Fetal stem cells and skeletal muscle regeneration: a therapeutic approach

Fetal progenitor cells for treatment of chronic limb ischemia

OBJECTIVES

This study investigated the therapeutic potential of fetal progenitor cells (FPCs) in the treatment of chronic non-healing wounds and ulcers associated with chronic limb ischemia (CLI). The research aimed to elucidate the mechanism of action of FPCs and evaluate their efficacy and safety in CLI patients.

METHODS

The researchers isolated FPCs from aborted human fetal liver, brain, and skin tissues and thoroughly characterized them. The preclinical phase of the study involved assessing the effects of FPCs in a rat model of CLI. Subsequently, a randomized controlled clinical trial was conducted to compare the efficacy of FPCs with standard treatment and autologous bone marrow mononuclear cells in CLI patients. The clinical trial lasted 12 months, with a follow-up period of 24-36 months. The primary outcomes included wound healing, frequency of major and minor amputations, pain reduction, and the incidence of complications. Secondary outcomes involved changes in local hemodynamics and histological, ultrastructural, and immunohistochemical assessments of angiogenesis.

RESULTS

In the animal model, FPC treatment significantly enhanced angiogenesis and accelerated healing of ischemic wounds compared to controls. The clinical trial in CLI patients demonstrated that the FPC therapy achieved substantially higher rates of complete wound closure, prevention of major amputation, pain reduction, and improvement in ankle-brachial index compared to control groups. Notably, the study reported no serious adverse events.

CONCLUSIONS

FPC therapy exhibited remarkable efficacy in promoting the healing of ischemic wounds, preventing amputation, and improving symptoms and quality of life in patients with CLI. The proangiogenic and provasculogenic effects of FPCs may be attributed to their ability to secrete specific growth factors. These findings provide new insights into the development of cellular therapeutic angiogenesis as a promising approach for the treatment of peripheral arterial diseases.

Extracellular Matrix-Derived Hydrogels as Biomaterial for Different Skeletal Muscle Tissue Replacements

Recently, skeletal muscle represents a complex and challenging tissue to be generated in vitro for tissue engineering purposes. Several attempts have been pursued to develop hydrogels with different formulations resembling in vitro the characteristics of skeletal muscle tissue in vivo. This review article describes how different types of cell-laden hydrogels recapitulate the multiple interactions occurring between extracellular matrix (ECM) and muscle cells. A special attention is focused on the biochemical cues that affect myocytes morphology, adhesion, proliferation, and phenotype maintenance, underlining the importance of topographical cues exerted on the hydrogels to guide cellular orientation and facilitate myogenic differentiation and maturation. Moreover, we highlight the crucial role of 3D printing and bioreactors as useful platforms to finely control spatial deposition of cells into ECM based hydrogels and provide the skeletal muscle native-like tissue microenvironment, respectively.

Stem Cell Differentiation Toward the Myogenic Lineage for Muscle Tissue Regeneration: A Focus on Muscular Dystrophy

Skeletal muscle tissue engineering is one of the important ways for regenerating functionally defective muscles. Among the myopathies, the Duchenne muscular dystrophy (DMD) is a progressive disease due to mutations of the dystrophin gene leading to progressive myofiber degeneration with severe symptoms. Although current therapies in muscular dystrophy are still very challenging, important progress has been made in materials science and in cellular technologies with the use of stem cells. It is therefore useful to review these advances and the results obtained in a clinical point of view. This article focuses on the differentiation of stem cells into myoblasts, and their application in muscular dystrophy. After an overview of the different stem cells that can be induced to differentiate into the myogenic lineage, we introduce scaffolding materials used for muscular tissue engineering. We then described some widely used methods to differentiate different types of stem cell into myoblasts. We highlight recent insights obtained in therapies for muscular dystrophy. Finally, we conclude with a discussion on stem cell technology. We discussed in parallel the benefits brought by the evolution of the materials and by the expansion of cell sources which can differentiate into myoblasts. We also discussed on future challenges for clinical applications and how to accelerate the translation from the research to the clinic in the frame of DMD.

Regenerative Therapy and Immune Modulation Using Umbilical Cord Blood-Derived Cells

Since the first cord blood transplantation in 1988, umbilical cord blood has become an important option as a source of cells for hematopoietic transplantation. Beyond its role in regenerating the blood and immune systems to treat blood diseases and inherited metabolic disorders, the role of nonhematopoietic progenitor cells in cord blood has led to new and emerging uses of umbilical cord blood in regenerative therapy and immune modulation. In this review, we provide an update on the clinical and preclinical studies using cord blood-derived cells such as mesenchymal stromal cells, endothelial-like progenitor cells, and others. We also provide insight on the use of cord blood cells as vehicles for the delivery of therapeutic agents through gene therapy and microvesicle-associated strategies. Moreover, cord blood can provide essential reagents for regenerative applications. Clinical activity using cord blood cells is increasing rapidly and this review aims to provide an important update on the tremendous potential within this fast-moving field.

Placental-derived stem cells: Culture, differentiation and challenges

Stem cell therapy is a promising approach to clinical healing in several diseases. A great variety of tissues (bone marrow, adipose tissue, and placenta) are potentially sources of stem cells. Placenta-derived stem cells (p-SCs) are in between embryonic and mesenchymal stem cells, sharing characteristics with both, such as non-carcinogenic status and property to differentiate in all embryonic germ layers. Moreover, their use is not ethically restricted as fetal membranes are considered medical waste after birth. In this context, the present review will be focused on the biological properties, culture and potential cell therapy uses of placental-derived stem cells. Immunophenotype characterization, mainly for surface marker expression, and basic principles of p-SC isolation and culture (mechanical separation or enzymatic digestion of the tissues, the most used culture media, cell plating conditions) will be presented. In addition, some preclinical studies that were performed in different medical areas will be cited, focusing on neurological, liver, pancreatic, heart, muscle, pulmonary, and bone diseases and also in tissue engineering field. Finally, some challenges for stem cell therapy applications will be highlighted. The understanding of the mechanisms involved in the p-SCs differentiation and the achievement of pure cell populations (after differentiation) are key points that must be clarified before bringing the preclinical studies, performed at the bench, to the medical practice.