Objective: Starting from results of studies made in the last ten years about the presence of myofibroblasts as the main cells involved into fibro-contractile disease, we investigated if this cells were also involved into pathogenesis of club foot deformities. Methods: Specimens removed surgically from five patients affected by congenital club foot were investigated. Each specimen was cut in three parts: the first, was fixed for optical microscopy in formalin; the second was fixed for trasmission electron microscopy (TEM) in glutaraldehyde and postfixed in osmium tetroxide; the third was immediately placed in cold (4°C) tissue culture medium. We have stained the first part of each specimen with: haematoxylineosin, Pasini, Masson, Congo red, Van Gieson, Martius scarlet blue and immunostaining for a-smooth muscle actin (a-SM actin). The third part of each specimen, dissected into 2mm. cubes, was place in standard medium and cultured at 37°C. On the cultured cells, we have valued metalloproteinases and a-SM actin expressions. Moreover, a part of culture cells, when reached confluence, were detached with trypsin-EDTA and centrifuged for 10 min. at 2000 rpm. to obtain a pellet, subsequently fixed for TEM. Results: Optical and electron microscopy have showed, only in one of our cases, the presence of myofibroblast’s clusters in the Henry’s nodule and in the medial and lateral fibrous nodules, that are characteristic nodule of congenital club foot. Conclusions: Starting from the results of our studies, we would like to study in detail the role of myofibroblast in the pathogenesis of club foot.
Objective: Bone marrow stromal cells (BMSC) represent an interesting target for novel strategies in the gene and cell therapy of skeletal pathologies, involving BMSC in vitro expansion/transfection and reinfusion. Materials and Methods: Stromal cells were obtained from healthy donors. For the first 2 weeks, culture medium was supplemented only with human recombinant fibroblast growth factor 2 (FGF-2) to promote cell proliferation and maintain cells in a more immature state. Confluent cultures were detached with trypsin-EDTA. Cells were replated for the in vitro differentiation experiments and for determination of BMSC growth kinetics. Cultures were stimulated with appropriate inductive media and the chondro-/osteo-/adipo-diferentiations were tested by staining with alizarin red, alcian blue, Sudan black and by immunostaining for osteocalcina or collagen II. Results: After the first passage, BMSC had a markedly diminish proliferation rate and gradually lost their multiple differentiation potential. Their bone-forming efficiency in vivo was reduced by about 36 times at first confluence as compared to fresh bone marrow. Conclusion: Culture expansion causes BMSC gradually to lose their early progenitor properties. Both the duration and the conditions of culture could be crucial to successful clinical use of these cells and must be considered when designing novel therapeutic strategies involving stromal mesenchymal progenitor manipulation and reinfusion. There are numerous potential applications of this novel strategy, for example: reconstruction of extensive long-bone defects, osteochondral defect repair, treatment of bone cyst, bioactivable scaffolds, etc.
