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Mesenchymal stromal cells and biological scaffolds for neural tissue regeneration
Kočí, Zuzana ; Kubinová, Šárka (advisor) ; Filová, Eva (referee) ; Zach, Petr (referee)
Despite tremendous progress in medicine, injuries of the adult central neural system remain without satisfactory solution. Regenerative medicine employs tissue engineering, cellular therapies, medical devices, gene therapy, or growth factors with the aim to bridge the lesion, re-establish lost connections and enhance endogenous repair in order to restore neural function. The aim of my thesis was to evaluate therapeutic potential of two approaches, transplantation of human mesenchymal stromal cells (hMSCs) and biological scaffolds derived from extracellular matrix (ECM) for neural regeneration, particularly in models of spinal cord injury (SCI). First, hMSCs from various sources - bone marrow (BM), adipose tissue (AT) and Wharton's jelly (WJ) - were isolated and characterized in vitro. All cell types met the minimal criteria for MSC phenotype and displayed similar properties in terms of their surface marker expression, differentiation potential, migratory capacity, and secretion of cytokines and growth factors. On the other hand, the cell yield from WJ and AT was significantly higher, and MSCs isolated from these tissues proliferated better than from BM. Therapeutic effect of intrathecal application of hWJ-MSCs was then evaluated in SCI compression model in rats. The effect of low (0.5 million) and...
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Development of extracellular-matrix scaffolds for CNS repair
Výborný, Karel ; Kubinová, Šárka (advisor) ; Hampl, Aleš (referee) ; Vandrovcová, Marta (referee)
Výborný, Karel. Vývoj materiálů na bázi extracelulární matrix pro léčbu centrálního nervového systému. [Development of extracellular-matrix scaffolds for CNS repair]. Praha, 2020. 105 stran, 3 přílohy. Dizertační práce (Ph.D.). Univerzita Karlova, 2. lékařská fakulta, Ústav experimentální medicíny, AV ČR v.v.i. Abstract Brain and spinal cord injury are a serious traumata and despite intensive research, there is still no effective treatment for patients. One of the studied approaches is to use various biomaterials to repair the damaged neural tissue. The aim of this thesis is to study the regenerative and neurotrophic effects of injectable extracellular matrix (ECM) hydrogels prepared by decellularization from porcine tissue (brain, spinal cord, bladder) and human umbilical cord (UC) in reconstruction of damaged neural tissue of the brain and spinal cord in rats. We characterized ECM hydrogels in terms of mechanical and rheological properties, structure and composition, cell adhesion, migration and proliferation. In a model of spinal cord hemisection, we compared the regenerative effect of ECM hydrogels derived from porcine spinal cord and urinary bladder. We found no benefits of tissue specific ECM prepared from the tissue of neural origin in terms of its neurotrophic properties in vitro or in vivo....
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Mesenchymal stromal cells and biological scaffolds for neural tissue regeneration
Kočí, Zuzana ; Kubinová, Šárka (advisor) ; Filová, Eva (referee) ; Zach, Petr (referee)
Despite tremendous progress in medicine, injuries of the adult central neural system remain without satisfactory solution. Regenerative medicine employs tissue engineering, cellular therapies, medical devices, gene therapy, or growth factors with the aim to bridge the lesion, re-establish lost connections and enhance endogenous repair in order to restore neural function. The aim of my thesis was to evaluate therapeutic potential of two approaches, transplantation of human mesenchymal stromal cells (hMSCs) and biological scaffolds derived from extracellular matrix (ECM) for neural regeneration, particularly in models of spinal cord injury (SCI). First, hMSCs from various sources - bone marrow (BM), adipose tissue (AT) and Wharton's jelly (WJ) - were isolated and characterized in vitro. All cell types met the minimal criteria for MSC phenotype and displayed similar properties in terms of their surface marker expression, differentiation potential, migratory capacity, and secretion of cytokines and growth factors. On the other hand, the cell yield from WJ and AT was significantly higher, and MSCs isolated from these tissues proliferated better than from BM. Therapeutic effect of intrathecal application of hWJ-MSCs was then evaluated in SCI compression model in rats. The effect of low (0.5 million) and...
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