The Immature Heart: The Roles of Bone Marrow Stromal Stem Cells in Growth and Myocardial Repair

Studies have shown that adult bone marrow derived stem cells (MSCs) can participate in repair of myocardial injury in adult hearts, as well as in cardiac growth during fetal development in utero. Yet, no studies have evaluated the role of MSCs with respect to normal growth or tissue repair in immature hearts after birth. The present study examines whether MSCs may participate in the myocardial growth and injury in the post-natal immature hearts. MSCs were isolated from adult Lewis rats and labeled with Lac-Z gene using retroviral vectors. These MSCs were injected systemically into groups of neonatal (NB=2days-old), immature (B=30days-old) and adult (A=>3months-old) isogeneic Lewis rats. Additionally, left coronary artery ligation was carried out in subgroups of immature (BL) and adult (AL) rats one week after MSCs injection. The hearts were harvested serially from 2-days to 6-weeks, stained with X-Gal for labeled MSCs. Cardiomyocyte phenotypic expression was evaluated by immunohistological staining for Troponin I-C and Connexin-43. Labeled MSCs were found to home into the bone marrow in all rats of different developmental stages. They could be recruited from bone marrow into the infarcted site of myocardium only in groups AL and BL. They were also capable of differentiating into cardiomyocyte phenotype after myocardial injury. In contrast to that reported in the developing fetus, MSCs did not appear to contribute to the growth of non-injured hearts after birth. However, they can be recruited from the bone marrow and regenerate damaged myocardium both in the adult and in the immature hearts

Cellular Cardiomyoplasty: Myocardial Regeneration With Satellite Cell Implantation

Background.: Damaged skeletal muscle is able to regenerate because of the presence of satellite cells, which are undifferentiated myoblasts. In contrast, destruction of cardiac myocytes is associated with an irreversible loss of myocardium and replacement with scar tissue, because it lacks stem cells. We tested the hypothesis that skeletal muscle satellite cells implanted into injured myocardium can differentiate into cardiac muscle fibers and thus repair damaged heart muscle. Methods.: Two series of canine studies were performed. In the first series (n = 26), satellite cells were isolated from skeletal muscle, cultured, and labeled with tritiated thymidine. The cells were implanted into acutely cryoinjured myocardium and the specimens harvested 4 to 18 weeks later. In the second series (n = 20), satellite cells in culture were labeled with lacZ reporter gene, which encodes production of Escherichia coli β-galactosidase. Four to 6 weeks later, β-galactosidase activity was studied using X-Gal stain. Results.: New striated muscles were found in the first series of experiments at the site of implantation, within a dense scar created by cryoinjury. These muscles showed histologic evidence of intercalated discs and centrally located nuclei, similar to those seen in cardiac muscle fibers. Tritiated thymidine radioactivity was not identified clearly, presumably due to dilutional effect as the stem cells replicated repeatedly. In the second series, histochemical studies of reporter gene-labeled and implanted satellite cells revealed the presence of β-galactosidase within the cells at the implant site, which confirmed the survival of implanted cells. Conclusions.: Our data are consistent with the hypothesis of milieu-influenced differentiation of satellite cells into cardiac-like muscle cells. Confirmation of these findings and its functional capabilities could have important clinical implications

Second Primary Bronchogenic Carcinoma: Life-Table Analysis of Surgical Treatment

Twelve patients had curative resection of primary bronchogenic carcinoma. Eleven to 84 months later, a second primary bronchogenic carcinoma was discovered and was operated on. Six patients underwent wedge resection, while the others had a lobectomy or pneumonectomy. There was no operative mortality. Two patients survived longer than 5 years. In addition to these patients, 26 patients who also had successive surgical resections for primary lung cancers were collected from the literature. Two operative deaths were related to respiratory insufficiency. Life-table analysis of this accumulated series of 38 patients revealed the survival rate 1 year after the resection of a second tumor to be 70%, and 2 and 3 years later, 55% and 27%, respectively. Thus, in patients in whom a second primary carcinoma of the lung develops, successive resections tailored to preserve respiratory reserve are compatible with low operative mortality and, in some instances, long-term survival

Cell Transplantation for Myocardial Repair: An Experimental Approach

Myocardium lacks the ability to regenerate following injury. This is in contrast to skeletal muscle (SKM), in which capacity for tissue repair is attributed to the presence of satellite cells. It was hypothesized that SKM satellite cells multiplied in vitro could be used to repair injured heart muscle. Fourteen dogs underwent explantation of the anterior tibialis muscle. Satellite cells were multiplied in vitro and their nuclei were labelled with tritiated thymidine 24 h prior to implantation. The same dogs were then subjected successfully to a myocardial injury by the application of a cryoprobe. The cells were suspended in serum-free growth medium and autotransplanted within the damaged muscle. Medium without cells was injected into an adjacent site to serve as a control. Endpoints comprised histology using standard stains as well as Masson trichrome (specific for connective tissue), and radioautography. In five dogs, satellite cell isolation, culture, and implantation were technically satisfactory. In three implanted dogs, specimens were taken within 6-8 wk. There were persistence of the implantation channels in the experimental sites when compared to the controls. Macroscopically, muscle tissue completely surrounded by scar tissue could be seen. Masson trichrome staining showed homogeneous scar in the control site, but not in the test site where a patch of muscle fibres containing intercalated discs (characteristic of myocardial tissue) was observed. In two other dogs, specimens were taken at 14 wk postimplantation. Muscle tissue could not be found. These preliminary results could be consistent with the hypothesis that SKM satellite cells can form neo-myocardium within an appropriate environment. Our specimens failed to demonstrate the presence of myocyte nuclei. It is therefore further hypothesized that in the late postoperative period, the muscle regenerate failed to survive