Fast Transport and Transformation of Biomacromolecular Substances via Thermo‐Stimulated Active “Inhalation–Exhalation” Cycles of Hierarchically Structured Smart pNIPAM–DNA Hydrogels

Fast Transport and Transformation of Biomacromolecular Substances via Thermo‐Stimulated Active “Inhalation–Exhalation” Cycles of Hierarchically Structured Smart pNIPAM–DNA Hydrogels

Although smart hydrogels hold great promise in biosensing and biomedical applications, their response to external stimuli is governed by the passive diffusion‐dependent substance transport between hydrogels and environments and within the 3D hydrogel matrices, resulting in slow response to biomacrom...

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Veröffentlicht in:Advanced materials (Weinheim) 2023-01, Vol.35 (2), p.e2206302-n/a
Hauptverfasser: Du, Xiaoxue, He, Ping‐Ping, Wang, Chunyan, Wang, Xiaowen, Mu, Yali, Guo, Weiwei
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Sprache:eng
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Biomedical materials
biosensing
cryogels
DNA
Exhalation
functional nucleic acids
Hydrogels
Materials science
Near infrared radiation
Polyisopropyl acrylamide
Respiration
responsive hydrogels
System effectiveness
thermosensitive polymers
Water
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container_start_page e2206302
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creator Du, Xiaoxue
He, Ping‐Ping
Wang, Chunyan
Wang, Xiaowen
Mu, Yali
Guo, Weiwei
description Although smart hydrogels hold great promise in biosensing and biomedical applications, their response to external stimuli is governed by the passive diffusion‐dependent substance transport between hydrogels and environments and within the 3D hydrogel matrices, resulting in slow response to biomacromolecules and limiting their extensive applications. Herein, inspired by the respiration systems of organisms, an active strategy to achieve highly efficient biomolecular substance transport through the thermo‐stimulated “inhalation–exhalation” cycles of hydrogel matrices is demonstrated. The cryo‐structured poly(N‐isopropylacrylamide) (pNIPAM)–DNA hydrogels, composed of functional DNA‐tethered pNIPAM networks and free‐water‐containing macroporous channels, exhibit thermally triggered fast and reversible shrinking/swelling cycles with high‐volume changes, which drive the formation of dynamic water stream to accelerate the intake of external substances and expelling of endogenous substances, thus promoting the functional properties of hydrogel systems. Demonstrated by catalytic DNAzyme and CRISPR‐Cas12a‐incorporating hydrogels, significantly enhanced catalytic efficiency with up to 280% and 390% is achieved, upon the introduction of active “inhalation–exhalation” cycles, respectively. Moreover, remotely near‐infrared (NIR)‐triggering of “inhalation–exhalation” cycles is achieved after the introduction of NIR‐responsive MXene nanosheets into the hydrogel matrix. These hydrogel systems with enhanced substance transport and transformation properties hold promise in the development of more effective biosensing and therapeutic systems. Inspired by the respiration systems of organisms, highly efficient transport and transformation of biomacromolecular substances are achieved through the thermo‐stimulated active “inhalation–exhalation” cycles of hierarchically structured smart DNA hydrogels. The application of active “inhalation–exhalation” cycles in the poly(N‐isopropylacrylamide)–DNA hydrogels improves the catalytic efficiency of the incorporated DNAzyme or CRISPR‐Cas12a systems by up to 280% or 390%, respectively.
doi_str_mv 10.1002/adma.202206302
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Herein, inspired by the respiration systems of organisms, an active strategy to achieve highly efficient biomolecular substance transport through the thermo‐stimulated “inhalation–exhalation” cycles of hydrogel matrices is demonstrated. The cryo‐structured poly(N‐isopropylacrylamide) (pNIPAM)–DNA hydrogels, composed of functional DNA‐tethered pNIPAM networks and free‐water‐containing macroporous channels, exhibit thermally triggered fast and reversible shrinking/swelling cycles with high‐volume changes, which drive the formation of dynamic water stream to accelerate the intake of external substances and expelling of endogenous substances, thus promoting the functional properties of hydrogel systems. Demonstrated by catalytic DNAzyme and CRISPR‐Cas12a‐incorporating hydrogels, significantly enhanced catalytic efficiency with up to 280% and 390% is achieved, upon the introduction of active “inhalation–exhalation” cycles, respectively. 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Moreover, remotely near‐infrared (NIR)‐triggering of “inhalation–exhalation” cycles is achieved after the introduction of NIR‐responsive MXene nanosheets into the hydrogel matrix. These hydrogel systems with enhanced substance transport and transformation properties hold promise in the development of more effective biosensing and therapeutic systems. Inspired by the respiration systems of organisms, highly efficient transport and transformation of biomacromolecular substances are achieved through the thermo‐stimulated active “inhalation–exhalation” cycles of hierarchically structured smart DNA hydrogels. 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Moreover, remotely near‐infrared (NIR)‐triggering of “inhalation–exhalation” cycles is achieved after the introduction of NIR‐responsive MXene nanosheets into the hydrogel matrix. These hydrogel systems with enhanced substance transport and transformation properties hold promise in the development of more effective biosensing and therapeutic systems. Inspired by the respiration systems of organisms, highly efficient transport and transformation of biomacromolecular substances are achieved through the thermo‐stimulated active “inhalation–exhalation” cycles of hierarchically structured smart DNA hydrogels. 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subjects Biomedical materials
biosensing
cryogels
DNA
Exhalation
functional nucleic acids
Hydrogels
Materials science
Near infrared radiation
Polyisopropyl acrylamide
Respiration
responsive hydrogels
System effectiveness
thermosensitive polymers
Water
title Fast Transport and Transformation of Biomacromolecular Substances via Thermo‐Stimulated Active “Inhalation–Exhalation” Cycles of Hierarchically Structured Smart pNIPAM–DNA Hydrogels
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