Contractile and morphological properties of hamster retractor muscle following 16 h of cold preservation |
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Authors: | Miriam CJ de With EPA Brigitte van der Heijden Matthijs F van Oosterhout M Kon Alfons BA Kroese |
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Institution: | aDepartment of Plastic Reconstructive and Hand Surgery, University Medical Center, G04.122, Heidelberglaan 100, 3584 CX Utrecht, The Netherlands;bDepartment of Pathology, University Medical Center, Utrecht, The Netherlands;cDepartment of Surgery, University Medical Center, Utrecht, The Netherlands;dInstitute for Risk Assessment Sciences, Utrecht University, The Netherlands |
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Abstract: | IntroductionCold hypoxia is a common factor in cold tissue preservation and mammalian hibernation. The purpose of this study was to determine the effects of cold preservation on the function of the retractor (RET) muscle of the hamster in the non-hibernating state and compare these with previously published data (van der Heijden et al., 2000) 52] on the rat cutaneus trunci (CT) muscle.Materials and methodsAfter cold storage (16 h at 4 °C), muscles were stimulated electrically to measure maximum tetanus tension (P0) and histologically analyzed. The protective effects of addition of the antioxidants trolox and deferiprone and the calcium release inhibitor BDM to the storage fluid were determined.ResultsAfter storage, the twitch threshold current was increased (from 60 to 500 μA) and P0 was decreased to 27% of control. RET morphology remained unaffected. RET muscle function was protected by trolox and deferiprone (P0, resp., 43% and 59% of control). Addition of BDM had no effect on the RET.ConclusionsThe observed effects of cold preservation and of trolox and deferiprone on the RET were comparable to those on CT muscle function, as reported in a previously published study (van der Heijden et al., 2000) 52]. Both hamster RET and rat CT muscles show considerable functional damage due to actions of reactive oxygen species. In contrast to the CT, in the RET cold preservation-induced functional injury could not be prevented by BDM and was not accompanied by morphological damage such as necrosis and edema. This suggests that the RET myocytes possess a specific adaptation to withstand the Ca2+ overload induced by cold ischemia. |
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Keywords: | Skeletal muscle Hamster Ischemia Reoxygenation Antioxidants Calcium homeostasis Reactive oxygen species Hibernation Composite tissue allograft Preservation |
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