OBJECTIVE: A key challenge to applying cell transplantation to treat severely damaged myocardium is in delivering large numbers of cells with minimum cell loss. We developed a new implantation method using skeletal myoblast (SMB) sheets, wrapped with an omentum flap as a blood supply to deliver huge numbers of SMBs to the damaged heart. We examined whether this method could be used to deliver a large amount of cells to deteriorated porcine myocardium. METHODS: Cell sheets were obtained by culturing mini-pig autologous SMB cells on temperature-responsive culture dishes. Myocardial infarction was induced by placing an ameroid constrictor around the left anterior descending artery. The mini-pigs were divided into 4 treatment groups (n = 6 in each): cell sheets with omentum, cell sheets only, omentum only, and sham operation. Each animal implant consisted of 30 cell sheets (1.5 × 10(7) cells per sheet). Six 5-layer constructs were each placed on a different area, immediately adjacent to but not overlapping one another, to cover the infarct and border regions. RESULTS: The new regenerative cell delivery system using SMB sheets covered and wrapped with omentum resulted in (1) a significantly reduced infarct size causing, at least in part, a thin scar with thick well-vascularized cardiac tissue; (2) increased angiogenesis, as determined by a significantly higher vascular density; and (3) improved cardiac function, as determined by echocardiography, compared with the conventional method (SMB sheet implantation). CONCLUSIONS: This cell delivery system shows potential for repairing the severely failed heart.
OBJECTIVE: A key challenge to applying cell transplantation to treat severely damaged myocardium is in delivering large numbers of cells with minimum cell loss. We developed a new implantation method using skeletal myoblast (SMB) sheets, wrapped with an omentum flap as a blood supply to deliver huge numbers of SMBs to the damaged heart. We examined whether this method could be used to deliver a large amount of cells to deteriorated porcine myocardium. METHODS: Cell sheets were obtained by culturing mini-pig autologous SMB cells on temperature-responsive culture dishes. Myocardial infarction was induced by placing an ameroid constrictor around the left anterior descending artery. The mini-pigs were divided into 4 treatment groups (n = 6 in each): cell sheets with omentum, cell sheets only, omentum only, and sham operation. Each animal implant consisted of 30 cell sheets (1.5 × 10(7) cells per sheet). Six 5-layer constructs were each placed on a different area, immediately adjacent to but not overlapping one another, to cover the infarct and border regions. RESULTS: The new regenerative cell delivery system using SMB sheets covered and wrapped with omentum resulted in (1) a significantly reduced infarct size causing, at least in part, a thin scar with thick well-vascularized cardiac tissue; (2) increased angiogenesis, as determined by a significantly higher vascular density; and (3) improved cardiac function, as determined by echocardiography, compared with the conventional method (SMB sheet implantation). CONCLUSIONS: This cell delivery system shows potential for repairing the severely failed heart.
Authors: Yasuhiro Shudo; Jeffrey E Cohen; John W MacArthur; Andrew B Goldstone; Satoru Otsuru; Alen Trubelja; Jay Patel; Bryan B Edwards; George Hung; Alexander S Fairman; Christopher Brusalis; William Hiesinger; Pavan Atluri; Arudo Hiraoka; Shigeru Miyagawa; Yoshiki Sawa; Y Joseph Woo Journal: Tissue Eng Part A Date: 2015-09-18 Impact factor: 3.845
Authors: Shera Lilyanna; Eliana C Martinez; Thang D Vu; Lieng H Ling; Shu U Gan; Ai L Tan; Thang T Phan; Theo Kofidis Journal: Tissue Eng Part A Date: 2013-02-28 Impact factor: 3.845