Post on 11-May-2015
Analysis of racemic acid derivitives by chiral high performance liquid chromatography
Tara Kuknyo Orech,
Knox College
Overview
Chiral HPLC Amino and Phosphonic
Acids α Hydroxy-
phosphonates Results and Future
Research
What is HPLC?
High Performance Liquid Chromatography
P can also stand for “Pressure”
Fast! Large number of
plates Detected by UV-Vis
Nelson, David L., Albert L. Lehninger, and Michael M. Cox. "3.3 Working with Proteins."Lehninger Principles of Biochemistry. New York: W.H. Freeman, 2008. Print.
http://www.cnwtech.eu/HPLC-CNW.png
http://www.onu.edu/files/images/chemistry/HPLC.jpg
Chirality Chiral molecules differ in “handedness”,
or 3-D orientation Common in organic chemistry and biology Very difficult to separate because they have
identical physical properties, except for light rotation
http://www.answersingenesis.org/images/chirality-rgb.jpg
Chiral Chromatography Chromatography…with chirality? Affinity Chromatography Separated by three chiral binding site or
chiral pocket stationary phases
"Online Guide to Chiral HPLC." Mark Earll's Homepage. Web. 20 Aug. 2009. <http://www.raell.demon.co.uk/chem/CHIbook/chiral.htm>.
Column Used Nucleosil Chiral-3, 4mm diameter,
pores 100Å, made for organic solvents Family of columns that uses Nucleosil silica Charge-transfer interactions, hydrogen
bonds, dipole-dipole intereactions and steric effects
NO2
O2N
O
HN
O
X SPACER (SiO2)n
Chiral Selector: N(3,5-dinitrobenzoyl)-L-phenylglycineNucleosil Silica
"NUCLEOSIL CHIRAL." MACHEREY-NAGEL Homepage. 2011. Web. 13 Apr. 2011. <http://www.mn-net.com/tabid/6150/default.aspx>.
Disadvantages to Chiral HPLC Expensive ($1,000-$10,000) Affinity chromatography=specific column for
different molecules Interactions between stationary phase and
chiral molecule are fairly weak, making it difficult to separate
"Online Guide to Chiral HPLC." Mark Earll's Homepage. Web. 20 Aug. 2009. <http://www.raell.demon.co.uk/chem/CHIbook/chiral.htm>.
Why Chiral Chromatography? Analyzes enantiomeric purity Optical Rotation does not work for new
compounds Less sensitive to impurities than opt. rot. Allows separation of enantiomers
NH2
OH
O
*
α β
NH2 P
OH
O
*
OH
OHNH2
O
*
* P
OHNH2
O
OH
What is a β-amino phosphonic acid?
Abrams, Martha Leigh. “Progress towards the synthesis of phosphorus analogs of β-amino acids.” Knox College Honors Thesis, May 2008.
β-Amino Phosphonic Acids
Tyrosine and phenylalanine derivatives R and S-Valine first, translate techniques
S-Phenylalanine S-Tyrosine S-Valine
FMOC-Derivative
Eluent100:18:1 heptane, dioxane and trifluoroacetic acid, very non polar
Can detect all amino acids with FMOC at similar wavelengths (~280 nm)
NH2
H
OH
O
+
O
Cl
O
Acetone:AcetonitrileWaterBuffer
O
HN
O
HO
O
FMOC-ClS-Valine
Kortenaar, Paul B.W. et al.""Rapid and Efficient Method for the Preparation of F-moc-amino Acids Starting from 9-fluorenylmethanol."" International Journal of Peptide and Protein Research 26.4 (1996): 398-400. Web. 12 Jan. 2009
Method
S and R Valine-FMOC separately
Optimize the Peak Run a racemic mixture
First Factor: Wavelength
Optimized Factors
Wavelength: 280 nm Flow Rate: 1 mL/min Output Range: 1.0 Amplifier Setting: 0-1V Sample Concentration: 12 mmol Sample Size: 20μL Solvent: Acetone:Acetonitrile, Buffer Eluent: 100:18:1 heptane, dioxane and
trifluoroacetic acid
Initial Readings
Problem: both at 8 minutes! S-Valine R-Valine
Mixed Example
Separation of the Peaks
Dilute from 12 mmol to 1 mmol
Slow flow rate to .5 mL/min
Alter eluent polarity All methods diluted
peaks, even if put them further downfield
FMOC-Cl? 8 mins!
L-Valine with x5 TFA
Extractions of FMOC-Cl
Before extractions One extraction Two extractions
Re-Optimized! Changes: wavelength at 265 nm, sample size
5 µL S-Valine at ~16 mins R-Valine at ~13 mins
S-valine
Future Research
Tyrosine and Phenylalanine β-amino phosphonic acid derivatives α-hydroxy phosphonates (racemic)
Project 2: Racemic Dimethyl 1-hydroxybenzylphosphonate
H
O
1. NaOMe
2. H+ (quench)
P
O
OMeOMe
P
O
OMeOMe
H
OH
HO
H
+P(OMe)2
O
H
Pogatchnik, D. M., Weimer, David F. “Enantioselective Synthesis of α-Hydroxy Phosphonates via Oxidation with (Camphor Sulfonyl). University of Iowa Department of Chemistry . 1997.
Optimal Settings
Flow Rate 1.0 mL/min
Wavelength 285 nm
Output Range 1.0
Amplifier Setting 0-200mV
Sample Concentration 4 mmol
Sample Size 5 μL
Solvent Heptane Dioxane TFA 100:20:.1
Eluent Heptane Dioxane TFA 100:20:.1
Separation of enantiomers
Results
Total Average 69.14 : 30.86 +/- 1.39
Average of Batch 1 68.5 : 31.5 +/- 1.42
Average of Batch 2 69.95 : 30.05 +/- .94
Future Research Optimize further to obtain 50:50 results Nucleosil Chiral-2 Polarimeter to determine on S vs R Complex products from HPLC to form diasteromers, determine S
vs R by NMR Another factor…temperature?
NO2
O2N
O
HN
O
X SPACER (SiO2)n
NO2
O2N
O
HN
O
X SPACER (SiO2)n
N(3,5-dinitrobenzoyl)-L-phenylglycine
N(3,5-dinitrobenzoyl)-D-phenylglycine
Thank You!
Howard Hughes Medical Internship
Knox College Dr. Larry Welch Dr. Diana Cermak American Chemical
Society Illinois State
Academe of Science