Intramyocardial implantation of CD133+ stem cells improved cardiac function without bypass surgery.

INTRODUCTION: Cell transplantation for myocardial regeneration has been shown to have beneficial effects on cardiac function after myocardial infarction. Most clinical studies of intramyocardial cell transplantation were performed in combination with coronary artery bypass grafting (CABG). The contribution of implanted stem cells could yet not be clearly distinguished from the effect of the CABG surgery. Our current phase 1 clinical study has focused on the safety and feasibility of CD133+-enriched stem cell transplantation without CABG and its potential beneficial effect on cardiac function. METHOD AND RESULTS: Ten patients with end-stage chronic ischemic cardiomyopathy (ejection fraction <22%) were enrolled in the study. Bone marrow (up to 380 mL) was harvested from the iliac crest. CD133+ cells were purified from bone marrow cells using the CliniMACS device with purities up to 99%. Autologous bone marrow CD133+ cells (1.5-9.7 X 106 cells) were injected into predefined regions. Cardiac functions prior to and 3, 6, and 9 months after cell transplantation were assessed by cardiac magnetic resonance imaging. Stem cell transplantation typically improved the heart function stage from New York Heart Association/Canadian Cardiovascular Society class III-IV to I-II. The mean preoperative and postoperative ventricular ejection fractions were 15.8 +/- 5% and 24.8 +/- 5%, respectively. CONCLUSION: CD133+ injection into ischemic myocardium was feasible and safe. Stem cell transplantation alone improved cardiac function in all patients. This technique might hold promise as an alternative to medical management in patients with severe ischemic heart failure who are ineligible for conventional revascularization.

Intraoperative isolation and processing of BM-derived stem cells.

To improve tissue regeneration of ischemic myocardium, autologous bone marrow-derived stem cells have been injected intramyocardially in five patients undergoing coronary artery bypass grafting and transmyocardial laser revascularization. An innovative method for the intraoperative isolation of CD133(+)-stem cells in less than 3 hours has been established. After induction of general anesthesia, approx. 60-240 ml of bone marrow were harvested from the posterior iliac crest and processed in the operating room under GMP conditions using the automated cell selection device Clini-MACS. Following standard CABG surgery, LASER channels were shot in predefined areas within the hibernating myocardium. Subsequently, autologous CD133(+)-stem cells (1.9-9.7 x 10(6) cells; purity up to 97%) were injected in a predefined pattern around the laser channels. Through the intraoperative isolation of CD133(+)-cells, this effective treatment of ischemic myocardium can be applied to patients scheduled both for elective and for emergency revascularisation procedures.

Autologous bone marrow-derived stem cell therapy in combination with TMLR. A novel therapeutic option for endstage coronary heart disease: report on 2 cases.

We report 2 cases in which patients with coronary heart disease not amenable for conventional revascularization underwent transmyocardial laser revascularization (TMLR) and implantation of AC133+ bone-marrow stem cells. The reason for using TMLR in combination with stem cell application is to take advantage of the synergistic angiogenic effect. The local inflammatory reaction induced by TMLR should serve as an informational platform for stem cells and may trigger their angiogenic differentiation. Functional analysis of myocardial performance after treatment in these 2 cases revealed dramatic improvement of the wall motion at the site of the TMLR and stem cell application. Because TMLR does not enhance myocardial contractility and there was no angiographic evidence of major collaterals to the ischemic region in either patient, we assume that the synergistic effect of stem cells and TMLR-induced angiogenesis occurred; however, our assumption is of a speculative nature. We think that TMLR in combination with stem cell transplantation might become a novel revascularization therapy for ischemic myocardium.

Role of cytochrome P4502D6 in the metabolism of brofaromine. A new selective MAO-A inhibitor.

The metabolic fate of brofaromine (CGP 11 305 A), a new, reversible, selective MAO-A inhibitor, has been assessed in poor (PM) and extensive (EM) metabolizers of debrisoquine. Compared to EM, PM had significantly longer t1/2 (136%) and larger AUC(0-infinity) (110%) of the parent compound brofaromine and a lower Cmax (69%) and AUC (0-72 h) (40%) of its O-desmethyl metabolite. The mean metabolite/substrate ratio (based on urine excretion) was about 6-times greater in EM than in PM. Treatment with quinidine converted all EM into phenocopies of PM. All pharmacokinetic parameters of brofaromine and O-desmethyl-brofaromine in EM treated with quinidine were similar to those of untreated PM, including the metabolite/substrate ratio. Quinidine treatment of PM did not alter the pharmacokinetics of brofaromine or of its metabolite, nor the metabolite/substrate ratio. The results indicate a role for the debrisoquine type of oxidation polymorphism in the O-demethylation and pharmacokinetics of brofaromine.