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Deposition Methods for the Integration of Molecularly Imprinted Polymers (MIPs) in Sensor Applications

Offering high specificity and selectivity, molecularly imprinted polymers (MIPs) are synthetic polymeric affinity reagents that have become increasingly popular over the last couple of decades. Due to their long‐term chemical and physical stability and low production cost, they have become an increa...

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Published in:	Advanced Sensor Research 2023-07, Vol.2 (7), p.n/a
Main Authors:	Caldara, Manlio, Wissen, Gil, Cleij, Thomas J., Diliën, Hanne, Grinsven, Bart, Eersels, Kasper, Lowdon, Joseph W.
Format:	Article
Language:	English
Subjects:	Bacteria Chemical sensors Deposition Electrodes Heat Imprinted polymers Knowledge bases (artificial intelligence) molecularly imprinted polymers Optical properties Oxidation Physical properties Polymer films Polymerization Polymers Production costs Proteins read‐out Reagents Receptors sensing Sensor arrays Sensors Substrates Temperature Voltammetry
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creator	Caldara, Manlio Wissen, Gil Cleij, Thomas J. Diliën, Hanne Grinsven, Bart Eersels, Kasper Lowdon, Joseph W.
description	Offering high specificity and selectivity, molecularly imprinted polymers (MIPs) are synthetic polymeric affinity reagents that have become increasingly popular over the last couple of decades. Due to their long‐term chemical and physical stability and low production cost, they have become an increasingly popular choice of receptor in the realm of sense. MIPs have therefore been associated with the detection of small molecules, proteins, cells, and pathogens, proving a highly robust and useful tool in the production of next‐gen sensing platforms. This said, the development of these sensors pivots on one simple fact; these receptors have to be deposited onto a substrate for their desired application. The deposition of MIPs during sensor fabrication is therefore of great importance, with the field utilizing an array of mechanical and chemical deposition methods to achieve this. To this end, this review, therefore, sets aim at coalescing these different deposition approaches, classifying them, and outlining their utility when it comes to receptor design and integration. Thus, offering a knowledge base on current deposition methods, potential future approaches and analyzing where the MIP deposition field is tending toward. With the increasing popularity of Molecularly Imprinted Polymers (MIPs), their association with sensory platforms is on the rise. Due to their highly versatile and tunable nature, the scenarios where MIPs can be deployed are vast but leaves a question, how can they be integrated? The recent progress in deposition methods for the integration of MIPs into the sensory platform is reviewed.
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Thus, offering a knowledge base on current deposition methods, potential future approaches and analyzing where the MIP deposition field is tending toward. With the increasing popularity of Molecularly Imprinted Polymers (MIPs), their association with sensory platforms is on the rise. Due to their highly versatile and tunable nature, the scenarios where MIPs can be deployed are vast but leaves a question, how can they be integrated? 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subjects	Bacteria Chemical sensors Deposition Electrodes Heat Imprinted polymers Knowledge bases (artificial intelligence) molecularly imprinted polymers Optical properties Oxidation Physical properties Polymer films Polymerization Polymers Production costs Proteins read‐out Reagents Receptors sensing Sensor arrays Sensors Substrates Temperature Voltammetry
title	Deposition Methods for the Integration of Molecularly Imprinted Polymers (MIPs) in Sensor Applications
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