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Development of a Human Mesenchymal Stem Cell and Pluripotent Stem Cell Derived Cardiomyocyte Seeded Biological Suture for Cell Delivery to Cardiac Tissue for Cardiac Regeneration ApplicationsHansen, Katrina J 13 December 2017 (has links)
"Recent data show that 7.6 million Americans have survived a myocardial infarction (MI), and 5.1 million Americans suffer from severe heart failure. Stem cell therapy has the potential to improve cardiac function after MI. Two promising cells for cardiovascular regeneration therapies include human mesenchymal stem cells (hMSCs) and pluripotent stem cell derived cardiomyocytes (hPS-CM) each with their own unique method for improving cardiac function post-infarct. However, a limiting factor to cell therapies is that the methods currently used to deliver cells to the myocardium, including intramyocardial injection (considered the gold standard), suffer from low retention rates. To promote localization of delivered cells to the infarct and increase retention rates, our lab has developed a fibrin biological suture that can deliver human mesenchymal stem cells (hMSCs) with an efficiency of 64% compared to just 11% with intramyocardial injection in the normal rat heart. In this dissertation we sought to examine the functionality of hMSC and hPS-CM seeded sutures and their impact on cardiovascular regeneration applications. We began by delivering hMSC seeded fibrin sutures to an infarcted rat heart and found that the sutures are an effective method to deliver cells to the infarcted myocardium and demonstrated a trend towards improved regional mechanical function in the infarct region over infarct alone. Next, we transitioned to using hPS-CM and developed methods to seed the sutures, as well as a method to measure hPS-CM contractility with high spatial and temporal resolution, while concurrently capturing calcium transients. This technique allowed us to examine the contractile behavior in terms of contractile strain and conduction velocity of hPS-CM seeded on fibrin microthreads over 21 days in culture. We found that the fibrin microthread is a suitable scaffold for hPS-CM attachment and contraction and that extended culture promotes cell alignment along the length of the suture as well as improvements in contractile function in terms of increases in contractile strain and conduction velocity. Finally, we delivered the hPS-CM seeded microthreads to an uninjured rat heart and found a delivery efficiency of 67%. Overall, we further demonstrated the technology of the fibrin suture to deliver cells to an infarct as well as the ability to support the attachment, contraction and delivery of hPS-CM to cardiac tissue. "
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Rapid and Uniform Cell Seeding on Fibrin Microthreads to Generate Tissue Engineered MicrovesselsParekh, Darshan P 05 May 2010 (has links)
A wide variety of techniques have been explored to synthesize small diameter tissue engineered blood vessels. Toward this end, we are exploring direct cell seeding and culture on tubular mandrels to create engineered vascular tissues. In the present study, v-shaped channels cast from polydimethyl siloxane (PDMS) were used as cell seeding wells. Fibrin microthreads placed in the chamber were used as model tubular seeding mandrels. Human mesenchymal stem cells (hMSCs) were seeded onto fibrin microthreads in v-shaped channels for 4 hours. Cell attachment to the microthreads was confirmed visually by Hoechst nuclear staining and a cell quantification assay showed that 5,114 ± 339 cells attached per 1 cm fibrin microthread sample (n = 6). Fibrin microthreads were completely degraded by hMSCs within 5 days of culture, therefore UV crosslinking was used to increase their mechanical strength and prolong the amount of time cells could be cultured on fibrin microthreads and generate tubular tissue constructs. Cell attachment was unaffected on UV-crosslinked microthreads compared to uncrosslinked microthreads, resulting in a count of 4,944 ± 210 cells per 1 cm of fibrin microthread sample (n = 3). Long term culture of the hMSCs on the UV-crosslinked fibrin microthreads showed an increase in cell number over time to 11,198 ± 582 cells per cm of microthread after 7 days with 92% cell viability (CYQUANT NF/DEAD staining) and evidence of cell proliferation. The results show that the v-well cell seeding technique was effective in promoting rapid hMSC attachment on UV-crosslinked fibrin microthreads and encouraged their growth, maintained viability and also promoted their proliferation over the culture period. In conclusion, the technique could serve as an efficient model system for rapid formation of tissue engineered vascular grafts.
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