Objective To study three-dimensional culturing methods of neonatal rat cardiac myocytes in simulated microgravity. Methods Neonatal rat primary cardiac myocytes were separated and seeded into polylactic acid scaffolds, stirredin spinner flasks for 24 hours, and then moved into rotary cell culture system for three-dimensional culture. The growth of cardiac myocytes was observed underinverted phase contrast microscope, scanning electron microscope and transmission electron microscope, and metabolic assay was assessed by MTT assay. Results Cardiac myocytes with sustained metabolic activity attached to the polylactic acid scaffolds, extended and confluenced. Pulsations of PLAcardiac myocytes was found in some areas. Conclusion The rotary cell culture system is suitable to develop neonatal rat cardiac myocytes culturing for three-dimensional modeling.
ObjectiveTo investigate the feasibility of small molecule compound XAV939 to induce mouse embryonic stem cells (mESC) to differentiate into cardiac myocytes. MethodsWe revived and cultured undifferentiated mESC growing confluently on trophoderm made of mouse embryonic inoblast cell. The mESCs were digested by trypsin to form embryoid bodies (EBs) by handing drop method. After plated, EBs were induced by XAV939 to differentiate into cardiac myocytes. We observed the cardiac myocytes with lightmicroscopy and identified it with immunofluorescence method. Result The XAV939 can effectively induce mESC into cardiac myocytes with the mean efficiency rate of 71.85%±1.05%. The differentiated cardiac myocytes shrinked spanteously and rhythmicly. The cardiac troponin T as the special marker of cardiac myocyte was positive. ConclusionThe small molecule compound XAV939 could effectively induce mES cells into cardiac myocytes.