consumed

was less and in par with the standard whereas it has not shown to be as effective

as the standard drug in causing death.

Vanillin derivatives also showed the same results as that of citral

derivatives; they have taken more time to cause death when compared with the

standard drug (Albendazole). Among the vanillin derivatives, compound X has

showed excellent paralytic effect on Indian earth worms but was not as effective

as standard drug in causing death. All the other derivatives showed good

paralytic effect on Indian earth worms. Carvone and camphor derivatives also

shown good paralytic effect but they consumed more time in causing death to

Indian earthworms.

236

SUMMARY AND CONCLUSION

Nature always stands as a golden mark to exemplify the outstanding

phenomenon of symbiosis. Several herbs consist of powerful ingredients, which

are helpful to cure a number of health problems. A crude (untreated) extract from

any one of these sources typically contains novel, structurally diverse chemical

compounds, which the natural environment is a rich source of Chemical diversity

in nature is based on biological and geographical diversity, so researchers travel

around the world obtaining samples to analyze and evaluate in drug discovery

screens or bioassays. As a result of rapid development of phytochemistry and

pharmacological testing methods in recent years, new plant drugs are finding

their way into medicine as purified phytochemicals, rather than in the form of

traditional galenical preparations. The earliest pure compounds discovered were

salicin, isolated from the bark of the white willow, Salix alba, in 1825-26. It was

subsequently converted to salicylic acid via hydrolysis and oxidation, and proved

as successful as an antipyretic (fever reducing) that it was actively manufactured

and used worldwide. The use of salicylic acid, however, often led to severe

gastrointestinal toxicity. This was overcome when Felix Hoffmann of Bayer

Company converted salicylic acid into acetylsalicylic acid (ASA) via acetylation.

Bayer then began marketing ASA under the trade name aspirin in 1899. Today,

aspirin is still the most widely used analgesic and antipyretic drug in the world.

Based on the above concept four pharmacologically potential compounds

were selected. Various derivatives of these compounds were synthesized using

237

simple synthetic procedures. A total of nineteen semi-synthetic derivatives were

synthesized and their structures are confirmed by Physical and spectral analysis.

The derivatives of the above mentioned compounds were synthesized as

per the scheme mentioned in earlier chapter. The compounds synthesized were

subjected for thin layer chromatography to identify the purity of the synthesized

compound.

The synthesized compound was subjected for physical analysis like

melting point, solubility, and elemental analysis; and was also subjected for

1HNMR spectroscopy, MASS spectroscopy and FT-IR spectroscopic studies for

characterizing the structure of the synthesized derivatives.

The physical, elemental and spectral datas of the above mentioned compounds

was interpreted and the structure of the synthesized derivatives was elucidated.

The list of newly synthesized derivatives is represented in the table below.

Table No.22. List of the Newly Synthesized Derivatives along with their

IUPAC Name.

Sl.NOCOMPOUND

NUMBERCOMPOUND NAME

1 Compound No. I2-[(2Z)-3,7-DIMETHYLOCTA-2,6-DIEN-1-YLIDENE]HYDRAZINE

CARBOXAMIDE

2 Compound No. II(2Z)-N-DIPHENYLMETHYLIDENE-3,7-DIMETHYLOCTA-2,6-

DIENAMIDE

3 Compound No. III 4[(E)-HYDRAZINYLIDENEMETHYL]-2-METHOXYPHENOL

4Compound No.IV

2-METHOXY-4-[(E)-(2-

PHENYLHYDRAZINYLIDENE)METHYL]PHENOL

5 Compound No. V4-{(E)[2-(2,4-DINITROPHENYL)HYDRAZINYLIDENE]METHYL}-2-

METHOXY PHENOL

238

6Compound No.VI

N-[(Z)-(4-HYDROXY-3-

METHYLPHENYL)METHYLIDENE]HYDRAZINECARBOXAMIDE

7Compound No.VII

4,4'-{BENZENE-1,2-DIYLBIS[NITRILO(E)METHYLYLIDENE]}BIS(2-

METHOXY PHENOL)

8Compound No.VIII

(2E)-3-(3-HYDROXY-2-METHYLPHENYL)-1-PHENYLPROP-2-EN-1-

ONE

9Compound No.IX

(1Z)-1-(4-HYDROXY-3-METHOXYPHENYL)PENT-1-EN-3-ONE

10 Compound No. X{3-[(Z)-(3-HYDROXY-2-METHOXYCYCLOHEXA-2,4-DIEN-1-YLIDENE)

METHY PHENYL}(PHENYL) METH ANONE

11Compound No.XI

4-[(Z)-2-{[(2E,3Z)-3-(HYDROXYIMINO)BUTAN-2-

YLIDENE]AMINO}ETHENYL]-2-METHOXYPHENOL

12Compound No.XII

(2E)-1-(2,4-DINITROPHENYL)-2-[2-METHYL-5-(PROP-1-EN-2-

YL)CYCLOHEX-2-EN-1-YLIDENE]HYDRAZINE

13Compound No.XIII

(1E)-[2-METHYL-5-(PROP-1-EN-2-YL)CYCLOHEX-2-EN-1-

YLIDENE]HYDRAZINE

14Compound No.XIV

(2E)-2-[2-METHYL-5-(PROP-1-EN-2-YL)CYCLOHEX-2-EN-1-

YLIDENE]HYDRAZINE CARBOXAMIDE

15Compound No.XV

N,N’-BIS[(1E)-2-METHYL-5-(PROP-1-EN-2-YL)CYCLOHEX-2-EN-1-

YLIDINE]BENZENE-1,2-DIAMINE

16Compound No.XVI

(1E)-N-HYDROXY-2-METHYL-5-(PROP-1-EN-2-YL)CYCLOHEX-2-EN-

1-IMINE

17Compound No.XVII

N,N’-BIS-[(2E)-1,7,7-TRIMETHYLBICYCLO[2.2.1]HEPT-2-

YLIDENE]BENZENE-1,2-DIAMINE-ETHANE(1:1)

18CompoundNo.XVIII

2-BENZYL-1,7,7-TRI METHYLBICYCLO[2.2.1]HEPT-2-BENZOATE

19Compound No.XIX

N-[(2E)-1,7,7-TRI METHYLBICYCLO[2.2.1]HEPT-2-YLIDENE]ANILINE

The above mentioned derivatives were subjected for various

pharmacological activities like Acute Toxicity Studies, Analgesic Activity, Anti-

239

Inflammatory Activity, Anthelmintic Activity, Antimicrobial Activity, Antifungal

Activity and Invitro Antioxidant Activity.

The main advantage of semi synthetic drug is they can act with higher

potency than their original natural products such as onset of action, potency, site

of action etc.

Based on the above facts Four Pharmacologically potential compounds

were selected. The various derivatives of this compound were synthesized by

using simple synthetic procedures. The total Nineteen semi synthetic derivatives

were synthsized and their structures are conformed by physical and spectral

analysis.

All the synthesized compounds were subjected for different activities, the

Anti-bacterial activity of the synthesized compounds were performed against two

Gram positive and Gram negative bacteria. The compound II, IX and XIII has

potent Anti-bacterial activity. Further more studies on these derivatives for safer

and potent Anti-bacterial drug.

The Anti-fungal activity of these derivatives compound I, IX, XV and XVII

has shown moderated activity, thus in future more works has to be carried out on

these derivatives to come up with potent moiety.

The compound III to XVIII showed good potent Anti-inflamatory activity

when compared with standard drug.

The acute toxicity studies showed that all theNineteen derivatives were

safe even up 1000mg/kg and thus a dose of 300mg/kg i.p. was used as safer

dose in experimental animals.

240

Based on the above it could be concluded that compound III, IV, IX

and XIII were found to have good potency in all activity performed. Thus structure

of these derivatives has to be optimized to explore the desired Pharmacological

activity

241

CONCLUSIONS

The conclusions drawn from the results discussed in the earlier chapters are as

follows.

1. Synthetic work performed in the present study was positive, as the

predicted compounds were obtained and confirmed using the spectral and

physical data’s.

2. Acute toxicity studies showed that all the nineteen derivatives were safe

even up to 1000 mg/kg and thus a dose of 300 mg/kg i.p. was used as

safer dose in experimental animals.

3. The antibacterial activity of the synthesized was performed against two

gram positive bacteria and negative bacteria proved that compound II,

compound IX, and compound XIII has potent antibacterial activity. This

concludes that further more studies on these derivatives could end up with

a safer and potent antibacterial drug.

4. Antifungal activity of these nineteen derivatives has not shown promising

results but compound I, Compound IX, Compound XV and compound XVII

has shown moderate activity, thus in future more works has to be carried

out on these derivatives to come up with a potent moiety.

5. Antioxidant activities carried out using radical ion scavenging property of

the molecules. Mostly all the molecules were having good activity.

Compound III, Compound IX and Compound XIII showed good radical ion

scavenging activity in all the three methods. Since antioxidant compounds

are likely to posses’ anticancer activity. Thus in future these compounds

242

should be subjected for anticancer screening to identify their anticancer

activity.

6. Compound III, IV, V, VI, VII, VIII, IX, XVI, XIV, XIX and XVIII showed good

potent anti-inflammatory when compared with the standard drug. Thus

more studies have to be carried out using other models to identify their

potency.

7. Analgesic activity results showed that Compound III, IV, V, VII IX and XIX

posses potent analgesic activity. Since these compounds has also proved

their anti inflammatory activity in our previous study. More pharmacological

studies has to be carried out and SAR studies showed be performed on

these derivatives to optimize their analgesic and anti-inflammatory activity.

8. The anthelmentic activity showed that all the derivatives have good

paralytic effect but was not so effective in causing death, thus the structure

has to be optimized in order to derive more potent and safer drug.

Overall it could be concluded that compound III, IV, IX and XIII were found

to have good potency in all the activity performed. Thus structure of these

derivatives has to be optimized to explore the desired pharmacological activity.

243

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