The adsorption of certain chiral amino acids from aqueous solution onto β-cyclodextrin silica particles (CDS) had been investigated with the aim of in-depth understanding of the host-guest interaction. The adsorption intensity was found to be strongly dependent on the aqueous phase pH and this dependence could be interpreted from a model for neutral species adsorption in all cases. Adsorption equilibrium data fitted well to the Freundlich isotherm. The adsorption efficiencies of L-amino acids were found to be higher compared to the corresponding D-isomers. Hydrogen bonding and hydrophocities of amino acids were responsible for the differences in adsorption, by influencing the strength of interactions between the amino acid and CDS. The adsorption rate curves for all the molecules appeared to be typical of the pseudo second-order kinetics. Infrared spectral analysis has been performed to characterize adsorptive interaction. The porous structure of CDS as revealed by scanning electron micrograph thus shown to be promising materials for enantioselective separation of amino acids. In addition, molecular modeling studies performed on such molecules were found to correlate very well to the experimental results obtained.
Chiral amino acids are one of the most important biomolecules because of their relevance in nature and their chemical richness. It is well known that in nature amino acids occur in L-forms and they play an important role in the food and pharmaceutical industries. It may be important to be able to detect the presence of D-amino acids in biological systems [
β-Cyclodextrin (β-CD) is a cyclic oligosaccharide with seven glucose units, with its cavity structure, and can form an inclusion complex with certain molecules through a host-guest interaction. The conical shape of β-CD molecule results in well-defined hydrophobic cavity with top and bottom diameters of 6.5 and 6.0 Å that can accommodate the inclusion of various organic molecules with suitable geometry and function [
In this paper, we report both experimental and theoretical results on adsorption behaviour of certain chiral amino acids on β-CD bonded to silica gel with emphasis on understanding the host-guest interaction and such a study will be useful for better understanding of the chiral recognition mechanism of amino acids by β-CD bonded silica gel as a selective sorbent. Also we have character-
ized the amino acid-β-CD complex by UV-Visible (UVVis) spectroscopy.
The amino acids used in this study namely D-phenylalanine, L-phenylalanine, D-tryptophan, L-tryptophan, Dtyrosine and L-tyrosine (guests) were obtained from Sigma-Aldrich Chemicals Pvt. Ltd., USA. β-CD was obtained from Hi Media Laboratories Pvt. Ltd., Mumbai, India. The silica gel of 60 - 120 mesh size was obtained from SRL Pvt. Ltd., Mumbai, India. We have chosen this particular silica gel because of its highly porous structure and appropriate physical and chemical properties to achieve both adequate loading capacity and high-binding capacities. Moreover, it is an efficient adsorbent for separation of organic compounds by chromatographic methods. 3-Glycidoxypropyltrimethoxysilane was also obtained from Sigma-Aldrich Chemicals Pvt. Ltd., USA. The other reagents used as buffer (sodium phosphate, sodium acetate, sodium carbonate and sodium chloride) were supplied by Qualigens, India (Mumbai) and were of analytical grade.
CDs are highly soluble in water and so must be to some solid form before implementing them to adsorption technology. CD containing polymers are useful materials for selective adsorption or separation of organic compounds. For that reason, we have synthesized a polymer (i.e. CDS) as reported in our earlier work [23,25] in which β-CD is bonded to silica particles. Briefly, 1.145 gm of β-CD was dissolved in 25 ml of dry dimethyl formamide (DMF), to which 0.1 gm of metal sodium was added. The reaction was allowed to occur with stirring at room temperature for about 30 min. After filtration, 0.45 ml of 3-glycidoxypropyltrimethoxysilane was added to the filtrate, which was allowed to react at 90˚C for 5 h. Then, 5.0 gm of silica gel was added, and the mixture was allowed to react for 10 h at 80˚C - 100˚C. The CDS was filtered, and washed with DMF, methanol, doubly distilled water and acetone in sequence. Subsequently, the CDS was dried at 120˚C for 3 h, and kept in a desiccator before use.
Equilibrium isotherms were obtained by contacting 25 ml of aqueous amino acid solution with different amounts of CDS in a thermostated shaker bath controlled at 25˚C ± 0.5˚C. The pH of the solution was varied between 3 and 9 using appropriate dose of buffer. The initial concentration of amino acid in the aqueous solution was varied between 5 and 10 mM. The equilibration time was 8 - 10 h. After equilibrium was achieved, the mixture was allowed to settle and the supernatant liquor was filtered to remove any particulate matter. The clear solution thus obtained was analyzed by means of a UV-Vis spectrophotometer (Lambda 25 UV/Vis, Perkin Elmer) calibrated at the wavelength of maximum absorbance (λmax) of the specific amino acid enantiomer. For quantitative spectrophotometric analysis, standard calibration curves of different amino acid enantiomers were prepared at their λmax values such as 289 nm for Dand L-phenylalanine; 288 nm for Dand L-tryptophan and 285 nm for Dand L-tyrosine. For the purpose of estimation 0.2 ml of the supernatant liquor was drawn with glass syringe and diluted with the buffer used for preparing the amino acids solution. Absorbance was measured in the spectrophotometer and the concentration was determined from calibration curve. The amount of amino acid per gram of CDS “q” (mmol∙g−1) was calculated as q = V∆C/W where, ∆C is the change in solute concentration (mmol∙l−1), V is the solution volume (l) and W is the weight of adsorbent (g).
Experiments on adsorption rate were conducted in a stirred constant volume vessel similar to that used in our previous work [
The UV-Vis spectra were recorded with a Varian Cary 50 Bio (Sweden) UV-Vis spectrophotometer using quartz cells, between 200 and 400 nm. In the experiments of guests with β-CD (host), the concentration of the host was varied from 1 × 10−3 M to 12 × 10−3 M while the concentration of the guest was kept constant at 2 × 10−3 M. The mixtures were stirred at 25˚C at a speed of 280 rpm for 4 h and the supernatant was analysed by UV-Vis spectrophotometer.
FT-IR spectra were obtained by the KBr method using PerkinElmer, model Spectrum One. Morphological features of samples were obtained with a LEO 1430 VP Scanning Electron Microscope.
The inclusion process involving the guests and host (β-CD) was investigated by using the Parametric Model 3 (PM3) quantum-mechanical semiempirical method. All theoretical calculations were performed using GAUSSIAN 09 software package [
where Ecomplex, Eguest and Ehost represent HF energies (heats of formation) of the complex, the free amino acid and the host, respectively.
The amino acids studied have molecular structures and pKa valiues shown in
sorption affinity. The pH dependence could be interpreted by considering the adsorption affinity, expressed as the slope of the linear region of the isotherm (q/Ce).
the isotherms, as shown in
model for neutral species adsorption and can well represent the pH variation.
The pH dependence of the affinity is more important, in that neutral form of the amino acids could be considered to have a high adsorption affinity. The reduction in adsorption capacity of various amino acids with increase of pH had been interpreted from a model incorporating hydronium ion concentration and dissociation constant [
hydrophobic and the hydrophobic interaction of the undissociated amino acids would be greater than the corresponding ionic form that exist at high pH. Thus, the observation of high q/Ce at low pH implied the probable role of hydrophobic interaction.
Estimated on the basis of the proposed hydrophobicity scale [
Freundlich isotherm (Equation (3)) was used to describe equilibrium adsorption data, because different energy adsorption sites are expected in the polymeric network [
where Kf is the Freundlich constant, Lg−1; and 1/n is the Freundlich constant characteristic of adsorption intensity. The fitting parameters for the Freundlich isotherm by non-linear regression analysis are shown in
Adsorption rate curve for amino acids on CDS were generated at a stirring speed of 800 rpm as shown in
UV-Vis spectrophotometric studies on the interactions of guests with host enabled the determination of stability constants of inclusion complexes when their formation gave rise to appreciable spectral changes. Upon addition of host, to the guests absorptivity increased in each case and the increase was significant with higher added concentration. The wavelength corresponding to maximum of absorbance (λmax) of free amino acids and their corresponding changes upon complexation with β-CD are listed in the
The shifts towards lower wavelength in the spectra of the complexes may be attributable to the formation of hydrogen bonds. Because hydrogen bonding lowers the energy of “n” orbitals, a hypsochromic shift (blue shift) was observed. L-phenylalanine-β-CD complex showed blue shift whereas no prominent changes were observed in case of D-phenylalanine. The blue shift was found to be significant in case of L-tryptophan-β-CD complex whereas D-tryptophan did not show any such changes. The L-tyrosine-β-CD complex showed blue shift but red shift have been noticed in case of D-tyrosine-β-CD complex. Thus, β-CD was found to be suitable as complexing agent for all the three chiral aromatic amino acids but formed greater number of hydrogen bonds with L-amino acids compared to D-amino acids, which will be more clear from molecular modelling studies performed on such complexes. The lack of selectivity towards phenylalanine may be due to lower number of hydrogen bonding sites in this molecule compared to the other two amino acids. Though UV-spectrometry is not conclusive to determine selectivity but from the changes we can infer that β-CD and its derivatives may be hopeful for chiral enantiomeric separation of molecules like tryptophan and tyrosine (see
The determination of formation constants (K) of the host to the guests were realized by UV-Vis spectroscopy titration experiments. The K values were calculated by applying least-squares fit to the plots of ([host][guest])/ΔA versus ([host] + [guest]), according to the modified Benesi-Hildebrand Equation (4) [35,36]:
where, [guest] and [host] are the equilibrium concentrations of guest and hosts, respectively. Δϵ is the difference between the extinction coefficients of free and complexed guest. ΔA is the difference between the absorbances of free and complexed guest at the same wavelength.
*Blue shift; **Red shift.
versus ([host] + [guest]). The initial concentration of amino acids were kept at 2.0 × 10−3 M, while the concentrations of the host were in the range from 1 to 12 × 10−3 M. A linear least-square fitted to the plots. The K values of inclusion complexes of host with guests were determined from the slopes and intercepts of the linear plots based on the Equation (4). The calculated K values of the inclusion complexes are summarized in
For the amino acids studied, the changes in K values reflected the same order as adsorption affinity, which suggests that the equilibrium of adsorption is a strong function of the strength of the solute-sorbent binding interaction. It is now apparent that the observed differences in adsorption affinity for various amino acids on CDS cannot be merely explained on the basis of hydrophobicity.
FTIR analysis permits spectrophotometric observation of the adsorbent surface in the range 450 - 4000 cm−1, and serves as a direct means for identification of the functional groups on the surface. An examination of the adsorbent surface after adsorption reaction possibly provides information regarding the surface groups that might have participated in the adsorption reaction and also indicates the surface sites on which adsorption has taken place.
The FTIR spectra of polymer showed a characteristic absorption band at 3481 cm−1 due to O-H stretching vibration. The absorption peak at 1645 cm−1 possibly due to the presence of hydroxyl groups that were part of an aromatic system; vibration bands of O-H were also visible at 1088 cm−1. Upon adsorption of amino acids on CDS the characteristics absorption peaks have been shifted from their position indicating interactions of the
amino acid molecules with silica-bonded surface of β-CD molecules. The adsorption complexes showed a lowering of frequency of the O-H stretching vibration thereby confirming complexation through hydrogen bonding and the lowering have been found more in case of complexes of L-amino acid molecules compared to that of D-amino acid molecules which may be due to stronger hydrogen bonding of L-series of molecules. In case of D-tyrosine, complexation caused a slight increase in O-H stretching frequency which is possibly due to cleavage of hydrogen bonding during complexation. Additionally, disappearance of N-H peak in any of the complexes clearly demonstrated complexation (see Figures S2 and S3 in the Appendix).
The scanning electron micrographs for the CDS, Ltryptophan and L-phenylalanine adsorbed on CDS are presented in
Intensive theoretical works have been performed over the past few years on CDs owing to their conformational flexibility and large size. Parametric Model 3 (PM3) has been chosen to study host-guest complexes between β-CD and three important chiral amino acid molecules: phenylalanine, tryptophan and tyrosine. Due to the molecular size, PM3 is a powerful technique which can be currently applied and performs better than Austin model 1 (AM1) in biochemical systems due to its improved description of the interactions between non bonded atoms, e.g. hydrogen bond and steric effects [
L-phenylalanine, D-phenylalanine, L-tyrosine, D-tyrosine and L-tryptophan all were found to enter through the narrower rim of the CD cavity whereas D-tryptophan entered to the cavity through the wider rim during complexation and stronger hydrogen bonding interactions had been found in case of tyrosine-β-CD, and tryptophan-β-CD complex compared to phenylalanine-β-CD complex. L-amino acids were found to penetrate more to
the cavity of the CD molecule compared to its D-enantiomer thereby enhancing the interaction sites to come in a suitable position for interaction. Hydrogen bonding and hydrophobic interactions were found to play a significant role in stabilising all these supramolecular assemblies and the hydrophobic interactions were found to be more prominent in case of complexes of tryptophan and phenylalanine molecules thereby giving most stable interaction with tryptophan molecules. On the basis of quantum-mechanical semi-empirical PM3 studies it was observed that β-CD showed complexation with all the three chiral amino acids studied and the stabilization of the complexes as obtained by calculating stabilization energy values (
The results of the investigation revealed some important insights for the adsorption mechanism of certain amino acid enantiomers on β-CD bonded to silica particles. The adsorption equilibrium may well characterized by the Freundlich isotherm. The rates of adsorption appeared to follow pseudo second order model under the experimental conditions used in the study. The adsorption intensity was strongly dependent on the aqueous phase pH and this dependence was typical of the behaviour predicted by a neutral species for all the amino acids on CDS. Adsorption of amino acids on CDS increased in the following order: tyrosine < phenylalanine < tryptophan. Hydrophobicity as well as hydrogen bonding interactions were mainly responsible for such differences in adsorption. Spectroscopic and theoretical studies supported such interactions and indicated that β-CD can bind the amino acids to form supramolecular complexes. Separation of chiral amino acids using CDS depended on the formation of an inclusion complex which was due to the hydrophobic effect, hydrogen bonding interactions between the molecule and secondary hydroxyl groups of the β-CD. This work further suggests that the host-guest interaction which can be postulated from the chemistry of binding mechanism may be used to adsorb amino acid enantiomers selectively onto CDS.
The authors gratefully acknowledge the award of a research Project under FAST TRACK SCHEME from Department of Science and Technology, New Delhi.
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