Degradable and biocompatible hydrogels bearing a hindered urea bond

Hanze Ying; Jonathan Yen; Ruibo Wang; Yang Lai; Jer Luen Aaron Hsu; Yuhang Hu; Jianjun Cheng

doi:10.1039/c7bm00669a

Degradable and biocompatible hydrogels bearing a hindered urea bond

Hanze Ying, Jonathan Yen, Ruibo Wang, Yang Lai, Jer Luen Aaron Hsu, Yuhang Hu, Jianjun Cheng

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

Abstract

A hindered urea bond (HUB), recently reported as a new type of dynamic chemical bond, can be facilely constructed by mixing an isocyanate and a hindered amine. Here, we report the use of the HUB in the design of degradable hydrogel materials for applications of stem cell encapsulation and delivery. Polyethyleneglycol (PEG) diamine was end-capped with a HUB and an allyl group in a one-pot synthesis. The resulting polymer was cross-linked to form a hydrogel under UV with the addition of a 4-arm PEG thiol and a photoinitiator. The degradation properties of the hydrogels were confirmed with NMR, GPC, weight loss, and protein release studies. We found that the degradation kinetics is dependent on the size of the N-substituents, and the one with the tert-butyl group shows complete degradation within 2 days. The new hydrogel materials were also demonstrated to be biocompatible with hMSCs, and the cell release kinetics can be facilely tuned over 5 days.

Original language	English (US)
Pages (from-to)	2398-2402
Number of pages	5
Journal	Biomaterials Science
Volume	5
Issue number	12
DOIs	https://doi.org/10.1039/c7bm00669a
State	Published - Dec 2017

ASJC Scopus subject areas

Biomedical Engineering
General Materials Science

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10.1039/c7bm00669a

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abstract = "A hindered urea bond (HUB), recently reported as a new type of dynamic chemical bond, can be facilely constructed by mixing an isocyanate and a hindered amine. Here, we report the use of the HUB in the design of degradable hydrogel materials for applications of stem cell encapsulation and delivery. Polyethyleneglycol (PEG) diamine was end-capped with a HUB and an allyl group in a one-pot synthesis. The resulting polymer was cross-linked to form a hydrogel under UV with the addition of a 4-arm PEG thiol and a photoinitiator. The degradation properties of the hydrogels were confirmed with NMR, GPC, weight loss, and protein release studies. We found that the degradation kinetics is dependent on the size of the N-substituents, and the one with the tert-butyl group shows complete degradation within 2 days. The new hydrogel materials were also demonstrated to be biocompatible with hMSCs, and the cell release kinetics can be facilely tuned over 5 days.",

author = "Hanze Ying and Jonathan Yen and Ruibo Wang and Yang Lai and Hsu, {Jer Luen Aaron} and Yuhang Hu and Jianjun Cheng",

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AU - Ying, Hanze

AU - Yen, Jonathan

AU - Wang, Ruibo

AU - Lai, Yang

AU - Hsu, Jer Luen Aaron

AU - Hu, Yuhang

AU - Cheng, Jianjun

PY - 2017/12

Y1 - 2017/12

N2 - A hindered urea bond (HUB), recently reported as a new type of dynamic chemical bond, can be facilely constructed by mixing an isocyanate and a hindered amine. Here, we report the use of the HUB in the design of degradable hydrogel materials for applications of stem cell encapsulation and delivery. Polyethyleneglycol (PEG) diamine was end-capped with a HUB and an allyl group in a one-pot synthesis. The resulting polymer was cross-linked to form a hydrogel under UV with the addition of a 4-arm PEG thiol and a photoinitiator. The degradation properties of the hydrogels were confirmed with NMR, GPC, weight loss, and protein release studies. We found that the degradation kinetics is dependent on the size of the N-substituents, and the one with the tert-butyl group shows complete degradation within 2 days. The new hydrogel materials were also demonstrated to be biocompatible with hMSCs, and the cell release kinetics can be facilely tuned over 5 days.

AB - A hindered urea bond (HUB), recently reported as a new type of dynamic chemical bond, can be facilely constructed by mixing an isocyanate and a hindered amine. Here, we report the use of the HUB in the design of degradable hydrogel materials for applications of stem cell encapsulation and delivery. Polyethyleneglycol (PEG) diamine was end-capped with a HUB and an allyl group in a one-pot synthesis. The resulting polymer was cross-linked to form a hydrogel under UV with the addition of a 4-arm PEG thiol and a photoinitiator. The degradation properties of the hydrogels were confirmed with NMR, GPC, weight loss, and protein release studies. We found that the degradation kinetics is dependent on the size of the N-substituents, and the one with the tert-butyl group shows complete degradation within 2 days. The new hydrogel materials were also demonstrated to be biocompatible with hMSCs, and the cell release kinetics can be facilely tuned over 5 days.

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Degradable and biocompatible hydrogels bearing a hindered urea bond

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