Generation of Induced Pluripotent Stem Cells and Neural Stem/Progenitor Cells from Newborns with Spina Bifida Aperta

STUDY DESIGN: We established induced pluripotent stem cells (iPSCs) and neural stem/progenitor cells (NSPCs) from three newborns with spina bifida aperta (SBa) using clinically practical methods. PURPOSE: We aimed to develop stem cell lines derived from newborns with SBa for future therapeutic use. OVERVIEW OF LITERATURE: SBa is a common congenital spinal cord abnormality that causes defects in neurological and urological functions. Stem cell transplantation therapies are predicted to provide beneficial effects for patients with SBa. However, the availability of appropriate cell sources is inadequate for clinical use because of their limited accessibility and expandability, as well as ethical issues. METHODS: Fibroblast cultures were established from small fragments of skin obtained from newborns with SBa during SBa repair surgery. The cultured cells were transfected with episomal plasmid vectors encoding reprogramming factors necessary for generating iPSCs. These cells were then differentiated into NSPCs by chemical compound treatment, and NSPCs were expanded using neurosphere technology. RESULTS: We successfully generated iPSC lines from the neonatal dermal fibroblasts of three newborns with SBa. We confirmed that these lines exhibited the characteristics of human pluripotent stem cells. We successfully generated NSPCs from all SBa newborn-derived iPSCs with a combination of neural induction and neurosphere technology. CONCLUSIONS: We successfully generated iPSCs and iPSC-NSPCs from surgical samples obtained from newborns with SBa with the goal of future clinical use in patients with SBa.

Effect of Exposure to a High-Voltage Alternating Current Electric Field on Muscle Extensibility / 日本温泉気候物理医学会雑誌

Background: To investigate the effect of high-voltage alternating current (AC) electric field exposure on muscle extensibility. Methods: The study design was a crossover comparison. Fifteen healthy men were randomly divided into two groups. The interventions were exposure and no exposure to a high-voltage AC electric field (18 kV, 30 min). Subjects then performed bilateral self-stretching of the trapezius, hamstrings, and rectus femoris. Skin temperature, blood flow rate, blood pressure, heart rate, muscle rigidity, and muscle extensibility were measured before and after the intervention, and muscle rigidity and muscle extensibility were measured again after stretching. Skin temperature was measured bilaterally on the palms, shoulder girdle, anterior thigh, and dorsum of foot. Blood flow rate was measured in the right radial artery and dorsal artery of the foot. Muscle rigidity was measured bilaterally in the trapezius, rectus femoris, and biceps femoris. Muscle extensibility indices were determined for the left and right angle of lateral neck flexion, heel-buttock distance, straight leg raise angle, and sit-and-reach distance. Skin temperature, blood flow rate, blood pressure, and heart rate were compared between before and after the intervention, and muscle rigidity and muscle extensibility were compared before and after the intervention and after stretching. Results: A significant improvement was found in muscle extensibility in the intervention group but not in the controls. Muscle extensibility improvements due to stretching were noted regardless of electric field exposure, but the degree and percentage of change in muscle extensibility was significantly higher after stretching following electric field exposure. Electric field exposure had no effect on muscle rigidity or circulatory dynamics. Conclusions: Exposure to the high-voltage AC electric field appeared to increase muscle extensibility and heighten the effect of stretching. However, as the mechanism for improved muscle extensibility due to high-voltage AC electric field exposure was not clear, further study is necessary.

Effect of Exposure to a High-Voltage Alternating Current Electric Field on Muscle Extensibility / 日本温泉気候物理医学会雑誌

<b>Background:</b> To investigate the effect of high-voltage alternating current (AC) electric field exposure on muscle extensibility. <BR><b>Methods:</b> The study design was a crossover comparison. Fifteen healthy men were randomly divided into two groups. The interventions were exposure and no exposure to a high-voltage AC electric field (18 kV, 30 min). Subjects then performed bilateral self-stretching of the trapezius, hamstrings, and rectus femoris. Skin temperature, blood flow rate, blood pressure, heart rate, muscle rigidity, and muscle extensibility were measured before and after the intervention, and muscle rigidity and muscle extensibility were measured again after stretching. Skin temperature was measured bilaterally on the palms, shoulder girdle, anterior thigh, and dorsum of foot. Blood flow rate was measured in the right radial artery and dorsal artery of the foot. Muscle rigidity was measured bilaterally in the trapezius, rectus femoris, and biceps femoris. Muscle extensibility indices were determined for the left and right angle of lateral neck flexion, heel-buttock distance, straight leg raise angle, and sit-and-reach distance. Skin temperature, blood flow rate, blood pressure, and heart rate were compared between before and after the intervention, and muscle rigidity and muscle extensibility were compared before and after the intervention and after stretching.<BR><b>Results:</b> A significant improvement was found in muscle extensibility in the intervention group but not in the controls. Muscle extensibility improvements due to stretching were noted regardless of electric field exposure, but the degree and percentage of change in muscle extensibility was significantly higher after stretching following electric field exposure. Electric field exposure had no effect on muscle rigidity or circulatory dynamics.<BR><b>Conclusions:</b> Exposure to the high-voltage AC electric field appeared to increase muscle extensibility and heighten the effect of stretching. However, as the mechanism for improved muscle extensibility due to high-voltage AC electric field exposure was not clear, further study is necessary.