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Using a sweating residuum/socket interface simulator for the evaluation of sweat management liners in lower limb prosthetics

Using a sweating residuum/socket interface simulator for the evaluation of sweat management liners in lower limb prosthetics
Using a sweating residuum/socket interface simulator for the evaluation of sweat management liners in lower limb prosthetics
BACKGROUND: Lab-based simulators can help to reduce variability in prosthetics research. However, they have not yet been used to investigate the effects of sweating at the residuum-liner interface. This work sought to create and validate a simulator to replicate the mechanics of residual limb perspiration. The developed apparatus was used to assess the effects of perspiration and different liner designs.

METHODOLOGY: By scanning a cast, an artificial residuum was manufactured using a 3D-printed, transtibial bone model encased in silicone, moulded with pores. The pores allowed water to emit from the residuum surface, simulating sweating. Dry and sweating cyclic tests were performed by applying compressive and tensile loading, while measuring the displacement of the residuum relative to the socket. Tests were conducted using standard and perforated liners.

FINDINGS: Although maximum displacement varied between test setups, its variance was low (coefficient of variation <1%) and consistent between dry tests. For unperforated liners, sweating increased the standard deviation of maximum displacement approximately threefold (0.04mm v 0.12mm, p<0.001). However, with the perforated liner, sweating had little effect on standard deviation compared to dry tests (0.04mm v 0.04mm, p=0.497).

CONCLUSIONS: The test apparatus was effective at simulating the effect of perspiration at the residual limb. Moisture at the skin-liner interface can lead to inconsistent mechanics. Perforated liners help to remove sweat from the skin-liner interface, thereby mitigating these effects.
2561-987X
McGrath, Michael
d97b973b-723e-46dc-af3b-9dffed24e24e
Davis, Katherine
1b89a859-f9b6-401e-b027-e8ec193ec72c
Gallego, Ana
85daaaa9-33d0-4135-9d8a-1071ead94741
Laszczak, Piotr
da02733e-0d18-4d14-bc54-af80ee97d2fb
Tang, Jinghua
b4b9a22c-fd6d-427a-9ab1-51184c1d2a2c
Zahedi, Saeed
fec0d8af-5088-4b23-b94e-2ba1d019850a
Moser, David
09874cab-348f-47f9-b018-1c2875d16998
McGrath, Michael
d97b973b-723e-46dc-af3b-9dffed24e24e
Davis, Katherine
1b89a859-f9b6-401e-b027-e8ec193ec72c
Gallego, Ana
85daaaa9-33d0-4135-9d8a-1071ead94741
Laszczak, Piotr
da02733e-0d18-4d14-bc54-af80ee97d2fb
Tang, Jinghua
b4b9a22c-fd6d-427a-9ab1-51184c1d2a2c
Zahedi, Saeed
fec0d8af-5088-4b23-b94e-2ba1d019850a
Moser, David
09874cab-348f-47f9-b018-1c2875d16998

McGrath, Michael, Davis, Katherine, Gallego, Ana, Laszczak, Piotr, Tang, Jinghua, Zahedi, Saeed and Moser, David (2021) Using a sweating residuum/socket interface simulator for the evaluation of sweat management liners in lower limb prosthetics. Canadian Prosthetics and Orthotics Journal, 4 (1). (doi:10.33137/cpoj.v4i1.35213).

Record type: Article

Abstract

BACKGROUND: Lab-based simulators can help to reduce variability in prosthetics research. However, they have not yet been used to investigate the effects of sweating at the residuum-liner interface. This work sought to create and validate a simulator to replicate the mechanics of residual limb perspiration. The developed apparatus was used to assess the effects of perspiration and different liner designs.

METHODOLOGY: By scanning a cast, an artificial residuum was manufactured using a 3D-printed, transtibial bone model encased in silicone, moulded with pores. The pores allowed water to emit from the residuum surface, simulating sweating. Dry and sweating cyclic tests were performed by applying compressive and tensile loading, while measuring the displacement of the residuum relative to the socket. Tests were conducted using standard and perforated liners.

FINDINGS: Although maximum displacement varied between test setups, its variance was low (coefficient of variation <1%) and consistent between dry tests. For unperforated liners, sweating increased the standard deviation of maximum displacement approximately threefold (0.04mm v 0.12mm, p<0.001). However, with the perforated liner, sweating had little effect on standard deviation compared to dry tests (0.04mm v 0.04mm, p=0.497).

CONCLUSIONS: The test apparatus was effective at simulating the effect of perspiration at the residual limb. Moisture at the skin-liner interface can lead to inconsistent mechanics. Perforated liners help to remove sweat from the skin-liner interface, thereby mitigating these effects.

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Accepted/In Press date: 10 March 2021
Published date: 19 March 2021

Identifiers

Local EPrints ID: 476155
URI: http://eprints.soton.ac.uk/id/eprint/476155
ISSN: 2561-987X
PURE UUID: 97ac9712-522b-4c79-a4c7-fd97288d672f
ORCID for Jinghua Tang: ORCID iD orcid.org/0000-0003-3359-5891

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Date deposited: 12 Apr 2023 16:56
Last modified: 17 Mar 2024 03:47

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Contributors

Author: Michael McGrath
Author: Katherine Davis
Author: Ana Gallego
Author: Piotr Laszczak
Author: Jinghua Tang ORCID iD
Author: Saeed Zahedi
Author: David Moser

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