Single rat left ventricular myocytes were attached at both ends using a newly described double-barreled micropipette technique. This attachment procedure enabled the measurement of the active and passive mechanical properties of chemically skinned cells that showed little structural deformation. The force and oscillatory stiffness (100 Hz) of the cells were measured with a high signal-to-noise ratio, and the sarcomere length throughout the entire cell was monitored using image analysis. The passive properties were investigated from the resting sarcomere length to > 3 microns. Analysis of the sarcomere behavior indicated a high level of homogeneity throughout the cell. The attachment method supported the full activation of the cells by increased free Ca2+ (pCa 4.5), which produced 22.3 mN/mm (mean sarcomere length 2.11 microns). A force/pCa relationship was determined, which, when fitted according to the Hill equation, gave parameters of nH = 2.62 and pCa50 = 5.58. The described techniques allow the accurate study of the mechanical properties of single myocytes with increased fidelity and reliability over the preexisting methods.
The effect of phosphate on the relaxation of isometrically contracting single skinned fibres from the semitendinosus muscle of the frog Rana temporaria has been investigated using laser pulse photolysis of the photolabile caged calcium-chelator diazo-2 to rapidly reduce the Ca2+ (<2 ms) within the fibre and produce >90% relaxation of force. Relaxation occurred in two phases - an initial linear shoulder which lasted approximately 20 ms followed by a double-exponential phase which gave two rate constants, k1 (43.4+/-1. 8 s-1, mean +/-SEM, n=14) and k2 (15.6+/-0.3 s-1, mean +/-SEM, n=14) at 12 degreesC. Increased phosphate concentrations did not affect the linear phase, but slowed the double-exponential phase following photolysis of diazo-2 in a dose-dependent fashion (k50= 0.9 mM for k1, 1.15 mM for k2). Reducing the concentration of contaminating phosphate (from 640 microM to 100 microM) led to an increase in the rate of the double-exponential phase (k1=67.1+/-4.4 s-1, k2=19.7+/-0. 6 s-1, mean +/-SEM, n=12). Time-resolved measurements of sarcomere length during relaxation, both in control fibres and in the presence of a raised phosphate concentration, reveal a<2% change throughout the whole relaxation transient, and less than 0.1% at the end of the linear phase. This finding implies that gross changes in sarcomere length do not contribute to the decay of the relaxation transient seen upon diazo-2 photolysis. Our results suggest that cross-bridges in states prior to phosphate release are already committed to force generation and must relax by releasing phosphate, rather than by a reversal of the force-generating step to a weakly bound, low-force phosphate-bound state. These findings also indicate that an increase in the phosphate concentration within muscle fibres plays an important part in the slowing of relaxation observed in skeletal muscle fatigue and that the relaxation transients observed upon diazo-2 photolysis represent a disengagement of the cross-bridges.
A fully submersible force transducer system for use with isolated heart cells has been implemented using microelectromechanical systems (MEMS) technology. By using integrated circuit fabrication techniques to make mechanical as well as electrical components, the entire low-mass transducer is only a few cubic millimeters in size and is of higher fidelity (approximately 100 nN and 13.3 kHz in solution) than previously available. When chemically activated, demembranated single cells attached to the device contract and slightly deform a strain gauge whose signal is converted to an amplified electrical output. When integrated with a video microscope, the system is capable of optical determination of contractile protein striation periodicity and simultaneous measurement of heart cell forces in the 100-nN to 50-microN range. The average measured maximal force was Fmax = 5.77 +/- 2.38 microN. Normalizing for the cell's cross-sectional area, Fmax/area was 14.7 +/- 7.7 mN/mm2. Oscillatory stiffness data at frequencies up to 1 kHz has also been recorded from relaxed and contracted cells. This novel MEMS force transducer system permits higher fidelity measurements from cardiac myocytes than available from standard macro-sized transducers.
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