Simultaneous crosslinking induces macroscopically phase-separated microgel from a homogeneous mixture of multiple polymers

Yuta Kurashina; Mio Tsuchiya; Atsushi Sakai; Tomoki Maeda; Yun  Jung J. Heo; Filippo Rossi; Nakwon Choi; Miho Yanagisawa; Hiroaki Onoe

doi:10.1016/j.apmt.2021.100937

Simultaneous crosslinking induces macroscopically phase-separated microgel from a homogeneous mixture of multiple polymers

Yuta Kurashina, Mio Tsuchiya, Atsushi Sakai, Tomoki Maeda, Yun  Jung J. Heo, Filippo Rossi, Nakwon Choi, Miho Yanagisawa, Hiroaki Onoe

Department of Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

This paper reports a unique phase separation behavior, a simultaneous-crosslinking-driven phase separation in co-gelation (SPSiC) core–shell microgel that spontaneously forms from a homogeneous pre-gel solution of multiple polymers. The SPSiC microgel, composed of an alginate shell and an N-isopropylacrylamide (NIPAM) core, were synthesized by a single fabrication step wherein a mixed pre-gel solution of sodium alginate and NIPAM monomer was ejected by centrifugation with photo-polymerization and ion crosslinking instantaneously. Phase separation was modeled by varying the degree of polymerization and the size of the polymer chain. Moreover, an implantable, multi-functional drug delivery system combined with a transdermal glucose sensor was demonstrated with core–shell Janus SPSiC microgels. This work shows a macroscopic phase separation behavior, which occurs during the gelation process, and also provides a simple and unique methodology to create multifunctional bio-microprobes.

Original language	English
Article number	100937
Journal	Applied Materials Today
Volume	22
DOIs	https://doi.org/10.1016/j.apmt.2021.100937
Publication status	Published - 2021 Mar

Keywords

Biosensor
Core–shell structure
Hydrogel
Microfluidics
Phase separation

ASJC Scopus subject areas

Materials Science(all)

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10.1016/j.apmt.2021.100937

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title = "Simultaneous crosslinking induces macroscopically phase-separated microgel from a homogeneous mixture of multiple polymers",

abstract = "This paper reports a unique phase separation behavior, a simultaneous-crosslinking-driven phase separation in co-gelation (SPSiC) core–shell microgel that spontaneously forms from a homogeneous pre-gel solution of multiple polymers. The SPSiC microgel, composed of an alginate shell and an N-isopropylacrylamide (NIPAM) core, were synthesized by a single fabrication step wherein a mixed pre-gel solution of sodium alginate and NIPAM monomer was ejected by centrifugation with photo-polymerization and ion crosslinking instantaneously. Phase separation was modeled by varying the degree of polymerization and the size of the polymer chain. Moreover, an implantable, multi-functional drug delivery system combined with a transdermal glucose sensor was demonstrated with core–shell Janus SPSiC microgels. This work shows a macroscopic phase separation behavior, which occurs during the gelation process, and also provides a simple and unique methodology to create multifunctional bio-microprobes.",

keywords = "Biosensor, Core–shell structure, Hydrogel, Microfluidics, Phase separation",

author = "Yuta Kurashina and Mio Tsuchiya and Atsushi Sakai and Tomoki Maeda and Heo, {Yun  Jung J.} and Filippo Rossi and Nakwon Choi and Miho Yanagisawa and Hiroaki Onoe",

note = "Funding Information: The authors would like to thank Takeshi Kubota and Keitaro Kasahara (Keio University, Japan) for their assistance in the measurement of fluorescent absorbances and confocal fluorescence investigations, respectively. This work was supported in part by the JSPS Grant-in-Aid for Early Career Scientists ( 19K149020 ), the Japan - Korea Basic Scientific Cooperation Program from JSPS (Japan) and NRF (Korea), Research Grant (Basic Research) from TEPCO Memorial Foundation, Basic Science Research Projects from the Sumitomo Foundation, and JKA and its promotion funds from KEIRIN RACE. Publisher Copyright: {\textcopyright} 2021",

year = "2021",

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doi = "10.1016/j.apmt.2021.100937",

language = "English",

volume = "22",

journal = "Applied Materials Today",

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AU - Kurashina, Yuta

AU - Tsuchiya, Mio

AU - Sakai, Atsushi

AU - Maeda, Tomoki

AU - Heo, Yun  Jung J.

AU - Rossi, Filippo

AU - Choi, Nakwon

AU - Yanagisawa, Miho

AU - Onoe, Hiroaki

N1 - Funding Information: The authors would like to thank Takeshi Kubota and Keitaro Kasahara (Keio University, Japan) for their assistance in the measurement of fluorescent absorbances and confocal fluorescence investigations, respectively. This work was supported in part by the JSPS Grant-in-Aid for Early Career Scientists ( 19K149020 ), the Japan - Korea Basic Scientific Cooperation Program from JSPS (Japan) and NRF (Korea), Research Grant (Basic Research) from TEPCO Memorial Foundation, Basic Science Research Projects from the Sumitomo Foundation, and JKA and its promotion funds from KEIRIN RACE. Publisher Copyright: © 2021

PY - 2021/3

Y1 - 2021/3

N2 - This paper reports a unique phase separation behavior, a simultaneous-crosslinking-driven phase separation in co-gelation (SPSiC) core–shell microgel that spontaneously forms from a homogeneous pre-gel solution of multiple polymers. The SPSiC microgel, composed of an alginate shell and an N-isopropylacrylamide (NIPAM) core, were synthesized by a single fabrication step wherein a mixed pre-gel solution of sodium alginate and NIPAM monomer was ejected by centrifugation with photo-polymerization and ion crosslinking instantaneously. Phase separation was modeled by varying the degree of polymerization and the size of the polymer chain. Moreover, an implantable, multi-functional drug delivery system combined with a transdermal glucose sensor was demonstrated with core–shell Janus SPSiC microgels. This work shows a macroscopic phase separation behavior, which occurs during the gelation process, and also provides a simple and unique methodology to create multifunctional bio-microprobes.

AB - This paper reports a unique phase separation behavior, a simultaneous-crosslinking-driven phase separation in co-gelation (SPSiC) core–shell microgel that spontaneously forms from a homogeneous pre-gel solution of multiple polymers. The SPSiC microgel, composed of an alginate shell and an N-isopropylacrylamide (NIPAM) core, were synthesized by a single fabrication step wherein a mixed pre-gel solution of sodium alginate and NIPAM monomer was ejected by centrifugation with photo-polymerization and ion crosslinking instantaneously. Phase separation was modeled by varying the degree of polymerization and the size of the polymer chain. Moreover, an implantable, multi-functional drug delivery system combined with a transdermal glucose sensor was demonstrated with core–shell Janus SPSiC microgels. This work shows a macroscopic phase separation behavior, which occurs during the gelation process, and also provides a simple and unique methodology to create multifunctional bio-microprobes.

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KW - Core–shell structure

KW - Hydrogel

KW - Microfluidics

KW - Phase separation

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Simultaneous crosslinking induces macroscopically phase-separated microgel from a homogeneous mixture of multiple polymers

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