Effect of cardiolipin oxidation on solid-phase immunoassay for antiphospholipid antibodies

Diagnostic assays for antiphospholipid antibodies are routinely performed on microtitre plates coated with cardiolipin. Here we show that contact between cardiolipin and NUNC-Immuno plates leads to extensive oxidation, generating a series of peroxy-cardiolipins which were identified by electrospray ionization mass spectrometry. To investigate the impact of oxidation on the antibody assay. cardiolipin was resolved into 12 molecular species, including oxidized species and non-oxidized species with different degrees of unsaturation. All 12 species reacted under anaerobic conditions with serum from patients with primary antiphospholipid syndrome. Immune reactivity was similar for tetralinoleoyl-cardiolipin, trilinoleoyl-oleoyl-cardiolipin, and peroxycardiolipins, but somewhat lower for tristearoyl-oleoyl-cardiolipin. Oxidative treatment of cardiolipin with air, cytochrome c, or Cu2+/tert-butylhydroperoxide, either before or during the assay, did not enhance immune reactivity. Similar results were obtained with a monoclonal IgM from lupus-prone mice, that binds cardiolipin in the absence of protein cofactors. We conclude that the solid-phase assay for antiphospholipid antibodies can be supported by various oxidized and non-oxididized molecular species of cardiolipin.

Isoflurane pretreatment ameliorates postischemic neurologic dysfunction and preserves hippocampal Ca2+/calmodulin-dependent protein kinase in a canine cardiac arrest model

BACKGROUND

Inhalational anesthetics are neuroprotective in rat models of global ischemia. To determine whether isoflurane at a clinically relevant concentration is neuroprotective in a canine model of cardiac arrest, we measured neurologic function and hippocampal Ca2+/calmodulin-dependent protein kinase II (CaMKII) content 20 h after cardiac arrest.

METHODS

We tested the neuroprotective effect of 30 min of 1.5% isoflurane exposure before 8 min of global ischemia induced with ventricular fibrillation. Animals were randomized to four groups: control, isoflurane-control, ischemia, and isoflurane-ischemia. After resuscitation and 20 h of intensive care, each animal's neurologic deficit score was determined by two blinded evaluators. The hippocampal content of CaMKII, determined by immunoblotting, was measured by an individual blinded to the treatment groups. CaMKII activity was measured in samples from the cortex, hippocampus, and striatum of animals in each group.

RESULTS

Isoflurane-ischemic animals had a median neurologic deficit score of 22.6% compared with 43.8% for the ischemic animals (P < 0.05). Hippocampal levels of the beta-subunit of CaMKII (CaMKIIbeta) were relatively preserved in isoflurane-ischemic animals (68 +/- 4% of control) compared with ischemic animals (48 +/- 2% of control; P < 0.001), although both groups were statistically significantly lower than control (P < 0. 001 ischemia vs. control and P < 0.05 isoflurane-ischemia vs. control).

CONCLUSIONS

Isoflurane is an effective neuroprotective drug in a canine cardiac arrest model in terms of both functional and biochemical criteria.

Advances and strategies for spinal cord regeneration

Although a cure for spinal cord injuries does not currently exist, advances have been made in the field of spinal cord regeneration. This article discusses the pathophysiology of spinal cord injury, animal models, and strategies for restoration and regeneration of the spinal cord.

CNS voltage-dependent Na(+) channel expression and distribution in an undifferentiated and differentiated CNS cell line

Upon serum removal, CAD-R1 cells undergo neurite outgrowth and an increase in voltage-dependent Na(+) current (VDNaC) density without changing their activation and inactivation properties. Insulin and endothelial cell growth supplement inhibited the increase in VDNaC density but not the neurite outgrowth. RI, RII, RIII Na(+) channel proteins were expressed in CAD-R1 cells. These proteins exhibited both similar and different distribution and clustering patterns which suggested the channel's structural differences play a role in channel distribution.

Halothane and isoflurane augment depolarization-induced cytosolic CA2+ transients and attenuate carbachol-stimulated CA2+ transients

BACKGROUND

Neuronal excitability is in part determined by Ca2+ availability that is controlled by regulatory mechanisms of cytosolic Ca2+ ([Ca2+]cyt). Alteration of any of those mechanisms by volatile anesthetics (VAs) may lead to a change in presynaptic transmission and postsynaptic excitability. Using a human neuroblastoma cell line, the effects of halothane and isoflurane on cytosolic Ca2+ concentration ([Ca2+]cyt) in response to K+ and carbachol stimulation were investigated.

METHODS

Volatile anesthetic (0.05-1 mm) action on stimulated [Ca2+]cyt transients were monitored in suspensions of SH-SY5Y cells loaded with fura-2. Potassium chloride (KCl; 100 mm) was used to depolarize and activate Ca2+ entry through voltage-dependent calcium channels; 1 mm carbachol was used to activate muscarinic receptor-mediated inositol triphosphate (IP3)-dependent intracellular Ca2+ release. Sequential stimulations, KCl followed by carbachol and vice versa, were used to investigate interactions between intracellular Ca2+ stores.

RESULTS

Halothane and isoflurane in clinically relevant concentrations enhanced the K+-evoked [Ca2+]cyt transient whether intracellular Ca2+ stores were full or partially depleted. In contrast, halothane and isoflurane reduced the carbachol-evoked [Ca2+]cyt transient when the intracellular Ca2+ stores were full but had no effect when the Ca2+ stores were partially depleted by KCl stimulation.

CONCLUSIONS

Volatile anesthetics acted on sites that differently affect the K+- and carbachol-evoked [Ca2+]cyt transients. These data suggest the involvement of an intracellular Ca2+ translocation from the caffeine-sensitive Ca2+ store to the inositol triphosphate-sensitive Ca2+ store that was altered by halothane and isoflurane.

Permeability of rat heart myocytes to cytochrome c

Rat heart myocytes undergoing progressive damage demonstrate morphological changes of shortening and swelling followed by the formation of intracellular vacuoles and plasma membrane blebbing. The damaged myocytes displayed impaired N,N'-tetramethyl-p-phenyldiamine (TMPD) ascorbate-stimulated respiratory activity which was restored by the addition of reduced cytochrome c to the cell culture medium. To clarify the role played by cytochrome c in the impairment of cell respiration, polarographic, spectrophotometric and fluorescence as well as electron microscopy imaging experiments were performed. TMPD/ascorbate-stimulated respiratory activity returned to control levels, at approximately 20 microM cytochrome c, establishing the threshold below which the turnover rate by cytochrome c oxidase in the cell depends on cytochrome concentration. Mildly damaged cardiac myocytes, as indicated by cell shortening, retention of visible striations and free-fluorescein exclusion, together with the absence of lactate dehydrogenase leakage and exclusion of trypan blue, were able to oxidize exogenous cytochrome c and were permeable to fluorescein-conjugated cytochrome c. The results, while consistent with an early cytochrome c release observed at the beginning of cell death, elucidate the role played by cytochrome c in the kinetic control of mitochondrial electron transfer under pathological conditions, particularly those involving the terminal part of the respiratory chain. These data are the first to demonstrate that the sarcolemma of cardiac myocytes, damaged but still viable, is permeable to cytochrome c.

Volatile anesthetic action on muscle Ca2+ homeostasis

It is proposed that volatile anesthetics act through the modification of Ca2+ homeostasis in excitable cells. To test this hypothesis, cardiac and skeletal muscles were used as models to examine Ca2+ response, and Ca2+ regulatory and delivery mechanisms. I found that halothane did not alter Ca2+ binding to cardiac troponin C. However, halothane and isoflurane reversibly decreased the Ca2+ affinity of calmodulin at low anesthetic concentration, and irreversibly increased the Ca2+ affinity of calmodulin at high anesthetic concentration. The volatile anesthetics also increased the permeability of light fraction of sarcoplasmic reticulum (SR) to Ca2+. I conclude that volatile anesthetics alter calcium homeostasis in cardiac and skeletal muscles. This work was in part performed in collaboration with Giovanni Salviati and the author benefited from Salviati's work in similar areas.

Microanalysis of cardiolipin in small biopsies including skeletal muscle from patients with mitochondrial disease

Cardiolipin is a specific mitochondrial phospholipid that is present in mammalian tissues in low concentration. To measure cardiolipin in small biopsies from patients with mitochondrial disease, we developed a new technique that can detect subnanomolar levels of well-resolved molecular species, the most abundant of which are tetralinoleoyl-cardiolipin (L(4)) and trilinoleoyl-oleoyl-cardiolipin (L(3)O). To this end, a fluorescence-labeled derivative of cardiolipin (2-[naphthyl-1'-acetyl]-cardiolipin dimethyl ester) was formed and analyzed by high performance liquid chromatography. Cardiolipin was measured in skeletal muscle biopsies from 8 patients with mitochondrial disease and in 17 control subjects. In 5 patients with mitochondrial disease, cardiolipin content was higher than normal (2. 4;-7.0 vs. 0.4;-2.2 nmol/mg protein). In 3 patients with mitochondrial disease, the L(4)/L(3)O ratio was lower than normal (2;-4 vs. 4;-6). Cardiolipin was also measured in various rat and dog muscle tissues. The L(4)/L(3)O ratio was higher in condensed "muscle" type mitochondria (heart ventricle, skeletal muscle, ratios 4;-7) than in orthodox "liver" type mitochondria (liver, smooth muscle, heart auricular appendage, H9c2 myoblasts, ratios 0.4;-3), suggesting that the L(4)/L(3)O proportion is important for cristae membrane structure. We concluded that the L(4)/L(3)O ratio is a tissue-specific variable that may change in the presence of mitochondrial disease. The new method is suitable to measure cardiolipin in muscle biopsies in order to estimate concentration of mitochondria.

Halothane and isoflurane alter calcium dynamics in rat cerebrocortical synaptosomes

An increase in synaptosomal Ca2+ triggers neurotransmitter release and volatile anesthetics have been shown to inhibit neurotransmitter release by inhibition of Ca2+ entry. We have examined the effect of isoflurane and halothane on the kinetics of increase and decrease of Ca2+ in rat cerebrocortical synaptosomes ([Ca2+]in). We have also used specific Ca2+ antagonists to examine the role of L-, N-, and P-type Ca2+ channels. Synaptosomal [Ca2+]in was measured spectrofluorometrically using fura-2 as a Ca2+ reporter; Ca2+ transients were initiated by depolarization with 40 mM KCl. We found that < or = 1 minimum alveolar anesthetic concentration halothane and isoflurane decreased peak [Ca2+]in by approximately 40%, that both anesthetics decreased the rate of [Ca2+]in increase and decrease, that specific voltage-dependent calcium channel antagonists had little effect on peak or plateau [Ca2+]in, and that the volatile anesthetics increased the permeability of synaptosomal membranes to Ca2+. These results suggest that the volatile anesthetics, at clinically relevant concentrations, can alter Ca2+ homeostasis in the synapse.

IMPLICATIONS

Clinically relevant concentrations of halothane and isoflurane markedly depress K+-evoked increases in rat cerebrocortical synaptosomal calcium (Ca2+) unrelated to L-, N-, and P-type voltage-dependent calcium channels and increase the Ca2+ permeability of the synaptosomal membrane. These changes in Ca2+ dynamics could have profound effects on Ca2+ signaling in the synapse.

The effects of halothane on single human neuronal L-type calcium channels

We investigated halothane's effects on the function of L-type Ca2+ channels in a human neuronal cell line, SH-SY5Y, by using the cell-attached patch voltage clamp configuration and Ba2+ as the charge carrier. In multiple-channel patches, halothane decreased the peak and persistent Ba2+ currents, accelerated the rate of inactivation, and slowed the rate of activation. Single-channel analysis showed that halothane (0.14-1.26 mM) increased the latency time for the first channel opening, increased the lifetime of nonconducting events, increased the proportion of short-lived open events, decreased the lifetime of the two open populations, and increased the percentage of current traces without channel activity. All of the observed halothane effects contribute to the halothane-induced decrease in macroscopic Ba2+ currents. The halothane concentration producing 50% reduction (IC50) of the peak Ba2+ current was 0.80 mM (approximately 1.9 hypothetical minimum alveolar anesthetic concentration [H-MAC] at 28 degrees C) and of the persistent Ba2+ current was 0.69 mM (approximately 1.7 H-MAC). The halothane effects did not always occur together, and the Hill slope of 1.6 suggested the presence of more than one interaction site or of more than one population of L-type Ca2+ channels. Halothane reduces L-type Ca2+ channel currents in human neuronal cells primarily through the stabilization of nonconducting states such as closed (before and after channel opening) and inactivated states.

IMPLICATIONS

Calcium is a signaling molecule in neurons. We measured the effect of halothane on Ba2+ (a Ca2+ surrogate) movement into a human neuron-like cell electronically. Ba2+ entry through the L-type channel was depressed. Halothane decreased the likelihood of the channel opening and enhanced the rate at which the channel closed and inactivated. These actions of halothane are probably related to its anesthetic action.

Global ischemia increases the density of voltage-dependent calcium channels in porcine cardiac sarcolemma

The objective of this work was to determine whether normothermic global cardiac ischemia in a porcine model was associated with a change in the density (Bmax) of voltage-dependent calcium channels in myocardial sarcolemmal membranes. Pigs were anesthetized, a thoracotomy was performed, and samples were taken of the left and right ventricles from control and ischemic hearts. Dihydropyridine-binding sites were quantified using [3H]isradipine, and 5'-nucleotidase activity was measured by the liberation of inorganic phosphate from adenosine monophosphate. Bmax and dissociation constants and 5'-nucleotidase activity for control and ischemic tissues, respectively, were compared by using Student's t-test for unpaired samples. After normothermic global ischemia, the Bmax of [3H]isradipine binding increased in the left ventricle by 81% (299% +/- 1.7% to 540% +/- 11% fmoles/mg, P < 0.01) and in the right ventricle by 33% (387% +/- 9.9% to 515% +/- 38% fmoles/mg, P < 0.01) compared with control. 5'-nucleotidase activity increased by 48% in the left ventricle and by 96% in the right ventricle (p < 0.05). Fifteen minutes of normothermic ischemia in the pig is associated with marked sarcolemmal abnormalities, including increases in specific dihydropyridine binding and 5'-nucleotidase activity, which reflect global changes in membrane function, which might contribute to the increase in myoplasmic calcium during ischemia.

Volatile anaesthetic effects on calcium conductance of planar lipid bilayers formed with synthetic lipids or extracted lipids from sarcoplasmic reticulum

Volatile anaesthetics are known to increase leakage of calcium from the light fraction of skeletal sarcoplasmic reticulum (L-SR) which has no calcium release channels. To explore the role of the lipid environment, we have examined the effect of volatile anaesthetics on calcium conductance (gCa) of lipid membranes. Planar lipid bilayers were formed with a mixture of synthetic phospholipids and cholesterol, resembling the composition of SR membranes, or with lipids extracted from skeletal L-SR, gCa was estimated by calculating the calcium transference number (tCa) using diffusion potential measurements. Membranes formed with L-SR-extracted lipids had a higher gCa than membranes formed with synthetic lipids. Volatile anaesthetics increased total conductance and gCa in a dose-dependent manner, but did not affect tCa or membrane specific capacitance. In membranes formed with L-SR-extracted lipids, isoflurane induced the largest increase in gCa (1260 (SEM 304) % increase, n = 4, 0.94 mmol litre-1), followed by enflurane (264 (75)%, n = 5, 1.88 mmol litre-1) and halothane (53 (33)%, n = 5; 1.54 mmol litre-1). In membranes formed with synthetic lipids, volatile anaesthetic-induced increases in gCa followed the same trend but were larger. Volatile anaesthetics increased gCa without changing the ionic selectivity of membranes. However, the magnitude of the increase in gCa in the presence of volatile anaesthetics cannot account for the previously observed calcium leakage from L-SR vesicles. Therefore, the volatile anaesthetic-induced increase in calcium leakage in L-SR vesicles must be mediated via other pathways involving membrane proteins.

Halothane and isoflurane alter the Ca2+ binding properties of calmodulin

BACKGROUND

Ca2+ plays an important role in signal transduction and anesthetic mechanisms. To date, no one has observed a direct effect of volatile anesthetics on a Ca(2+)-binding protein. We therefore examined the effects of halothane and isoflurane on the Ca(2+)-binding properties of bovine brain calmodulin.

METHODS

The fluorescence emission of calmodulin was obtained over a range of Ca2+ concentrations (10(-7)-10(-4)M) in the presence and absence of halothane and isoflurane. The intrinsic tyrosine fluorescence of calmodulin was measured at an excitation wavelength of 280 nm and an emission wavelength of 320 nm. Fluorescence measurements were carried out in 50 mM hydroxyethylpiperazineethane sulfonic acid, 100 mM KC1, and 2 mM ethyleneglycol-bis-(beta-aminoethyl ether) tetraacetic acid at pH 7.0 and 37 degrees C. Experiments were performed in polytetrafluorethylene-sealed cuvettes so that the volatile anesthetic concentrations remained constant. The titration data were analyzed in two ways. The data were fit to the Hill equation by using nonlinear regression analysis to derive the Hill coefficient and the dissociation constant. The data were also analyzed by two-way analysis of variance with multiple comparisons to determine statistically significant effects. Volatile anesthetic concentrations were measured by gas chromatography.

RESULTS

The presence of volatile anesthetics altered the Ca(2+)-binding affinity of calmodulin in a dose-dependent fashion. At 0.57% (0.25 mM) halothane and 1.7% (0.66 mM) isoflurane, the affinity of calmodulin for Ca2+ relative to control was decreased. However, at higher concentrations of both anesthetics, the affinity for Ca2+ was increased. When the volatile anesthetics were allowed to evaporate from the experimental solutions, the observed rightward shift of the calmodulin-Ca2+ binding curve for Ca2+ at low concentrations of the anesthetics returned to the control position. The leftward shift seen at high concentrations of the anesthetics was irreversible after evaporation of 8.7% (3.3 mM) isoflurane and 5.7% (2.5 mM) halothane.

CONCLUSIONS

These data demonstrate a complex interaction of two hydrophobic volatile anesthetics with calmodulin. A biphasic effect was observed both for halothane and for isoflurane. Calmodulin, an EF-hand Ca(2+)-binding protein, undergoes a conformational shift when binding Ca2+, exposing several hydrophobic residues. These residues may be sites at which the anesthetics act.

Calcium-dependent translocation of sorcin to membranes: functional relevance in contractile tissue

Sorcin, a 22 kDa calcium binding protein present in abundance in cardiac tissue and in multi-drug resistant cells and previously described as a soluble protein, is now shown to undergo a calcium-dependent translocation process from the cytosol to cellular membranes in both systems. The translocation process takes place also in E. coli BL21 cells that express recombinant sorcin, r-sorcin, and can be exploited in the purification of the protein. Calcium binding to purified r-sorcin occurs at micromolar concentrations of the metal and is accompanied by a conformational change that renders the protein soluble in the non-ionic detergent Triton X-114. This finding suggests that lipids are the target of sorcin on cellular membranes. The possible significance of the calcium-dependent translocation of sorcin in the specialized functions of sorcin-expressing cells is discussed.

The effects of halothane on voltage-dependent calcium channels in isolated Langendorff-perfused rat heart

BACKGROUND

Halothane has been previously shown in vitro to decrease both the inward calcium current in isolated cells and the density of calcium antagonist binding sites in cardiac sarcolemmal membranes prepared from several species, including humans, presumably contributing to the negative inotropic effects seen with volatile anesthetics. In this study we examined whether halothane produced similar changes in calcium channel antagonist binding characteristics ex vivo in an intact perfused heart by using isradipine, a dihydropyridine calcium channel blocker that binds specifically to the alpha 1 subunit of the L-type voltage-dependent calcium channel.

METHODS

The rat hearts were perfused by the Langendorff method in the presence of halothane and unlabeled isradipine. After the hearts were homogenized and prepared into membranes, a radioligand binding assay was performed and binding curves obtained. Data were analyzed by nonlinear regression analysis of a one-site binding equation and were evaluated by a paired t test.

RESULTS

Halothane protected or inhibited the binding of unlabeled isradipine to calcium channels in a dose-dependent manner such that as the halothane is removed during the membrane preparation process, previously obscured sites were then available for specific binding of the radioligand. The sites that were protected by halothane had a lower affinity for [3H]-isradipine than controls.

CONCLUSIONS

In both isolated membranes and the intact heart, halothane changes the availability of calcium channel antagonist binding sites, indicating a change in conformation of the voltage-dependent calcium channel in the presence of anesthetic. This change may result from a direct effect on the protein or from an indirect effect mediated through the membrane lipid bilayer. It also is demonstrated that halothane "protected" channels are probably a modified class of channels compared to those in control tissues as exemplified by the much lower affinity that the protected channels have for [3H]-isradipine. We conclude that a major mechanism by which halothane depresses contractility is mediated through the voltage-dependent calcium channel, and this process results from a conformational change in the channel.

Increased activation of L-type voltage-dependent calcium channels is associated with glycine enhancement of N-methyl-D-aspartate-stimulated dopamine release in global cerebral ischemia/reperfusion

We investigated the relationships among N-methyl-D-aspartate, glycine, L-type voltage-dependent calcium channels, and [3H]dopamine release in a canine model of global cerebral ischemia/reperfusion. The binding of [3H]PN200-110 ([3H]isradipine) to L-type voltage-dependent calcium channels, that open as a consequence of N-methyl-D-aspartate-induced changes in membrane potential, was approximately doubled in striatal membranes prepared from ischemic animals relative to controls, and remained significantly elevated at 30 min and 2 h of reperfusion. These changes coincided temporally with changes in the ability of the voltage-sensitive calcium channel blocker nitrendipine to inhibit glycine enhancement of N-methyl-D-aspartate-stimulated [3H]dopamine release in striatal slices prepared from the same animals. Compared with nonischemic controls, N-methyl-D-aspartate-stimulated [3H]dopamine release was increased in ischemic animals and remained increased throughout reperfusion up to at least 24 h. Glycine enhanced N-methyl-D-aspartate-stimulated release in all treatment groups. The enhancement of N-methyl-D-aspartate-stimulated dopamine release by glycine was reduced by the inclusion of nitrendipine in striatal slices from ischemic and 30-min reperfused animals. These data suggest that glycine may facilitate opening of the voltage-dependent calcium channels activated by N-methyl-D-aspartate and that this facilitation is blocked by the antagonist nitrendipine.

Lonidamine-mediated respiratory changes in rat heart myocytes: a re-examination of the functional response of mitochondrial cytochrome c oxidase

Respiratory activity of intact cardiac myocytes isolated from rats treated with lonidamine (LND) has been examined under conditions where cytochrome oxidase turns over at its maximal rate. Compared to myocytes isolated from control rat hearts, those treated with LND displayed a 60% increase in the cytochrome oxidase-dependent rate of respiration; electron microscopy revealed, in agreement with the literature, that the membrane structure of the mitochondrion had become disorganized. The increase in the rate of oxygen consumption was correlated with the (partial) impairment of the membrane ability to maintain the proton electrochemical potential gradient which normally inhibits oxidase activity. Results are discussed with reference to previous reports showing no effect of LND on cytochrome c oxidase activity. The evidence reported better clarifies the contribution of cytochrome oxidase to the demonstrated energetic failure displayed by cells treated with LND.

2,3,7,8-tetrachlorodibenzo-p-dioxin increases cardiac myocyte intracellular calcium and progressively impairs ventricular contractile responses to isoproterenol and to calcium in chick embryo hearts

Binding by 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) to the Ah receptor leads to transcriptional activation of several genes and a toxicity syndrome that includes tumor promotion, wasting, hormonal and immune system dysfunction, and death. Recent findings indicate that TCDD may also affect cardiac function. Here, we used the chick embryo, a TCDD-sensitive species, to further characterize the effects of TCDD on ventricular muscle contraction and on cardiac myocyte [Ca2+]i assessed with fura 2. The results show that TCDD causes an evolving sequence of contractile defects, independent of changes in diet, first impairing cAMP-modulated contraction (after 48 hr) and later (by seven days) decreasing responses to [Ca2+]o. Phenobarbital, even at high doses, failed to affect the inotropic response to isoproterenol, supporting the specificity of the ventricular contractile effects of TCDD. TCDD treatment also depressed inotropic responses to theophylline and forskolin, indicating that it has a post-beta-adrenergic receptor effect on cAMP action. In contrast to its depression of responses to beta-adrenergic stimuli and to [Ca2+]o, TCDD did not affect initial tensions of ventricular muscle stimulated at 1 Hz or the force-frequency response up to 1 Hz, indicating that TCDD-treated ventricles can respond normally at slow rates of stimulation. TCDD treatment depressed lusitropic (relaxation) responses to isoproterenol and to increasing [Ca2+]o indicating that it impairs the ability of the sarcoplasmic reticulum to sequester Ca2+. Fura 2-based measurements showed that [Ca2+]i was nearly doubled after TCDD treatment. The increase in [Ca2+]i is consistent with the decrease in the contractile response to [Ca2+]o, amelioration of the response to isoproterenol by subphysiologic concentrations of [Ca2+]o, and intermittent lack of response to electrical stimulation in high K+ observed in ventricles from TCDD-treated embryos. TCDD treatment also depressed the initial increase in [Ca2+]i by isoproterenol, consistent with the decreased contractile response to isoproterenol. The findings show that TCDD causes well defined, progressive impairment of avian ventricular responses to inotropic stimuli, providing new evidence that the heart is a target of TCDD action and that TCDD disturbs intracellular calcium processing.

Time-resolved optical spectroscopy on intact myocytes

Myocytes prepared from perfused rat heart were studied spectroscopically using a photodiode array spectrophotometer adapted to a rapid mixing stopped-flow apparatus. The isolated cells were found to be viable for 3 to 4 hours, i.e. over the total time of the experiments. Sodium ascorbate and tetramethyl-para-phenylenediamine were used as exogenous reductants. Cytoplasmic and mitochondrial membranes were found to be freely permeable to tetramethyl-para-phenylenediamine. The use of singular value decomposition proved to be powerful in resolving the spectral contributions of the chromophoric components within the overall absorption spectrum. Spectral resolution was improved by adding carbon monoxide at a concentration that kept myoglobin fully saturated without affecting the activity of cytochrome c oxidase. The redox state of cytochrome c and cytochrome a was observed during the steady-state consumption of oxygen and during the reduction following the exhaustion of oxygen. The redox state of the two chromophores was found to be approximately equal and close to 25-30% oxidized during steady-state respiration; during the final reduction they changed simultaneously. These experiments suggest that in living cells, as in the purified enzyme, the rate limiting step of the turnover of cytochrome oxidase is the internal transfer of electrons from cytochrome a to cytochrome a3.

Spectral analysis of cytochromes in rat heart myocytes: transient and steady-state photodiode array spectrophotometry measurements

Myocytes prepared from rat heart have been studied by optical spectroscopy using a photodiode array spectrophotometer adapted to a stopped flow apparatus (PASF). The isolated cells were viable for 3-4 h (i.e., over the total time of the experiments), as tested employing morphological parameters of cell damage, reactivity toward trypan blue, and the ability to use succinate in the absence and presence of digitonin. Respiration was activated by addition of sodium ascorbate and tetramethyl-para-phenylenediamine (TMPD) as exogenous reductants, in order to single out the contributions of cytochrome c and cytochrome c oxidase among the complexes of the mitochondrial respiratory chain. TMPD was shown to be freely permeable across cytoplasmic and mitochondrial membranes, with a measured KD = 0.9 mM. The use of singular value decomposition analysis coupled to PASF acquisition proved very powerful in resolving statically and kinetically, in the millisecond time region, the spectral contributions of the cytochromes. Spectral analysis was improved by adding carbon monoxide at concentrations which did not affect cytochrome c oxidase activity, but kept myoglobin fully saturated (and thus uninfluential to absorbance changes).

Halothane, enflurane, and isoflurane stimulate calcium leakage from rabbit sarcoplasmic reticulum

The sarcoplasmic reticulum (SR) controls uptake and release of Ca2+ in muscle. Little information is available regarding the effect of volatile anesthetics on Ca2+ release from SR isolated from normal skeletal muscle, even though an abnormality of Ca2+ handling is implicated in malignant hyperthermia. In this study we used a Ca2+ electrode to monitor continuously the release of Ca2+ from SR and the effect of volatile anesthetics on this process. We found that halothane, enflurane, and isoflurane at 0.6, 0.7, and 0.8 vol%, respectively, each increased the velocity of Ca2+ leakage by at least 150% when compared to control. Ruthenium red, a blocker of the SR Ca(2+)-release channel, was shown to have no effect on the velocity of Ca2+ leakage. Halothane and isoflurane both shortened the time at which Ca2+ leakage began (T) in a dose-dependent fashion. Halothane at 4.8 vol% decreased T from 293 +/- 21 s to 149 +/- 20 s. Isoflurane (4.8 vol%) decreased T to 203 +/- 16 s, and enflurane at 5 vol% had little effect, decreasing T to 259 +/- 19 s. We noted a marked stimulation in the ATPase activity of the SR by all three volatile anesthetics. Halothane at 0.63 vol%, isoflurane at 0.42 vol%, and enflurane at 0.62 vol% each increased ATPase activity by at least 300%. We conclude that the stimulation of the velocity of Ca2+ leakage by the volatile anesthetics is related to the more rapid depletion of ATP, but that the shortening of the onset of Ca2+ leakage is a independent phenomenon with a markedly different dose dependence.(ABSTRACT TRUNCATED AT 250 WORDS)

Depression of calcium channel blocker binding to rat brain membranes by halothane

The present study evaluates the action of volatile anesthetics on the voltage-dependent Ca2+ channels in isolated rat brain membranes, measured as changes in binding of the Ca2+ channel blocker [3H]isradipine to these membranes. Equilibrium binding studies with increasing concentrations of [3H]isradipine (0.01-1 nM) in the presence of halothane (1.9%), isoflurane (2.3%), and enflurane (4.8%) at 25 degrees C were performed. Only halothane produced a significant depression in the specific binding of isradipine to the brain membranes at 0.5 and 1.0 nM [3H]isradipine (P = 0.028 and 0.018, respectively). Isoflurane and enflurane had such inconsistent effects that the data were inconclusive. Halothane produced a significant dose-dependent inhibition of binding, the maximum inhibition being 44% (P less than 0.005). Nonlinear regression analysis fit of the binding data indicates halothane produced a 48% decrease (P less than 0.05) in the maximal number of binding sites (Bmax) with no effect on the dissociation constant (Kd). As voltage-dependent Ca2+ channels are important in mediating neurotransmission, the marked decrease in channel number (Bmax) associated with halothane exposure suggests that this phenomenon might be related to the mechanism of general anesthesia.

Alteration of voltage-dependent calcium channels in canine brain during global ischemia and reperfusion

Elevated intracellular calcium (iCa2+) plays an important role in the pathophysiology of ischemic brain damage. The mechanisms by which iCa2+ increases are uncertain. Recent evidence implicates the voltage-dependent calcium channel (VDCC) as a likely site for the alteration in Ca2+ homeostasis during ischemia. The purpose of this study was to determine whether VDCCs are altered by global ischemia and reperfusion in a canine cardiac arrest, resuscitation model. We employed the radioligand, [3H]PN200-110, to quantitate the equilibrium binding characteristics of the VDCCs in the cerebral cortex. Twenty-five adult beagles were separated into four experimental groups: (a) nonischemic controls, (b) those undergoing 10-min ventricular fibrillation and apnea, (c) those undergoing 10-min ventricular fibrillation and apnea followed by spontaneous circulation and controlled respiration for 2 and (d) 24 h. Brain cortex samples were taken prior to killing of the animal, frozen immediately in liquid nitrogen, and crude synaptosomal membranes isolated by differential centrifugation/filtration. After 10 min of ischemia the maximal binding (Bmax) of [3H]PN200-110 increased to greater than 250% of control values (control Bmax 11.16 +/- 0.98; ischemic 28.35 +/- 2.78 fmol/mg protein; p less than 0.05). Bmax returned to near control values after 2 h of reperfusion but remained significantly greater than the control at 24 h. Although the affinity constant (Kd) (control = 0.12 +/- 0.03 nM) appeared to increase with ischemia and normalize with reperfusion, the changes were not statistically significant. We conclude that the binding of [3H]PN200-110 to L-type VDCCs is increased after 10 min of global ischemia/anoxia produced by ventricular fibrillation and apnea in the dog.(ABSTRACT TRUNCATED AT 250 WORDS)

Halothane does not alter Ca2+ affinity of troponin C

Troponin C has been suggested as a possible target for the negative inotropic action of volatile anesthetics. This study has examined the effect of halothane on the structure and response of isolated cardiac troponin C to Ca2+ and the response of skinned soleus and cardiac muscle fibers to Ca2+. The high-affinity Ca(2+)-binding sites of cardiac troponin C were assessed by measurement of the change in intrinsic tyrosine fluorescence and ultraviolet circular dichroism in response to Ca2+ in the presence and absence of halothane. Halothane (0.9 mM, 1.4%) did not alter the 45% enhancement in intrinsic tyrosine fluorescence that occurs with saturation of the high-affinity sites or change the Ca2+ concentration at which half-maximal enhancement occurred. The molar ellipticity in the far ultraviolet region, a measure of the secondary structure, increased to a similar extent with addition of 10(-6) M Ca2+ in the absence and presence of 1.0 mM (1.6%) halothane. The binding rate of the sulfhydryl reagent, 5,5'-dithiobis (2-nitrobenzoic acid), to troponin C in response to Ca2+ titration was used as a measure of the integrity of the low-affinity Ca(2+)-binding site in troponin C in the presence and absence of 1.0 mM (1.6%) halothane. The rate of reaction was stimulated twofold, and the half maximal effect was observed at pCa 4.8 +/- 0.2 in both control and halothane-treated samples. Halothane (5 mM; 7.8%) did not change the pCa/tension response of skinned soleus fibers; the data were fit to the Hill equation and yielded dissociation constants of 6.2 x 10(-7) M for control and halothane-treated specimens.(ABSTRACT TRUNCATED AT 250 WORDS)

Hemodynamic effects and onset time of increasing doses of vecuronium in patients undergoing myocardial revascularization

Study objectives were (1) to compare the hemodynamic effects of increasing doses of vecuronium, given as a bolus during induction of anesthesia using high-dose fentanyl, in patients undergoing myocardial revascularization; and (2) to determine whether increasing the dose of vecuronium would decrease the onset time to maximal depression of twitch response. Forty patients scheduled for elective coronary artery bypass surgery were randomly assigned to four equal groups to receive either 0.1, 0.2, 0.3, or 0.4 mg/kg of vecuronium. Hemodynamic measurements and neuromuscular blockade were recorded at five time points: A, awake state; B, anesthetized state after the administration of fentanyl, 10 micrograms/kg; C, 2 minutes after vecuronium bolus; D, 5 minutes after vecuronium bolus; and E, after intubation. Increasing the dose of vecuronium from 0.1 to 0.2 mg/kg decreased the onset time from 3.8 +/- 0.3 minutes to 1.8 +/- 0.2 minutes (P less than 0.05). However, higher doses of vecuronium (0.3 or 0.4 mg/kg) did not result in further decreases in onset time. There were no significant differences in any hemodynamic parameter measured among the four groups in the anesthetized baseline state. Compared with the anesthetized state, the administration of vecuronium resulted in few alterations in hemodynamics within the groups studied. There were no changes in any hemodynamic parameter at 2 and 5 minutes following administration of 0.4 mg/kg of vecuronium. There were also no dose-related changes in any hemodynamic parameter. Thus, high doses of vecuronium of up to 0.4 mg/kg may be administered to patients with coronary artery disease with few hemodynamic changes.(ABSTRACT TRUNCATED AT 250 WORDS)

Halothane depresses D600 binding to bovine heart sarcolemma

Volatile anesthetics exert their negative inotropic effects by interfering with Ca2+ homeostasis in the myocardial cell. The mechanism of this dose-dependent action is uncertain. 3H-D600 (3H-Gallopamil), a Ca(2+)-channel antagonist, binds to the voltage-dependent Ca2+ channels (VDCC) in a specific, saturable, and reversible manner. We used this ligand to study the effect of halothane on the binding characteristics of the VDCC in purified bovine heart sarcolemma. Cardiac sarcolemmal vesicles were isolated from fresh bovine heart by differential centrifugation and filtration. 3H-D600 equilibrium binding assays were performed in the presence or absence of 1.0 mM unlabeled D600 to determine total and nonspecific binding in room air and at 0.7, 1.3, and 2.5% (vol/vol) halothane. Halothane produced a significant dose-dependent and reversible depression of 3H-D600 specific binding in bovine heart sarcolemma. Depression was completely reversed when halothane had evaporated from the samples prior to filtration. Halothane 1.3% (vol/vol) produced a 40% reduction in the maximum binding capacity. The dissociation constant was not affected by any concentration of halothane. One mechanism by which the volatile anesthetics may induce negative inotropism is through the reduction of functional VDCCs in the heart, leading to reduction of Ca2+ entry. The results of this study support this hypothesis.

Volatile anesthetic effects on left ventricular relaxation in swine

The effects of halothane (0.5, 1.0, and 1.5%; n = 10), enflurane (1.0, 2.0, and 3.0%; n = 8), and isoflurane (0.75, 1.5, and 2.25%; n = 8) on isovolumic relaxation were studied in open-chest swine. The time constant for isovolumic left ventricular pressure decline, T, was determined at each anesthetic concentration at the intrinsic heart rate and during atrial pacing to 150 beats per min. The effect of increased left ventricular afterload on T was investigated by partial occlusion of the thoracic aorta to raise the left ventricular systolic pressure to baseline in the presence of volatile anesthetics, and 20% above baseline in the absence of volatile anesthetics. Heart rate and left ventricular systolic pressure decreased substantially with all three anesthetics, whereas left ventricular end-diastolic pressure increased (by 3-4 mmHg). Relaxation time constants increased with all three anesthetics at the intrinsic heart rate; when the heart rate was controlled by pacing, T increased in the halothane and enflurane, but not in the isoflurane, experiments. T was significantly prolonged (by 30-100%) by partial aortic occlusion in the presence of anesthetic, but not in the control measurements. T did not change significantly in the isoflurane experiments when atrial pacing was employed with partial aortic occlusion. The volatile anesthetics, particularly halothane, seem to impair the relaxation process of the left ventricle; further investigation of the mechanisms of this interference, such as anesthetic effects on intracellular calcium movement and total left ventricular load, is warranted.

Depression of myocardial force and stiffness without change in crossbridge kinetics: effects of volatile anesthetics reproduced by nifedipine

The authors examined the effects of nifedipine, a sarcolemmal slow Ca2+ channel blocker, on dynamic stiffness and force of rabbit right ventricular trabeculum and papillary muscle in Ba2+ contracture, in an attempt to reproduce the effects of halothane, enflurane, and isoflurane on a similar preparation as reported by Shibata et al. Once barium contracture force was established, muscle length was perturbed with small amplitude sinusoidal oscillations in the frequency range of 0.1-100 Hz. Nifedipine 1 microM was then added to the superfusate and dynamic stiffness was again measured. Additional barium was used to determine restoration of contracture force to and beyond control levels. Nifedipine produced a significant decrease in contracture force and high-frequency stiffness with no effect on the frequency (fmin) at which stiffness amplitude exhibited a minimum (P less than 0.005). Contracture force and stiffness could be restored by adding additional barium to the nifedipine-treated muscles. These results are similar to those reported by Shibata et al. using volatile anesthetics. Since nifedipine, which acts specifically at the sarcolemmal slow Ca2+ channel, affects contracture force and dynamic stiffness in this preparation in a manner similar to the volatile anesthetics, the authors suggest that the anesthetics studied by Shibata et al. may well exert a significant component of their negative inotropic activity via their action on the sarcolemmal slow Ca2+ channel.

The effect of halothane, enflurane, and isoflurane on the dynamic stiffness of rabbit papillary muscle

The authors examined the effect of halothane, enflurane, and isoflurane on the dynamic stiffness of rabbit papillary muscles in Ba2+ contracture. Ca2+ was replaced by Ba2+ in order to constantly activate myofibrils. The dynamic stiffness of the contractured muscle was examined by exposing the muscle to sinusoidal length perturbations at frequencies of 0.05-30 Hz under two concentrations of anesthetic, approximately 0.5, and 1.5-2 mM, and at two Ba2+ concentrations, 0.5 and 1.5-2 mM. The anesthetics had no effect on the frequency (fmin) at which minimum stiffness occurred, but markedly decreased the stiffness modulus at high frequencies (Khi). The decrease in Khi was significant for all anesthetics at the P less than 0.05 level. Increasing the Ba2+ concentration from 0.5 to 1.5-2 mM in the presence of 0.5 mM of anesthetic resulted in a return of Khi to control levels. The authors conclude that halothane, enflurane, and isoflurane did not alter actin-myosin ATPase kinetics, because fmin was unchanged, but decreased the number of crossbridge interactions, because Khi was significantly decreased by all three anesthetics.

Halothane decreases calcium channel antagonist binding to cardiac membranes

The effect of halothane concentration on the binding of the calcium antagonist, [3H] nitrendipine (3HNTP), to rat and rabbit heart membranes was examined in vitro because it has been hypothesized that one mechanism by which halothane depresses cardiac contractility is by interfering with Ca2+ channel function. Membranes were incubated for 90 minutes in a closed system with 3HNTP and increasing concentrations of halothane. The amount of 3HNTP bound to membranes was quantified by radioligand binding technique and liquid scintillation counting. It was found in both the rat and rabbit cardiac membranes that halothane (0.4-2.0%) caused a dose-dependent decrease in specific 3HNTP binding (P less than 0.0001). The decrease in 3HNTP binding caused by halothane was also found to be reversible. These results indicate that halothane interferes with one property of the Ca2+ channel and suggest that this may be one possible mechanism for the negative inotropic action of halothane.

Creatine kinase activity and temperature in children after cardiac surgery

The preoperative and postoperative serum creatine kinase (CK) activity and postoperative temperatures were studied in children undergoing surgery for congenital heart disease. Using multiple linear and logistic regression and analysis of variance, associations were found between postoperative CK activity (>2000 IU/L) and the use of succinylcholine, aortic cross-clamp time (>30 minutes), cardiopulmonary bypass time (>60 minutes), the development of fever (>38.5 degrees C), and complications. Complications were defined as hemodynamic instability, poor peripheral perfusion, metabolic acidosis, and eventual multiple organ failure. Associations were also found between postoperative fever and the development of complications. The results suggest that children who develop serum CK elevations greater than 2000 IU/L and fever greater than 39.5 degrees C during the early postoperative period after cardiac surgery more often develop serious complications.

Thiopental does not alter Ca2+ uptake by cardiac sarcoplasmic reticulum

The effect of thiopental on Ca2+ uptake by cardiac sarcoplasmic reticulum (SR) isolated from the rabbit was examined to clarify the role of the sarcoplasmic reticulum in the negative inotropic action of thiopental. Thiopental, from 0 to 378 microM, did not alter the rate of Ca2+ uptake by the SR. We also compared the ATP dependence of Ca2+ uptake in the presence and absence of 284 microM thiopental. The Km for ATP and the Vmax of Ca+ uptake were unaffected by thiopental. It is concluded that thiopental does not alter Ca2+ uptake by the SR and that the negative inotropic effects of thiopental occur at other sites in the myocardial cell.

Effects of halothane on myocardial high-energy phosphate metabolism and intracellular pH utilizing 31P NMR spectroscopy

Utilizing 31phosphorus nuclear magnetic resonance (NMR) spectroscopy, the authors tested the two hypotheses that the negative inotropic action of halothane is the result of: 1) myocardial intracellular acidosis, and 2) a decrease in myocardial high-energy phosphates. In isolated, paced, Langendorff-perfused rabbit hearts, halothane (1.5 vol %) dissolved in the coronary perfusate produced a 48 +/- 2% decrease (P less than 0.01) in left ventricular developed pressure. In contrast, halothane administration had no significant effect on myocardial intracellular pH (7.18 +/- 0.04 at control vs 7.21 +/- 0.02 during halothane). Halothane exposure decreased (P less than 0.01) the forward rate constant of the creatine kinase reaction by 32 +/- 6%, as measured using saturation transfer NMR, suggesting a decline in the rate of high-energy phosphate metabolism. This was further indicated by a concomitant decrease (P less than 0.05) in myocardial oxygen consumption (20 +/- 5%). During the halothane-induced reduction in left ventricular developed pressure, only small decreases in the myocardial steady state concentrations of phosphocreatine (7 +/- 1%; P less than 0.01) and beta ATP (12 +/- 4%; P less than 0.05), and an increase in Pi (18 +/- 6%; P less than 0.05) were observed. However, similar changes in steady-state high-energy phosphate metabolites were also measured in time-control hearts not exposed to halothane. These results indicate that the negative inotropic action of halothane is not mediated by myocardial intracellular acidosis. Moreover, these findings do not support the concept that the negative inotropic action of halothane is the result of a reduction in myocardial high-energy phosphates.

The effect of volatile anesthetics on the pH dependence of calcium uptake by cardiac sarcoplasmic reticulum

The effect of volatile anesthetics (VA) on the pH dependence of calcium uptake by cardiac sarcoplasmic reticulum (SR) was studied. SR was incubated at 37 degrees C with 45CaCl2 in the control state (no anesthetic) and in the presence of each of the VA from pH 6.6-7.6. The VA used were: halothane, 1.3%; enflurane, 1.8%; and isoflurane, 1.2%. In the control state, the initial rate of calcium uptake, measured after a 2-min incubation, was maximal at pH 6.8 (mean +/- SEM: 665 +/- 37 nmoles/mg) and markedly inhibited at pH 7.6 (107 +/- 9 nmoles/mg). In the presence of the VA, the calcium uptake rate was mildly depressed (7-32%) at pH 6.6-6.8, unchanged at pH 7.0, and greatly enhanced (52-78%) at pH 7.2-7.6, when compared to control. The maximal uptake of calcium by the SR at a calcium concentration of 10(-6)M, measured by a 20-min incubation, had a similar pH dependence in the control state, with a decline first evident at pH 7.2 and a 50% drop in the maximal uptake of calcium from pH 7.0-7.6. The presence of the VA was associated with a uniform depression of the maximal uptake of calcium by the SR at all pH levels measured. In view of these findings, it appears that pH does affect SR function in the presence of VA. This alteration of the pH effect by VA may be a factor responsible for discrepancies in results previously reported by investigators studying the effects of VA on the uptake of calcium by the SR.

Immediate improvement of dysfunctional myocardial segments after coronary revascularization: detection by intraoperative transesophageal echocardiography

To ascertain the immediate effects of coronary artery bypass grafting on regional myocardial function, intraoperative transesophageal two-dimensional echocardiograms were obtained in 20 patients using a 3.5 MHz phased array transducer at the tip of a flexible gastroscope. Cross-sectional images of the left ventricle were obtained at multiple levels before skin incision and were repeated serially before and immediately after cardiopulmonary bypass. Using a computer-aided contouring system, percent systolic wall thickening was determined for eight anatomic segments in each patient at similar loading conditions (four each at mitral and papillary muscle levels). Of the 152 segments analyzed, systolic wall thickening improved from a prerevascularization mean value (+/- SEM) of 42.7 +/- 2.9% to a postrevascularization mean value of 51.6 +/- 2.6% (p less than 0.001). Thickening improved most in those segments with the worst preoperative function (p less than 0.001). Chest wall echocardiograms obtained 8.4 +/- 2.3 days after operation showed no deterioration or further improvement in segmental motion compared with transesophageal echocardiograms obtained after revascularization. Thus: regional myocardial function frequently improves immediately after bypass grafting, with increases in regional thickening being most marked in those segments demonstrating the most severe preoperative dysfunction, and this improvement appears to be sustained; and in some patients, chronic subclinical ischemic dysfunction is present which can be improved by revascularization.

Low molecular weight proteins in human malignant hyperthermic muscle

Malignant hyperthermia (MH) is a pharmacogenetic disorder provoked by volatile anesthetics and depolarizing muscle relaxants. The preoperative diagnosis of MH is difficult because it requires a large muscle biopsy and a laboratory dedicated to such diagnostic studies. The authors performed electrophoresis of six muscles taken from MH patients or their relatives to determine whether the protein composition is different from normal muscle. MH muscle was found to contain large amounts of two low molecular weight proteins (15,000 daltons and 13,500 daltons) that are not present in normal muscle. Although it has not been determined that these differences are specific for MH, this finding eventually might be of assistance in diagnosing MH.

Association of post-anaesthetic hyperthermia with abnormal muscle characteristics: a case report

A previously healthy 18-year-old male, following appendectomy developed post-anaesthetic hyperthermia (42.1 degrees C) with an elevation of serum creatine kinase and activated partial thromboplastin time. Repeated arterial blood gases were normal. Cooling and anti-pyretic medication did not control the fever. In contrast, sodium dantrolene appeared effective in lowering the patient's temperature and normalizing the vital signs, both acutely and over the following three days. Subsequent muscle biopsy revealed a normal contracture response to caffeine alone or in the presence of halothane. However, the muscle had a larger than normal potentiation of evoked twitch tension in the presence of caffeine and halothane. Electrophoresis of the muscle revealed a marked increase of an unidentified low molecular weight protein. The patient's clinical course, and the results of the muscle studies, suggest that an abnormality of skeletal muscle.

Calcium uptake by isolated sarcoplasmic reticulum: examination of halothane inhibition, pH dependence, and Ca2+ dependence of normal and malignant hyperthermic human muscle

Ca2+ uptake and release in muscle homogenates and fragmented sarcoplasmic reticulum were examined in biopsy specimens from nonsusceptible and malignant hyperthermia (MH) susceptible patients. Ca2+ flux was examined by the filter binding assay technique using 45Ca. It was found that Ca2+ uptake and release were the same in both normal and MH muscle homogenates. Halothane inhibited the uptake of Ca2+ by the sarcoplasmic reticulum. The halothane inhibition of Ca2+ uptake in normal and MH sarcoplasmic reticulum was fitted to a single line with a correlation coefficient (r) of -0.958. The pH and Ca2+ dependence of Ca2+ uptake were the same for both normal and MH sarcoplasmic reticulum. The pK for Ca2+ uptake is approximately 5.9. It is concluded that the Ca2+ uptake function of the muscle from the five patients with MH examined is not abnormal and might not be the locus for the initiation of MH.

Calcium transport by cardiac sarcoplasmic reticulum: modulation of halothane action by substrate concentration and pH

The response of calcium transport to halothane by the cardiac sarcoplasmic reticulum (SR) was investigated to determine whether the SR is a site for anesthetic depression of the myocardium. It was observed that halothane could both stimulate (by 800%) and inhibit (by 500%) calcium transport. The varied effects are dependent on adenosine triphosphate (ATP) and calcium and hydrogen ion concentrations. At 2.25% halothane, the Km for ATP is decreased from 2.35 to 0.712 mM and Vmax is decreased from 292 to 149 nmoles/mg/2min. It was found that the steady-state level of calcium in the SR was decreased by 33% by halothane at pH 6.9, whereas halothane had no effect at pH 7.3. It was concluded that the SR is an unlikely site of halothane-induced myocardial depression in the normal heart when substrate concentrations and pH are maintained. In the ischemic heart in which the pH and substrate concentration have decreased, the interaction of halothane with the SR might contribute to a decrease in Ca2+ for contraction.

Measurement of halothane by ultraviolet spectroscopy

Halothane absorbs strongly in the ultraviolet region of the spectrum. This property has been employed to measure the concentration of halothane in samples in which the effect of halothane on enzyme kinetics was being studied. Halothane can be completely extracted into heptane, displays a concentration-dependent linear increase in absorbance over a broad concentration range, and has a molar extinction coefficient of 447 M cm-1 at 208 nm. The procedure described for the measurement of halothane will enable other investigators who do not have a gas chromatograph to measure the concentration of halothane.