Artificial urinary bladder model
Artificial urinary bladder model
Technological advancements in the medical field are often slow and expensive, sometimes due to complexities associated with pre-clinical testing of medical devices and implants. There is therefore a growing need for new test beds that can mimic more closely the in vivo environment of physiological systems. In the present study, a novel bladder model was designed and fabricated with the aim of providing a pre-clinical testing platform for urological stents and catheters. The model is collapsible, has a Young's modulus that is comparable to a biological bladder, and can be actuated on-demand to enable voiding. Moreover, the developed fabrication technique provides versatility to adjust the model's shape, size, and thickness, through a rapid and relatively inexpensive process. When compared to a biological bladder, there is a significant difference in compliance; however, the model exhibits cystometry profiles during priming and voiding that are qualitatively comparable to a biological bladder. The developed bladder model has therefore potential for future usage in urological device testing; however, improvements are required to more closely replicate the architecture and relevant flow metrics of a physiological bladder.
Artificial organs, artificial muscles (biomechanics), biomaterials (see also medical biomaterials), biomedical devices, polymers
588-597
Read, Benjamin
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Tan Sze Wuan, Annecia
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Pietropaolo, Amelia
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Somani, Bhaskar K.
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Carugo, Dario
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Mosayyebi, Ali
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Read, Benjamin
a93c0d94-de24-4b24-92b8-896684e448c0
Tan Sze Wuan, Annecia
6b1a8627-c288-4093-aa25-b7c016e94e17
Pietropaolo, Amelia
dd6770c4-bf2e-46a9-b7a2-7bd3f9fdba56
Somani, Bhaskar K.
7ed77b4e-3ffc-43ef-bc61-bd1c1544518c
Carugo, Dario
cf740d40-75f2-4073-9c6e-6fcf649512ca
Mosayyebi, Ali
ab9cf6da-58c4-4441-993b-7d03d5d3549a
Read, Benjamin, Tan Sze Wuan, Annecia, Pietropaolo, Amelia, Somani, Bhaskar K., Carugo, Dario and Mosayyebi, Ali
(2024)
Artificial urinary bladder model.
Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine, 238 (6), .
(doi:10.1177/09544119241262372).
Abstract
Technological advancements in the medical field are often slow and expensive, sometimes due to complexities associated with pre-clinical testing of medical devices and implants. There is therefore a growing need for new test beds that can mimic more closely the in vivo environment of physiological systems. In the present study, a novel bladder model was designed and fabricated with the aim of providing a pre-clinical testing platform for urological stents and catheters. The model is collapsible, has a Young's modulus that is comparable to a biological bladder, and can be actuated on-demand to enable voiding. Moreover, the developed fabrication technique provides versatility to adjust the model's shape, size, and thickness, through a rapid and relatively inexpensive process. When compared to a biological bladder, there is a significant difference in compliance; however, the model exhibits cystometry profiles during priming and voiding that are qualitatively comparable to a biological bladder. The developed bladder model has therefore potential for future usage in urological device testing; however, improvements are required to more closely replicate the architecture and relevant flow metrics of a physiological bladder.
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e-pub ahead of print date: 30 July 2024
Keywords:
Artificial organs, artificial muscles (biomechanics), biomaterials (see also medical biomaterials), biomedical devices, polymers
Identifiers
Local EPrints ID: 493142
URI: http://eprints.soton.ac.uk/id/eprint/493142
ISSN: 0954-4119
PURE UUID: 379c651f-bda5-4d5f-8ee8-2b370f0f39ce
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Date deposited: 23 Aug 2024 16:53
Last modified: 14 Dec 2024 02:54
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Contributors
Author:
Benjamin Read
Author:
Annecia Tan Sze Wuan
Author:
Amelia Pietropaolo
Author:
Bhaskar K. Somani
Author:
Dario Carugo
Author:
Ali Mosayyebi
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