Mechanisms of hypoxia-induced decrease of load dependence of relaxation in cat papillary muscle

Altered resting-state functional networks in patients with premenstrual syndrome: a graph-theoretical based study

Premenstrual syndrome (PMS) is a menstrual cycle-related disorder. Previous studies have indicated alterations of brain functional connectivity in PMS patients. However, little is known about the overall organization of brain network in PMS patients. Functional magnetic resonance imaging data deriving from 20 PMS patients and 21 healthy controls (HCs). Pearson correlation between mean time-series was used to estimate connectivity matrix between each paired regions of interest, and the connectivity matrix for each participant was then binarized. Graph theory analysis was applied to assess each participant's global and local topological properties of brain functional network. Correlation analysis was performed to evaluate relationships between the daily rating of severity of problems (DRSP) and abnormal network properties. PMS patients had lower small-worldness values than HCs. PMS-related alterations of nodal properties were mainly found in the posterior cingulate cortex, precuneus and angular gyrus. The PMS-related abnormal connectivity components were mainly associated with the thalamus, putamen and middle cingulate cortex. In the PMS group, the DRSP score were negatively correlated with the area under the curves of nodal local efficiency in the posterior cingulate cortex. Our study suggests that the graph-theory method may be one potential tool to detect disruptions of brain connections and may provide important evidence for understanding the PMS from the disrupted network organization perspective.

Effects of sevoflurane on the contractility of ferret ventricular myocardium

Isotonic and isometric variables of contractility and relaxation of isolated ferret right ventricular papillary muscles were measured before and during exposure to incremental concentrations of sevoflurane (0-4.9% vol/vol) (30 degrees C) (n = 9). In a second group of muscles (n = 8), effects of sevoflurane were compared with those of low [Ca(2+)](o) (0.45-2.25 mM in steps of 0.45 mM). Sevoflurane caused a reversible concentration-dependent decrease in contractility (ED(50) of developed force 4.6+/-0.9% vol/vol). When compared with twitches of equal amplitude in low extracellular Ca(2+) concentration, sevoflurane accelerated both isometric and isotonic relaxation. The myocardial depressant effect of sevoflurane is less than that of isoflurane and results mainly from a decrease of intracellular Ca(2+) availability. The abbreviated isometric relaxation likely reflects a decrease in Ca(2+) sensitivity and the faster isotonic relaxation may reflect a mild stimulation of Ca(2+) uptake by the sarcoplasmic reticulum.

Impaired load dependence of diaphragm relaxation during congestive heart failure in the rabbit

The load dependence (LD) of relaxation was studied in the diaphragm of rabbits with congestive heart failure (CHF). CHF (n = 15) was induced by combined chronic volume and pressure overload. Aortic insufficiency was induced by forcing a catheter through the aortic sigmoid valves, followed 3 wk later by abdominal aortic stenosis. Six weeks after the first intervention, animals developed CHF. Sham-operated animals served as controls (C; n = 12). Diaphragm mechanics were studied in vitro on isolated strips, at 22 degrees C, in isotonic and isometric loading conditions. Contractility was lower in the CHF group, as reflected by lower total tension: 1.11 +/- 0.10 in CHF vs. 2.38 +/- 0.15 N/cm(2) in C in twitch (P < 0.001) and 2.46 +/- 0.22 in CHF vs. 4.90 +/- 0.25 N. cm(-2) in C in tetanus (P < 0.001). The index LD was used to quantify the load dependence of relaxation: LD is <1 in load-dependent muscles and tends toward 1 in load-independent muscles. LD was significantly higher in CHF than in C rabbits, in both twitch (0.99 +/- 0.01 vs. 0.75 +/- 0.03; P < 0. 001) and tetanus (0.95 +/- 0.02 vs. 0.84 +/- 0.02; P < 0.001). In the CHF rabbits' diaphragm, the fall in total tension was linearly related to the fall in load dependence of relaxation. The decrease in load dependence of relaxation in CHF animals suggests sarcoplasmic reticulum abnormalities. Impairment of the sarcoplasmic reticulum may also partly account for the decrease in contractile performance of diaphragm in CHF animals.

Cardiotoxicity of colchicine in the rat

OBJECTIVES

Colchicine poisoning may be lethal and a decrease in cardiac function has been reported in several case reports, but the precise cardiotoxicity of colchicine remains unknown.

DESIGN

The experimental in vitro study assessed the intrinsic contractility of left ventricular papillary muscle in rats, 24 h after administration of intraperitoneal colchicine or saline.

RESULTS

The administration of colchicine (2 or 4 mg.kg-1) in adult Wistar rats markedly impaired intrinsic myocardial contractility, as shown by a decrease in maximum shortening velocity (-32 and -61%, respectively), active isometric force (-47 and -65%, respectively), and peak power output (-57 and -69%, respectively) of left ventricular papillary muscle. Colchicine impaired isotonic relaxation and load dependence of relaxation, suggesting a decrease in sarcoplasmic reticulum function. Conversely, colchicine significantly accelerated isometric relaxation, suggesting a decrease in calcium myofilament sensitivity. Myothermal economy was markedly impaired only in some rats (3/10 in each group), in which the negative inotropic effect of colchicine appeared to be more particularly pronounced.

CONCLUSION

The results indicate that the administration of high doses of colchicine induced intrinsic cardiotoxic effects. Due to its amplitude, such cardiotoxic action may participate in the fatal outcome of acute colchicine poisoning.

Contraction and relaxation of isolated cardiac myocytes of the frog under varying mechanical loads

The mechanics of cardiac systole and relaxation have been studied primarily at the level of the whole heart or intact muscle. End-systolic pressure-volume relations of frog hearts have been found to be load dependent, whereas those of the mammal are relatively load independent. On the other hand, myocardial relaxation as studied at the muscle level is load independent in the frog but markedly load dependent in the mammal. Interpretation of these studies is complicated because of the unknown contribution of extracellular connective tissue, neurohumoral factors, and, in the case of the heart, the complex chamber geometry. Therefore, it is valuable to study cardiac mechanics at the level of the basic unit of contractile activity--the isolated myocyte. The goal of this study was to subject isolated frog cardiomyocytes to mechanical loading paradigms that mimic those presented to the cells within the heart. In the first part of this study, the afterload and preload of contracting cells were varied to study their effects on the end-systolic force-length relation, which was consistently found to be load independent over the range of isotonic shortening tested (typically 5%). We also investigated the force-length-time response of the cells to test the concept of the heart behaving as a time-varying elastance. Our results suggest that in this regard the frog myocyte behaves like mammalian muscle, and they are consistent with the presence of a small viscosity within the cell. We conclude that the tissue structure of the frog heart may contribute to disparity in mechanical behavior at the different structural levels. In the second part of this study, we subjected isolated frog cardiomyocytes to four different loading paradigms to test the hypothesis that myocardial relaxation in the frog is independent of load. These sequences consisted of afterloaded contractions followed by conventional isotonic-isometric relaxation (ACCR) or afterloaded contractions followed by physiologically reversed isometric-isotonic relaxation (ACPR). Relaxation was measured under isometric conditions using a variable afterload with either the ACCR or ACPR paradigms. The decay of force was independent of the cell length at which it occurred or the amount of shortening prior to it within the contractile cycle. Relaxation also was measured as relengthening of the cell under isotonic late-load conditions, using the ACPR paradigm either with a variable afterload or variable late load. Relengthening had a time course that was unaffected by changes in afterload (i.e., extents of shortening) or late load (equivalent to the filling pressure for the heart).(ABSTRACT TRUNCATED AT 400 WORDS)

[Mechanisms of action of halogenated anesthetics on isolated cardiac muscle]

The mechanisms responsible for the direct negative inotropic effects of the three currently used volatile anesthetics (halothane, enflurane and isoflurane) are reviewed. These agents interfere at each step of excitation-contraction coupling, i.e. sarcolemmal membrane, sarcoplasmic reticulum and contractile proteins. At the myofilament level, they decrease both calcium sensitivity and maximal developed force of cardiac skinned fibers of various species, a preparation in which all functional membranes are destroyed and thus allowing to study the direct effects of volatile anesthetics on myocardial contractile proteins. The effects of the three volatile anesthetics are similar at equipotent concentrations. The site of action seems to involve the regulatory proteins of the thin myofilament, especially troponin-tropomyosin complex. At the sarcolemmal level, all three anesthetics decrease Ca++ entry through the voltage-dependent calcium channels, an effect that seems slightly more important for both halothane and enflurane than for isoflurane. However, these two sites of action (contractile proteins and sarcolemmal membrane) are not sufficient to explain their overall negative inotropic effect. The third site of action involves the sarcoplasmic reticulum. Halothane and enflurane produce an initial liberation of Ca++ from internal stores, while isoflurane does not. All three agents decrease the net uptake of Ca++ and increase the permeability of sarcoplasmic reticulum to Ca++, similar to the effect of caffeine. However, the resulting effect, i.e. a reduction of sarcoplasmic reticulum Ca++ content occurs at clinical concentrations of halothane or enflurane, while much higher concentrations of isoflurane are required to produce a similar reduction. This differential effect on the sarcoplasmic reticulum function (which is quantitative but not qualitative) seems to be mainly responsible for the lesser negative inotropic effect of isoflurane as observed in intact cardiac muscles of various species including humans. The knowledge of the mechanisms of action of volatile anesthetics is important for understanding the potential consequences associated with their use in patients receiving cardiac drugs, especially calcium blockers and phosphodiesterase inhibitors.

Differences in load dependence of relaxation between the left and right ventricular myocardium as a function of age in rats

To determine whether the variation in the magnitude of work load sustained by the left and right ventricles during adulthood and senescence affects the load-dependent aspect of relaxation, posterior papillary muscles from the left and right ventricles of rats at 4, 10, and 20 months of age were studied under variably loaded conditions in vitro. Because of differences between the life spans of Fischer and Sprague-Dawley rats, the functional characteristics of relaxation were investigated to evaluate the possibility of a differential age-associated response in these two strains of animals. The kinetic performance of the diastolic phase of myocardial contraction was measured by assessing the relative time during which load bearing occurred in a series of afterloaded isotonic twitches. This measurement was expressed as the ratio of the duration of afterloaded isotonic shortening and relengthening to the time required for isometric force to decline to the same level during isometric relaxation. A ratio of less than unity identified a load-dependent state whereas a value greater than one reflected a load-independent condition. Results showed that the right myocardium was completely load independent whereas the left myocardium was fully load dependent at all physiological afterloads. Aging reduced the load independence of the right ventricle and the load dependence of the left ventricle in Fischer rats. In contrast, no aging effect on the properties of afterloaded isotonic relaxation was seen in Sprague-Dawley rats. In conclusion, distinct differences exist in the mechanical dynamics of inactivation between the left and right ventricular myocardium. Aging reduced these variations in Fischer rats but had no apparent influence in Sprague-Dawley animals up to 20 months after birth.

Is stiffness increased during ischemia?

Possible sources of increased ventricular stiffness can be more easily appreciated when pressure and volume patterns are considered as a function of time. A discussion on sources of effective or apparent stiffness or stiffness changes includes viscoelastic properties and active behavior at the muscular level. Chamber geometry and coronary vascular pressure and flow are intrinsic ventricular components. Together with the pressure head and crosstalk as extraventricular components, all these properties are integrated to determine intact heart behavior in late relaxation and diastole.

Assessment of diastolic function of the heart: background and current applications of Doppler echocardiography. Part I. Physiologic and pathophysiologic features

In the past, evaluation of the myocardium has been limited to examining systolic function of the heart. Recently, however, investigators have demonstrated that abnormalities of diastolic function of the heart provide important contributions to the signs and symptoms experienced by patients with heart disease. In addition, abnormalities of diastolic function may precede abnormalities of systolic function in the early stages of disease. Diastolic filling of the heart, however, is a complex sequence of interrelated events. In order to understand diastolic function, each of these factors contributing to filling of the heart must be examined. They include relaxation, passive compliance, atrial contraction, erectile effect of the coronary arteries, viscoelastic properties, ventricular interaction, and pericardial restraint--all of which are interrelated. In addition, diastolic factors are affected by changes in loading conditions and contractility, and they demonstrate nonuniformity in time and space. This report provides an overview of these various factors from the clinical perspective, based on studies involving the isolated papillary muscle and the isolated heart as well as basic clinical studies.

Effects of ryanodine on relaxation in isolated myocardium from different animal species

Relaxation in mammalian ventricular cardiac muscle is sensitive to the prevailing load. This "load dependence of relaxation" (LD) can be demonstrated only when an efficient sarcoplasmic reticulum (SR) is present. To define further the role of the SR in LD, we studied contraction and relaxation in cat, rat and frog cardiac muscle after exposure to ryanodine. Ryanodine is a selective inhibitor of calcium release from the SR. This view was confirmed in the present study in single cardiac rat myocytes with functioning SR. Ryanodine did not affect LD in multicellular mammalian myocardium even though it had already significantly depressed contractility, suggesting that calcium release from the SR plays no role in establishing LD. Calcium accumulation in the SR as a consequence of the inhibited release can account for the late depression of LD in the presence of ryanodine.

Differential effects of reoxygenation on intracellular calcium and isometric tension

We used the bioluminescent Ca2+ indicator, aequorin to record intracellular calcium transients during reoxygenation of hypoxic ferret ventricular muscle in order to determine whether alterations in the amplitude and time course of isometric contraction are mediated by changes in [Ca2+]i. Papillary muscles less than or equal to 1 mm in diameter were removed from the hearts of male ferrets and perfused with a bicarbonate-buffered physiologic salt solution at 30 degrees C. Muscles were stimulated to contract isometrically at 0.33 Hz and were loaded with aequorin by a chemical procedure. Hypoxia was induced by changing the gas mixture bubbling the perfusate to 95% N2, 5% CO2; reoxygenation was accomplished by switching the gas mixture to 95% O2, 5% CO2. Hypoxia produced a decrease in peak Ca2+ and tension that was reversed by reoxygenation. However, the effects on tension of changes in oxygenation were greater than expected from the degree of change in [Ca2+]i. The time courses of the Ca2+ transient and isometric twitch moved in opposite directions and were respectively prolonged/abbreviated by hypoxia and abbreviated/prolonged by reoxygenation. These results indicate that changes in the amplitude and time course of the isometric twitch induced by hypoxia and reoxygenation cannot be attributed alone to changes in intracellular Ca2+ availability and are caused in part by a significant decrease in the calcium sensitivity of the contractile apparatus.

Major alterations in relaxation during cardiac hypertrophy induced by aortic stenosis in guinea pig

Left ventricular hypertrophy (LVH) was produced in guinea pigs after aortic stenosis (AS). The percentage of LVH in AS was determined by normalizing left ventricular (LV) weight by the mean LV weight of sham-operated controls (n = 12). After 3 weeks of cardiac overload, a mild LVH (30 +/- 3%) was induced in 17 animals and a relatively severe LVH (56 +/- 3%) was induced in 7 animals. LV papillary muscles were rapidly excised for mechanical studies. No significant differences were observed between control and mild hypertrophy groups. In contrast, a marked decrease in myocardial performance was seen in the more severe cardiac hypertrophy group and was expressed as a percentage of sham-operated levels (Vmax, 22%; active isometric force/mm2, 23%; +dF/dt max/mm2, 26%). Relaxation in this group was still more impaired than contraction (peak lengthening velocity, 14%; -dF/dt max/mm2, 19%). Moreover, the load sensitivity of relaxation was present in both sham-operated controls and mild hypertrophy but almost disappeared in more severe hypertrophy. Isometric relaxation was delayed in the latter group, as shown by the 15% increase of the half-time of the decline of isometric relaxation (t 1/2). On the other hand, acute hypoxia (95% N2-5% CO2 for 20 minutes) also induced a fall in contractility and the disappearance of the load sensitivity of relaxation but with a 67% decrease of t 1/2. Thus, the mechanical analysis of relaxation allows the effects of chronic overload in relatively severe cardiac hypertrophy to be separated from those of acute hypoxia. Moreover, in severe cardiac hypertrophy, the impairment of the load sensitivity of relaxation with increased t 1/2 strongly suggests alterations of the sarcoplasmic reticulum, especially since the moderate decrease in the myofibrillar ATPase activity, which has been observed previously in guinea pig pressure overload, cannot account completely for the marked fall in myocardial performance.