Design of Biomimetic Catalysts by Molecular Imprinting in Synthetic Polymers: The Role of Transition State Stabilization

Wulff, Günter; Liu, Junqiu

doi:10.1021/ar200146m

Cited by 289 publications

(227 citation statements)

References 48 publications

(78 reference statements)

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“…In this way, NICE complements an ongoing revolution in bioinspired chemistry and materials science [2 ,3 ,4-6], which already sees applications in, for example, enzymemimics and antibody-mimics for catalysis [7][8][9][10] and in artificial photosynthesis [11 ,12 ,13-15]. These applications implement essential mechanistic steps of the biological model system at molecular and supramolecular scales.…”

Section: Introductionmentioning

confidence: 99%

“…These mechanisms include: (1) use of optimized, hierarchical networks to bridge scales, minimize transport limitations, and realize efficient, scalable solutions; (2) careful balancing of forces at one or more scales to achieve superior performance, for example, in terms of yield and selectivity; (3) emergence of complex functions from simple components, using dynamics as an organizing mechanism. Figure 1 presents an overview.In this way, NICE complements an ongoing revolution in bioinspired chemistry and materials science [2 ,3 ,4-6], which already sees applications in, for example, enzymemimics and antibody-mimics for catalysis [7][8][9][10] and in artificial photosynthesis [11 ,12 ,13-15]. These applications implement essential mechanistic steps of the biological model system at molecular and supramolecular scales.…”

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confidence: 99%

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A nature-inspired approach to reactor and catalysis engineering

Coppens

2012

Current Opinion in Chemical Engineering

111

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Available online at www.sciencedirect.com A nature-inspired approach to Q1 reactor and catalysis engineering Marc-Olivier Coppens Q2Mechanisms used by biology to solve fundamental problems, such as those related to scalability, efficiency and robustness could guide the design of innovative solutions to similar challenges in chemical engineering. Complementing progress in bioinspired chemistry and materials science, we identify three methodologies as the backbone of nature-inspired reactor and catalysis engineering. First, biology often uses hierarchical networks to bridge scales and facilitate transport, leading to broadly scalable solutions that are robust, highly efficient, or both. Second, nano-confinement with carefully balanced forces at multiple scales creates structured environments with superior catalytic performance. Finally, nature employs dynamics to form synergistic and adaptable organizations from simple components. While common in nature, such mechanisms are only sporadically applied technologically in a purposeful manner. Nature-inspired chemical engineering shows great potential to innovate reactor and catalysis engineering, when using a fundamentally rooted approach, adapted to the specific context of chemical engineering processes, rather than mimicry. Introduction Nature-inspired engineering researches the fundamental mechanism underlying a desired property or function in nature, most often in biology, and applies this mechanism in a technological context. In the context of chemical engineering, we call this approach: nature-inspired chemical engineering (NICE) [1].Application of biological mechanisms to a non-physiological context in reaction engineering requires adaptations, because the relevant time scales and available building blocks are different. Also, we are able to manipulate parameters such as temperature and pressure, which are much less tunable in biology. Hence, like in an abstract portrait, essential aspects of the subject are preserved, but not literally, emphasizing those features that serve a desired purpose. Such features underpin the rational design of an artificial structure that uses the same fundamental mechanism as the natural system. The ultimate implementation is assisted by theory and experimentation. NICE aims to innovate, guided by nature, but it does not mimic nature, and should be applied in the right context.Emphasizing reactor and catalysis engineering, we illustrate how mechanisms used in biology to satisfy complicated requirements, essential to life, are adapted to guide innovative solutions to similar challenges in chemical engineering. These mechanisms include: (1) use of optimized, hierarchical networks to bridge scales, minimize transport limitations, and realize efficient, scalable solutions; (2) careful balancing of forces at one or more scales to achieve superior performance, for example, in terms of yield and selectivity; (3) emergence of complex functions from simple components, using dynamics as an organizing mechanism. Figure 1 presents an overview....

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Section: Introductionmentioning

confidence: 99%

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confidence: 99%

A nature-inspired approach to reactor and catalysis engineering

Coppens

2012

Current Opinion in Chemical Engineering

111

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“…Since the idea of molecular imprinting was first put forward by Pauling in 1940s [43], over the past decades, it is well known that molecular imprinting is a very promising and rapidly evolving technology, with many possible applications such as preparative analytical separations [44][45], enzyme-like catalysis [46][47], solidphase extractions [48][49], chemical sensors [50][51] and drug delivery [52][53], etc. Molecular imprinting has proven to be particularly successful for small molecules.…”

Section: Photonic Crystalsmentioning

confidence: 99%

Molecular imprinted photonic crystal for sensing of biomolecules

Chen¹,

Meng²,

Xue³

et al. 2016

Molecular Imprinting

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Molecularly imprinted polymers (MIPs) are highly cross-linked polymers with high binding capacity and selectivity to the target molecules. MIPs become increasingly important because of the potential applications in drug delivery, purification and separation. In spite of the tremendous progress that has been made in the molecular imprinting field, many challenges remain to be addressed, especially in transforming the binding event into a detectable optical signal. The combination of photonic crystal and molecular imprinting technique is becoming a popular research idea. Compared to the conventional MIPs, the molecularly imprinted photonic crystal sensors (MIPCB) have the advantage of directly convert the molecule recognition process into optical signal. This review comprehensively summarizes various MIPCB, including the principle of molecular imprinted photonic crystal sensors, recent development, some challenges and effective strategies for MIPCB.

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“…As monomers conform to the shape of the template, they are fixed by a rapid polymerization of the network, thus forming MIPs. Subsequent removal of the template leaves active sites in MIPs, capable of specifically recognizing the original template [9][10][11]. MIPs have the advantage of being stable at any temperature, can be stored dry for several years, and can be rapidly manufactured at any scale [12].…”

Section: Introductionmentioning

confidence: 99%

Molecular Imprinted Silica with West Nile Antibody Templates show Specific and Selective Binding in Immunoassays

Rincon

Santillan

Infante

et al. 2017

J Biotechnol Biomater

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A new molecular imprinting technique was developed for molecularly imprinted polymer particles (MIPs). Particles were synthesized using organic silane chemistries by a sol-gel process, where the relative amount of active monomers was complementary matched to the relative amount of surface charges of the West Nile antibody template. Synthesized MIPs showed specific binding to affinity purified polyclonal West Nile antibodies (WNA) with a loading capacity of 80 µg/mg, while MIPs absorbed non-specific proteins at a loading capacity of 28 µg/mg. A dissociation constant of Kd=57.45 μM was measured from the binding isotherms. MIPs selectively absorbed 27 times more WNA than either albumin or immunoglobulin, while MIPs absorbed 16 times more WNA than nonimprinted particles (NIPs). Finally, fluorescently labeled MIPs were incubated in a high bind 96 well plate previously loaded with template, albumin, or immunoglobulin as an immunoassay test. Fluorescent MIPs significantly bound more to wells with WNA than any other control. Thus, the development of new affordable and robust immunoassays with MIPs would be possible in the future.

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Design of Biomimetic Catalysts by Molecular Imprinting in Synthetic Polymers: The Role of Transition State Stabilization

Cited by 289 publications

References 48 publications

A nature-inspired approach to reactor and catalysis engineering

A nature-inspired approach to reactor and catalysis engineering

Molecular imprinted photonic crystal for sensing of biomolecules

Molecular Imprinted Silica with West Nile Antibody Templates show Specific and Selective Binding in Immunoassays

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