Comparative evaluation of fracture healing potential of differentiated and undifferentiated guinea pig and canine bone marrow-derived mesenchymal stem cells in a guinea pig model.

BACKGROUND AND AIM: This work was conducted to compare the therapeutic potential of undifferentiated and osteogenic differentiated canine (xenogeneic) and guinea pig (allogeneic) BMSCs in fracture healing using guinea pig as a model. MATERIALS AND METHODS: A well-characterized homogenous population of third passage mesenchymal stem cells of bone marrow origin was used in all the experiments. MSCs from both the species, i.e., canine and guinea pigs, were differentiated and characterized. Expression of MHC I and II along with co-stimulatory molecules was assessed based on relative mRNA expression. The osteogenic differentiated and undifferentiated MSCs from both species were used for evaluating fracture healing in the guinea pig model. The healing potential was assessed based on radiographic, histopathology, and clinical observations. RESULTS: BMSCs from both species expressed MSC surface antigens and successfully differentiated to osteogenic, chondrogenic, and adipogenic lineages. The mRNA expression of class I and II MHC molecules in all the three lineages showed no significant (p > 0.05) differences after differentiating to adipogenic, chondrogenic, and osteogenic lineages. Radiographic and clinical examination revealed that MSCs therapy significantly improved bone fracture healing with a non-significant (p > 0.05) difference between differentiated and undifferentiated BMSCs. In addition, allogeneic MSCs therapy performed better than xenogeneic therapy. CONCLUSION: MSCs remained hypo immunogenic after differentiation and have comparable fracture healing potential though allogeneic MSCs have better therapeutic potential than xenogenic MSCs.

Allogeneic mesenchymal stem cells and growth factors in gel scaffold repair osteochondral defect in rabbit.

Aim: An attempt was made to improve osteochondral healing with allogeneic mesenchymal stem cells (MSCs) along with certain growth factors. Materials & methods: Induced knee osteochondral defects were filled as: phosphate buffer saline (group A); MSCs in collagen gel (group B); group B plus insulin like growth factor-1 (group C); group C plus transforming growth factor ß-1 (group D). Results: Gross and scanning electron microscopy showed superior morphology and surface architecture of the healed tissue in groups D and C. Histologically, group D revealed hyaline cartilage characteristic features followed in order by group C and group B. In all treatment groups, chondrogenic matrix, collagen II2B (col II 2B) and aggrecan were secreted. Conclusion: Combined use of MSCs and growth factors could accelerate osteochondral healing.

In vitro strategies to enhance oocyte developmental competence.

Oocyte quality influences early embryonic survival, establishment and maintenance of pregnancy, fetal development and adult diseases. The developmental competence of oocytes is acquired gradually and increases with follicular development. The ability of an oocyte to develop into an embryo depends on, having enough specific information in the form of mRNA or proteins. If this information is insufficient, defects in nuclear or cytoplasmic maturation, or in both processes, may arise and thus affect the in vitro development of fertilized oocytes. The greater developmental competence of oocytes aspirated from larger follicles is reported as compared with smaller follicles. Oocyte developmental competence is greatly correlated with the morphology of the cumulus oocyte complexes (COCs). Apart from morphological or biochemical markers, molecular markers have also been investigated. Until now, no specific markers of oocyte developmental competence could be described for the oocyte developmental competence. To, utilize female germplasm to its maximum, there is a need to enhance developmental competence of lesser competent oocytes derived from the follicles which are not fully grown. The oocyte pre-maturation and maturation conditions affect gene expression not only in the oocyte but till the blastocyst stages too. Strategies have been discussed in this review would be useful to enhance the developmental competence of oocytes.

Equine Mesenchymal Stem Cells: Properties, Sources, Characterization, and Potential Therapeutic Applications.

Properties like sustained multiplication and self-renewal, and homing and multilineage differentiation to undertake repair of the damaged tissues make stem cells the lifeline for any living system. Therefore, stem cell therapy is regarded to carry immense therapeutic potential. Though the dearth of understanding about the basic biological properties and pathways involved in therapeutic benefits currently limit the application of stem cells in humans as well as animals, there are innumerable reports that suggest clinical benefits of stem cell therapy in equine. Among various stem cell sources, currently adult mesenchymal stem cells (MSCs) are preferred for therapeutic application in horse owing to their easy availability, capacity to modulate inflammation, and promote healing. Also the cells carry very limited teratogenic risk compared to the pluripotent stem cells. Mesenchymal stem cells were earlier considered mainly for musculoskeletal tissues, but now may also be utilized in other diverse clinical problems in horse, and the results may be extrapolated even for human medicine. The current review highlights biological properties, sources, mechanisms, and potential therapeutic applications of stem cells in equine practice.

Mesenchymal stem cell basic research and applications in dog medicine.

The stem cells, owing to their special characteristics like self-renewal, multiplication, homing, immunomodulation, anti-inflammatory, and dedifferentiation are considered to carry an "all-in-one-solution" for diverse clinical problems. However, the limited understanding of cellular physiology currently limits their definitive therapeutic use. Among various stem cell types, currently mesenchymal stem cells are extensively studied for dog clinical applications owing to their readily available sources, easy harvesting, and ability to differentiate both into mesodermal, as well as extramesodermal tissues. The isolated, culture expanded, and characterized cells have been applied both at preclinical as well as clinical settings in dogs with variable but mostly positive results. The results, though positive, are currently inconclusive and demands further intensive research on the properties and their dependence on the applications. Further, numerous clinical conditions of dog resemble to that of human counterparts and thus, if proved rewarding in the former may act as basis of therapy for the latter. The current review throws some light on dog mesenchymal stem cell properties and their potential therapeutic applications.

Mesenchymal stem cell: Basic research and potential applications in cattle and buffalo.

Characteristic features like self-renewal, multilineage differentiation potential, and immune-modulatory/anti-inflammatory properties, besides the ability to mobilize and home distant tissues make stem cells (SCs) a lifeline for an individual. Stem cells (SCs) if could be harvested and expanded without any abnormal change may be utilized as an all-in-one solution to numerous clinical ailments. However, slender understanding of their basic physiological properties, including expression potential, behavioral alternations during culture, and the effect of niche/microenvironment has currently restricted the clinical application of SCs. Among various types of SCs, mesenchymal stem cells (MSCs) are extensively studied due to their easy availability, straightforward harvesting, and culturing procedures, besides, their less likelihood to produce teratogens. Large ruminant MSCs have been harvested from various adult tissues and fetal membranes and are well characterized under in vitro conditions but unlike human or other domestic animals in vivo studies on cattle/buffalo MSCs have mostly been aimed at improving the animals' production potential. In this document, we focused on the status and potential application of MSCs in cattle and buffalo.

Mesenchymal Stem Cell Research in Veterinary Medicine.

BACKGROUND: The researchers working in the field of medical, veterinary and other biological sciences have uniformly described unique characteristic features of stem cells including selfrenewal, prolonged multiplication, immuno-modulation and multi-lineage differentiation. These characteristics of stem cells have opened new horizons in cellular therapy for the management of numerous incurable diseases in human and veterinary patients. Though the mechanisms involved in reparative processes may be similar, the indication for the stem cell therapy may be disparate in human and veterinary subjects. OBJECTIVE: Among various stem cell types, currently mesenchymal stem cells (MSCs) are extensively studied in regenerative medicine owing to their readily available sources, easy harvesting and ability to differentiate both into mesodermal as well as non-mesodermal tissues under specific culture conditions with little associated ethical issues. The objective of the study was to analyze and summarize the studies and their results pertaining to the basic biology of stem cells, preclinical trials and their potential therapeutic application in veterinary medicine. RESULTS: MSCs have been variably isolated, cultured and characterized from almost all the body tissues and fetal membranes in domestic and pet animals. The cells have been studied in numerous pre-clinical and clinical studies, in addition, to lab animal models. The results although are promising but need further extensive research studies before the cellular application becomes a clinical reality in veterinary medicine. CONCLUSION: The current review throws some light on different aspects of mesenchymal stem cells like sources, isolation, characterization and their potential therapeutic applications in farm and pet animals.

Mesenchymal stem cells with IGF-1 and TGF- ß1 in laminin gel for osteochondral defects in rabbits.

OBJECTIVE: Healing of articular cartilage is still a challenge due to its limited potential to regenerate. In the present study, we evaluated allogenic bone marrow mesenchymal stem cells (BM-MSCs) alone or in combination with growth factors, insulin-like growth factor-1 (IGF-1) and transforming growth factor-ß1 (TGF-ß1) in laminin scaffolds for healing of osteochondral defects. DESIGN: Osteochondral defects of 4mm (diameter) x 5mm (depth) were induced in the rabbit knee joints and treated with phosphate-buffered saline (PBS; control), BM-MSCs, BM-MSCs in laminin, BM-MSCs in laminin with IGF-1, or BM-MSCs in laminin with IGF-1 and TGF-ß1 in 10 animals each. Gross, radiographic, scanning electron microscopic (SEM) and histologic examinations besides chondrocyte-specific genes expression by quantitative real time qPCR were carried out at 8 and 12 weeks. RESULTS: Gross and SEM examination revealed superior morphology and surface architecture of the healing site in animals that received MSCs with IGF-1 or IGF-1 and TGF-ß1. The application of laminin composites containing MSCs with IGF-1 and TGF-ß1 significantly enhanced hyaline cartilage formation with improved cellular arrangement, proteoglycan deposition, clear tidemark zone and subchondral bone formation. However, regenerated tissue in defects that received only MSCs had poor tidemark zone and proteoglycans deposition Aggrecan and Coll2 expression was significantly higher in case of MSCs with growth factors. CONCLUSION: The treatment with BM-MSCs combined with IGF-1/TGF-ß1 into laminin gel scaffold might enhance the restoration of hyaline cartilage in osteochondral defect.