Browsing by Subject "In vivo"

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    Immunomodulatory function and in vivo properties of pediococcus pentosaceus OZF, a promising probiotic strain
    (Springer, 2013) Osmanagaoglu, O.; Kiran, F.; Yagci, F. C.; Gursel, I.
    Some of the important properties of probiotics are the ability to survive during gastrointestinal transit and to modulate the immune functions. The objectives of the reported study were to assess in vivo gastrointestinal survival of orally administered Pediococcus pentosaceus OZF using an animal model BALB/c mice, and to examine its effects on the immune response. Following oral administration to mice, the ability of Pediococcus pentosaceus OZF to pass and survive through the mouse gastrointestinal system was investigated by analyzing the recovery of the strain in fecal samples. Microbiological and polymerase chain reaction (PCR) methods proved that the strain OZF could overcome specific conditions in the gastrointestinal tract of mice and reach the intestine alive after ingestion. To observe the effect of oral administration on immune response, IL-6, IL-12 and IFN-γ were measured by ELISA, and the strain OZF was found to cause increases in IL-6 synthesis in regularly fed mice. However, stimulation was carried out with various concentrations of bacterial ssDNA and heat killed cells of Pediococcus pentosaceus OZF. The heat killed cells of the strain OZF were shown to produce IFN- γ independently from IL-12. On the other hand, a significant difference between control and experimental group was noticed when lipopolysaccharide, a TLR4 (toll like receptor) ligand, was used. Overall, Pediococcus pentosaceus OZF may be a valuable probiotic strain for therapeutic uses. Nevertheless, further studies on the mechanisms of immunomodulatory effect will allow for better clarification of the immune functions of this strain. © Springer-Verlag Berlin Heidelberg and the University of Milan 2012.
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    Investigation of the effects of bioactive peptide nanofibers on acute muscle injury regeneration
    (2016-10) Eren Çimenci, Çağla
    Skeletal muscle constitutes a large part of the human body. It is a hierarchically organized heterogeneous tissue and is composed of muscle fiber bundles, muscle fibers, myofibrils and myofilaments. Since muscle cells are terminally differentiated, they have limited capacity to renew themselves. Only new cells can fuse with muscle fibers and increase the size and volume of skeletal muscle. Myosatellite cells or satellite cells are small, mononuclear progenitor cells with virtually no cytoplasm. They are located in between the sarcolemma and basement membrane of terminally-differentiated muscle fibers. Satellite cells are precursors to skeletal muscle cells, and are able to give rise to satellite cells or differentiated skeletal muscle cells. They are normally found in silent state in adult muscle, but act as a reserve cell population that is able to proliferate in response to injury and give rise to regenerated muscle and to more satellite cells. Formation of the new muscular tissue is called myogenesis. During this event, satellite cells differentiate into myoblasts, and then myoblasts fuse with each other in order to form myofibers. There are many genes that regulate the myogenesis process and each of them is activated in a different step of myogenesis. Increased or decreased levels of gene expression determine the differentiation capacity. Peptide nanofibers are supramolecular structures formed via self-assembly and they are promising molecules in regenerative medicine and tissue engineering. Peptide-based molecules for tissue regeneration is a widely studied area and currently used in the treatment-investigation of many different tissues such as bone, cartilage, skin and nerve. Since laminin is one of the most abundant proteins found in the basal membrane of the skeletal muscle; in this thesis, we designed and synthesized a laminin-mimetic bioactive (LM/E-PA) molecule functionalized with bioactive groups for mimicking laminin activities and capable of accelerating satellite cell activation. Our research group had previously shown that LM/E-PA containing nanofibers can support muscle differentiation in vitro. In this thesis, the clinical relevance was demonstrated further by assessing laminin-mimetic bioactive scaffold in acute muscle injury in an in vivo rat model. Our findings revealed that this scaffold system significantly promotes satellite cell activation in skeletal muscle and accelerates regeneration following acute muscle injury. In addition, our findings show that the regeneration capacity of the skeletal muscle was increased and consequently regeneration time was reduced. This study is one of the first examples of molecular level and tissue level regeneration of skeletal muscle by using bioactive peptide nanofibers following acute muscle injury, and shows that laminin mimetic nanofiber system is a promising material for development of new therapeutic curatives for acute skeletal muscle injuries.