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Using Porcine Embryonic Stem Cells to Advance Xenotransplantation to the Clinic
Mark Nottle,Ivan M Vassiliev,Sharon Harrison,Stephen McIlfatrick,Wayne Hawthorne,Philip O’Connell,Peter Cowan,Anthony d’Apice 한국동물생명공학회(구 한국동물번식학회) 2011 발생공학 국제심포지엄 및 학술대회 Vol.2011 No.1
Pig‐to‐human transplantation (xenotransplantation) is currently the most advanced approach to solving the increasing demand for human organs and tissues. However, two critical requirements must be addressed before xenotransplantation can be considered for clinical application. First, the level of immunosuppression required to maintain xenografts must be equivalent to (or less than) that used in allotransplantation. It is now evident that multiple genetic modifications of the donor pig will be needed to achieve this goal (d’Apice et al. 2002 Transplant Proceedings. 33: 3053‐3054). These include gene knockouts (e.g. of the GalT gene, responsible for synthesis of the major porcine xenoantigen) and gene addition by transgenesis. Progress has been hindered by the current technology, which allows only a single cycle of genetic modification per generation and therefore necessitates large and complex breeding programs. Second, donor pigs should have defined, relatively homogeneous genotypes including the inability to produce endogenous retroviruses (PERV) that may infect human recipients. Inbred miniature swine are best suited in this regard but are difficult to genetically manipulate due to poor reproductive capacity. What is critically needed to advance xenotransplantation to the clinic is the ability to perform multiple cycles of genetic modifications per generation on the background of choice. We have recently made an important step towards this goal by developing a novel method for the isolation of porcine embryonic stem cells (ESC) (Vassiliev et al. 2010 Cellular Reprogramming 12: 223‐230). These cells can be stably grown for at least 150 population doublings, dramatically increasing the window for introducing multiple genetic modifications before the cells are used to clone pigs by somatic cell nuclear transfer (SCNT). Furthermore we have used this method to isolate ESCs from cloned embryos (Vassiliev et al 2011 Cellular Reprogramming 13: 205‐213) which allows us to isolate ESCs directly from breeds of pigs specifically bred for xenotransplantation. Together these advances will accelerate xenotransplantation research to the clinic.
JIN HO KANG,JOYCELYN S. HARRISON,CHEOL PARK,STEVEN J. GAIK,SHARON E. LOWTHER 성균관대학교(자연과학캠퍼스) 성균나노과학기술원 2006 NANO Vol.1 No.1
Recently, a series of single wall carbon nanotube (SWNT) polyimide nanocomposites were developed since the demand of electroactive polymeric materials as sensors and actuators for use in high temperature applications has been growing. Adding SWNTs into electroactive polyimides enhanced their electrostrictive strain as well as their mechanical integrities and chemical stability. Although an increase in piezoelectricity resulting from the incorporation of SWNTs could be expected, there has been no systematic study detailing the effect of SWNTs on piezoelectricity. In this article, the effects of various types and concentrations of SWNT on the dipole orientation and piezoelectricity were investigated using a thermally stimulated current (TSC) technique and a modified Rheovibron. It was found that the barely modified SWNTs led to a more substantial increase in the remanent polarization (Pr) than the highly modified SWNTs did. As the loading level of SWNTs increased, Pr increased.However, excessive loading of SWNTs showed a reduction in Pr since the actual poling field decreased due to a large leakage of current. The trend of the piezoelectric strain coefficient, d31, was consistent with that of Pr. The increase in interfacial polarization caused by adding SWNT was believed to be primarily responsible for the increase of Pr and d31.