Active multilayered capsules for in vivo bone formation.

Interest in the development of new sources of transplantable materials for the treatment of injury or disease has led to the convergence of tissue engineering with stem cell technology. Bone and joint disorders are expected to benefit from this new technology because of the low self-regenerating capacity of bone matrix secreting cells. Herein, the differentiation of stem cells to bone cells using active multilayered capsules is presented. The capsules are composed of poly-L-glutamic acid and poly-L-lysine with active growth factors embedded into the multilayered film. The bone induction from these active capsules incubated with embryonic stem cells was demonstrated in vitro. Herein, we report the unique demonstration of a multilayered capsule-based delivery system for inducing bone formation in vivo. This strategy is an alternative approach for in vivo bone formation. Strategies using simple chemistry to control complex biological processes would be particularly powerful, as they make production of therapeutic materials simpler and more easily controlled.

RXRalpha overexpression in cardiomyocytes causes dilated cardiomyopathy but fails to rescue myocardial hypoplasia in RXRalpha-null fetuses.

Retinoid X receptor alpha-null (RXRalpha-null) mutants exhibit hypoplasia of their ventricular myocardium and die at the fetal stage. In the present study, we wished to determine whether transgenic re-expression of RXRalpha in mutant cardiac myocytes could rescue these defects. Two transgenic mouse lines specifically overexpressing an RXRalpha protein in cardiomyocytes were generated, using the cardiac alpha-myosin heavy chain (alpha-MHC) promoter. Breeding the high copy number transgenic line onto an RXRalpha-null genetic background did not prevent the myocardial hypoplasia and fetal lethality associated with the RXRalpha(-/-) genotype, even though the transgene was expressed in the ventricles as early as 10. 5 days post-coitum. These data suggest that the RXRalpha function involved in myocardial growth may correspond to a non-cell-autonomous requirement forsignal orchestrating the growth and differentiation of myocytes. Interestingly, the adult transgenic mice developed a dilated cardiomyopathy, associated with myofibrillar abnormalities and specific deficiencies in respiratory chain complexes I and II, thus providing an additional model for this genetically complex disease.