Plant-based shape memory cryogel for hemorrhage control
The escalating global demand for sustainable manufacturing, motivated by concerns over energy conservation and carbon footprints, encounters challenges due to insufficient renewable materials and arduous fabrication procedures to fulfill specific requirements in medical and healthcare systems. Here,...
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sg-ntu-dr.10356-1808382024-10-29T04:59:11Z Plant-based shape memory cryogel for hemorrhage control Deng, Jingyu Zhao, Ze Yeo, Xin Yi Yang, Chungmo Yang, Jueying Ferhan, Abdul Rahim Jin, Bohwan Oh, Chansik Jung, Sangyong Suresh, Subra Cho, Nam-Joon School of Materials Science and Engineering Centre for Cross Economy Engineering Bioinspired materials Deep noncompressible wounds The escalating global demand for sustainable manufacturing, motivated by concerns over energy conservation and carbon footprints, encounters challenges due to insufficient renewable materials and arduous fabrication procedures to fulfill specific requirements in medical and healthcare systems. Here, biosafe pollen cryogel is engineered as effective hemostats without additional harmful crosslinkers to treat deep noncompressible wounds. A straightforward and low-energy approach is involved in forming stable macroporous cryogel, benefiting from the unique micro-hierarchical structures and chemical components of non-allergenic plant pollen. It is demonstrated that the pollen cryogel exhibits rapid water/blood-triggered shape-memory properties within 2 s. Owing to their inherent nano/micro hierarchical structure and abundant chemical functional groups on the pollen surface, the pollen cryogel shows effective hemostatic performance in a mouse liver penetration model, which is easily removed after usage. Overall, the self-crosslinking pollen cryogel in this work pioneers a framework of potential clinical applications for the first-hand treatment on deep noncompressible wounds. Ministry of Education (MOE) This work was supported by the Minister of Education, MOE AcRF Tier 1 (Grant no. 023126-00001), RG111/20 and RG34/22, and MOE AcRF Tier 3 (Grant No. MOET32022-0008). It was also supported by National Natural Science Foundation of China (Grant No. 52303131) and “the Fundamental Research Funds for the Central Universities” (Grant no. 2042023kf0177). And it was supported by the industry academic cooperation foundation, CHA University grant(CHA-202300230001). 2024-10-29T04:59:11Z 2024-10-29T04:59:11Z 2024 Journal Article Deng, J., Zhao, Z., Yeo, X. Y., Yang, C., Yang, J., Ferhan, A. R., Jin, B., Oh, C., Jung, S., Suresh, S. & Cho, N. (2024). Plant-based shape memory cryogel for hemorrhage control. Advanced Materials, 36(36), e2311684-. https://dx.doi.org/10.1002/adma.202311684 0935-9648 https://hdl.handle.net/10356/180838 10.1002/adma.202311684 39011812 2-s2.0-85198543770 36 36 e2311684 en 023126-00001 RG111/20 RG34/22 MOET32022-0008 Advanced Materials © 2024 Wiley-VCH GmbH. All rights reserved. |
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Engineering Bioinspired materials Deep noncompressible wounds |
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Engineering Bioinspired materials Deep noncompressible wounds Deng, Jingyu Zhao, Ze Yeo, Xin Yi Yang, Chungmo Yang, Jueying Ferhan, Abdul Rahim Jin, Bohwan Oh, Chansik Jung, Sangyong Suresh, Subra Cho, Nam-Joon Plant-based shape memory cryogel for hemorrhage control |
| description |
The escalating global demand for sustainable manufacturing, motivated by concerns over energy conservation and carbon footprints, encounters challenges due to insufficient renewable materials and arduous fabrication procedures to fulfill specific requirements in medical and healthcare systems. Here, biosafe pollen cryogel is engineered as effective hemostats without additional harmful crosslinkers to treat deep noncompressible wounds. A straightforward and low-energy approach is involved in forming stable macroporous cryogel, benefiting from the unique micro-hierarchical structures and chemical components of non-allergenic plant pollen. It is demonstrated that the pollen cryogel exhibits rapid water/blood-triggered shape-memory properties within 2 s. Owing to their inherent nano/micro hierarchical structure and abundant chemical functional groups on the pollen surface, the pollen cryogel shows effective hemostatic performance in a mouse liver penetration model, which is easily removed after usage. Overall, the self-crosslinking pollen cryogel in this work pioneers a framework of potential clinical applications for the first-hand treatment on deep noncompressible wounds. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Deng, Jingyu Zhao, Ze Yeo, Xin Yi Yang, Chungmo Yang, Jueying Ferhan, Abdul Rahim Jin, Bohwan Oh, Chansik Jung, Sangyong Suresh, Subra Cho, Nam-Joon |
| format |
Article |
| author |
Deng, Jingyu Zhao, Ze Yeo, Xin Yi Yang, Chungmo Yang, Jueying Ferhan, Abdul Rahim Jin, Bohwan Oh, Chansik Jung, Sangyong Suresh, Subra Cho, Nam-Joon |
| author_sort |
Deng, Jingyu |
| title |
Plant-based shape memory cryogel for hemorrhage control |
| title_short |
Plant-based shape memory cryogel for hemorrhage control |
| title_full |
Plant-based shape memory cryogel for hemorrhage control |
| title_fullStr |
Plant-based shape memory cryogel for hemorrhage control |
| title_full_unstemmed |
Plant-based shape memory cryogel for hemorrhage control |
| title_sort |
plant-based shape memory cryogel for hemorrhage control |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/180838 |
| _version_ |
1814777731725918208 |