TY - JOUR
T1 - Novel para-aortic cardiac assistance using a pre-stretched dielectric elastomer actuator
AU - Jahren, Silje Ekroll
AU - Martinez, Thomas
AU - Walter, Armando
AU - Clavica, Francesco
AU - Heinisch, Paul Philipp
AU - Buffle, Eric
AU - Luedi, Markus Martin
AU - Hörer, Jürgen
AU - Obrist, Dominik
AU - Carrel, Thierry
AU - Civet, Yoan
AU - Perriard, Yves
N1 - Publisher Copyright:
© The Author(s) 2024. Published by Oxford University Press on behalf of the European Association for Cardio-Thoracic Surgery.
PY - 2024/3/1
Y1 - 2024/3/1
N2 - OBJECTIVES: We propose an evolution of a dielectric elastomer actuator-based cardiac assist device that acts as a counterpulsation system. We introduce a new pre-stretched actuator and implant the device in a graft bypass between the ascending and descending aorta to redirect all blood through the device (ascending aorta clamped). The objective was to evaluate the influence of these changes on the assistance provided to the heart. METHODS: The novel para-aortic device and the new implantation technique were tested in vivo in 5 pigs. We monitored the pressure and flow in the aorta as well as the pressure-volume characteristics of the left ventricle. Different activation timings were tested to identify the optimal device actuation. RESULTS: The proposed device helps reducing the end-diastolic pressure in the aorta by up to 13 ± 4.0% as well as the peak systolic pressure by up to 16 ± 3.6%. The early diastolic pressure was also increased up to 10 ± 3.5%. With different activation, we also showed that the device could increase or decrease the stroke volume. CONCLUSIONS: The new setup and the novel para-aortic device presented here helped improve cardiac assistance compared to previous studies. Moreover, we revealed a new way to assist the heart by actuating the device at different starting time to modify the left ventricular stroke volume and stroke work.
AB - OBJECTIVES: We propose an evolution of a dielectric elastomer actuator-based cardiac assist device that acts as a counterpulsation system. We introduce a new pre-stretched actuator and implant the device in a graft bypass between the ascending and descending aorta to redirect all blood through the device (ascending aorta clamped). The objective was to evaluate the influence of these changes on the assistance provided to the heart. METHODS: The novel para-aortic device and the new implantation technique were tested in vivo in 5 pigs. We monitored the pressure and flow in the aorta as well as the pressure-volume characteristics of the left ventricle. Different activation timings were tested to identify the optimal device actuation. RESULTS: The proposed device helps reducing the end-diastolic pressure in the aorta by up to 13 ± 4.0% as well as the peak systolic pressure by up to 16 ± 3.6%. The early diastolic pressure was also increased up to 10 ± 3.5%. With different activation, we also showed that the device could increase or decrease the stroke volume. CONCLUSIONS: The new setup and the novel para-aortic device presented here helped improve cardiac assistance compared to previous studies. Moreover, we revealed a new way to assist the heart by actuating the device at different starting time to modify the left ventricular stroke volume and stroke work.
KW - Cardiac assist device
KW - Counterpulsation
KW - Dielectric elastomer actuator
KW - in vivo experiment
UR - http://www.scopus.com/inward/record.url?scp=85188546519&partnerID=8YFLogxK
U2 - 10.1093/icvts/ivae027
DO - 10.1093/icvts/ivae027
M3 - Article
AN - SCOPUS:85188546519
SN - 1569-9285
VL - 38
JO - Interdisciplinary Cardiovascular and Thoracic Surgery
JF - Interdisciplinary Cardiovascular and Thoracic Surgery
IS - 3
M1 - ivae027
ER -