Using skeletal muscle as an endogenous power source is an attractive approach to long-term cardiac assistance. The principle advantage of this technique over current methods is that it obviates the need for extracorporeal power sources and provides a reliable, low-cost, self- sustaining source of energy without immune compromise or loss of patient autonomy. The applicants' long-range goal is to develop a safe and reliable means to harness energy from electrically stimulate skeletal muscle in order to assist the failing heart. The objective of this application is to assemble and test (in unrestrained, conscious dugs) a prototype ventricular assist system powered by linear in situ skeletal muscle contractions. The central hypotheses to be tested is that the mechanical power of conditioned skeletal muscle can be converted into hydraulic energy at levels sufficient to drive a ventricular assist devise, in particular, on the basis of preliminary studies, skeletal muscle conditioned via long-term electrical stimulation is expected to yield roughly 2.0 mW per gram of muscle without fatigue-enough to provide substantial cardiac support. The rationale behind the proposed research centers on the fact that skeletal muscles express oxidative (fatigue-resistant) phenotypes in response to chronic activation and that these muscles have been shown to perform work at rates compatible with long-term cardiac assistance. Therefore, given the limitations of current medical therapies for congestive heart failure and the difficulties associated with delivering extracorporeal power to aid the failing heart, research to develop and test a muscle-powered blood pump is warranted. To accomplish the objectives of this research, the following three specific aims are proposed: 1) Optimize the performance, durability, and biocompatibility of a muscle energy converter (MEC) designed to transform linear muscle contractions into hydraulic energy; 2) quantify MEC efficiency and steady-state power output in vivo and assess the physiologic adaptations which occur in skeletal muscle contracting under conditions of chronic circulatory support; and 3) assemble, bench-test, and implant a complete muscle-actuated ventricular assist system compatible with the steady-state power levels measured during MEC implant studies. Upon the conclusion of this research, the applicants expect to have definitively established the steady-state work capacity of electro-stimulated skeletal muscle and for the first time demonstrated the viability of harnessing energy from in situ muscle over prolonged periods. The applicants further expect that practical application of this technology will have been demonstrated via implant testing of a complete muscle-actuated ventricular assist system.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
1R01HL059896-01A1
Application #
6011504
Study Section
Surgery and Bioengineering Study Section (SB)
Project Start
1999-08-01
Project End
2003-07-30
Budget Start
1999-08-01
Budget End
2000-07-30
Support Year
1
Fiscal Year
1999
Total Cost
Indirect Cost
Name
Allegheny-Singer Research Institute
Department
Type
DUNS #
033098401
City
Pittsburgh
State
PA
Country
United States
Zip Code
15212
Trumble, Dennis R; Melvin, David B; Dean, David A et al. (2008) In vivo performance of a muscle-powered drive system for implantable blood pumps. ASAIO J 54:227-32
Trumble, Dennis R; Melvin, David B; Byrne, Mark T et al. (2005) Improved mechanism for capturing muscle power for circulatory support. Artif Organs 29:691-700
Trumble, Dennis R; Magovern, James A (2003) Capturing in situ skeletal muscle power for circulatory support: a new approach to device design. ASAIO J 49:480-5
Trumble, Dennis R; Melvin, David B; Magovern, James A (2002) Method for anchoring biomechanical implants to muscle tendon and chest wall. ASAIO J 48:62-70
Trumble, Dennis R; Magovern, James A (2002) Muscle-powered mechanical blood pumps. Science 296:1967; author reply 1967
Trumble, D R; Magovern, J A (2001) Method for measuring long-term function of muscle-powered implants via radiotelemetry. J Appl Physiol 90:1977-85