Molecular Imprinting with Functional DNA

Zhang, Zijie; Liu, Juewen

doi:10.1002/smll.201805246

Cited by 61 publications

(31 citation statements)

References 129 publications

(83 reference statements)

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“…Using molecularly imprinted polymers has been shown to solve the selectivity problem of nanozymes [ 24 ] , although imprinting AR or luminol has yet to be demonstrated. [ 115,116 ]…”

Section: Discussionmentioning

confidence: 99%

Nanozyme‐based luminescence detection

Zhang

Liu

2020

Luminescence

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Nanozymes refer to nanomaterial‐based enzyme mimics. Most nanozyme assays use chromogenic molecules as substrates that can produce an absorbance change in the visible region upon reaction. For certain applications, such as imaging, fluorescence and luminescence signals are required. Fluorescence detection is also advantageous for sensor development due to its low background signal and high sensitivity. A few substrates, such as Amplex Red and luminol, allow luminescence generation with many oxidative nanozymes. In addition, these substrates can work at neutral pH, useful for intracellular applications. In this review, we summarize luminescence signalling‐based nanozyme systems. We begin with the properties of commonly used substrates. A few specific nanozymes are highlighted, including metal nanoparticles, metal oxide nanomaterials, carbon‐based nanomaterials, and metal–organic frameworks. Finally, a few future research opportunities are discussed.

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“…Using molecularly imprinted polymers has been shown to solve the selectivity problem of nanozymes [ 24 ] , although imprinting AR or luminol has yet to be demonstrated. [ 115,116 ]…”

Section: Discussionmentioning

confidence: 99%

Nanozyme‐based luminescence detection

Zhang

Liu

2020

Luminescence

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“…Mainly developed during the 1970s, MIPs are synthetic receptors able to bind to a template molecule with high selectivity. MIPs offer an attractive solution to replicate biological interactions in synthetic materials, since templates such as DNA [2,3], proteins [4], viruses [5], bacteria [6], or cells [7] can be used. When comparing MIPs with natural antibodies, their key advantage is that the binding sites present high specificity for the template but are also stable and capable of withstanding harsher environmental conditions (e.g., temperature, pH) when compared to natural receptors, thanks to the polymeric component [4,8].…”

Section: Introductionmentioning

confidence: 99%

Molecular Imprinting Strategies for Tissue Engineering Applications: A Review

2021

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Tissue Engineering (TE) represents a promising solution to fabricate engineered constructs able to restore tissue damage after implantation. In the classic TE approach, biomaterials are used alongside growth factors to create a scaffolding structure that supports cells during the construct maturation. A current challenge in TE is the creation of engineered constructs able to mimic the complex microenvironment found in the natural tissue, so as to promote and guide cell migration, proliferation, and differentiation. In this context, the introduction inside the scaffold of molecularly imprinted polymers (MIPs)—synthetic receptors able to reversibly bind to biomolecules—holds great promise to enhance the scaffold-cell interaction. In this review, we analyze the main strategies that have been used for MIP design and fabrication with a particular focus on biomedical research. Furthermore, to highlight the potential of MIPs for scaffold-based TE, we present recent examples on how MIPs have been used in TE to introduce biophysical cues as well as for drug delivery and sequestering.

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“…As a result, they self‐fold in water via secondary structure formation to form inherent tertiary structure containing precision nanocavities, in which functional groups are spatially placed at specific position. To create such well‐organized nanospaces in synthetic macromolecules and related materials, molecular imprinting techniques coupled with template molecules have been developed . This imprinting method allows us to make nanospaces that are specifically fitted to template molecules.…”

Section: Introductionmentioning

confidence: 99%

“…To create such well-organized nanospaces in synthetic macromolecules and related materials, molecular imprinting techniques coupled with template molecules have been developed. [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18] This imprinting method allows us to make nanospaces that are specifically fitted to template molecules. Generally, monomers physically interacting with or covalently connecting to templates are crosslinked to give templateembedded polymers and gels.…”

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confidence: 99%

Molecular imprinting on amphiphilic folded polymers for selective molecular recognition in water

Nagao

Sawamoto

Terashima

2020

Journal of Polymer Science

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We report amphiphilic folded polymers with imprinted nanocavities for selective molecular recognition in water. For this, a molecular imprinting technique is applied to the polymer synthesis: amphiphilic polymer micelles interacting with template molecules are crosslinked in water to fix the folded architecture and memorize the template structure within the polymers; the removal of the templates provides imprint polymers bearing template‐specific nanospaces. Here, a hydrophilic dye bearing two anionic groups, Orange G (OG), is used as a model template. For the imprinting, we design amphiphilic random copolymers bearing hydrophilic poly(ethylene glycol) (PEG) chains, hydrophobic olefin groups, and quaternary ammonium groups that can interact with the template. The copolymers were prepared by living radical polymerization and post functionalization. In the presence of OG and methyl blue (MB), the imprinted nanocavity polymers simultaneously capture both of the dyes in water. The total number of encapsulated dyes increased with increasing the number of polymer‐bound quaternary ammonium groups. The selectivity of OG against MB increased with the crosslinking density, while imprint polymers encapsulated OG more efficiently than nonimprint polymers. © 2020 Wiley Periodicals, Inc. J. Polym. Sci. 2020, 58, 215–224

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Molecular Imprinting with Functional DNA

Cited by 61 publications

References 129 publications

Nanozyme‐based luminescence detection

Nanozyme‐based luminescence detection

Molecular Imprinting Strategies for Tissue Engineering Applications: A Review

Molecular imprinting on amphiphilic folded polymers for selective molecular recognition in water

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