Minimally invasive electroceutical catheter for endoluminal defect sealing
Surgical repair of lumen defects is associated with periprocedural morbidity and mortality. Endovascular repair with tissue adhesives may reduce host tissue damage, but current bioadhesive designs do not support minimally invasive deployment. Voltage-activated tissue adhesives offer a new strategy f...
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2021
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sg-ntu-dr.10356-1510112023-03-05T16:28:41Z Minimally invasive electroceutical catheter for endoluminal defect sealing Singh, Manisha Varela, Claudia E. Whyte, William Horvath, Markus A. Tan, Nigel Chew Shun Ong, Chee Bing Liang, Patric Schermerhorn, Marc L. Roche, Ellen T. Steele, Terry W. J. Interdisciplinary Graduate School (IGS) School of Materials Science and Engineering NTU-Northwestern Institute for Nanomedicine Science::Medicine Adhesives Catheters Surgical repair of lumen defects is associated with periprocedural morbidity and mortality. Endovascular repair with tissue adhesives may reduce host tissue damage, but current bioadhesive designs do not support minimally invasive deployment. Voltage-activated tissue adhesives offer a new strategy for endoluminal repair. To facilitate the clinical translation of voltage-activated adhesives, an electroceutical patch (ePATCH) paired with a minimally invasive catheter with retractable electrodes (CATRE) is challenged against the repair of in vivo and ex vivo lumen defects. The ePATCH/CATRE platform demonstrates the sealing of lumen defects up to 2 millimeters in diameter on wet tissue substrates. Water-tight seals are flexible and resilient, withstanding over 20,000 physiological relevant stress/strain cycles. No disruption to electrical signals was observed when the ePATCH was electrically activated on the beating heart. The ePATCH/CATRE platform has diverse potential applications ranging from endovascular treatment of pseudo-aneurysms/fistulas to bioelectrodes toward electrophysiological mapping. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) Nanyang Technological University Published version We would like to acknowledge the Ministry of Education Tier 2 Grant: Reversible, electrocuring adhesives (MOE2014-T2-2-100); NTU-Northwestern Institute for Nanomedicine Grant: 3D-Printing of Electro-Curing Nanocomposite Living Electrodes for Cardiac Tissue Regeneration, Agency for Science, Technology and Research (A*STAR) IRG17283008 “Microprocessor-based methods of composite curing,” NTU research scholarship; and NSF EFRI grant 1935291. E.T.R. acknowledges departmental funding from the Institute for Medical Engineering and Science and the Mechanical Engineering Department at the Massachusetts Institute of Technology. 2021-06-25T03:19:23Z 2021-06-25T03:19:23Z 2021 Journal Article Singh, M., Varela, C. E., Whyte, W., Horvath, M. A., Tan, N. C. S., Ong, C. B., Liang, P., Schermerhorn, M. L., Roche, E. T. & Steele, T. W. J. (2021). Minimally invasive electroceutical catheter for endoluminal defect sealing. Science Advances, 7(14), eabf6855-. https://dx.doi.org/10.1126/sciadv.abf6855 2375-2548 https://hdl.handle.net/10356/151011 10.1126/sciadv.abf6855 33811080 2-s2.0-85103780375 14 7 eabf6855 en MOE2014-T2-2-100 IRG17283008 Science Advances © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC). application/pdf |
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Science::Medicine Adhesives Catheters |
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Science::Medicine Adhesives Catheters Singh, Manisha Varela, Claudia E. Whyte, William Horvath, Markus A. Tan, Nigel Chew Shun Ong, Chee Bing Liang, Patric Schermerhorn, Marc L. Roche, Ellen T. Steele, Terry W. J. Minimally invasive electroceutical catheter for endoluminal defect sealing |
| description |
Surgical repair of lumen defects is associated with periprocedural morbidity and mortality. Endovascular repair with tissue adhesives may reduce host tissue damage, but current bioadhesive designs do not support minimally invasive deployment. Voltage-activated tissue adhesives offer a new strategy for endoluminal repair. To facilitate the clinical translation of voltage-activated adhesives, an electroceutical patch (ePATCH) paired with a minimally invasive catheter with retractable electrodes (CATRE) is challenged against the repair of in vivo and ex vivo lumen defects. The ePATCH/CATRE platform demonstrates the sealing of lumen defects up to 2 millimeters in diameter on wet tissue substrates. Water-tight seals are flexible and resilient, withstanding over 20,000 physiological relevant stress/strain cycles. No disruption to electrical signals was observed when the ePATCH was electrically activated on the beating heart. The ePATCH/CATRE platform has diverse potential applications ranging from endovascular treatment of pseudo-aneurysms/fistulas to bioelectrodes toward electrophysiological mapping. |
| author2 |
Interdisciplinary Graduate School (IGS) |
| author_facet |
Interdisciplinary Graduate School (IGS) Singh, Manisha Varela, Claudia E. Whyte, William Horvath, Markus A. Tan, Nigel Chew Shun Ong, Chee Bing Liang, Patric Schermerhorn, Marc L. Roche, Ellen T. Steele, Terry W. J. |
| format |
Article |
| author |
Singh, Manisha Varela, Claudia E. Whyte, William Horvath, Markus A. Tan, Nigel Chew Shun Ong, Chee Bing Liang, Patric Schermerhorn, Marc L. Roche, Ellen T. Steele, Terry W. J. |
| author_sort |
Singh, Manisha |
| title |
Minimally invasive electroceutical catheter for endoluminal defect sealing |
| title_short |
Minimally invasive electroceutical catheter for endoluminal defect sealing |
| title_full |
Minimally invasive electroceutical catheter for endoluminal defect sealing |
| title_fullStr |
Minimally invasive electroceutical catheter for endoluminal defect sealing |
| title_full_unstemmed |
Minimally invasive electroceutical catheter for endoluminal defect sealing |
| title_sort |
minimally invasive electroceutical catheter for endoluminal defect sealing |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/151011 |
| _version_ |
1759854203307556864 |