CaproGlu : multifunctional tissue adhesive platform
Driven by the clinical need for a strong tissue adhesive with elastomeric material properties, a departure from legacy crosslinking chemistries was sought as a multipurpose platform for tissue mending. A fresh approach to bonding wet substrates has yielded a synthetic biomaterial that overcomes the...
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sg-ntu-dr.10356-1442592023-07-14T16:01:08Z CaproGlu : multifunctional tissue adhesive platform Djordjevic, Ivan Pokholenko, Oleksandr Shah, Ankur Harish Wicaksono, Gautama Blancafort, Lluis Hanna, John V. Page, Samuel J. Nanda, Himansu Sekhar Ong, Chee Bing Chung, Sze Ryn Chin, Andrew Yuan Hui McGrouther, Duncan Choudhury, Muntasir Mannan Li, Fang Teo, Jonathan Shunming Lee, Lui Shiong Steele, Terry W. J. School of Materials Science and Engineering Engineering::Materials::Biomaterials Engineering::Bioengineering Polycaprolactone Bioadhesive Driven by the clinical need for a strong tissue adhesive with elastomeric material properties, a departure from legacy crosslinking chemistries was sought as a multipurpose platform for tissue mending. A fresh approach to bonding wet substrates has yielded a synthetic biomaterial that overcomes the drawbacks of free-radical and nature-inspired bioadhesives. A food-grade liquid polycaprolactone grafted with carbene precursors yields CaproGlu. The first-of-its-kind low-viscosity prepolymer is VOC-free and requires no photoinitiators. Grafted diazirine end-groups form carbene diradicals upon low energy UVA (365 nm) activation that immediately crosslink tissue surfaces; no pre-heating or animal-derived components are required. The hydrophobic polymeric environment enables metastable functional groups not possible in formulations requiring solvents or water. Activated diazirine within CaproGlu is uniquely capable of crosslinking all amino acids, even on wet tissue substrates. CaproGlu undergoes rapid liquid-to-biorubber transition within seconds of UVA exposure–features not found in any other bioadhesive. The exceptional shelf stability of CaproGlu allows gamma sterilization with no change in material properties. CaproGlu wet adhesiveness is challenged against current unmet clinical needs: anastomosis of spliced blood vessels, anesthetic muscle patches, and human platelet-mediating coatings. The versatility of CaproGlu enables both organic and inorganic composites for future bioadhesive platforms. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) Published version NTU-Surgery ACP, Strategic Joint Research Fund (SJRF): Fast, 2 min surgical procedure for splicing of blood vessels; Singapore General Hospital Research Grant (SRGOF16Jan29): Dynamic release of local anaesthetics through novel tissue adhesives; Ministry of Education Tier 1 Grant: Coil Expanding Layers (COELS) For Intravascular Repairs; Ministry of Education Tier 2 Grant: Tailored soft-tissue bioadhesives for site-specific therapy (MOE2012-T2-2-046) & CaproGlu, Double sided wet-tissue adhesives (MOE2018-T2-2-114); NTU-Northwestern Institute for Nanomedicine Grant: 3D-Printing of Electro-Curing Nanocomposite Living Electrodes for Cardiac Tissue Regeneration; NTUitive POC (Gap) Fund Aesthetic Applications of CaproGlu Bioadhesives NGF/2018/05/; A*Star IAF PP Grant (H19/01/a0/0II9): CathoGlu Bioadhesivespreventing catheter extravasation and skin infections. JVH acknowledges support for the solid state NMR instrumentation at Warwick used in this research which was funded by EPSRC (grants EP/M028186/1 and EP/K024418/1) the University of Warwick, and the Birmingham Science City AM1 and AM2 projects which were supported by Advantage West Midlands (AWM) and the European Regional Development Fund (ERDF). 2020-10-23T07:33:07Z 2020-10-23T07:33:07Z 2020 Journal Article Djordjevic, I., Pokholenko, O., Shah, A. H., Wicaksono, G., Blancafort, L., Hanna, J. V., . . . Steele, T. W. J. (2020). CaproGlu: Multifunctional tissue adhesive platform. Biomaterials, 260, 120215-. doi:10.1016/j.biomaterials.2020.120215 0142-9612 https://hdl.handle.net/10356/144259 10.1016/j.biomaterials.2020.120215 260 120215 en Biomaterials © 2020 The Author(s). Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). application/pdf |
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Engineering::Materials::Biomaterials Engineering::Bioengineering Polycaprolactone Bioadhesive |
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Engineering::Materials::Biomaterials Engineering::Bioengineering Polycaprolactone Bioadhesive Djordjevic, Ivan Pokholenko, Oleksandr Shah, Ankur Harish Wicaksono, Gautama Blancafort, Lluis Hanna, John V. Page, Samuel J. Nanda, Himansu Sekhar Ong, Chee Bing Chung, Sze Ryn Chin, Andrew Yuan Hui McGrouther, Duncan Choudhury, Muntasir Mannan Li, Fang Teo, Jonathan Shunming Lee, Lui Shiong Steele, Terry W. J. CaproGlu : multifunctional tissue adhesive platform |
| description |
Driven by the clinical need for a strong tissue adhesive with elastomeric material properties, a departure from legacy crosslinking chemistries was sought as a multipurpose platform for tissue mending. A fresh approach to bonding wet substrates has yielded a synthetic biomaterial that overcomes the drawbacks of free-radical and nature-inspired bioadhesives. A food-grade liquid polycaprolactone grafted with carbene precursors yields CaproGlu. The first-of-its-kind low-viscosity prepolymer is VOC-free and requires no photoinitiators. Grafted diazirine end-groups form carbene diradicals upon low energy UVA (365 nm) activation that immediately crosslink tissue surfaces; no pre-heating or animal-derived components are required. The hydrophobic polymeric environment enables metastable functional groups not possible in formulations requiring solvents or water. Activated diazirine within CaproGlu is uniquely capable of crosslinking all amino acids, even on wet tissue substrates. CaproGlu undergoes rapid liquid-to-biorubber transition within seconds of UVA exposure–features not found in any other bioadhesive. The exceptional shelf stability of CaproGlu allows gamma sterilization with no change in material properties. CaproGlu wet adhesiveness is challenged against current unmet clinical needs: anastomosis of spliced blood vessels, anesthetic muscle patches, and human platelet-mediating coatings. The versatility of CaproGlu enables both organic and inorganic composites for future bioadhesive platforms. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Djordjevic, Ivan Pokholenko, Oleksandr Shah, Ankur Harish Wicaksono, Gautama Blancafort, Lluis Hanna, John V. Page, Samuel J. Nanda, Himansu Sekhar Ong, Chee Bing Chung, Sze Ryn Chin, Andrew Yuan Hui McGrouther, Duncan Choudhury, Muntasir Mannan Li, Fang Teo, Jonathan Shunming Lee, Lui Shiong Steele, Terry W. J. |
| format |
Article |
| author |
Djordjevic, Ivan Pokholenko, Oleksandr Shah, Ankur Harish Wicaksono, Gautama Blancafort, Lluis Hanna, John V. Page, Samuel J. Nanda, Himansu Sekhar Ong, Chee Bing Chung, Sze Ryn Chin, Andrew Yuan Hui McGrouther, Duncan Choudhury, Muntasir Mannan Li, Fang Teo, Jonathan Shunming Lee, Lui Shiong Steele, Terry W. J. |
| author_sort |
Djordjevic, Ivan |
| title |
CaproGlu : multifunctional tissue adhesive platform |
| title_short |
CaproGlu : multifunctional tissue adhesive platform |
| title_full |
CaproGlu : multifunctional tissue adhesive platform |
| title_fullStr |
CaproGlu : multifunctional tissue adhesive platform |
| title_full_unstemmed |
CaproGlu : multifunctional tissue adhesive platform |
| title_sort |
caproglu : multifunctional tissue adhesive platform |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/144259 |
| _version_ |
1773551336002945024 |