Investigating the effects of cervical collar design and fit on the biomechanical and biomarker reaction at the skin
Investigating the effects of cervical collar design and fit on the biomechanical and biomarker reaction at the skin
Research has shown that up to 33% of pressure ulcers (PUs) acquired in hospitals result from the application of a medical device. Cervical collars (C-collars) have been implicated in causing PUs, due to the mechanical force they apply to the skin. In order to improve our understanding of collar related PUs, the present study aimed to assess the biomechanical, biochemical and microclimate effects of C-collar design and fitting tension.
A cohort of 15 healthy volunteers were fitted with two different C-collars according to the manufacturer guidelines. Two further collar tensions were also defined as loose and tight for each device. Each collar condition was applied for 15 minutes, with a 10 minute refractory period. Measurements at the device-skin interface included interface pressures, inflammatory biomarkers, microclimate, range of cervical motion and comfort scores.
The interface pressures at each tissue site increased monotonically with greater collar tension (p<0.01), irrespective of collar design. Biomarker analysis revealed that inflammatory cytokines (IL-1a) were elevated during collar application, with the highest increase during the tight fit condition, representing over a 4-fold increase from unloaded conditions. Regardless of collar tension or type, there as an increase in temperature 1.5±0.8°C compared to baseline values. Range of motion significantly decreased with greater strap tension (p<0.05), with an associated increase in discomfort.
The present findings revealed that increasing C-collar tensions caused elevated contact pressures at the device-skin interface, with a corresponding inflammatory response at the skin. These peak contact pressures were highest at the occiput, corresponding with reported PU locations. Devices should be designed to uniformly distribute pressures and appropriate guidance is needed for their application.
Worsley, Peter
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Stanger, Nathan D.
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Horrell, Aran K.
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Bader, Dan L.
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Worsley, Peter
6d33aee3-ef43-468d-aef6-86d190de6756
Stanger, Nathan D.
1145f5bb-8d4e-4f34-bd94-f227560cf4e5
Horrell, Aran K.
05113a8f-9488-4d3a-8894-fe005c2768c0
Bader, Dan L.
9884d4f6-2607-4d48-bf0c-62bdcc0d1dbf
Worsley, Peter, Stanger, Nathan D., Horrell, Aran K. and Bader, Dan L.
(2018)
Investigating the effects of cervical collar design and fit on the biomechanical and biomarker reaction at the skin.
Medical Devices Evidence and Research.
(doi:10.2147/MDER.S149419).
Abstract
Research has shown that up to 33% of pressure ulcers (PUs) acquired in hospitals result from the application of a medical device. Cervical collars (C-collars) have been implicated in causing PUs, due to the mechanical force they apply to the skin. In order to improve our understanding of collar related PUs, the present study aimed to assess the biomechanical, biochemical and microclimate effects of C-collar design and fitting tension.
A cohort of 15 healthy volunteers were fitted with two different C-collars according to the manufacturer guidelines. Two further collar tensions were also defined as loose and tight for each device. Each collar condition was applied for 15 minutes, with a 10 minute refractory period. Measurements at the device-skin interface included interface pressures, inflammatory biomarkers, microclimate, range of cervical motion and comfort scores.
The interface pressures at each tissue site increased monotonically with greater collar tension (p<0.01), irrespective of collar design. Biomarker analysis revealed that inflammatory cytokines (IL-1a) were elevated during collar application, with the highest increase during the tight fit condition, representing over a 4-fold increase from unloaded conditions. Regardless of collar tension or type, there as an increase in temperature 1.5±0.8°C compared to baseline values. Range of motion significantly decreased with greater strap tension (p<0.05), with an associated increase in discomfort.
The present findings revealed that increasing C-collar tensions caused elevated contact pressures at the device-skin interface, with a corresponding inflammatory response at the skin. These peak contact pressures were highest at the occiput, corresponding with reported PU locations. Devices should be designed to uniformly distribute pressures and appropriate guidance is needed for their application.
Text
Investigating the Effects of Cervical Collar Design and Fit on the Biomechanical and Biomarker Reaction at the Skin
- Accepted Manuscript
More information
Accepted/In Press date: 15 November 2017
e-pub ahead of print date: 15 March 2018
Identifiers
Local EPrints ID: 417845
URI: http://eprints.soton.ac.uk/id/eprint/417845
ISSN: 1179-1470
PURE UUID: 71b93e12-ffbf-477f-9c66-77baba7a3fda
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Date deposited: 15 Feb 2018 17:30
Last modified: 16 Mar 2024 03:58
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Author:
Nathan D. Stanger
Author:
Aran K. Horrell
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