TY - JOUR
T1 - A numerical study to analyse the risk for pressure ulcer development on a spine board
AU - Oomens, C.W.J.
AU - Zenhorst, W.
AU - Broek, M.
AU - Hemmes, B.
AU - Poeze, M.
AU - Brink, P.R.G.
AU - Bader, D.L.
PY - 2013
Y1 - 2013
N2 - Background: Spine boards are used to immobilise accident victims suspected of having spinal injury. Guidelines about the maximum time patients remain on the board are often exceeded and on occasions may lead to pressure ulcers. Etiological research has shown that two processes ultimately lead to pressure ulcers:"Ischemic damage" which takes several hours to initiate and "deformation damage" at high strains. The latter process is very quick and the first signs of cell damage are already evident within minutes. Thus in order to minimise the risk of pressure ulcer development during prolonged loading, a new soft-layered long spine board has been designed. Methods: A subject specific numerical approach has been adopted to evaluate the prototype spine board in comparison to a conventional spine board, with reference to the estimated strains in the soft tissues adjacent to the sacrum in the supine position. The model geometry is derived from magnetic resonance images of three human volunteers in an unloaded situation. The loaded images are used to "tune" the material parameters of skin, fat and muscle. The prediction of the deformed contours on the soft-layered board is used to validate the model. Findings: Comparison of the internal strains in muscle tissue near the spine showed that internal strains on the soft-layered board are reduced and maximum strains are considerably less than the threshold at which deformation damage is possible. By contrast, on the rigid spine board this threshold is exceeded in all cases. Interpretation: The prototype comfort board is able to reduce the risk for deformation damage and thus reduces the risk of developing pressure ulcers. (C) 2013 Elsevier Ltd. All rights reserved.
AB - Background: Spine boards are used to immobilise accident victims suspected of having spinal injury. Guidelines about the maximum time patients remain on the board are often exceeded and on occasions may lead to pressure ulcers. Etiological research has shown that two processes ultimately lead to pressure ulcers:"Ischemic damage" which takes several hours to initiate and "deformation damage" at high strains. The latter process is very quick and the first signs of cell damage are already evident within minutes. Thus in order to minimise the risk of pressure ulcer development during prolonged loading, a new soft-layered long spine board has been designed. Methods: A subject specific numerical approach has been adopted to evaluate the prototype spine board in comparison to a conventional spine board, with reference to the estimated strains in the soft tissues adjacent to the sacrum in the supine position. The model geometry is derived from magnetic resonance images of three human volunteers in an unloaded situation. The loaded images are used to "tune" the material parameters of skin, fat and muscle. The prediction of the deformed contours on the soft-layered board is used to validate the model. Findings: Comparison of the internal strains in muscle tissue near the spine showed that internal strains on the soft-layered board are reduced and maximum strains are considerably less than the threshold at which deformation damage is possible. By contrast, on the rigid spine board this threshold is exceeded in all cases. Interpretation: The prototype comfort board is able to reduce the risk for deformation damage and thus reduces the risk of developing pressure ulcers. (C) 2013 Elsevier Ltd. All rights reserved.
U2 - 10.1016/j.clinbiomech.2013.07.005
DO - 10.1016/j.clinbiomech.2013.07.005
M3 - Article
C2 - 23953331
SN - 0268-0033
VL - 28
SP - 736
EP - 742
JO - Clinical Biomechanics
JF - Clinical Biomechanics
IS - 7
ER -