Highly efficient semiconductor modules making controllable parallel microchannels for non-compressible hemorrhages
Nature makes the most beautiful solution to involuted problems. Among them, the parallel tubular structures are capable of transporting fluid quickly in plant trunks and leaf stems, which demonstrate an ingenious evolutionary design. This study develops a mini-thermoelectric semiconductor P–N module...
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Veröffentlicht in: | Bioactive materials 2024-06, Vol.36, p.30-47 |
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Sprache: | eng |
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Zusammenfassung: | Nature makes the most beautiful solution to involuted problems. Among them, the parallel tubular structures are capable of transporting fluid quickly in plant trunks and leaf stems, which demonstrate an ingenious evolutionary design. This study develops a mini-thermoelectric semiconductor P–N module to create gradient and parallel channeled hydrogels. The modules decrease quickly the temperature of polymer solution from 20 °C to −20 °C within 5 min. In addition to the exceptional liquid absorption rate, the foams exhibited shape memory mechanics. Our mini device universally makes the inspired structure in such as chitosan, gelatin, alginate and polyvinyl alcohol. Non-compressible hemorrhages are the primary cause of death in emergency. The rapid liquid absorption leads to fast activation of coagulation, which provides an efficient strategy for hemostasis management. We demonstrated this by using our semiconductor modules on collagen-kaolin parallel channel foams with their high porosity (96.43%) and rapid expansion rate (2934%). They absorb liquid with 37.25 times of the own weight, show 46.5-fold liquid absorption speed and 24-fold of blood compared with random porous foams. These superior properties lead to strong hemostatic performance in vitro and in vivo.
Arranging mini-semiconductors for aligned micro-tubular structures for hemostasis applications. [Display omitted]
•Highly efficient thermal control.•Mini-semiconductors device.•Aligned micro-channels for super-hemostasis.•Universal fabrication for most polymers.•Injectable and shape memory. |
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ISSN: | 2452-199X 2097-1192 2452-199X |
DOI: | 10.1016/j.bioactmat.2024.02.006 |