OBJECTIVE: To measure and quantify the force-frequency (FFR) and Ca(2+)-frequency (CaFR) relationships in isolated rat left ventricular (LV) muscle at physiological heart rates and compare the obtained FFR to that measured in larger mammalian muscle from dog and human using the same experimental protocol. METHODS: Rat papillary muscle was isolated from the LV of adult male Sprague-Dawley rats, and dog and human muscles were from free-wall LV biopsies, loaded with the Ca(2+) indicator Fura-2, allowed to recover from isolation trauma and then subjected to direct electrical stimulation while measuring force production and intracellular Ca(2+) transients. RESULTS: We obtained a positive FFR between 1 and 4 Hz that is qualitatively similar to that found in isolated LV epicardial muscle strips from dogs and humans with normal LV function. The FFR reflects the cytosolic Ca(2+) transients in amplitude. Isoproterenol yielded an enhancement in force, but flattening of the FFR, whereas cyclopiazonic acid caused depression of FFR amplitude without changing frequency-dependent shape. CONCLUSION: We describe an experimental protocol that consistently yields positive FFRs in rat, dog and human LV muscle at stimulation rates between 1 and 4 Hz, without significant qualitative differences. We attribute previously observed negative FFR in rat muscle to an increase in SERCA activity early after excision and preparation of the muscle strips.
OBJECTIVE: To measure and quantify the force-frequency (FFR) and Ca(2+)-frequency (CaFR) relationships in isolated rat left ventricular (LV) muscle at physiological heart rates and compare the obtained FFR to that measured in larger mammalian muscle from dog and human using the same experimental protocol. METHODS:Rat papillary muscle was isolated from the LV of adult male Sprague-Dawley rats, and dog and human muscles were from free-wall LV biopsies, loaded with the Ca(2+) indicator Fura-2, allowed to recover from isolation trauma and then subjected to direct electrical stimulation while measuring force production and intracellular Ca(2+) transients. RESULTS: We obtained a positive FFR between 1 and 4 Hz that is qualitatively similar to that found in isolated LV epicardial muscle strips from dogs and humans with normal LV function. The FFR reflects the cytosolic Ca(2+) transients in amplitude. Isoproterenol yielded an enhancement in force, but flattening of the FFR, whereas cyclopiazonic acid caused depression of FFR amplitude without changing frequency-dependent shape. CONCLUSION: We describe an experimental protocol that consistently yields positive FFRs in rat, dog and human LV muscle at stimulation rates between 1 and 4 Hz, without significant qualitative differences. We attribute previously observed negative FFR in rat muscle to an increase in SERCA activity early after excision and preparation of the muscle strips.
Authors: Damir Nizamutdinov; Hao Feng; Fnu Gerilechaogetu; Joseph A Dostal; Donald M Foster; Shannon S Glaser; David E Dostal Journal: Physiol Rep Date: 2016-02