Download - new drug development by harsha
NEW DRUG DEVELOPME
NT
Moderator – Dr.Amitabh kumar , Professor
Presenter – Dr.Sriharsha Rayam
INTRODUCTION
• Average time to develop new drug is 10 -12 years.• On an average out of 10,000 – 30,000 potential
substances only 1 could make it to the market.• As per 2006 estimates, the cost of bringing a new
drug could vary from 500 million to 2,000 million USD.
unmet medical need;
new diseases ( AIDS, Alzheimer’s; obesity);
low efficacy (dementia, cancer);
side effects (antidepressants, antipsychotics)
cost of therapy; (Interleukins)
costs to individual/country; (Alzheimer’s; spinal
injury, depression)
sustain industrial activity ( pharmaceutical industry
employs thousands and makes a massive contribution
to overseas earnings); patent expiry
WHY ARE NEW DRUGS NEEDED?
• Folk medicine - natural product remedies
• Early 19th century - extraction of compounds from plants (morphine, cocaine )
History of Drug Discovery….
• James Lind – Citrus fruits – Scurvy – clinical trail
1909 - First rational drug design. • Goal: safer syphilis treatment than Atoxyl.
• Paul Erhlich and Sacachiro Hata wanted to maximize toxicity to pathogen and minimize toxicity to human (therapeutic index).
• They found Salvarsan (which was replaced by penicillin in the 1940’s)
H2N
AsHO O
O
Atoxyl
As AsHO OH
ClH.H2N NH2.HCl
Salvarsan
Na+
• Mid to late 20th century - understand disease states, biological structures, processes, drug transport, distribution, metabolism. Medicinal chemists use this knowledge to modify chemical structure to influence a drug’s activity, stability, etc.
• procaine = local anaesthetic; Procainamide = antirhythmic
H2N
O
NHCH2CH2N(C2H5)2H2N
O
OCH2CH2N(C2H5)2
Procaine Procainamide
Drug development process – 3 main phases
• 1.drug discovery phase• 2.preclinical phase • 3.clinical trial phase
Drug discovery phase
1. Random screening
2. Serendipity ( By chance )
3. Rational drug designing
4. Designing of a prodrug or an active metabolite as a drug
1.RANDOM SCREENING
• Blind hitting procedure where new chemical entities are subjected to pharmacological screening procedures
• Studies on animal models , isolated tissues etc • It is time consuming, expensive, inefficient in
providing fruitful results ,burdensome• Ex:• Morphine, Atropine , digitalis, Quinidine,
cyclosporine
2.SERENDIPITY (BY CHANCE / HAPPY OBSERVATION)
• New use from old drug or its side effects
• Lignocaine & Phenytoin
• Methotrexate – psoriasis
• Cyclophosphamide & Azathioprine – Graft rejection
• Penicillin 1928, Fleming studied Staph, but contamination of plates with airborne mold. Noticed bacteria were lysed in the area of mold. A mold product inhibited the growth of bacteria: the antibiotic penicillin
3.RATIONAL DRUG DESIGNING
• A. compound centered approach
: from natural products – Pencillin,paclitaxel,cyclosporine
DA – complex molecules – difficult to synthesized
: from synthetic products – from pharmacological data
Ex: Based on proponolol structure- B blokers
H2 blockers - modifying structure of histamine
• Molecular modification ended up in molecular manipulation
New drugs are serving as me too drugs , no added advantage
B. Target centered approach
* Biochemical or molecular targets Ex: ACE blockers or AT II blockers -Now a days large number of drugs this way -Promising agents for lead optimisation
4. DESIGNING OF A PRODRUG OR AN ACTIVE METABOLITE AS A DRUG
• Administered as the precursor of a drug and is converted into active therapeutic agent Ex; Levodopa
• Paracetamol, an active metabolite of phenacetin
• N-acetyl procainamide, an active metabolite of procainamide does not cause SLE
Drug sources
• After the synthesis or isolation of the compound =
• Purity by physico chemical and analytical studies Then these are subjected to biological screening LEAD COMPOUND - which have a potential of becoming
new drug
•compounds can elicit a positive response in a particular assay, which is called a hit.
• “Lead” is a hit series for which the structure–activity relationship is shown and activity demonstrated both in vitro and in vivo
Leads are optimised with respect to
Pharmacodynamic properties-efficacy, potency,
selectivity.
Pharmacokinetic properties- metabolic stability and
toxological aspects
Physiochemical properties
Chemical optimisation-ease of chemical synthesis &
derivation
PRECLINICAL EVALUATION PHASE ( ANIMAL STUDIES)
Major areas are:
Pharmacodynamic studies In vivo in animals, In vitro preparation
Absorption, distribution , elimination studies (pharmacokinetics)
Acute ,sub acute, chronic toxicity studies (toxicity profile)
Therapeutic index (safety & efficacy evaluation)
Pharmacodynamic studies •Action relavent to proposed therapeutic use are studied on animals Ex: Antihypertensive activity – dogs,cats,rats To find out – B.P - ECG changes - inotropic & chrinotropic efforts - CO & t.p.r •Once L.C exibits promising results – futhur studies at cellular level •Receptor activity in vitro on cultured cells •Further extended to molecular level to find out receptor affinity & selectivity by performing in vitro studies on cell membrane fractions from organs •Graded response assy or Quantal assay - ED 50 of the drug•
Pharmacokinetic profile
New compounds subjected in several species of animals.
Studies should establish
a) Relative bioavailability of the compound on oral or parenteral administration
b) Elimination half life for assessment of optimal dosage interval
Acute toxicity Acute toxicity studies most commonly median lethal
dose
i.e. LD50 is determined. Drug is given in graded doses to at least 2 animal
species by at least 2 routes. To minimize biological variation, animal groups should
be similar. Percentage of animals dying in each group within
specified time (24 hrs) is plotted against the dose. Other toxic symptoms suffered also recorded.
Toxicity profile
Sub acute toxicity To identify target organs susceptible to drug toxicity. Laboratory studies like hematology, renal ,hepatic
function test are carried out. Animals are maintained at max. tolerated dose for 4 wks
– 3 months & killed for HPE.
Chronic toxicity If drug intended for chronic use in humans. 2 species of animals ,1 rodent and 1 non rodent are
used.
Drug administered for many months (6-24 months),detailed biochemical & histological measurements are made.
To evaluate cumulative toxicity To assist carcinogenic potential Study may run simultaneously with clinical trial.
Test for fertility & reproductive performance Carried out in rats, treated with new drug before & after
mating period. Effects on early & late stages of embryonic & fetal
development are studied .
Teratogenicity Carried out in 2 animal species to assess the effects of
drug on organogenesis. Drugs given after mating Fetuses are carefully examined for abnormalities.
Genotoxicity/ Mutagenicity:
It is invivo – invitro test conducted to detects
compounds which induces genetic damage directly or
indirectly. The following standard test is generally expected to be conducted : 1. A test for gene mutation in bacteria – AMES test
2. An invitro test with cytogenetic evaluation of chromosome damage with mammalian cells
3. In vivo test for chromosomal damage using rodent Hematopoietic cells.
Parameters:
Frequency of damage cells ,Total number, types and frequency of metaphase chromosomal aberration
CARCINOGENECITY :
• for all drugs that are expected to be clinically used for six months as well as for drugs used frequently in an intermittent manner in the treatment of chronic or recurrent condition
• Animals : rodent 2 animal species , same dose of chronic study,
for 2 years.• Parameters : Autopsy and detailed Histopathology of organ and
tissues
LOCAL TOXICITY:
These studies are required when the new drug is proposed to be used by some special route in human.
Dermal toxicity Vaginal toxicity Rectal tolerance test Ocular toxicity
1. Dermal toxicity: Animals: rabbit & rat Parameters: erythema & edema2. Vaginal toxicity: Animals: rabit & dog Parameters: swelling, closure of introitus & histopathology
of vaginal wall.
3. Rectal tolerance test-
Animals: rabbit & dog
Parameters: sign of pain, blood/mucus in faeces, histopathology of rectal mucosa.
4. Ocular toxicity-
Animals: rabbit
Parameters: Slit Lamp Test & Fluroscent Dye Test
3.Therapeutic index Relative margin of safety of a drug
TI =LD50/ED50• Maximum Tolerated Dose • No Adverse Effect Dose • Human Equivalent Dose
REDUCING ANIMAL USAGE
• About 2.6m animals/y used in procedures in UK (11.6m in Europe)
• Likely to increase; more research, more targets, genetic capability
• 3Rs -- 3Rs -- 3Rs
• REPLACEMENT: use non-animal tests if possible (cheaper, less trouble, less variable but not possible for everything at this time)
• REDUCTION: get the statistics right, don’t replicate work unnecessarily, don’t overbreed
• REFINEMENT: reduce suffering and severity of procedure, pay attention to housing, stress, husbandry and rich environments, proper analgesia and pre- and post- operative care
CLINICAL TRIAL PHASE(HUMAN PHASE)
• To determine safety & efficacy of a new drug in humans
• Good clinical practices (GCP) by international Conference on Harmonization (ICH) and declaration of Helsinki.
• It provides details about – designing the trail
- collection of data
- recording of information
- statistical analysis
- documentation & reporting
IND APPLICATION
• When the new compound passes the preclinical phase , manufacturer may file a Investigational New Drug (IND) application to authorized drug control body
• In INDIA - drugs controller general,Govt.of india,Delhi
• It contains information about the test drug –
- source,structure,manufacturing data
- preclinical data
- dosage forms,investigational protocol
- details about investigators
- agreement from the sponsers
- certification that Informed Consent will be obtained from volunteers
Eight basic elements of informed consent purpose of the research risks or discomforts any benefits to the subject which may reasonable be expected from
the research Any alternative procedures or treatment that may be available to the
subject confidentiality of records identifying the subject will be maintained any compensation and whether any medical treatments are
available if injury occurs An explanation of whom to contact for answers to questions about
the research and research subjects’ rights A statement that participation is voluntary
Informed consent
Ethics committee & its responsibilities
• At the institutional level – independent E.C to ensure rights & welfare of the participants
• Responsibilities - review protocol - safeguard the rights , safety of trail subjects - periodical review – SOPs • 7 members – Member secretary - chair person (outside) - medical & non medical persons
ROLE OF PLACEBO
• Placebo controls – on healthy volunteers – Appetite stimulant or new vaccine
• No place – Pt suffering from a disease – effective drug already available
• Ethics – consent is taken
PHASES OF CLINICAL TRIALS
• 4 phases
phase I
phase II
phase III
phase IV
PHASE 1 CLINICAL TRIALS :
• Begins after 30 days of filing IND.• Drug given to 20-100 healthy volunteers
• Duration could vary from 1 month to 1 year. • Following is studied here :
• Drug absorption/Metabolism in human. • Effect on organs and tissues. -Side affect of different
dosages. • Thus early evidences on effectiveness are achieved*NON BLIND OR OPEN LABEL TRAIL
Phase I studies are carried out in 2 stagesSingle rising doseRepeat administration
Each volunteer given a single dose of drug/placebo. Dose-escalating study design. Initial dose and route of administration decided from existing
pre-clinical data. 8 -12 volunteers . 2-4 volunteers receive placebo and 6-8 volunteers receive drug
under study.
STAGE 1–SINGLE RISING DOSE
Started after single dose administration results assessed.
Drug / placebo given repeatedly for 1 or more weeksE. g. Antibiotics given for 5-7 daysAnticonvulsants tested for 4 weeks or more
Interval between doses is usually one half life. Kinetic data obtained from blood and urine sample
collected after 1st and last dose
STAGE 2 REPEATED ADMINISTRATION
PHASE 2 CLINICAL TRIALS :
• Therapeutic exploratory trial• First time in patients
• Less than 300 patients• Doses are usually less than the highest doses
used in phase I *SINGLE BLIND TRAIL
1. Efficacy in patients
2. Safety issues
3. Optimum dose finding Dose efficacy relationship Therapeutic dose regimen Duration of therapy Frequency of administration Therapeutic window
OBJECTIVES
PHASE II DIVIDED INTO EARLY & LATE PHASE
• EARLY PHASE II
small number of pts – upto 200
detail therapeutic benefited & ADR
idea to establish dose range
SINGLE BLIND STUDY
• LATE PHASE II
large number of pts – 200-400
DOUBLE BLIND STUDY
third party holds the code identifying studies
PHASE 3 CLINICAL TRIALS :
• By several physicians at many centres• Large scale – 1000 to 5000 plus• To further establish the safety & efficacy • Long term side effects in patients• Duration could vary from 5 years to 6 years. • DOUBLE BLIND CROSS OVER design • At end of trail statistical analysis of data is
performed
Pts groups Week 1 Week 2 Week 3
ISTANDARD DRUG
PLACEBO NEW DRUG
IIPLACEBO NEW DRUG STANDARD
DRUG
IIINEW DRUG
STANDARD DUG
PLACEBO
Double-Blind Cross Over design
NDA
• NDA Refers to New Drug Application • Formal proposal for the FDA to approve a new drug for
sale • Sufficient evidences provided to FDA to establish:
• Drug is safe and effective. • Benefits outweigh the risks. • Proposed labeling is appropriate.
PHASE IV
• launched to the Market • Post marketing surveillance – field trails • No fixed duration • To discover relatively rare side effects(congenital effects) or
drug interactions• From hundreds to thousands of people• Usually takes place after drug is approved to provide additional
information on the drug’s risks, benefits and optimal use
PERIODIC SAFETY UPDATE REPORT (PSUR)• Report any new information about the new drug & its
safety
• Every 6 months for 2 yrs & annually next 2 yrs
Where the drug fails ?
EXAMPLE: THALIDOMIDE
Thalidomide was developed by German pharmaceutical company Grünenthal. It was sold from 1957 to 1961 in almost 50 countries under at least 40 names. Thalidomide was chiefly sold and prescribed during the late 1950s and early 1960s to pregnant women, as an antiemetic to combat morning sickness and as an aid to help them sleep. Before its release, inadequate tests were performed to assess the drug's safety, with catastrophic results for the children of women who had taken thalidomide during their pregnancies.
Birth defects
caused by use of thalidomide
EXAMPLE: THALIDOMIDE
From 1956 to 1962, approximately 10,000 children were born with severe malformities, including phocomelia, because their mothers had taken thalidomide during pregnancy. In 1962, in reaction to the tragedy, the United States Congress enacted laws requiring tests for safety during pregnancy before a drug can receive approval for sale in the U.S.
Phocomelia presents at birth very short or absent long bones and flipper-like appearance of hands and sometimes feet.
Pharmacovigilance
• Pharmakon – a drug , vigilare – to be observant • Continuous monitoring for unwanted effects & other
safety related aspects of marketed drugs • Thalidomide, Isotretinoin , • Fenfluramine & Phentermine – PHTN & valvular H.D• Troglitazone – liver toxicity
• WHO – safety monitoring of medical products - setting a P.V centre in every country
• P.V – Detection,Assessment, Understanding and Prevention (DAUP) of ADR
• INDIA ,National P.V centre – AIIMS, New Delhi by central drug standard control organization (CDSCO)
• 2 zonal , 8 regional & 28 peripheral P.V centres• Generated data – global P.V database at WHO-Uppsala
monitoring centre-Sweden• Reporting ADR includes: -drug interaction -death -life-threatening reaction -hospitalization -disability -congenital abnormality
• Pharmaceutical companies are commercial enterprises• Pharmaceutical companies will, therefore, tend to avoid
products with a small market (i.e. a disease which only affects a small subset of the population)
• Pharmaceutical companies will also avoid products that would be consumed by individuals of lower economic status (i.e. a disease which only affects third world countries)
Choosing a Disease
Most research is carried out on diseases which afflict “first world” countries: (e.g. cancer, cardiovascular diseases, depression, diabetes, flu, migraine, obesity).
Choosing a Disease
The Orphan Drug Act
• The Orphan Drug Act of 1983 was passed to encourage pharmaceutical companies to develop drugs to treat diseases which affect fewer than 200,000 people
• Because the cost incurred will not be recovered• So rare diseases are left untreated – orphan diseases ,
drugs – orphan drugs • Govt. offered tax relief and exclusive marketing rights • > 300 drugs Ex: factor XIII , Erythropoietin , Atravaquone ,
Antithrombin III , Miltefosine , Acetyl cysteine , Relaxin
New tools for drug screening
HIGH THROUGHPUT SCREENING
Screening large libraries of 2 lakh compoundsRate of 1,00,000 compounds/day
In HTS chemicals are tested for their ability to modify a target
Methods – screening of combinatorial chemistry ,genomics, proteomics & peptidelibraries
Drugs are tested for their activity on these molecules using plates wherein a large number of compounds are simultaneously tested.
Screening depends on inhibition of enzymic products which are detected using fluoroscopy or photometry
Instrumentation 24 WELL PLATE. 96 WELL PLATE. - COMPOUND STORAGE. - COMBINATORIAL CHEMISTRY. - SAMPLE COLLECTION. -SCREENING. 384 WELL PLATES. -LOW VOLUME -DNA LIBRARY MANIPULATION. 1536 WELL PLATES.
Advantages
Lead compound.
Molecular mechanism.
Minimizing cost and maximizing patent life time.
Highly efficient development.
Disadvantages
Availability Of Instruments.
Trained Personnels.
HTS is a remarkable achievement in drug discovery process
to speed up preclinical discovery process. This automation in
the process is supported by the excellent software packages.
.
The goal of the HTS is to accelerate drug discovery by
screening large libraries at a rate that may exceed 50,000
compounds per week.
CASSETTE DOSING / N-IN-ONE DOSING
• Elegant, inexpensive , time intensive novel technique – aim to rapidly assess P.K of large number of compounds
• Several compounds(5-10) to single animal & rapid sample analysis by liquid chromatography or mass spectography
• Advantages – to reduce no. of animals
- increased quality of kinetics data
- reduce the amount of the drug
- time minimized
• Disadvantages – drug to drug interactions
- false positives
Micro dosing / First In Human( FIH) studies /Phase O
•Study of new drug in microdoses to derive PK information in human before undertaking phase I studies is called PHASE 0
•“1/100th or lower of the expected therapeutic dose.”A dose less than 100ug
•(The test compound has no pharmacologic effect at microdose concentrations)
• Microdosing approach in man could ‘accelerate’ drug development without compromising clinical safety
• Microdosing helps researchers select better drug candidates for clinical trials by providing early human PK and bioavailability data.
• Reduced cost of development• Reduced development time
Objectives Primary:
Determine the pharmacokinetics Determine a non -toxic dose range
Secondary : Determine the safety of an chemical entity
Limitations ? Predictive accuracy of microdosing
PK at microdose vs. therapeutic dose False positive/ negatives Compound metabolism and solubility (limited solubility at
higher doses; ? Microdose too small) Study mainly based on PK parameters - not efficacy and
safety based
• 3rd world diseases?• orphan drugs with few users?• improve safety and efficacy records• reduce animal utilisation (cell lines; early
human volunteers, )• new diseases (AIDS; Alzheimer’s; CJ
disease;human BSE variant; obesity; cancer)• new biology - (clone human receptors;
disease model by gene changes)
The future ?
References :
• Pharmacological basis of Therapeutics – Goodman & Gilman 12th Edition .
• Principles of pharmacology – HL Sharma & KK sharma 2nd edition .• Drug Screening methods – Gupta 2 nd edition
• Experimental Pharmacology – Bikash Medhi
• Text book of pharmacology – K. D. Tripathi.7th Edition.
• Basics & clinical pharmacology – Katzung 11th edition • www.history of clinicaltrails.in
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