Molecular imprinting of small, poorly functionalised organic compounds

Kueh, Alona Swee Hua

January 2008

Molecularly imprinted polymers (MIPs) have been compared to natural antibodies in that they can specifically bind target compounds in a similar way that antibodies specifically bind to an antigen. The attraction of the MIPs technology is the ease of creating binding elements which are relatively cheap compared with the process of isolating natural antibodies. In this research monoterpenes, such as α-terpineol, were chosen to be the model compounds for investigating the molecular imprinting of small, poorly functionalised organic compounds. The conventional non-covalent approach was mainly used to synthesise these MIPs, but the sacrificial-spacer semi-covalent approach was also investigated. A less widely used method, porogen-imprinting - a variant of non-covalent imprinting - was adapted for α-terpineol. The latter novel terpene MIP appeared to specifically bind α-terpineol, by hydrogen bonding, so the polymer was characterised in detail. The main parameters which were altered for preparing non-covalent MIPs included the template (α-terpineol, (-)-menthol or trans-terpin); the functional monomer (methacrylic acid, 2-hydroxyethyl methacrylate, bilirubin and phenol [for the semi-covalent MIP]); the cross-linking monomer (ethylene glycol dimethacrylate, divinylbenzene and trimethylolpropane trimethacrylate); and also the polymerisation method (block or precipitation polymerisation). The binding specificity and cross-reactivity for all the polymers were tested using a liquid batch-binding setup. The batch-binding setup required the detection of analyte that was not bound in order to calculate by difference the fraction of analyte bound to the polymer. Initially the terpenes were to be detected by a colorimetric method; however attempts to make the method sensitive and reliable were not successful. In comparison, gas chromatography was more reliable for the detection of terpenes and was used for the experiments presented in this thesis. 1H-NMR studies of the interaction between α-terpineol and acetic acid (as a non-polymerisable analogue of methacrylic acid) were investigated as a basis for understanding the binding to the carboxyl functional group moiety employed in many of the non-covalent MIPs that were made. The interaction between (-)-menthol and phenol was also investigated because the phenol moiety was employed in the semi-covalent MIP. Only selected MIPs, which appeared to specifically bind the template, were physically characterised. This included optimising the batch-binding parameters, scanning electron microscopy imaging, surface area and pore radius analysis and in some cases Fourier transform-infrared spectroscopy of the polymers.

Molecularly imprinted polymers

porogen-imprinting

terpenes

non-covalent imprinting

semi-covalent imprinting

Development of a thermometric sensor for fructosyl valine and fructose using molecularly imprinted polymers as a recognition element

Rajkumar, Rajagopal

January 2007

Nature has always served as a model for mimicking and inspiration to humans in their efforts to improve their life. Researchers have been inspired by nature to produce biomimetic materials with molecular recognition properties by design rather than evolution. Molecular imprinting is one way to prepare such materials. Such smart materials with new functionalities are at the forefront of the development of a relevant number of ongoing and perspective applications ranging from consumer to space industry. Molecularly imprinted polymers were developed by mimicking the natural enzymes or antibodies that serve as host for binding target molecules. These imprints were used as a recognition element to substitute natural biomolecules in biosensors. The concept behind molecular imprinting is to mold a material (with the desired chemical properties) around individual molecules. Upon removal of the molecular templates, one is left with regions in the molded material that fit the shape of the template molecules. Thus, molecular imprinting results in materials that can selectively bind to molecules of interest. Imprinted materials resulted in applications ranging from chemical separation to bioanalytics. In this work attempts were made particularly in the development of molecularly imprinted polymer based thermometric sensors. The main effort was focused towards the development of an covalently imprinted polymer that would be able to selectively bind fructosyl valine (Fru-Val), the N-terminal constituent of hemoglobin A1c ß-chains. Taking into account the known advantages of imprinted polymers, e.g. robustness, thermal and chemical stability, imprinted materials were successfully used as a recognition element in the sensor. One of the serious problems associated with the development of MIP sensors and which lies in the absence of a generic procedure for the transformation of the polymer-template binding event into a detectable signal has been addressed by developing the "thermometric" approach. In general the developed approach gives a new insight on MIP/Analyte interactions. / In dem Bestreben, ihr eigenes Leben zu verbessern, haben die Menschen stets die Natur nachgeahmt und sich von ihr inspirieren lassen. Die Natur hat Forscher zur Erzeugung smarter biomimetischer Stoffe mit molekularen Erkennungseigenschaften nach dem Vorbild der Evolution inspiriert. Eine der Methoden zur Herstellung solcher Substanzen ist das molekulare Prägen. Smarte Materialien mit neuen Eigenschaften stehen an der Spitze der Entwicklung potentieller Anwendungen vom Verbraucher bis hin zur Raumfahrtindustrie. Durch Nachahmung von natürlichen Enzymen oder Antikörpern wurden molekular geprägte Polymere (MIPs) entwickelt, die der Bindung von Zielmolekülen dienen. Diese geprägten Polymere (imprints) wurden anstelle von Biomolekülen als Erkennungselemente in Biosensoren eingesetzt. Das Konzept, das dem molekularen Prägen zugrunde liegt, besteht in der Formung eines Polymers (mit den entsprechenden chemischen Eigenschaften) um einzelne Zielmoleküle herum. Nach Entfernen dieser molekularen Template bleiben Abdrücke im Polymer übrig, die der Form der Templatmoleküle entsprechen. Mit Hilfe des molekularen Prägens kann man also Stoffe herstellen, die sich selektiv an bestimmte Moleküle binden können. Geprägte Polymere finden breite Anwendung, etwa in chemischen Aufreinigungsprozessen und der Bioanalytik. Hauptanliegen der vorliegenden Arbeit war es, thermometrische Sensoren auf der Basis molekular geprägter Polymere zu entwickeln. Die Anstrengungen richteten sich vor allem auf die Entwicklung eines kovalent geprägten Polymers, das in der Lage ist, selektiv Fruktosyl-Valin (Fru-Val), den N-terminalen Bereich von Hämoglobin A1c, zu binden. Aufgrund der bekannten Vorzüge geprägter Polymere – z. B. Robustheit und thermische und chemische Stabilität – wurden geprägte Polymere erfolgreich als Erkennungselement im Sensor angewendet. Eine der größten Herausforderungen bei der Entwicklung von MIP-Sensoren, das Fehlen eines generischen Verfahrens zur Umwandlung der Bindungsreaktion in ein nachweisbares Signal, wurde mit der Entwicklung der thermometrischen Methode in Angriff genommen. Diese Methode führt allgemein zu neuen Einsichten in die Interaktionen zwischen MIP und Analyt.

Covalent imprinting

Fructosyl valine

MIP sensor

Fructose

Glycated hemoglobin

HbA1c

Thermistor

Biosensor

Calorimetry

Chemistry and allied sciences

Molecularly Imprinted Polymers: Towards a Rational Understanding of Biomimetic Materials

Molinelli, Alexandra Lidia

22 November 2004

The research described in this thesis contributes to the development of new strategies facilitating advanced understanding of the fundamental principles governing selective recognition of molecularly imprinted polymers (MIPs) at a molecular level for the rational optimization of biomimetic materials. The nature of non-covalent interactions involved in the templating process of molecularly imprinted polymers based on the self-assembly approach were investigated with a variety of analytical techniques addressing molecular level interactions. For this purpose, the concerted application of IR and 1H-NMR spectroscopy enabled studying the complexation of the template molecules 2,4-dichlorophenoxyacetic acid, quercetin, and o-, m-, and p-nitrophenol with a variety of functional monomers in the pre-polymerization solution by systematically varying the ratio of the involved components. In aqueous and non protic porogenic solvents, information on the interaction types, thermodynamics, and complex stoichiometry was applied toward predicting the optimum imprinting building blocks and ratios. Molecular dynamics simulations of 2,4-dichlorophenoxyacetic acid and its interactions with the functional monomer 4-vinylpyridine in aqueous and aprotic explicit solvent allowed demonstrating the fundamental potential of computer MD simulations for predicting optimized pre-polymerization ratios and the involved interaction types. The obtained results clearly demonstrate that the application of rapid IR/NMR pre-screening methods in combination with molecular modeling strategies is a promising strategy towards optimized imprinting protocols in lieu of the conventionally applied labor intensive and time-consuming trial-and-error approach. Furthermore, HPLC characterization of the produced MIPs compared to control polymers enabled a systematic approach to imprinting based on advanced understanding of the factors governing the formation of high-affinity binding sites during the polymerization. In addition, the importance of the combination of size, shape, and molecular functionalities for the selective recognition properties of MIPs was investigated. MIPs for the mycotoxins deoxynivalenol and zearalenone and for the antioxidant quercetin were applied as separation materials for advanced sample preparation in beverage analysis. The obtained results demonstrated the potential of MIPs for rapid one-step sample clean-up and pre-concentration from beverages such as wine and beer.

Beverage analysis

Solid phase extraction

NMR spectroscopy

IR spectroscopy

Non-covalent imprinting

Molecularly imprinted polymers

Infrared spectroscopy

Nuclear magnetic resonance spectroscopy

Molecular imprinting

Imprinted polymers