Cellulose acetate-based molecularly imprinted polymeric membrane for separation of vanillin and o-vanillin

Zhang, Chunjing; Zhong, Shian; Yang, Zhengpeng

doi:10.1590/S0104-66322008000200014

Abstract

Cellulose acetate-based molecularly imprinted polymeric membranes were prepared using vanillin as template molecule. The microscopic structure of the resultant polymeric membranes was characterized by SEM and FTIR spectroscopy, and the selective binding properties and separation capacity of the membranes for vanillin and o-vanillin were tested with binding experiments and separate experiments, respectively. The results showed that the vanillin-imprinted polymeric membranes displayed higher binding and separation capacity for vanillin in comparison with the non-imprinted polymeric membranes; the maximum binding amount Qmax for vanillin is 387.3 µmol/g and the selectivity factor is 3.82 for vanillin/o-vanillin. In addition, the effect of cross-linker concentration on the binding of vanillin on the imprinted polymeric membranes was also evaluated and the optimal concentration is 320 mM.

Cellulose acetate (CA); Molecularly imprinted polymeric membrane; Vanillin; O-vanillin; Separation

KINETICS AND CATALYSIS; REACTION ENGINEERING; AND MATERIALS SCIENCE

Cellulose acetate-based molecularly imprinted polymeric membrane for separation of vanillin and o-vanillin

Chunjing Zhang; Shian Zhong^* * To whom correspondence should be addressed ; Zhengpeng Yang

College of Chemistry and Chemical Engineering, Phone: 0731-8830416, Fax: 0731-8879616, Central South University, Changsha, 410083, China. E-mail: zhongshian@yahoo.com.cn

ABSTRACT

Cellulose acetate-based molecularly imprinted polymeric membranes were prepared using vanillin as template molecule. The microscopic structure of the resultant polymeric membranes was characterized by SEM and FTIR spectroscopy, and the selective binding properties and separation capacity of the membranes for vanillin and o-vanillin were tested with binding experiments and separate experiments, respectively. The results showed that the vanillin-imprinted polymeric membranes displayed higher binding and separation capacity for vanillin in comparison with the non-imprinted polymeric membranes; the maximum binding amount Q_max for vanillin is 387.3 µmol/g and the selectivity factor is 3.82 for vanillin/o-vanillin. In addition, the effect of cross-linker concentration on the binding of vanillin on the imprinted polymeric membranes was also evaluated and the optimal concentration is 320 mM.

Keywords: Cellulose acetate (CA); Molecularly imprinted polymeric membrane; Vanillin; O-vanillin; Separation.

INTRODUCTION

Over the past years, molecularly imprinting polymers (MIPs) have been investigated widely (Xu et al., 2004), and have shown unique advantages over natural biological receptors in terms of physical and chemical stability and the possibility of using MIPs in harsh environmental conditions (Hilal and Kochkodan, 2003). Usually, MIPs are produced in non-aqueous solutions by bulk polymerization of functional and cross-linker monomers in the presence of template molecules. After removal of the template molecules, the MIP retains receptor sites that are complementary to the template molecule in shape and position of the functional groups. In this way, molecular memory is produced in the polymer, making the MIPs capable of selectively rebinding the template molecule (Vlatakis et al., 1993, Cormack and Mosbach, 1999). Based on imprinting effect of the MIPs, MIPs have been employed in many fields, such as chromatographic separation (Sellergren et al., 1998, Brauner and Shacham, 1999, Fan et al., 2003), recognition of elements in biological sensors (Kroger et al., 1999, Jakusch et al., 1999), solid phase extraction (Mullett and Lai, 1998, Kugimiya and Takeuchi, 1999, Jodlbauer et al., 2002), receptor mimics in biological systems (Zhou et al., 1998) and so on. However, the practical application of MIPs is still under development (Haupt and Mosbach, 2000). Recently, MIP membranes prepared by photoinitiated surface modification of microfiltration membranes in the presence of template molecules have attracted much research interest due to the ability to change their diffusive permeability automatically by responding to the template molecules (Piletsky et al., 2000, Kochkodan et al., 2001). The MIP membranes have shown selective adsorption of target molecules (Takeda and Kobayashi, 2006), and the technique has also been applied to other research fields, which focus on separation of food (Trotta et al., 2002) and medicine (Yoshikawa et al., 2006).

In the present work, the imprinting technique has been extended to prepare selective MIP membranes on the surface of cellulose acetate (CA) membranes using vanillin as template molecules (namely CA-MIP membranes). The microscopic structure of the imprinted membranes was characterized, and the binding properties and permeation selectivity of the membranes for separation of vanillin and o-vanillin were investigated.

EXPERIMENTAL

Materials and Instruments

Cellulose acetate (CA) membranes were purchased from Aldrich Chemical Co. Vanillin and o-vanillin were obtained from Sigma Chemical Co. Methacrylic acid (MAA), 2,2-Azobisisobutyronitrile (AIMN) and ethylene glycol dimethacrylate (EGDMA) were purchased from Aldrich. EGDMA and MAA were distilled to remove the inhibitor prior to use. Acetonitrile and methanol were of chromatographic grade. All other chemicals were of analytical grade and used without further purification.

UV spectrophotometer (DMS 80/90, Varian Techtron, Australia), Protégé 460 FTIR spectrometer (Nicolet Instrumental Corp.), JSM-5310LVB scanning electron microscopy (SEM) (JOEL, Japan) were employed for the spectroscopic measurements.

Preparation of the CA-MIP Membranes

The vanillin-imprinted CA-MIP membranes were prepared according to the following procedure. 7.61 mg (0.05 mmol) of vanillin was dissolved in 5 ml acetonitrile, then 34.40 mg (0.4 mmol) MAA, 0.33 ml (1.7 mmol) EGDMA and 5 mg AIBN were added to the vanillin solution, respectively. The mixture was degassed with an ultrasonic oscillator in an ice-water bath for 10 min. The CA membrane was placed into the above solution and stored in an icebox for 20 min. The CA membrane was then taken from the mixture, placed between two glass plates and compressed in order to remove the air bubbles. A 300 W UV lamp was employed to illuminate the membrane for 6 h at about 4ºC. After the glass plates were separated, the CA-MIP membrane was washed repeatedly with methanol/acetic acid (9:1 v/v) solution until the template molecule vanillin could not be detected by UV-vis spectroscopy and then washed with methanol and kept in methanol at 4ºC.

The CA-NMIP membranes were prepared in the same way, but without the addition of the imprint molecule vanillin and worked up by the same procedure.

The morphology of the surface of the polymer membranes supported on the CA membrane was observed by scanning electron microcopy (SEM). The structural changes of the CA-MIP membrane were evaluated from FT-IR spectra in comparison with the structures of the blank CA membrane and vanillin-imprinted MIP powder.

Binding Experiments

The vanillin-imprinted CA-MIP membranes were immersed in 2.0 mL acetonitrile solution with template molecule vanillin at 25 Cº for 24 h under constant stirring. The concentration of vanillin was measured by UV spectrophotometry. The amount Q (µmol) of vanillin bound to the imprinted membranes can be calculated according to the concentration change of vanillin in solution before and after binding experiments. Q is the average value of three experiments.

Evaluation of Membrane Separation Properties

For separation tests, the polymeric membranes were mounted tightly between the two stirred chambers in an H-shaped two-compartment cell with constant stirring and permeation properties were examined at 25ºC. A 50 mL methanol solution containing 1.00 mM vanillin and 1.00 mM o-vanillin was placed in the feeding chamber, and 50 mL pure methanol in the receiving chamber. At an interval of 2 hours, the amount of each diffused analyte was determined by UV spectrophotometry.

RESULTS AND DISCUSSION

Characteristics of Membranes

When a blank CA membrane was soaked in the prepolymerization solution, some self-assembly complexes were loaded into the pores of the CA membrane. After polymerization and removal of the template molecules, an imprinted polymeric membrane attached to the CA membrane was achieved. It was observed that the modified membrane was smooth and flexible, and no obvious difference in macrography between CA membrane and CA-MIP membrane. However, obvious differences between the membranes were detected by scanning electron microscopy (Fig. 1). As seen in Fig. 1, the CA membrane possessed regular fibrous structure (Fig. 1a), while significant change was observed in its morphology after it interacted with the prepolymerization solution. The fibrous structure of the CA membrane disappeared and polymeric membrane was formed at its surface (Fig.1b), showing that the reaction between CA membrane and prepolymerization solution was really reliable. According to the surfaces and cross-sections of membranes observed by SEM, it was estimated that the thickness of the CA-MIP membrane was 35 µm, which was a little higher than that of the CA-NMIP membrane. This may be attributed to the presence of vanillin in the process of reaction, facilitating the formation of complexes at the surface of CA. In addition, the pore density of the CA-MIP membrane was higher due to the removal of the template molecule, suggesting a high porosity.

In order to confirm the interaction between MIP and CA membrane, IR spectra of (a) MIP powder, (b) CA membrane and (c) CA-MIP membrane were measured (Fig. 2). In the spectrum of the CA membrane, the IR bands at 1740 and 1045 cm^-1 were attributed to the >C=O stretch and -C-O-C- stretch, respectively. In the spectrum of the CA-MIP membrane, it was found that the >C=O and -C-O-C- stretching bands were shifted to shorter wavenumber; the >C=O stretching band changed from 1740 cm^-1to 1735 cm^-1 and the -C-O-C- stretching band changed from 1045 cm^-1 to 1041 cm^-1. In addition, it was also noted that the -OH stretching band at 3448 cm^-1and the -CH₃ stretching band at 2960 cm^-1 for MIP powder disappeared in the CA-MIP membrane. These changes in the IR spectra suggested that there is interaction between MIP and CA membrane.

Study on the Interaction Between Template Molecule (Vanillin) and Functional Monomer (MAA)

Because UV-vis spectrophotometry has been successfully used to investigate the interaction between the template molecule and the functional monomer (Chen et al., 2006), we employed it to study the interaction between vanillin and MAA. Assuming that the concentration of vanillin is a₀, and the concentration of MAA is b₀ and that the analytical concentration of MAA is greater than that of vanillin, the binding reaction can be expressed as:

where V and M represent the reactants vanillin and MAA respectively; W represents the complex formed between them and n is the stoichiometric coefficient of M. At equilibrium, the association constant can be written as

According to mass balances, one has that:

Because b₀>> a₀, then [W] in Eq. (4) can be ignored. Thus,

By substituting Eqs. (3) and (5) into Eq. (2), we obtain:

According to the Lambert-Beer law, the absorbance of the solution is

Defining A_0,V =e_Vla₀, A_0,M =e_Mlb₀, then:

Combination of Eq. (6) and Eq. (8) leads to Eq. (9):

Where A_0,V and A_0,M can be calculated from the spectra of pure acetonitrile solutions of vanillin and MAA, respectively. n is a simple positive integer. For n = 1, 2, 3, the plots of DA/b₀ⁿversus DA are presented in Fig. 3. Because the wavelength employed in UV-vis measurement is the maximal absorption wavelength of vanillin (280 nm), DA (DA = A - A_0,V - A_0,M) is a negative value. As seen in Fig. 3, when n = 1 or 3, the plots of DA/b₀ⁿ versus DA are curved, while for n = 2, the plot of DA/b₀ⁿ versus DA is linear, which indicates that 1:2 complexes between vanillin and MAA are formed. In addition, the association constant (K) can be calculated from the slope of the line and the value is 3.12 × 10⁵ M^-2, which shows that the formed complexes have considerable stability. After cross-linker and initiator were added to the solution, the complexes were imprinted in the polymeric matrix. Fig. 4 shows the schematic illustration of the molecular imprinting process.

Selective Binding Properties of the Membranes

In this group of experiments, vanillin and o-vanillin were employed to evaluate the selectivity of the membranes. Fig. 5 presents the molecular structures of vanillin and o-vanillin. As seen in Fig. 5, vanillin and o-vanillin are isomers. In the equilibrium situation, the distribution coefficient (K_D) of substrate between membrane and solution rather than the amount of binding substrate onto the membrane was used to characterize the selectivity properties of membranes. Herein, K_D is expressed as

where Q_m represents the amount of substrate binding to the membrane (µmol.g^-1), and Q_s the equilibrium concentration of substrate in solution (mM). The values of K_D calculated according to Eq. (10) are shown in Table 1. Compared with the CA-NMIP membrane, the CA-MIP membrane showed high selectivity for substrate. It was noted that K_Dof vanillin on the CA-MIP membrane was 31.26 ml.g^-1, which was almost 3.5 times higher than that on the CA-NMIP membrane and 6.0 times higher than K_Dof o-vanillin on the CA-MIP membrane. Based on the above data analysis, it may be suggested that a comparatively large number of binding sites exist in the CA-MIP membrane, and these binding sites possess the shape of the molecular structure of vanillin. As a result, higher selectivity was exhibited by the CA-MIP membrane and more vanillin was bound to the membrane.

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In order to further understand the binding capacity of vanillin in the CA-MIP membrane, we carried out the binding isotherm and Scatchard analysis for the CA-MIP membrane. Fig. 6 shows the binding isotherm for the CA-MIP membrane; when the concentration of vanillin was varied from 0.1-2.5 mM, the loading amount of vanillin on the CA-MIP membrane increased with the increase of vanillin concentration. It is well known that binding equilibrium constants (K_a) rather than binding amount can give more effective information about the substrate binding to the imprinted polymer membrane. Thus, based on the data presented in Fig. 6, the value of K_afor the CA-MIP membrane was determined according to the Scatchard equation (Sihn and Chung, 2003).

where c_eand Q_maxrepresent the free concentration of vanillin at equilibrium and the binding capacity of vanillin to the CA-MIP membrane, respectively. According to Eq. (11), Q/c_e was plotted on the vertical axis and Q on the horizontal axis. The plot of Q/c_e versus Q was a straight line (Fig. 7), which indicated that the binding sites in the CA-MIP membrane are equivalent and present equal binding capacity for vanillin. K_a and Q_max were determined from the slope and intercept of the line, and the values of K_a and Q_maxwere 2.19 × 10⁴M^-1 and 387.3 µmol/g, respectively.

Effect of Cross-Linker Concentration on Vanillin Adsorption on Membranes

Cross-linker concentration has a direct relationship with vanillin adsorption on membranes. As seen in Fig. 8, compared with the blank CA membrane, the concentration of EGDMA has a significant effect on vanillin binding to CA-MIP and CA-NMIP membranes. An increase of EGDMA concentration up to 320 mM in the reaction mixture lead to an obvious elevation in binding amount of vanillin, while a further increase of EGDMA concentration caused a slight decrease of vanillin binding. It may be suggested that, on the one hand, the imprinted polymer membrane should be rather rigid in order to preserve the structure of the selective cavity after the removal of the template molecule; on the other hand, a certain flexibility of polymer chains should be present to facilitate a fast equilibration with the template molecule in the cavity. Apparently, at increasing levels of vanillin binding, an increase of EGDMA concentration reduces the polymer chain flexibility and thus provides a gain in stabilization of the structure of the selective cavity. This improves the contribution of specific binding to receptor sites and causes an increase of vanillin binding. However, too high of an EGDMA concentration will increase excessively the cross-linker domains, which possess a reduced number of receptor sites. This causes a decrease of vanillin binding for the CA-MIP and CA-NMIP membranes prepared at high EGDMA concentration. Therefore, 320 mM EGDMA was employed to prepare the CA-MIP and CA-NMIP membranes.

Selective Separation Capacity of Membranes

In order to better understand separation capacity of polymer membranes, competitive transport experiments with the CA-MIP and CA-NMIP membranes were performed, where the two substrates vanillin and o-vanillin were employed simultaneously. Fig. 9 presents time-transport curves of the two substrates, vanillin and o-vanillin, through CA-MIP membrane and CA-NMIP membrane. Compared with the CA-MIP membrane, diffusion rates of the substrates through the CA-NMIP membrane were slow. As seen from curves a and c in Fig. 9, the transport rate of vanillin through the CA-MIP membrane was obviously higher than that through the CA-NMIP membrane. The distinctly different transport rates of the CA-MIP and CA-NMIP membranes showed that the molecular imprinting process created channels through which template molecules could pass successfully. In this way, a kind of continuous and fast transport process was accomplished based on selective shape and size and position of functional groups in the channels which could recognize the best suitable template molecule. In contrast, the CA-NMIP membrane did not present any imprinting effect, and the dense and small pores are arranged in a disordered manner that cannot generate channels. In addition, it is also possible that the routeways in the CA-NMIP membrane were jammed, causing vanillin molecules to be transported at a low rate. According to above analysis, it can be suggested that the different diffusional behavior of vanillin in the CA-MIP and CA-NMIP membranes results from the molecular imprinting effects. Imprinting creates channels that are not present in the CA-NMIP membrane. Moreover, the effect was also confirmed in curves a and b of Fig. 10, the vanillin molecules were transported faster through the CA-MIP membrane than o-vanillin, showing that the CA-MIP membrane is permselective to the template molecule vanillin. This can be attributed to the molecular imprinting effect of the template molecule vanillin. Thus, after the removal of the template molecule vanillin from the CA-MIP membrane, the shape and size of the pores that exist in the CA-MIP membrane resemble the structure of the vanillin molecule, making the imprinted membrane selective to vanillin and more vanillin were transported through the CA-MIP membrane. In order to further understand the separation capacity of membranes, selectivity factors (ratios of diffusive flux of vanillin to that of o-vanillin) were employed in this group of experiments. As seen in Table 2, the permselectivity of the CA-MIP membrane for vanillin is higher than that of the CA-NMIP membrane by comparing their selectivity factors. The selectivity factor of the CA-MIP membrane for vanillin/o-vanillin is 3.82, while that of the CA-NMIP membrane is 1.61 after a permeation time of 24 h. This further demonstrates the molecular imprinting effect and shows that the imprinted membranes possess good separation capacity. Therefore, it is suggested that the CA-MIP membranes can be used for the separation and enrichment of vanillin and o-vanillin.

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CONCLUSIONS

Cellulose acetate-based composite microfiltration membranes were prepared successfully using photoinitiated copolymerisation of methacrylic acid (MAA) as functional monomer and ethylene glycol dimethacrylate (EGDMA) as crosslinker in the presence of the template molecule vanillin. The selective binding experiments of substrates indicated that the CA-MIP membranes exhibited high selectivity for vanillin in comparison with o-vanillin, and the maximum binding amount for vanillin was 387.3 µmol/g. By comparing separation capacity of the CA-MIP and CA-NMIP membranes, it was found that the separation capacity of the CA-MIP membranes was significantly higher than that of the CA-NMIP membranes and a selectivity factor up to 3.82 for vanillin/o-vanillin was achieved. Therefore, it is suggested that such porous imprinted membranes can be very useful for separation of vanillin and o-vanillin.

(Received: October 28, 2006 ; Accepted: July 13, 2007)

Brauner, N. and Shacham, M., Considering Error Propagation in Stepwise Polynomial Regression, Ind Eng Chem Res, 38, No. 11,4477 (1999).
Chen, C. B., Chen, Y.J. and Zhou, J., A 9-vinyladenine-based Molecularly Imprinted Polymeric Membrane for the Efficient Recognition of Plant Hormone ¹H-indole-3-acetic Acid, Anal Chim Acta, 569, No. 1, 58 (2006).
Cormack, P. A. G. and Mosbach, K., Molecular Imprinting: Recent Developments and the Road Ahead, Reactive Functional Polymers, 41, No.1-3,115 (1999).
Fan, Z. L., Yang, G. L. and Liu, H.Y., Investigation of Molecularly Imprinted Polymer Rod with Aminoantipyrine as Template by In situ Polymerization Method and Their Separation Characteristics, Chin J Chromatogr, 21, No. 3, 199 (2003).
Haupt, K. and Mosbach, K., Molecularly Imprinted Polymers and Their Use in Biomimetic Sensors, Chem Rev, 100, No. 7, 2495 (2000).
Hilal, N. and Kochkodan, V., Surface Modified Microfiltration Membranes with Molecularly Recognising Properties, J Membr Sci, 213, No. 1, 97 (2003).
Jakusch, M., Janotta, M. and Mizaikoff, B., Molecularly Imprinted Polymers and Infrared Evanescent Wave Spectroscopy, A Chemical Sensors Approach, Anal Chem, 71, No. 20,4786 (1999).
Jodlbauer, J., Maier, N.M. and Lindner, W., Towards Ochratoxin A Selective Molecularly Imprinted Polymers for Solid-phase Extraction, J Chrogatogr A. 945, No. 1, 45 (2002).
Kochkodan, V., Weigel, W. and Ulbricht, M., Thin Layer Molecularly Imprinted Microfiltration Membranes by Photofunctionalization Using a Coated a-Cleavage Photoinitiator, Analyst, 126, No. 6, 803 (2001).
Kroger, S., Turner, A. P. F. and Mosbach, K., Imprinted Polymer-based Sensor System for Herbicides Using Differential-pulse Voltammetry on Screen-printed Electrodes, Anal Chem, 71, No. 17, 3698 (1999).
Kugimiya, A. and Takeuchi, T., Application of Indoleacetic Acid-imprinted Polymer to Solid Phase Extraction, Anal Chim Acta, 395, No. 3, 251 (1999).
Mullett, W. M. and Lai, E. P. C., Determination of Theophylline in Serum by Molecularly Imprinted Solid-phase Extraction with Pulsed Elution, Anal Chem, 70, No. 17, 3636 (1998).
Piletsky, S. A., Matuschewski, H. and Schedler, U., Surface Functionalization of Porous Polypropylene Membranes with Molecularly Imprinted Polymers by Photograft Copolymerization in Water, Macromolecules, 33, No. 8, 3092 (2000).
Sellergren, B., Wieschemeyer, J. and Boos, K. S., Imprinted Polymers for Selective Adsorption of Cholesterol from Gastrointestinal Fluids, Chem Mater, 10, No.12, 4037 (1998).
Sihn, Y. S. and Chung H. S., Interpretations of the TDxFLx^® Calibration Data of the Abused Drugs, Forensic Science International, 131, No. 1, 1 (2003).
Takeda, K. and Kobayashi, T., Hybrid Molecularly Imprinted Membranes for Targeted Bisphenol Derivatives, J Membr Sci, 275, No. 1-2, 61 (2006).
Trotta, F., Drioli, E. and Baggiani, C., The Use of Trace Ions for Advanced Characterisation of Transport Properties of NF Membranes in Electrolyte Solutions: Theoretical Analysis, J Membr Sci, 201, No. 1, 77 (2002).
Vlatakis, G., Andersson, L.I. and Muller, R., Drug Assay Using Antibody Mimics Made by Molecular Imprinting, Nature, 361, No.6413, 645 (1993).
Xu, X. J., Zhu, L. L. and Chen, L.R., Separation and Screening of Compounds of Biological Origin Using Molecularly Imprinted Polymers, J Chromatogr B, 804, No.1,61 (2004).
Yoshikawa, M., Murakoshi, K. and Kogita, T., Chiral Separation Membranes from Modified Polysulfone Having Myrtenal-derived Terpenoid Side Groups, European Polymer Journal, 42, No. 10, 2532 (2006).
Zhou, J., He, X. W. and Yang, W. L, Studies on Character of Adsorption and Recognition of Etharidine Template Polymer, Chem. J Chin Univ., 19, No. 9, 1388 (1998).

*

To whom correspondence should be addressed

Publication Dates

Publication in this collection
03 July 2008
Date of issue
June 2008

History

Accepted
13 July 2007
Received
28 Oct 2006

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Brauner, N. and Shacham, M., Considering Error Propagation in Stepwise Polynomial Regression, Ind Eng Chem Res, 38, No. 11,4477 (1999).

[2] Chen, C. B., Chen, Y.J. and Zhou, J., A 9-vinyladenine-based Molecularly Imprinted Polymeric Membrane for the Efficient Recognition of Plant Hormone ¹H-indole-3-acetic Acid, Anal Chim Acta, 569, No. 1, 58 (2006).

[3] Cormack, P. A. G. and Mosbach, K., Molecular Imprinting: Recent Developments and the Road Ahead, Reactive Functional Polymers, 41, No.1-3,115 (1999).

[4] Fan, Z. L., Yang, G. L. and Liu, H.Y., Investigation of Molecularly Imprinted Polymer Rod with Aminoantipyrine as Template by In situ Polymerization Method and Their Separation Characteristics, Chin J Chromatogr, 21, No. 3, 199 (2003).

[5] Haupt, K. and Mosbach, K., Molecularly Imprinted Polymers and Their Use in Biomimetic Sensors, Chem Rev, 100, No. 7, 2495 (2000).

[6] Hilal, N. and Kochkodan, V., Surface Modified Microfiltration Membranes with Molecularly Recognising Properties, J Membr Sci, 213, No. 1, 97 (2003).

[7] Jakusch, M., Janotta, M. and Mizaikoff, B., Molecularly Imprinted Polymers and Infrared Evanescent Wave Spectroscopy, A Chemical Sensors Approach, Anal Chem, 71, No. 20,4786 (1999).

[8] Jodlbauer, J., Maier, N.M. and Lindner, W., Towards Ochratoxin A Selective Molecularly Imprinted Polymers for Solid-phase Extraction, J Chrogatogr A. 945, No. 1, 45 (2002).

[9] Kochkodan, V., Weigel, W. and Ulbricht, M., Thin Layer Molecularly Imprinted Microfiltration Membranes by Photofunctionalization Using a Coated a-Cleavage Photoinitiator, Analyst, 126, No. 6, 803 (2001).

[10] Kroger, S., Turner, A. P. F. and Mosbach, K., Imprinted Polymer-based Sensor System for Herbicides Using Differential-pulse Voltammetry on Screen-printed Electrodes, Anal Chem, 71, No. 17, 3698 (1999).

[11] Kugimiya, A. and Takeuchi, T., Application of Indoleacetic Acid-imprinted Polymer to Solid Phase Extraction, Anal Chim Acta, 395, No. 3, 251 (1999).

[12] Mullett, W. M. and Lai, E. P. C., Determination of Theophylline in Serum by Molecularly Imprinted Solid-phase Extraction with Pulsed Elution, Anal Chem, 70, No. 17, 3636 (1998).

[13] Piletsky, S. A., Matuschewski, H. and Schedler, U., Surface Functionalization of Porous Polypropylene Membranes with Molecularly Imprinted Polymers by Photograft Copolymerization in Water, Macromolecules, 33, No. 8, 3092 (2000).

[14] Sellergren, B., Wieschemeyer, J. and Boos, K. S., Imprinted Polymers for Selective Adsorption of Cholesterol from Gastrointestinal Fluids, Chem Mater, 10, No.12, 4037 (1998).

[15] Sihn, Y. S. and Chung H. S., Interpretations of the TDxFLx^® Calibration Data of the Abused Drugs, Forensic Science International, 131, No. 1, 1 (2003).

[16] Takeda, K. and Kobayashi, T., Hybrid Molecularly Imprinted Membranes for Targeted Bisphenol Derivatives, J Membr Sci, 275, No. 1-2, 61 (2006).

[17] Trotta, F., Drioli, E. and Baggiani, C., The Use of Trace Ions for Advanced Characterisation of Transport Properties of NF Membranes in Electrolyte Solutions: Theoretical Analysis, J Membr Sci, 201, No. 1, 77 (2002).

[18] Vlatakis, G., Andersson, L.I. and Muller, R., Drug Assay Using Antibody Mimics Made by Molecular Imprinting, Nature, 361, No.6413, 645 (1993).

[19] Xu, X. J., Zhu, L. L. and Chen, L.R., Separation and Screening of Compounds of Biological Origin Using Molecularly Imprinted Polymers, J Chromatogr B, 804, No.1,61 (2004).

[20] Yoshikawa, M., Murakoshi, K. and Kogita, T., Chiral Separation Membranes from Modified Polysulfone Having Myrtenal-derived Terpenoid Side Groups, European Polymer Journal, 42, No. 10, 2532 (2006).

[21] Zhou, J., He, X. W. and Yang, W. L, Studies on Character of Adsorption and Recognition of Etharidine Template Polymer, Chem. J Chin Univ., 19, No. 9, 1388 (1998).

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Cellulose acetate-based molecularly imprinted polymeric membrane for separation of vanillin and o-vanillin

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