Hydroxocobalamin vs cobalt toxicity on rat cardiac and diaphragmatic muscles.

BACKGROUND: Hydroxocobalamin has been shown to be a rapid and powerful antidote in acute cyanide poisoning and to prevent cyanide poisoning during sodium nitroprusside administration. This cobalt-containing compound has been shown to be devoid of significant immediate side effects during acute administration. However, its potential delayed toxicity related to cobalt accumulation in tissue remains unknown. Therefore, we evaluated the toxicity of hydroxocobalamin as compared with that of cobalt salts on rat cardiac and diaphragmatic muscles. METHODS: For a 21-day period, rats were treated intraperitoneally with either hydroxocobalamin (70 mg kg-1 per day, n = 14), cobalt chloride hexahydrate (12 mg kg-1 per day, n = 14) or saline (n = 10). Hydroxocobalamin and cobalt chloride groups received equimolar doses of cobalt. We studied: (1) the mechanical properties of isolated left ventricular papillary muscles and diaphragmatic strips, (2) the cardiac and diaphragmatic cobalt tissue concentrations, and (3) the myocardial histological aspect. RESULTS: During the study period, no significant increase in body weight was noted in the cobalt-treated group (-4 +/- 1%), which was in contrast to the hydroxocobalamin-treated group (+21 +/- 2%) and the saline-treated group (22 +/- 2%). Compared with controls, the mechanical properties of cardiac and diaphragmatic muscles were unchanged after either hydroxocobalamin or cobalt salt treatments, and myocardial histological characteristics were similar in all groups. Conversely, large amounts of cobalt deposit were observed in the cobalt-treated group in both the diaphragm (41.90 +/- 16.30 vs 0.70 +/- 0.40 mu mol mu g-1 in the control group, P < 0.001) and the myocardium (16.90 +/- 6.40 vs 0.14 +/- 0.01 mu mol mu g-1 in the control group, P < 0.001). After hydroxocobalamin administration, cobalt concentrations were significantly lower in the diaphragm (25.10 +/- 16.50 mu mol mu g-1, P < 0.001 vs cobalt-treated group) and the myocardium (4.50 +/- 1.20 mu mol mu g, P < 0.001 vs cobalt-treated group). CONCLUSION: These results indicate that repeated administration of hydroxocobalamin was devoid of significant diaphragmatic and cardiac muscle toxicity and therefore remains a safe antidote for acute cyanide poisoning.

[Mechanical determinants of isotonic relaxation of the isolated diaphragmatic muscle]. / Déterminants mécaniques de la relaxation isotonique du muscle diaphragmatique isolé.

The aim of this study was to define the mechanical determinants of isotonic relaxation of isolated diaphragm muscle in the rat over a load range (n = 30). We tested several hypotheses to determine the effect of i) load conditions (preload, post-load), ii) sudden changes in load during contraction, iii) length of the muscle at peak shortening, iv) maximal amplitude of shortening (delta L) and v) stimulation conditions on peak rate of isotonic reelongation (+dL/dmax). At tetanus at 30 Hz, +dL/dmax was linearly correlated to delta L peak shortening and total load. Variations in preload, peak shortening or postload did not modify the +dL/dmax vs delta L relationship but such variations did affected the relationships +dL/dmax vs total load or +dL/dmax vs peak shortening. For a given value of L, +dL/dmax was weaker for twitch than for tetanus. In conclusion, four findings show that over a wide lad range the maximal amplitude of shortening the main mechanical determinant of the rate of isotonic reelongation of the isolated diaphragm muscle, independently of the length of the muscle at peak shortening, the initial length of the muscle and independently of the load during reelongation.

Effects of fatigue on force-velocity relation of diaphragm. Energetic implications.

Characteristics of the force (P)-velocity (V) relationship were investigated before and after fatigue in isolated diaphragm muscle of two species: mouse (n = 12), in which diaphragm is composed almost exclusively of fast-twitch fatigue-resistant fiber type, and rat (n = 12), in which diaphragm contains both fatigue-sensitive and fatigue-resistant fiber types. Following fatigue protocol, the mechanical performance of both the contraction and relaxation phases were significantly depressed in the two species. Consequences of the fatigue procedure on P-V characteristics differed markedly according to the two species. In mouse diaphragm, fatigue trial did not change the G curvature of the P-V hyperbola, the maximum mechanical efficiency Effmax, or the normalized peak power output M2. Conversely, in rat diaphragm, fatigue resulted in higher G curvature (p < 0.001), higher Effmax (p < 0.001) and a lower M2 (p < 0.001) compared with control values. This suggests that fatigue improved the economy of force generation in mixed rat diaphragm and not in mouse. This is consistent with an increased proportion of slow fatigue-resistant fibers caused by fatigue of fast fatigue-sensitive fibers in rat diaphragm.

Relaxant effects of isoproterenol in isolated cardiac muscle: influence of loading patterns.

The purpose of this study was to test the hypothesis that loading patterns (i.e., loading sequence, total load, and preload) modulate the relaxant effects of isoproterenol. The effects of isoproterenol (10(-6) M) on peak rate of force decline (-dF/dt) were studied in rat left ventricular papillary muscle (n = 24) with respect to two sequences of relaxation: the classical, isotonic-isometric sequence, in which tension fall occurs at initial muscle length, and the physiological, isometric-isotonic sequence, in which tension fall occurs at end-systolic muscle length. The influences of muscle load and initial length were accounted for in the evaluation of relaxation rate by plotting -dF/dt against the entire range of loads both at preload = maximum length (Lmax) and 90% Lmax. The main results are the following: 1) in the classical, isotonic-isometric sequence of relaxation, and whatever the preload, the magnitude of the relaxant effect of isoproterenol increased with load; 2) after reversal into the physiological, isometric-isotonic sequence of relaxation, the relaxant effect of isoproterenol behaved independently of load level in muscle preloaded at Lmax; 3) conversely, in muscle preloaded at 90% Lmax and relaxing according to the physiological sequence, the relaxant effect of isoproterenol increased with load; and 4) the peak relaxant effect of isoproterenol was proportionally higher in the physiological sequence of relaxation than in the classical one and occurred at a similar level of load, whatever the loading sequence and whatever the preload level. Our results indicate that loading patterns finely modulated the relaxant effects of isoproterenol and that muscle length, both before the contraction phase and at the onset of relaxation phase, influenced the effects of isoproterenol on myocardial relaxation rate.

Mechanics of human quadriceps muscle.

Mechanics of human quadriceps muscle strips (vastus lateralis; n = 10) were investigated over the whole load continuum. Mechanical experiments were performed at 29 degrees C and in both twitch and tetanus modes. For a given level of isotonic total load (P) and over a large part of the contraction phase, instantaneous velocity (V) was shown to be a unique function of instantaneous length (L), regardless of time and initial length. By considering this time- and initial length-independent mechanical property between instantaneous L and instantaneous V over the whole P continuum, a three-dimensional P-V-L relationship was constructed. Any variations in stimulation conditions modified the time-independent P-V-L diagram. Such modifications in the P-V-L relationship were characteristics of changes in contractile performance. Moreover, characteristics of the P-V relationship were investigated in both twitch and tetanus modes. The curvature of the P-V hyperbola was significantly higher in tetanus at 30 Hz than in twitch mode (P < 0.001). In conclusion, our study indicates that, in human quadriceps muscles, contractility can be defined as the time- and initial length-invariant part of a three-dimensional P-V-L relationship. Moreover, our data are consistent with an increase in economy of force generation in tetanus contractions compared with that in twitches.

Isometric relaxation of isolated diaphragm muscle: influence of load, length, time, and stimulation.

Determinants of the isometric relaxation rate were investigated in isolated rat diaphragm (n = 30). We tested the hypothesis that these determinants could include loading conditions, namely preload and afterload; abrupt changes in load during the contraction phase; stimulation conditions; and time. Two relaxation sequences were studied. When isometric relaxation occurred at initial muscle length (isotonic-isometric sequence), an increase in total load (P) accelerated the negative peak rate of tension decline (-dP/dtmax). Variations in initial length, stimulation, and onset of relaxation did not modify the -dP/dtmax vs. afterload relationship. When isometric relaxation was analyzed after -dP/dtmax, for a given afterload level the instantaneous rate of tension decline (-dP/dt) was a unique function of instantaneous tension, regardless of previous loading conditions, stimulation mode, or time. When the isometric relaxation occurred at end-shortening muscle length (isometric-isotonic sequence), the -dP/dtmax vs. P relationship was flat. The rate of tension decay, as attested by either -dP/dtmax or instantaneous -dP/dt vs. instantaneous tension phase plane, differed markedly depending on stimulation conditions. Thus the regulation of isometric relaxation rate differed according to the relaxation sequence. In muscle isometrically relaxing at initial muscle length, peak isometric relaxation rate was mainly determined by afterload. Conversely, in muscle isometrically relaxing at end-shortening length, isometric relaxation rate was highly dependent on the level of activation and was independent of preload and afterload.

[Role of sarcoplasmic reticulum in the regulation of myocardial relaxation]. / Rôle du réticulum sarcoplasmique dans la régulation de la relaxation myocardique.

In order to investigate cardiac muscle behavior after inhibition of either sarcoplasmic reticulum (SR) Ca2+ release or SR Ca2+ uptake, 35 papillary muscles of adult Wistar rats were studied after a 60 minutes exposure to ryanodine 10(-7) M (n = 11) or to cyclopiazonic acid (CPA) 10(-5) M (n = 14) and compared with a control group containing the solvent alone (n = 10). We measured the maximum extent of muscle shortening of the preloaded twitch (DLp) and the normalized total force of the fully isometric twitch (FTi). The peak lengthening velocity of the preloaded twitch (VRp) and the normalized negative peak force derivative of the fully isometric twitch (-DFi) tested the lusitropic state. Intrinsic changes in the relaxation phase, independent of the contractile state, i.e., the relaxant effects, were analysed using 1) two ratios; the VRp/DLp ratio of the preloaded twitch and the -DFi/FTi ratio of the fully isometric twitch and 2) the slopes of the VR versus DL and of the -DF versus FT relationship over the whole continuum of load. Ryanodine induced a marked negative inotropic effect associated with a decrease in VRp from 2.7 +/- 0.2 to 1.4 +/- 0.2 Lmax/s (p < 0.001). The VRp/DLp ratio and the slope of the VR versus DL relationship remained unchanged, indicating that ryanodine was devoid of intrinsic relaxant effect under isotonic conditions. At a 10/min stimulation frequency, inhibition of Ca(2+)-uptake function of the SR with CPA had no inotropic effect but decreased VRp from 2.9 +/- 0.1 to 2.2 +/- 0.1 Lmax/s (p < 0.001).(ABSTRACT TRUNCATED AT 250 WORDS)

A comparison of cyclopiazonic acid and ryanodine effects on cardiac muscle relaxation.

We investigated cardiac muscle behavior after inhibition of either sarcoplasmic reticulum (SR) Ca2+ release or SR Ca2+ uptake. Mechanics of 35 rat papillary muscles were studied after either ryanodine 10(-7) M (n = 11) or cyclopiazonic acid (CPA) 10(-5) M (n = 14) and compared with a control group containing the solvent alone (n = 10). We measured the maximum extent of shortening (delta L) of the preloaded twitch (delta Lp), and the normalized total force (TF) of the full isometric twitch (TFi). The peak lengthening velocity (Vl) of the preloaded twitch (Vlp) and the normalized negative peak force derivative of the fully isometric twitch (-DFi) tested the lusitropic state. With the influence of shortening and/or load on relaxation taken into account, analysis of relaxation was performed using 1) Vlp-to-delta Lp and magnitude of -DFi-to-TFi ratios and 2) slopes of the Vl-delta L and magnitude of -DF-TF relationships over the entire continuum of load. Ca(2+)-release inhibition with ryanodine induced a negative inotropic effect and a decrease in Vlp from 2.7 +/- 0.2 to 1.4 +/- 0.2 Lmax/S, where Lmax is the initial length at the peak of the length-active tension curve (P < 0.001). The Vlp-to-delta Lp ratio and the slope of the Vl-delta L relationship were preserved, indicating that ryanodine was devoid of intrinsic relaxant effect under isotonic conditions. Ca(2+)-uptake inhibition with CPA had no inotropic effect but decreased Vlp from 2.9 +/- 0.1 to 2.2 +/- 0.1 Lmax/s (P < 0.001).(ABSTRACT TRUNCATED AT 250 WORDS)