Medical Physiology

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Browsing Medical Physiology by Subject "Adult rat cardiomyocytes"

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    Identifying appropriate attachment factors for isolated adult rat cardiomyocyte culture and experimentation
    (Stellenbosch : Stellenbosch University, 2014-04) Lumkwana, Dumisile; Lopes, John; Stellenbosch University. Faculty of Medicine and Health Sciences. Dept. of Biomedical Sciences, Division of Medical Physiology.
    ENGLISH ABSTRACT: Introduction: Primary culture of isolated adult rat cardiomyocytes (ARCMs) is an important model for cardiovascular research, but successful maintenance of these cells in culture for their use in experiments remains challenging (Xu et al, 2009; Louch et al, 2011). Most studies are done on acutely isolated cardiomyocytes immediately after isolation, which is due to low survival of these cells in culture. Obstacles in culture are due to the type of medium and attachment factors (tissue culture adhesives) used to culture and grow these cells. Although we previously identified an optimum medium and adhesive for culture, an adhesive that permits cells to remain attached to the culture surface until after an ischemia/reperfusion insult was elusive. Aims: We therefore aimed to identify the best attachment factor and concentration that will allow adult rat cardiomyocytes to remain attached to the culture surfaces after ischemia/reperfusion experiments. Methods: Cardiomyocytes were isolated from adult Wistar rat hearts and cultured overnight on different concentrations (25 -200 μg/ml) of collagen 1, collagen 4, extracellular matrix (ECM), laminin/entactin (L/E) and laminin. Following overnight cultures, experiments were done in PBS and in PBS versus MMXCB to compare ARCM attachment and viability. Cardiomyocytes cultured on ECM, L/E and L (25−200μg/ml) were subjected to 1 hour of simulated ischemia using MMXCB that contained 3mM SDT and 10mM 2DG, followed by 15 minutes reperfusion. Cell viability was determined by staining cells with JC-1 and images of cells in a field view of 1.17μm/mm2 were captured using fluorescence microscopy. The cells were analysed according to morphology and fluorescence intensity. Results: Total and rod-shaped ARCMs attachment was improved when MMXCB was used as an experimental buffer instead of PBS. Regardless of the buffer used, morphological viability was poor on substrates of Col 1 and Col 4. In contrast to collagens, ARCMs attached efficiently and morphological viability was high on substrates of ECM, L/E and L in MMXCB, but this was greatly reduced in PBS. Mitochondrial viability was high in MMXCB compared to PBS on Col 1 and Col 4 at 75−175μg/ml and on ECM, L/E and L at all concentrations, except at 50 and 150μg/ml ECM, 175μg/ml L/E and 25μg/ml L. When cardiomyocytes cultured on ECM, L/E and L were subjected to simulated ischemia, total ARCMs, rod-shaped and R/G fluorescence (mitochondrial viability) was reduced at all concentrations compared to the control group. Hypercontracted cells were higher in the ischemic treated cells compared to the controls on ECM at 75−150μg/ml and 200μg/ml, L/E at 50,100μg/ml and 175μg/ml and on L at 125μg/ml. Total numbers of ARCMs attached on ECM, L/E and L in the ischemic group consisted of similar numbers of non-viable hypercontracted and viable rod-shaped cells. Conclusion: Cardiomyocytes should be cultured on ECM or L/E or L at concentrations from 25−200μg/ml in MMXCB. PBS is harmful to cultured ARCMs and should thus not be used as an experimental buffer. Ischemia/reperfusion can be simulated on ARCMs cultured on ECM, L/E or L from 25−200μg/ml, provided that a modified culture buffer is used as experimental buffer.