TY - JOUR
T1 - Development and validation of an improved mechanical thorax for simulating cardiopulmonary resuscitation with adjustable chest stiffness and simulated blood flow
AU - Eichhorn, Stefan
AU - Spindler, Johannes
AU - Polski, Marcin
AU - Mendoza, Alejandro
AU - Schreiber, Ulrich
AU - Heller, Michael
AU - Deutsch, Marcus Andre
AU - Braun, Christian
AU - Lange, Rüdiger
AU - Krane, Markus
N1 - Publisher Copyright:
© 2017 IPEM
PY - 2017/5/1
Y1 - 2017/5/1
N2 - Investigations of compressive frequency, duty cycle, or waveform during CPR are typically rooted in animal research or computer simulations. Our goal was to generate a mechanical model incorporating alternate stiffness settings and an integrated blood flow system, enabling defined, reproducible comparisons of CPR efficacy. Based on thoracic stiffness data measured in human cadavers, such a model was constructed using valve-controlled pneumatic pistons and an artificial heart. This model offers two realistic levels of chest elasticity, with a blood flow apparatus that reflects compressive depth and waveform changes. We conducted CPR at opposing levels of physiologic stiffness, using a LUCAS device, a motor-driven plunger, and a group of volunteers. In high-stiffness mode, blood flow generated by volunteers was significantly less after just 2 min of CPR, whereas flow generated by LUCAS device was superior by comparison. Optimal blood flow was obtained via motor-driven plunger, with trapezoidal waveform.
AB - Investigations of compressive frequency, duty cycle, or waveform during CPR are typically rooted in animal research or computer simulations. Our goal was to generate a mechanical model incorporating alternate stiffness settings and an integrated blood flow system, enabling defined, reproducible comparisons of CPR efficacy. Based on thoracic stiffness data measured in human cadavers, such a model was constructed using valve-controlled pneumatic pistons and an artificial heart. This model offers two realistic levels of chest elasticity, with a blood flow apparatus that reflects compressive depth and waveform changes. We conducted CPR at opposing levels of physiologic stiffness, using a LUCAS device, a motor-driven plunger, and a group of volunteers. In high-stiffness mode, blood flow generated by volunteers was significantly less after just 2 min of CPR, whereas flow generated by LUCAS device was superior by comparison. Optimal blood flow was obtained via motor-driven plunger, with trapezoidal waveform.
KW - Blood flow
KW - Mechanical thorax model
KW - Resuscitation
KW - Thorax stiffness
UR - http://www.scopus.com/inward/record.url?scp=85013654437&partnerID=8YFLogxK
U2 - 10.1016/j.medengphy.2017.02.005
DO - 10.1016/j.medengphy.2017.02.005
M3 - Article
C2 - 28242180
AN - SCOPUS:85013654437
SN - 1350-4533
VL - 43
SP - 64
EP - 70
JO - Medical Engineering and Physics
JF - Medical Engineering and Physics
ER -