Patterned enteroscopy balloon design factors influence tissue anchoring

Balloon-assisted enteroscopy procedures allow visualization and intervention in the small intestine. These balloons anchor an endoscope and/or overtube to the small intestine, allowing endoscopists to plicate the small intestine over the overtube. This procedure can extend examination deeper into th...

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Vydané v:	Journal of the mechanical behavior of biomedical materials Ročník 111; s. 103966
Hlavní autori:	Bowen, Leah K., Johannes, Karl, Zuetell, Emily, Calahan, Kristin N., Edmundowicz, Steven A., Long, Rong, Rentschler, Mark E.
Médium:	Journal Article
Jazyk:	English
Vydavateľské údaje:	Netherlands Elsevier Ltd 01.11.2020
Predmet:	Animals Endoscopy, Gastrointestinal Equipment Design Humans Intestine, Small Laparoscopy Silicones Swine
ISSN:	1751-6161, 1878-0180, 1878-0180
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Abstract	Balloon-assisted enteroscopy procedures allow visualization and intervention in the small intestine. These balloons anchor an endoscope and/or overtube to the small intestine, allowing endoscopists to plicate the small intestine over the overtube. This procedure can extend examination deeper into the small intestine than the length of the endoscope would allow with direct examination. However, procedures are often prolonged or incomplete due to balloon slippage. Enteroscopy balloons are pressure-limited to ensure patient safety and thus, improving anchoring without increasing pressure is essential. Patterning balloon exteriors with discrete features may enhance anchoring at the tissue-balloon interface. Here, the pattern design space is explored to determine factors that influence tissue anchoring. The anchoring ability of smooth versus balloons with patterned features is investigated by experimentally measuring a peak force required to induce slippage of an inflated balloon inside ex-vivo porcine small intestine. Stiffer materials, low aspect-ratio features, and pattern area/location on the balloons significantly increase peak force compared to smooth silicone balloons. Smooth latex balloons, used for standard enteroscopy, have the lowest peak force. This work demonstrates both a method to pattern curved surfaces and that a balloon with patterned features improves anchoring against a deformable, lubricated tissue interface. [Display omitted]
AbstractList	Balloon-assisted enteroscopy procedures allow visualization and intervention in the small intestine. These balloons anchor an endoscope and/or overtube to the small intestine, allowing endoscopists to plicate the small intestine over the overtube. This procedure can extend examination deeper into the small intestine than the length of the endoscope would allow with direct examination. However, procedures are often prolonged or incomplete due to balloon slippage. Enteroscopy balloons are pressure-limited to ensure patient safety and thus, improving anchoring without increasing pressure is essential. Patterning balloon exteriors with discrete features may enhance anchoring at the tissue-balloon interface. Here, the pattern design space is explored to determine factors that influence tissue anchoring. The anchoring ability of smooth versus balloons with patterned features is investigated by experimentally measuring a peak force required to induce slippage of an inflated balloon inside ex-vivo porcine small intestine. Stiffer materials, low aspect-ratio features, and pattern area/location on the balloons significantly increase peak force compared to smooth silicone balloons. Smooth latex balloons, used for standard enteroscopy, have the lowest peak force. This work demonstrates both a method to pattern curved surfaces and that a balloon with patterned features improves anchoring against a deformable, lubricated tissue interface.Balloon-assisted enteroscopy procedures allow visualization and intervention in the small intestine. These balloons anchor an endoscope and/or overtube to the small intestine, allowing endoscopists to plicate the small intestine over the overtube. This procedure can extend examination deeper into the small intestine than the length of the endoscope would allow with direct examination. However, procedures are often prolonged or incomplete due to balloon slippage. Enteroscopy balloons are pressure-limited to ensure patient safety and thus, improving anchoring without increasing pressure is essential. Patterning balloon exteriors with discrete features may enhance anchoring at the tissue-balloon interface. Here, the pattern design space is explored to determine factors that influence tissue anchoring. The anchoring ability of smooth versus balloons with patterned features is investigated by experimentally measuring a peak force required to induce slippage of an inflated balloon inside ex-vivo porcine small intestine. Stiffer materials, low aspect-ratio features, and pattern area/location on the balloons significantly increase peak force compared to smooth silicone balloons. Smooth latex balloons, used for standard enteroscopy, have the lowest peak force. This work demonstrates both a method to pattern curved surfaces and that a balloon with patterned features improves anchoring against a deformable, lubricated tissue interface. Balloon-assisted enteroscopy procedures allow visualization and intervention in the small intestine. These balloons anchor an endoscope and/or overtube to the small intestine, allowing endoscopists to plicate the small intestine over the overtube. This procedure can extend examination deeper into the small intestine than the length of the endoscope would allow with direct examination. However, procedures are often prolonged or incomplete due to balloon slippage. Enteroscopy balloons are pressure-limited to ensure patient safety and thus, improving anchoring without increasing pressure is essential. Patterning balloon exteriors with discrete features may enhance anchoring at the tissue-balloon interface. Here, the pattern design space is explored to determine factors that influence tissue anchoring. The anchoring ability of smooth versus balloons with patterned features is investigated by experimentally measuring a peak force required to induce slippage of an inflated balloon inside ex-vivo porcine small intestine. Stiffer materials, low aspect-ratio features, and pattern area/location on the balloons significantly increase peak force compared to smooth silicone balloons. Smooth latex balloons, used for standard enteroscopy, have the lowest peak force. This work demonstrates both a method to pattern curved surfaces and that a balloon with patterned features improves anchoring against a deformable, lubricated tissue interface. Balloon-assisted enteroscopy procedures allow visualization and intervention in the small intestine. These balloons anchor an endoscope and/or overtube to the small intestine, allowing endoscopists to plicate the small intestine over the overtube. This procedure can extend examination deeper into the small intestine than the length of the endoscope would allow with direct examination. However, procedures are often prolonged or incomplete due to balloon slippage. Enteroscopy balloons are pressure-limited to ensure patient safety and thus, improving anchoring without increasing pressure is essential. Patterning balloon exteriors with discrete features may enhance anchoring at the tissue-balloon interface. Here, the pattern design space is explored to determine factors that influence tissue anchoring. The anchoring ability of smooth versus balloons with patterned features is investigated by experimentally measuring a peak force required to induce slippage of an inflated balloon inside ex-vivo porcine small intestine. Stiffer materials, low aspect-ratio features, and pattern area/location on the balloons significantly increase peak force compared to smooth silicone balloons. Smooth latex balloons, used for standard enteroscopy, have the lowest peak force. This work demonstrates both a method to pattern curved surfaces and that a balloon with patterned features improves anchoring against a deformable, lubricated tissue interface. [Display omitted]
ArticleNumber	103966
Author	Rentschler, Mark E. Bowen, Leah K. Johannes, Karl Zuetell, Emily Calahan, Kristin N. Long, Rong Edmundowicz, Steven A.
Author_xml	– sequence: 1 givenname: Leah K. orcidid: 0000-0001-7417-4845 surname: Bowen fullname: Bowen, Leah K. email: leah.bowen@colorado.edu organization: Department of Mechanical Engineering, ECME 114, 1111 Engineering Drive, University of Colorado Boulder, Boulder, CO, 80309, USA – sequence: 2 givenname: Karl surname: Johannes fullname: Johannes, Karl email: karl.johannes@colorado.edu organization: Department of Mechanical Engineering, ECME 114, 1111 Engineering Drive, University of Colorado Boulder, Boulder, CO, 80309, USA – sequence: 3 givenname: Emily orcidid: 0000-0003-4106-8637 surname: Zuetell fullname: Zuetell, Emily email: emily.zuetell@colorado.edu organization: Department of Mechanical Engineering, ECME 114, 1111 Engineering Drive, University of Colorado Boulder, Boulder, CO, 80309, USA – sequence: 4 givenname: Kristin N. surname: Calahan fullname: Calahan, Kristin N. email: kristin.calahan@colorado.edu organization: Department of Mechanical Engineering, ECME 114, 1111 Engineering Drive, University of Colorado Boulder, Boulder, CO, 80309, USA – sequence: 5 givenname: Steven A. surname: Edmundowicz fullname: Edmundowicz, Steven A. email: steven.edmundowicz@cuanschutz.edu organization: Department of Medicine, Gastroenterology, University of Colorado, Anschutz Medical Campus, 12631 E. 17th Ave. B158, Aurora, CO, 80045, USA – sequence: 6 givenname: Rong orcidid: 0000-0001-8992-2420 surname: Long fullname: Long, Rong email: rong.long@colorado.edu organization: Department of Mechanical Engineering, ECME 114, 1111 Engineering Drive, University of Colorado Boulder, Boulder, CO, 80309, USA – sequence: 7 givenname: Mark E. surname: Rentschler fullname: Rentschler, Mark E. email: mark.rentschler@colorado.edu organization: Department of Mechanical Engineering, ECME 114, 1111 Engineering Drive, University of Colorado Boulder, Boulder, CO, 80309, USA
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Snippet	Balloon-assisted enteroscopy procedures allow visualization and intervention in the small intestine. These balloons anchor an endoscope and/or overtube to the...
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SubjectTerms	Animals Endoscopy, Gastrointestinal Equipment Design Humans Intestine, Small Laparoscopy Silicones Swine
Title	Patterned enteroscopy balloon design factors influence tissue anchoring
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