Cell-Based Cardiac Repair

Abstract

Received February 28, 2005; revision received April 25, 2005; accepted April 29, 2005. It has now been more than a decade since the first experiments were performed using cell transplantation for the prevention and treatment of heart failure.1–3 Although the biomedical community was initially somewhat skeptical of this approach, a large body of experimental evidence was amassed showing that injected cells could create new tissue and improve function of the failing heart. This evidence, coupled with the recognized limitations of heart failure treatments and the intuitively appealing concept of “regenerative medicine,” has contributed to a crescendo of activity in cell-based cardiac repair. Given the flurry of clinical trials that are currently under way, we think it is timely to review progress over the past 10 years and provide a critical assessment of where the field stands and where it appears to be headed. Cell-based cardiac repair began with studies of skeletal myoblasts derived from skeletal muscle satellite cells.1–3 Myoblasts were the initial choice because of their availability from autologous or syngeneic sources, their ability to proliferate, and their ability to withstand ischemia better than many cell types. Although it was originally hoped that these cells would transdifferentiate into cardiomyocytes, it is now clear that myoblasts remain stubbornly committed to form mature skeletal muscle in the heart3–5 (with the exception of rare cell fusion events at the graft–host interface6). Skeletal muscle is one of the few cell types in the body that does not normally express gap junction proteins, and hence, structural and physiological studies indicate that skeletal muscle cells do not form electromechanical junctions with cardiomyocytes when engrafted into the heart.7,8 Despite this, numerous studies have shown beneficial effects of skeletal myoblast grafting into the infarcted heart in rodents and large animals.8–13 Cardiomyocytes would …