Investigation of Stem Cell Applications on In Vitro Fertilization in Rats

ΔΕΝ ΔΙΑΤΙΘΕΤΑΙ ΠΕΡΙΛΗΨΗWe aimed to search the effects of bone marrow-derived mesenchymal stem cell-conditioned media on in vitro fertilization by investigation of lifetime of germ cells cleavage, degeneration rates and embryo quality. For this purpose, firstly MSCs were isolated from femurs and tibias of the rat, and cells were cultured until the fourth passage. Sperm and oocytes were collected from male and female rats. Oocytes were added in Human Tubal Fluid Media (HTFM), Single Step Media (SSM), Alpha-MEM Media (AMM) and Bone Marrow-Derived Mesenchymal Stem Cell-Conditioned Media (CM). Thousand sperm were added into the media which including oocytes. Embryos were allowed to produce by IVF. The development of the embryos was followed until the 11th day, and the arrest, degeneration rates and alive embryos were established. The embryos reached 2, 4, 8, 16 cells stages and morula stage in the CM. While AMM had a negative effect on fertilization and embryo development, the most favourable effect was shown to be caused by CM in comparison with the other medias. These results have shown that the beneficial effects of CM in IVF would be a significant increase in the rate of fertility and development of embryos

KAFKAS UNIVERSITESI VETERINER FAKULTESI DERGISI

Mandibular fractures present a challenge in maxillo-facial surgery due to difficulties in healing and complications. In recent years, advances in bio-engineering as well as stem-cell studies suggest that it may be possible to treat these fractures by stem cell treatment with biomaterials. In the present study, we explored the efficacy of differentiated stem cells placed on biomaterials on fracture treatment and its relation with oxidative stress and apoptosis. A 4 mm circular defect was made on the mandibulae of 20 adults Wistar rats. Hydroxyapatite gel (control, n=5) and bone marrow stromal cells differentiated into osteoblast-seeded hydroxyapatite gel (n=5) were implanted within these defects. We were also used empty cavities (n=5) and cavities filled with only cells (n=5) for negative controls. Animals were sacrificed after a 6-week healing period and samples were examined blindly by histological, immunohistochemical, radiological and morphometric methods. Compared to the control cavities that underwent no procedure or filled with just cells, there were significant (P<0.001) healings in both groups. Hydroxyapatite gel with differentiated stem cells on, however, yielded significantly (P<0.05) better new bone formation and osteoid production decreased fibrous tissue and increased cellular activity. Differentiated stromal cells combined with biomaterial accelerated the treatment in defects of critical volume within a 6-week period of healing, activated and resulted in significant formation of bone of higher quality. Promotion of bone formation by the helps of bioengineering and stromal cells has gained importance in the treatment and reconstruction of fractures

2016 20TH NATIONAL BIOMEDICAL ENGINEERING MEETING (BIYOMUT)

The biologic effects of electomagnetic fields application on medical field has been increased. Their effect on medical treatment depends on cell behaviour which can be observed by in vivo and in vitro studies. Their effect on the stem cells and the cell lines and the organs of experimental animals with morphological alterations are helpful to understand cell behaviour. The behaviour of the cells can be analyse at ultrastructial level by scaning electron microscopy. Application of electomagnetic fields cause increase of proliferation, migrationand improvement of wound healing with beneficial effects while they cause oxidative stress and cell daeth including apoptosis for cancer cells in different types of cell line. The minimal side effect with maximum beneficial treatment of these products suggest that they could be very useful for clinical trials

The effect of Electro Magnetic Fields on Cell Behaviour

The biologic effects of electomagnetic fields application on medical field has been increased. Their effect on medical treatment depends on cell behaviour which can be observed by in vivo and in vitro studies. Their effect on the stem cells and the cell lines and the organs of experimental animals with morphological alterations are helpful to understand cell behaviour. The behaviour of the cells can be analyse at ultrastructial level by scaning electron microscopy. Application of electomagnetic fields cause increase of proliferation, migrationand improvement of wound healing with beneficial effects while they cause oxidative stress and cell daeth including apoptosis for cancer cells in different types of cell line. The minimal side effect with maximum beneficial treatment of these products suggest that they could be very useful for clinical trials