3 . 2017

Skeletal muscle сirculatory support

Stephenson Larry

Abstract

From edition

The author is one of the most famous cardiovascular surgeons in the world, actively develops theoretical and experimental basis of circulatory support assisted by biological skeletal muscle ventricle. In this article the results of study of dynamic cardiomyoplasty, aortomyoplasty (counterpulsation) and skeletal muscle ventricle for the purpose of organ-preserving surgical cardiomyopathy treatment in long-term experiment in animals are represented. A review of current clinical experience and long-term results of cardiomyoplasty usage is also given.

Keywords:cardiomyopathies, heart failure, dynamic cardiomyoplasty, skeletal muscle ventricle

Clin. Experiment. Surg. Petrovsky J. 2017; 5 (3): 71–80.

Received: 20.06.2017. Accepted: 07.07.2017.

References

1. Carpentier A., Chachques J.C. Myocardial substitution with a stimulated skeletal muscle: First successful clinical case. Lancet. 1985; 1: 1267.

2. Stephenson L.W. Invited commentary on: dynamic cardiomyoplasty: long-term outcomes. Ann Thorac Surg. 2003; 76: 821-7.

3. Chachques J.C., Jegaden.O., Mesana.T., Glock Y., Grandjean.P., Carpentier.A. Cardiac Bioassist: results of the French multicenter cardiomyoplasty study. Asian Cardiovasc Thorac Ann. 2009; 17: 573-80.

4. Chachques J.C., Radermecker M., Grandjean P., et al. Dynamic aortomyoplasty for long-term circulatory support: experimental studies and clinical experience. In: Carpentier A.F., Chachques J.C., Grandjean P.A., eds. Cardiac Bioassist. Armonk, NY: Futura Publishing Co., 1997: 488.

5. Mannion J.D., Bitto T. Hammond R.L., et al. Histochemical fatigue characteristics of conditioned canine latissimus dorsi mus- cle. Circ Res. 1986; 58: 298-304.

6. Mannion J.D., Hammond R.L., Stephenson L.W. Canine latissimus dorsi hydraulic pouches. Potential for left ventricular assistance. J Thorac Cardiovasc Surg. 1986; 91: 534-44.

7. Mannion J.D., Acker M.A., Hammond R.L., Stephenson L.W. Four-hour circulatory assistance with canine skeletal muscle ventricles. Surg Forum. 1986; 27: 211-3.

8. Acker M.S., Hammond R.L., Mannion J.D., et al. An autologous biologic pump motor. J Thorac Cardiovasc Surg. 1986; 92: 733-46.

9. Mocek F.W., Anderson D.R., Pocchetino A., et al. Skeletal muscle ventricles in circulation long-term: 191 to 836 days. J Heart Lung Transplant. 1992; 11: S334-40.

10. Thomas G.A., Lu H., Isoda S., et al. Skeletal muscle ventricles in circulation: decreased incidence of rupture. Ann Thorac Surg. 1996; 61: 430-6.

11. Thomas G.A., Hammond R.L., Greer K.A., et al. Functional assessment of skeletal muscle ventricles after pumping for up to four years in circulation. Ann Thorac Surg. 2000; 70: 1281-90.

12. Thomas G.A., Lelkes P.I., Chick D.M.C., et al. Skeletal muscle ventricles seeded with autologous endothelium. ASAIO J. 1995; 41: 204-11.

13. Thomas G.A., Lelkes P.I., Chick D.M., et al. Endothelial- lined skeletal muscle ventricles: open and percutaneous techniques. J Card Surg. 1995; 10: 245-56.

14. Thomas G.A., Lelkes P.I., Chick D.M., et al. Endothelial-lined skeletal muscle ventricles in circulation. J Thorac Cardiovasc Surg. 1995; 109: 66-73.

15. Thomas G.A., Lu H., Isoda S., et al. Pericardial-lined skeletal muscle ventricles in circulation up to 589 days. Ann Thorac Surg. 1994; 58: 978-88.

16. Patel B.G., Shah S.H., Astra L.I., et al. Skeletal muscle ventricle aortic counterpulsation: function during chronic heart failure. Ann Thorac Surg. 2002; 73 (2): 588-93.

17. Guldner N.W., Klapproth P., Zimmerman H., Sievers, H. Sketetal muscle ventricles (SMVs) and biomechanical hearts (BMHs) with a self-endothelializing titanized blood contacting surface. In: Tissue engineering and regenerative medicine by Andrades JA, intechopen.com, open access ccby 3.0, license pub May 22, 2013 pp 4-35.(www.intechopen.com/books/regenerative medicine-and-tissue-engineering/skeletal-....accessed June 22, 2017.)

18. Hooper T.L., Niinami H., Lu H., et al. Skeletal muscle ven- tricles as left atrial-aortic pumps: short-term studies. Ann Thorac Surg. 1992; 54: 316-22.

19. Platt K.L., Moore T.W., Barnea O. Performance optimization of left ventricular assistance: a computer model study. ASAIO J. 1993; 39: 29-38.

20. Thomas G.A., Stephenson L.W.: Update on skeletal muscle ventricles: Left ventricular apex to aorta configuration. Ann Thorac Surg. 71: 1736-7, 2001.

21. Lu H., Fietsam R., Hammond R.L., et al. Skeletal muscle ventricles: left ventricular apex-to-aorta configuration. Ann Thorac Surg. 1993; 55: 78-85.

22. Stevens L., Badylak S.F., Janas W., et al. A skeletal muscle ventricle made from rectus abdominis muscle in the dog. J Surg Res. 1989; 46: 84-9.

23. Thomas G.A., Baciewicz F.A., Hammond R.L., Greer K.A., Lu H., Bastian S., Jindal P., Stephenson L.W. Power output of pericardium-lined skeletal muscle ventricles, left ventricular apex to aorta configuration: up to 8 months in circulation. J Thorac Cardiovasc Surg. 1998; 116: 1029-42.

24. Bridges C.R., Anderson W.A., Hammond R.L., et al. Functional right heart replacement with skeletal muscle. Circulation.1989; 80 (5pt.2): III-183-91.

25. Niinami H., Hooper T.L., Hammond R.L., et al. A new configuration for right ventricular assist with a skeletal muscle ventricle: short-term studies. Circulation. 1991; 84: 2470-5.

26. Niinami H., Hooper T.L., Hammond R.L., et al. Skeletal muscle ventricles in the pulmonary circulation: up to sixteen weeks’ experience. Ann Thorac Surg. 1992; 53: 750-7.

27. Magovern G.J., Sr., Simpson K.A.. Clinical cardiomyoplasty: review of the ten-year United States experience. Ann Thorac Surg. 1996; 61 (1): 413-9.