by daniel c. perrinez morse hall 103 faculty contact: ihab h. … · 2015. 9. 18. · 0.079...

By Daniel C. Perrinez

Morse Hall 103

Faculty Contact: Ihab H. Farag, Sc.D., P.E.

Overview

Background

Project

Process Description

Approach

Chemicals, Equipment , and Wastes

Status & Future Steps

http://www.rbgsyd.nsw.gov.au/__data/assets/image/0019/47350/chlorella2.gif

Picture of Triglyceride Lipid

Transesterfication

Project

Objectives: Develop lipid extraction for Chlorella sp.

(micro-algae)

Develop Lipid profiling method for Chlorella sp.:

○ Identify Lipids by class

○ Quantify Lipid class constituents

Goal: Observe trends between the abundance of

triglyceride molecules and other in-vivo lipids.

Process Description

Microalgae are grown in a

photo-bioreactor

Cells are lypholized

Lipids are extracted from Cells

Lipid molecules are separated & quantified by

High-performance liquid chromatography (HPLC)

Gas Chromatography (GC)

Process Description

Microalgae are grown in bio reactor


(freeze dried)





Process Description







Process Description




Lipid molecules are

separated & quantified by: Gas Chromatography (GC)


Approach

Lots of Reading!

Difficulties:

○ Chlorella is Small! (~2-10μm)

and hard to break

○ Limited prior research is speculative

○ Not all lipids can dissolve in just one solvent

Approach

Lots of Reading!

Difficulties:

○ Chlorella is Small! (~2-10μm)

and hard to break

○ Limited prior research is speculative

○ Not all lipids can dissolve in just one solvent

~2mm @ 1000x

Approach

Cell Disruption Experiments

Experiment 1:

Absorbance Method

0.079 Blank/Unbroken Cells

0.175 Sonication ~20sec

0.185 Sonication + an extra ~20sec

0.170 Sonication + ½ volume .3-.5mm glass beads ~ 20 sec

0.135 Nitrogen gas press @ 170 psi

0.120 Glass tissue grinder~ 1min

0.150 Glass tissue grinder + ½ volume .3-.5mm glass beads ~ 1min

Approach

Cell Disruption Experiments

Experiment 2

Absorbance Method

0.36 Blank/Unbroken Cells

0.41 Mortar & Pestle (5min)

0.46 Teflon grinder (5min)

0.45 Sonication (40 sec) + Mortar & Pestle (5min)

0.49 Sonication (40 sec) + Teflon grinder (5min)

0.41 Sonication (40 sec)

Approach

Lipid Extraction:

Cell Disruption

1. Homogenize (10 hr)

1. Sonicate (15 min)

1. Teflon Grinder (10 min)

1. Homogenize (5 hr)

Approach

Lipid Extraction:5. Centrifuge

6. Evaporate off solvent

(Chloroform: Methanol)

7. Preserve

○ Freezer (0˚C)

○ Nitrogen atmosphere

○ Butylated hydroxytoluene (BHT)

Approach

Lipid Analysis: HPLC

○ Phospholipids

○ Glycolipids

GC

○ Fatty Acid Methyl Esters (FAMEs)

Gas Chromatography

FAMEs

were

detected

But, did not

separate

well

May be an

old column

Matrix Assisted Laser

Desorption/ Ionization

Mass measurements

are essential to

confirming HPLC and

GC readings.

matrix of 2,5

dihydroxybenzoic acid

C18:3 standard

C19 standard

C16 standard

C19:H1A (30:70; in-situ

transesterfication


Chemicals used: Function:

Chloroform (CHCl3) Solvent

Methanol (CH3OH) Solvent

Butylated hydroxytoluene (C15H24O) Antioxidant

Sedmax’s Solution Protein binding dye

Nitrogen Gas Inert atmosphere

Nile Red Lipid fluorescent dye

Phosphate Buffer 2/10mol (K2HPO4) Ph buffer solution for Sedmax test

2,5-dihydroxybenzoic acid MALDI matrix


Equipment used: For use in:

Spectrophotometer Sedmax test

Spectroflourometer Nile red test

GC + columns Lipid separation + quantification

Teflon Grinder Cell disruption

Sonicator Cell disruption

Nitrogen gas tank & two-stage regulator

Lipid Extraction

Centrifuge (large and small sizes)

Lipid Extraction

Freeze dryer Preparation

MALDI Mass Measurement


Waste byproducts:

Algae biomass

Chloroform (CHCl3)

Methanol (CH3OH)

Sedmax’s solution

Analyzed lipids

Water

Nile Red solution

Phosphate Buffer 2/10mol (K2HPO4)

Acknowlegements

Dr. Ihab H. Farag

Professor of Chemical Engineering

W315 Kingsbury Hall

(603) 862-2313

[email protected]

Dr. Leland S. Jahnke

Professor of Plant Biology

Rudman Hall Rm 183

(603) 862-3857

[email protected]

Nancy L.Whitehouse (Agricultural Experiment Stat)

Dr. Samuel C. Smith

Professor of Emeritus (Active)-Molecular,

Cellular, Biomed SC

Kendall Hall Rm 13

(603) 862-2505

[email protected]

John E. Newell

ENGINEERING TECHNICIAN

Kingsbury Hall

(603) 86 2-1921

[email protected]

mailto:[email protected]




References

Briggs, Widescale Biodiesel Production from Algae [Internet]: University of New Hampshire, Physics Department; c2004 [cited 2009 9/4]. Available from:

http://www.unh.edu/p2/biodiesel/article_alge.html .

Erwin JA, editor. 1973. Lipids and biomembranes of eukaryotic microorganisms. New York: Academic Press.

Ferrentino J. 2007. Microalgal oil extraction and in situ transesterification.

Folch J, Lees M, Sloane-Stanley G. 1957. A simple method for the isolation and purification of total lipids from animal tissue. J. Biol. Chem. (226):497-509.

Gerpen JV, Shanks B, Pruszko R. 2004. Biodiesel production technology .

Guckert JB, Cooksey KE, Jackson LL. 1988. Lipid sovent systems are not equivalent for analysis of lipid classes in the microeukaryotic green alga, chlorella. J

Microbiol Methods 8(3):139-49.

Gurr MI, Harwood JL, Frayn KN. 2002. Lipid biochemistry: An introduction. 5th ed. Oxford, England: Blackwell Science.

Sheehan J, Dunahay T, Benemann J, Roessler P. 1998. A look back at the U.S. department of Energy’s aquatic species Program—bio-diesel from algae. U.S.

Department of Energy’s Office of Fuels Development, National Renewable Energy Laboratory 1617 Cole Boulevard. Golden, Colorado 80401-3393.

Schiller J, Arnhold J, Benard S, Müller M, Reichl S, Arnold K. 1999. Lipid analysis by matrix-assisted laser desorption and ionization mass spectrometry: A

methodological approach. Anal Biochem 267(1):46-56.

http://www.unh.edu/p2/biodiesel/article_alge.html

Questions?

by daniel c. perrinez morse hall 103 faculty contact: ihab h. … · 2015. 9. 18. · 0.079...

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