Peroxynitrite induces contractile dysfunction and lipid peroxidation in the diaphragm.

Peroxynitrite may be generated in and around muscles in several pathophysiological conditions (e.g., sepsis) and may induce muscle dysfunction in these disease states. The effect of peroxynitrite on muscle force generation has not been directly assessed. The purpose of the present study was to assess the effects of peroxynitrite administration on diaphragmatic force-generating capacity in 1) intact diaphragm muscle fiber bundles (to model the effects produced by exposure of muscles to extracellular peroxynitrite) and 2) single skinned diaphragm muscle fibers (to model the effects of intracellular peroxynitrite on contractile protein function) by examining the effects of both peroxynitrite and a peroxynitrite-generating solution, 3-morpholinosydnonimine, on force vs. pCa characteristics. In intact diaphragm preparations, peroxynitrite reduced diaphragm force generation and increased muscle levels of 4-hydroxynonenal (an index of lipid peroxidation). In skinned fibers, both peroxynitrite and 3-morpholinosydnonimine reduced maximum calcium-activated force. These data indicate that peroxynitrite is capable of producing significant diaphragmatic contractile dysfunction. We speculate that peroxynitrite-mediated alterations may be responsible for much of the muscle dysfunction seen in pathophysiological conditions such as sepsis.     

Acetate-induced depression of electrical and contractile activity in normoxic and hypoxic guinea pig papillary muscle

The action potential configuration, developed tension, and resting tension were monitored in normoxic and hypoxic guinea pig papillary muscles superfused with solutions containing no substrate, glucose, or acetate (1-10 mM). In normoxic muscle, acetate provoked a concentration-dependent transient depression of the action potential duration and force of contraction, depression was maximal after 10-30 min, and recovery was complete after 90-120 min. In hypoxic muscle, acetate accelerated functional rundown (action potential shortening, decline of developed tension, increase in resting tension). Because rundown in hypoxic muscle was sensitive to factors affecting glycolysis (moderated by external glucose; accentuated by 2-deoxyglucose), the accentuated rundown with acetate may be accounted for by a partial block of glycolysis. However, block of glycolysis cannot explain the acetate-induced transient depression in normoxic muscle, since the depression was enhanced in normoxic muscle with 2-deoxyglucose-blocked glycolysis. We suggest that the transient depression is due to a transient depression of high energy nucleotides with consequent effects on ionic currents.     

The major metabolite of doxorubicin is a potent inhibitor of membrane-associated ion pumps. A correlative study of cardiac muscle with isolated membrane fractions

Doxorubicin (adriamycin) is a highly effective cancer chemotherapeutic drug but its clinical utility is limited by its cardiotoxicity. Doxorubicinol, the major metabolite of doxorubicin, is up to 10 times more potent than doxorubicin at inhibiting isometric contraction of the papillary muscle isolated from the right ventricle of rabbit heart. Doxorubicinol also increases resting tension of isolated cardiac muscle indicative of incomplete relaxation between contractions, a characteristic of doxorubicinol but not of doxorubicin. This study assesses the effect(s) of doxorubicinol on a variety of ion pumps which may explain, in part, the action of the metabolite in the intact muscle. We find the doxorubicinol is a potent inhibitor (IC50 less than 5 micrograms/ml) of calcium-stimulated ATPase activity of sarcoplasmic reticulum from canine heart and rabbit skeletal muscle. At comparable levels, doxorubicinol is also a potent inhibitor of (Na + K)-ATPase of cardiac sarcolemma and the Mg-dependent ATPase activity referable to the F0F1 proton pump of mitochondria. For each of these ion pumps, doxorubicinol is at least 80 times more potent an inhibitor than doxorubicin. Doxorubicinol, between 10 and 50 micrograms/ml, increases resting tension up to 4-fold in isolated papillary muscles cyclically contracting at 30 times/min. Resting stress is relatively insensitive to doxorubicin. Thus, doxorubicinol is a potent inhibitor of several key cationic pumps that directly or indirectly regulate cell calcium and inhibits relaxation in the isolated fiber preparation. These observations add a new dimension to understanding the cardiotoxicity of doxorubicin.     

Scattered-light intensity fluctuations in diastolic rat cardiac muscle caused by spontaneous Ca++-dependent cellular mechanical oscillations

Laser light scattered by nonstimulated rat cardiac muscle bathed in physiological saline containing a [Ca++] of 0.4-2.5 mM displays scattered-light intensity fluctuations (SLIF); the frequencies of both SLIF and resting force are Ca++ dependent. Direct inspection of these muscles by phase-contrast microscopy under incoherent illumination revealed the presence of spontaneous asynchronous cellular motions that are also Ca++ dependent. The physical properties of the scattered light are compatible with the hypothesis that SLIF are due to the diastolic motion, except for the dependence on scattering angle, which may be perturbed because the muscles are optically thick. To determine whether diastolic SLIF and motion are an intrinsic property of activated myofilaments, photon-counting auto-correlation of the scattered light was performed both in rat right-ventricular papillary muscles skinned with the detergent Triton X-100 (1%) and in muscles with intact membranes under conditions that alter cellular Ca++ fluxes. In skinned muscles activated over a range of Ca++ from threshold to maximum force production, neither SLIF nor asynchronous motion was observed when Ca++ was buffered to constant values. In intact muscles the frequency of SLIF and the amplitude of diastolic motion were (a) markedly increased by substituting K+ or Li+ for Na+ in the bath; (b) not altered by verapamil (1 microM); and (c) reversibly abolished by caffeine (greater than or equal to 10 mM). These properties are exactly those of mechanical oscillations that have been observed in isolated cardiac cell fragments, which are the result Ca++ oscillations caused by Ca++ release from the sarcoplasmic reticulum (SR). We infer that mechanical oscillations caused by spontaneous Ca++-induced Ca++ release from the SR occur in intact nonstimulated cardiac muscle even in the absence of Ca++ overload and are the principle cause of SLIF, and that myoplasmic [Ca++] in "resting" muscle is not in a microscopic steady state.     

Adenosine triphosphate alters the selenite-induced contracture and negative inotropic effect on cardiac muscle contractions

Selenium is known to play an important role in the physiology of many different cell types and extracellular application of selenite causes cellular dysfunction in many different types of tissues. In a previous study, we have shown that in rat ventricles, sodium selenite (≥1 mM) caused an increase in the resting tension and a decrease in contractile force, in a time-dependent manner. In the present study, we have shown that sodium selenite caused a contracture state both in Langendorff perfused hearts and isolated papillary muscles. We also showed that the application of extracellular ATP (0.1 mM) markedly reduced this detrimental effect of sodium selenite on ventricular contraction in Langendorff perfused hearts and delayed it in isolated papillary muscle preparations. In contrast, isoproterenol (0.1 μM) did not seem to influence this action of sodium selenite in papillary muscle preparations. Possible reasons for this protective effect of ATP to selenite-induced contracture are also discussed.     

Acute negative inotropic effects of homocysteine are mediated via the endothelium

Previous studies have shown that chronic hyperhomocysteinemia is associated with an adverse cardiac remodeling and heart failure. This study, which utilized coronary-perfused hearts and superfused papillary muscle, was designed to determine whether homocysteine acts acutely to alter cardiac contractile function. Left ventricular developed pressure was used as a measure of systolic function in the Langendorff-perfused heart, whereas isometric developed tension was used in papillary muscle. All preparations were bathed in physiological buffer and paced electrically. Initial results showed that homocysteine elicits a relatively rapid onset (maximum effect observed within 5 min), concentration-dependent (10-300 microM), and moderate negative inotropic action (maximum decrease in tension was approximately 15% of control values) in Langendorff-perfused hearts but not in papillary muscle. In contrast, effluent from homocysteine-treated hearts decreased contractility in papillary muscle, and all inotropic actions were largely eliminated when brief Triton X-100 treatment was utilized to inactivate the coronary endothelium in the intact heart. The homocysteine-induced decrease in contractile function was not antagonized by N(omega)-nitro-l-arginine, a nitric oxide synthase inhibitor, or the cyclooxygenase inhibitor indomethacin. Thus data suggest that pathophysiological concentrations of homocysteine elicit an acute negative inotropic effect on ventricular myocardium that is mediated by a coronary endothelium-derived agent other than nitric oxide or products of cyclooxygenase. Future studies are required to elucidate the mechanism by which homocysteine acts to elicit the release of the proposed endothelial mediator, the identity of the proposed paracrine agent, and the mechanism of its negative inotropic action.     

Energetics of the Frank-Starling effect in rabbit myocardium: economy and efficiency depend on muscle length

We tested the hypothesis that economy and efficiency are independent of length in intact cardiac muscle over its normal working range. We measured force, force-time integral, force-length area, and myocardial oxygen consumption in eight isometrically contracting rabbit right ventricular papillary muscles. 2,3-Butanedione monoxime was used to partition nonbasal oxygen consumption into tension-independent and tension-dependent components. Developed force, force-time integral, and force-length area increased by factors of 2.4, 2.7, and 4.8, respectively, as muscle length was increased from 90% to 100% maximal length, whereas tension-dependent oxygen consumption increased only 1.6-fold. Economy (the ratio of force-time integral to tension-dependent oxygen consumption) increased significantly with muscle length, as did contractile efficiency, the ratio of force-length area to tension-dependent oxygen consumption. The average force-length area-nonbasal oxygen consumption intercept was more than the twice tension-independent oxygen consumption. We conclude that economy and efficiency increase with length in rabbit myocardium. This conclusion is consistent with published data in isolated rabbit and dog hearts but at odds with studies in skinned myocardium.     

Role of endothelial cells in modulation of contractility induced by hexarelin in rat ventricle.

The synthetic growth hormone (GH) secretagogue hexarelin has important cardiac effects, that include a reduction of dysfunction in ischemic-reperfused hearts from GH-deficient rats after a chronic treatment and an increase of ejection fraction in acutely treated men. To investigate the mechanisms of its cardiac activity, we studied the effects of hexarelin (1-10 microM) on contractility of rat papillary muscles. We observed, in hexarelin treated papillary muscles, an improved recovery of contractility after anoxia. Hexarelin induced time- and frequency-dependent inotropic effects on papillary muscle. These effects were a transient increase in contractile force, abolished by propranolol (0.2 microM), followed by a reduction at low (60-240/min), but not at high (400-600/min) beating frequencies. The typical negative force-frequency relationship present in rat papillary muscles was therefore modified, and a minor increase in diastolic tension occurred after a sudden increase in stimulus frequency. Blockade of NO synthesis with 1 mM L-NAME, partially altered the response to hexarelin. MK-677 (1 microM), a non peptidyl GH secretagogue, reduced contractility, but did not alter the force-frequency relationship. The remaining effects of hexarelin were absent in papillary muscles pre-treated with indomethacin (1 microM), or after removal of endocardial endothelium with 0.5% triton X-100. The release of the prostacyclin metabolite 6-keto-PGF1alpha was increased during reoxygenation after a period of anoxia in hexarelin treated papillary muscles. Hexarelin had no significant effect on calcium transients and on I(Ca) measured in isolated ventricular cells. These findings suggest that the effects of hexarelin are mainly due to endothelium-released PGI2.     

Relationship between force and intracellular [Ca2+] in tetanized mammalian heart muscle

To determine features of the steady state [Ca2+]-tension relationship in intact heart, we measured steady force and intracellular [Ca2+] ([Ca2+]i) in tetanized ferret papillary muscles. [Ca2+]i was estimated from the luminescence emitted by muscles that had been microinjected with aequorin, a Ca2+-sensitive, bioluminescent protein. We found that by raising extracellular [Ca2+] and/or by exposing muscles to the Ca2+ channel agonist Bay K 8644, tension development could be varied from rest to an apparently saturating level, at which increases in [Ca2+]i produced no further rise in force. 95% of maximal Ca2+-activated force was reached at a [Ca2+]i of 0.85 +/- 0.06 microM (mean +/- SEM; n = 7), which suggests that the sensitivity of the myofilaments to [Ca2+]i is far greater than anticipated from studies of skinned heart preparations (or from previous studies using Ca2+-sensitive microelectrodes in intact heart). Our finding that maximal force was reached by approximately 1 microM also allowed us to calculate that the steady state [Ca2+]i-tension relationship, as it might be observed in intact muscle, should be steep (Hill coefficient of greater than 4), which is consistent with the Hill coefficient estimated from the entire [Ca2+]i-tension relationship derived from families of variably activated tetani (6.08 +/- 0.68; n = 7). Finally, with regard to whether steady state measurements can be applied directly toward understanding physiological contractions, we found that the relation between steady force and [Ca2+]i obtained during tetani was steeper than that between peak force and peak [Ca2+]i observed during physiological twitches.     

O2(*-) production at 37 degrees C plays a critical role in depressing tetanic force of isolated rat and mouse skeletal muscle

To find out whether the decrease in muscle performance of isolated mammalian skeletal muscle associated with the increase in temperature toward physiological levels is related to the increase in muscle superoxide (O(2)(*-)) production, O(2)(*-) released extracellularly by intact isolated rat and mouse extensor digitorum longus (EDL) muscles was measured at 22, 32, and 37 degrees C in Krebs-Ringer solution, and tetanic force was measured in both preparations at 22 and 37 degrees C under the same conditions. The rate of O(2)(*-) production increased marginally when the temperature was increased from 22 to 32 degrees C, but increased fivefold when the temperature was increased from 22 to 37 degrees C in both rat and mouse preparations. This increase was accompanied by a marked decrease in tetanic force after 30 min incubation at 37 degrees C in both rat and mouse EDL muscles. Tetanic force remained largely depressed after return to 22 degrees C for up to 120 min. The specific maximum Ca(2+)-activated force measured in mechanically skinned fibers after the temperature treatment was markedly depressed in mouse fibers but was not significantly depressed in rat muscle fibers. The resting membrane and intracellular action potentials were, however, significantly affected by the temperature treatment in the rat fibers. The effects of the temperature treatment on tetanic force, maximum Ca(2+)-activated force, and membrane potential were largely prevented by 1 mM Tempol (4-hydroxy-2,2,6,6-tetramethylpiperidine-1-oxyl), a membrane-permeable superoxide dismutase mimetic, indicating that the increased O(2)(*-) production at physiological temperatures is largely responsible for the observed depression in tetanic force at 37 degrees C by affecting the contractile apparatus and plasma membrane.     

Activity-induced recovery of excitability in K(+)-depressed rat soleus muscle

Increased extracellular K(+) concentration ([K(+)](o)) can reduce excitability and force in skeletal muscle. Here we examine the effects of muscle activation on compound muscle action potentials (M waves), resting membrane potential, and contractility in isolated rat soleus muscles. In muscles incubated for 60 min at 10 mM K(+), tetanic force and M wave area decreased to 23 and 24%, respectively, of the control value. Subsequently, short (1.5 s) tetanic stimulations given at 1-min intervals induced recovery of force and M wave area to 81 and 90% of control levels, respectively, within 15 min (P < 0.001). The recovery of force and M wave was associated with a partial repolarization of the muscle fibers. Experiments with tubocurarine suggest that the force recovery was related to activation of muscle Na(+)-K(+) pumps caused by the release of some compound from sensory nerves in response to muscle activity. In conclusion, activity produces marked recovery of excitability in K(+)-depressed muscle, and this may protect muscles against fatigue caused by increased [K(+)](o) during exercise.     

Effects of low temperature on contraction in papillary muscles from rabbit, rat, and hedgehog

During hibernation the body temperature may fall to only a few degrees above 0 degree C. The heart of the hedgehog continues to function whereas the hearts of nonhibernating mammals stop beating. The present study was performed to investigate and compare the mechanical responses to hypothermia in rabbits, rats, and hedgehogs. Isometric force was recorded from papillary muscles mounted in an organ bath and effects of hypothermia on the mechanical restitution curve were also compared. A reduction of bath temperature from 35 degrees C caused an increase in peak developed force. Maximum force was seen at 20 degrees C in the rabbit, 15 degrees C in the rat, and 10 degrees C in the hedgehog preparations. In all the species there was a similar prolongation of time to peak force and of time from peak to half-relaxation as temperature was lowered. An increase in resting force and after-contractions were recorded in the rabbit and rat muscles at temperatures below 15 and 10 degrees C, respectively. The rabbit and rat preparations became inexcitable at temperatures below 10 and 5 degrees C, respectively. The hedgehog papillary muscle, on the other hand, still contracted at 0 degree C and did not show increased resting force nor after-contractions. The results are consistent with the hypothesis that there is a calcium overload in cardiac cells from rabbit and rat at low temperatures but there is no calcium overload in the hedgehog muscle during hypothermia.     

Effect of sustained hypobaric hypoxia during maturation and aging on rat myocardium. I. Mechanical activity.

Long-lasting cardioprotection may be attained by chronic hypoxia. The basal parameters of contractile function and their response to hypoxia/reoxygenation were measured under isometric conditions, in papillary muscles isolated from left ventricle of rats that were submitted to 53.8 kPa in a hypobaric chamber from 7 wk of age and for their lifetime and of their siblings kept at 101.3 kPa. During acclimatization, hematocrit increased, body weight gain decreased, and heart weight increased with right ventricle hypertrophy. Papillary muscle cross-sectional area was similar in both control and hypoxic groups up to 45 wk of exposure. Developed tension (DT) was 34-64% higher in rats exposed to hypoxia for 10, 26, and 45 wk than in their age-matched controls, whereas resting tension was unchanged. Maximal rates of contraction and relaxation showed a similar pattern of changes as DT. Recovery of DT and maximal rates of contraction and relaxation after 60-min hypoxia and 30-min reoxygenation was also improved in adult hypoxic rats to values similar to those of young rats. Heart acclimatization was lost after 74 wk of exposure. Results are consistent with the development of cardioprotection during high-altitude acclimatization and provide an experimental model to study the mechanisms involved, which are addressed in the accompanying paper.     

增强Na+-Ca2+交换对大鼠心脏的正性变力作用及对哇巴因效应的加强

本文采用大鼠乳头肌张力测定及离体心脏灌流技术,研究大鼠心肌Na -Ca2 交换对乳头肌及离体灌流心肌变力性的影响。采用大鼠特异性Na -Ca2 交换激动剂E-4031能剂量依赖性地增加大鼠乳头肌的发展张力(P<0.05,n=6)及离体心脏的心泵功能(P<0.05,n=4);特异性Na -Ca2 交换抑制剂KB-R7943具有相反的效应,并可完全消除E-4031引起的正性变力作用。哇巴因(ouabain,0.5μmol/L)与E-4031(3μmol/L)联合使用,可使乳头肌发展张力由单独使用哇巴因时的0.25±0.03 g升高至0.29±0.04g(P<0.05,n=6);联合用药对大鼠离体心脏心泵功能的影响也强于哇巴因单独作用的效果。本研究结果证实,E-4031通过增强心肌Na -Ca2 交换,对大鼠乳头肌和离体心脏产生正性变力作用;与哇巴因合用时,它们的正性变力作用有相加作用。     

Intracellular calcium related to force development in twitch contraction of mammalian myocardium

To characterize the relationship between force production and Ca2+ occupancy of troponin C, investigators have related peak intracellular Ca2+, measured with a variety of Ca2(+)-indicators, and peak force during twitches. Inherent in the force-[Ca2+] relationship is the responsiveness of the myofilaments to Ca2+ which can be altered by different pharmacological manipulations. In this study we compared the force-[Ca2+] relationship obtained in aequorin-injected papillary muscles and saponin skinned trabeculae from control, right ventricular pressure-overload hypertrophy (POH), and hyperthyroid ferret hearts. In POH, the twitch and [Ca2+]i transient were prolonged as compared to control. Force-[Ca2+] relationships from skinned fiber preparations were superimposable between control and POH. The peak force-peak [Ca2+]i relationship in intact muscles from POH was shifted to the left as compared to control. In hyperthyroid hearts, the twitch and [Ca2+]i were abbreviated. Force-[Ca2+]i relationships from skinned fiber preparations were superimposable between control and thyrotoxic hearts. The peak force-peak [Ca2+]i relationship in intact muscles from hyperthyroid hearts was shifted to the right as compared to control. Our findings indicate that time course changes in the calcium transient artifacturally shift the peak force-peak calcium relationship in a predictable manner. Therefore, this relationship can not be used to address changes at the level of the myofilaments as previously suggested.     

The extracellular matrix in hibernating myocardium - a significant factor causing structural defects and cardiac dysfunction

The time course of force generation and the time course of muscle stiffness were measured in rabbit soleus muscles during eccentric contraction to understand the underlying basis for the force loss in these muscles. Muscles were activated for 600 msec every 10 sec for 30 min. Soleus muscles contracting isometrically maintained constant tension throughout the treatment period, while muscles subjected to eccentric contraction rapidly dropped tension generation by 75% within the first few minutes and then an additional 10% by the end of 30 min. This indicated a dramatic loss in force-generating ability throughout the 30 min treatment period. To estimate the relative number of cross-bridges attached during the isometric force generation phase immediately preceding each eccentric contraction, stiffness was measured during a small stretch of a magnitude equal to 1.5% of the fiber length. Initially, muscle stiffness exceeded 1300 g/mm and, as eccentric treatment progressed, stiffness decreased to about 900 g/mm. Thus, while muscle stiffness decreased by only 30% over the 30 min treatment period, isometric force decreased by 85%. In isometrically activated muscles, stiffness remained constant throughout the treatment period. These data indicate that, while soleus muscles decreased their force generating capability significantly, there were a number of cross-bridges still attached that were not generating force. In summary, the loss of force generating capacity in the rabbit soleus muscle appears to be related to a fundamental change in myosin cross-bridge properties without the more dramatic morphological changes observed in other eccentric contraction models. These results are compared and contrasted with the observations made on muscles composed primarily of fast fibers.     

Sustained postischemic cardiodepression following magnesium-diltiazem cardioplegia

Magnesium-diltiazem cardioplegia was evaluated in the intact, perfused rat heart to determine whether the joint administration of these agents would adversely affect myocardial contractile and high-energy phosphate recovery following intermittent, normothermic global ischemic arrest. Sequential metabolic and functional analyses were performed on isolated perfused rat hearts during each phase of the experimental protocol: control (10 min), normoxic cardioplegia (10 min), intermittent global ischemic arrest (two 15-min periods separated by 2 min infusion of the normoxic cardioplegic perfusate), and normoxic postischemic control reperfusion (60 min). Four different cardioplegic solutions were evaluated: 30 mM KCl, 30 mM KCl with 2 mg diltiazem/liter, 20 mM MgCl2, and 20 mM MgCl2 with 2 mg diltiazem/liter. Myocardial phosphatic metabolite levels and intracellular pH were analyzed nondestructively in the intact hearts by phosphorus-31 NMR spectroscopy. Corresponding measurements of peak left intraventricular pressure, rate of peak pressure development (dP/dt), and contraction frequency were performed at the midpoint during each 5-min interval of 31P NMR signal averaging. Magnesium plus diltiazem-treated hearts were distinguished from all other groups by a marked delay in postischemic functional recovery consisting of a prolonged depression in contractility (34% of control, P less than 0.01) that persisted throughout the first 50 min of postischemic reperfusion. Diltiazem in combination with magnesium cardioplegia was detrimental to postischemic functional recovery, despite a rapid restoration of high-energy phosphate stores. The apparent adverse interactive effects of excess magnesium and diltiazem suggest that elective ischemic arrest with magnesium cardioplegia in combination with diltiazem may be contraindicated clinically. The mechanistic basis and drug specificity of this response require further clarification. The present findings appear to exclude ATP and PCr production, and structural causes as the basis for the observed aberrant functional recovery from global ischemia of magnesium plus diltiazem-arrested hearts.     

Intracellular Ca2+ storage sites in the carp heart: comparison with the rat heart.

The Ca(2+)-releasing mechanisms of the sarcoplasmic reticulum responsible for cardiac muscle contraction in carp were examined and compared with these mechanisms in rats. Morphologically, the ventricular muscles of the carp heart are composed of an outer compact and an inner spongy layer. In the present study, ventricular muscle preparations were obtained from the compact layer of the carp heart, because the spongy layer does not contribute significantly to the overall force of contraction. Electron microscopic observations showed that the sarcoplasmic reticulum in the carp ventricular muscle, compared to that in the rat ventricular muscle, was poorly developed. Consistent with this finding, specific [3H]ryanodine binding to partially purified sarcoplasmic reticulum preparations obtained from carp ventricular muscle as compared with the preparations isolated from the rat ventricular muscle showed a lower affinity and a smaller number of binding sites. Additionally, a higher Ca2+ concentration was required to cause a half maximal stimulation of [3H]ryanodine binding in the carp heart. In skinned ventricular muscle fibers isolated from carp hearts, the caffeine-induced contracture was significantly weaker than that observed in rat hearts. These results suggest that, in carp hearts, the sarcoplasmic reticulum has an important role as a supply source of Ca2+ for muscle contraction, though the storage capacity and/or amount of Ca2+ release in carp was significantly smaller than that in rats.     

Preserved contractile function despite atrophic remodeling in unloaded rat hearts

The present study was designed to determine whether myocardial atrophy is necessarily associated with changes in cardiac contractility. Myocardial unloading of normal hearts was produced via heterotopic transplantation in rats. Contractions of isolated myocytes (1.2 mM Ca2+; 37 degrees C) were assessed during field stimulation (0.5, 1.0, and 2.0 Hz), and papillary muscle contractions were assessed during direct stimulation (2.0 mM Ca2+; 37 degrees C; 0.5 Hz). Hemodynamic unloading was associated with a 41% decrease in median myocyte volume and proportional decreases in myocyte length and width. Nevertheless, atrophic myocytes had normal fractional shortening, time to peak contraction, and relaxation times. Despite decreases in absolute maximal force generation (F(max)), there were no differences in F(max)/ area in papillary muscles isolated from unloaded transplanted hearts. Therefore, atrophic remodeling after unloading is associated with intact contractile function in isolated myocytes and papillary muscles when contractile indexes are normalized to account for reductions in cell length and cross-sectional area, respectively. Nevertheless, in the absence of compensatory increases in contractile function, reductions in myocardial mass will lead to impaired overall work capacity.     

Antioxidant changes in heart hypertrophy: significance during hypoxia-reoxygenation injury.

Because hypertrophied rat hearts display an increase in antioxidant enzyme activities and because hypoxia-reoxygenation injury is known to involve free radicals, we tested the hypothesis that the hypertrophied heart may be more resistant to this type of injury. Hypertrophied rat hearts after 10 weeks of chronic pressure overload showed elevated superoxide dismutase (SOD) and glutathione peroxidase (GSHPx) activities and a decrease in lipid peroxidation as indicated by malondialdehyde (MDA) content. Glucose-free hypoxia for 15 min resulted in a complete failure of developed tension and about 200% increase in resting tension in both hypertrophied and sham control groups (p < 0.05). Upon reoxygenation for up to 30 min, hypertrophied hearts recovered developed tension to 60% and resting tension was higher by only 80% of prehypoxic values. In contrast, sham hearts showed only a 25% recovery of developed tension, whereas resting tension remained 130% higher than prehypoxic control values. During hypoxia, the SOD activity was significantly reduced in both sham and hypertrophied groups, whereas GSHPx was reduced only in the sham group. Upon reoxygenation there was no further change in these enzyme activities. Both the SOD and GSHPx activities in the hypertrophied group remained significantly higher than the corresponding reoxygenated sham hearts. During hypoxia, there was no apparent change in MDA content in either the sham or hypertrophied hearts. However, reoxygenation resulted in a significant increase in MDA content in both sham and hypertrophied hearts, but the MDA content was significantly less in the hypertrophied group (p < 0.05). It is suggested that maintenance of an adequate endogenous antioxidant reserve during hypoxia may be important in recovery upon reoxygenation.