Effect on airway resistance of ketamine by aerosol in guinea pigs

The effect of aerosolized ketamine hydrochloride was investigated by measuring airway resistance with a two-compartment plethysmograph in guinea pigs challenged with histamine. In the first phase of the study, treatment with ketamine prior to histamine challenge did not protect against elevation of airway resistance. In the second phase of the study, ketamine inhalation after histamine challenge did not significantly diminish airway resistance. Aerosolized ketamine is not recommended for use in human subjects with asthma.     

Differential effects of desflurane and halothane on peripheral airway smooth muscle

Volatile anaesthetics have been shown to have direct relaxant effects on airway smooth muscle. We have examined the effects of 0.9, 1.9, and 2.8 dog MAC of desflurane and halothane on isolated proximal and distal canine airways precontracted with acetylcholine. The proximal and distal airway smooth muscle relaxed with increasing concentration of each anaesthetic in a dose-related manner. Desflurane had a greater relaxant effect than halothane on the proximal airway only at 2.8 MAC. Desflurane relaxed the distal airway to a greater extent than halothane at 1.9 and 2.8 MAC. The distal airway smooth muscle was more sensitive to volatile anaesthetics than the proximal airway smooth muscle with either halothane or desflurane at all concentrations tested. This effect may be a result of differences in cartilage content, myosin content, epithelium-dependent effects, receptor density, myofilament sensitivity to Ca2+, sarcoplasmic reticulum Ca2+ control, or ionic fluxes in the proximal airway compared with the distal airway. The increased sensitivity of airway smooth muscle to desflurane compared with halothane is not known but may be related to possible differences in the effects of Ca2+ homeostasis.      

Effects of halothane on sarcoplasmic reticulum calcium release channels in porcine airway smooth muscle cells

BACKGROUND: Volatile anesthetics relax airway smooth muscle (ASM) by altering intracellular Ca2+ concentration ([Ca2+]i). The authors hypothesized that relaxation is produced by decreasing sarcoplasmic reticulum Ca2+ content via increased Ca2+ "leak" through both inositol trisphosphate (IP3) and ryanodine receptor channels. METHODS: Enzymatically dissociated porcine ASM cells were exposed to acetylcholine in the presence or absence of 2 minimum alveolar concentration (MAC) halothane, and IP3 levels were measured using radioimmunoreceptor assay. Other cells were loaded with the Ca2+ indicator fluo-3 and imaged using real-time confocal microscopy. RESULTS: Halothane increased IP3 concentrations in the presence and absence of acetylcholine. Inhibition of phospholipase C blunted the IP3 response to halothane. Exposure to 2 MAC halothane induced a transient [Ca2+]i response, suggesting depletion of sarcoplasmic reticulum Ca2+. Exposure to 20 microM Xestospongin D, a cell-permeant IP3 receptor antagonist, resulted in a 45+/-13% decrease in the [Ca2+]i response to halothane compared with halothane exposure alone. In permeabilized cells, Xestospongin D or 0.5 mg/ml heparin decreased the [Ca2+]i response to halothane by 65+/-13% and 68+/-22%, respectively, compared with halothane alone. In both intact and permeabilized cells, 20 microM ryanodine blunted the [Ca2+]i response to halothane by 32+/-13% and 39+/-21%, respectively, compared with halothane alone. Simultaneous exposure to Xestospongin D and ryanodine completely inhibited the [Ca2+]i response to halothane. CONCLUSIONS: The authors conclude that halothane reduces sarcoplasmic reticulum Ca2+ content in ASM cells via increased Ca2+ leak through both IP3 receptor and ryanodine receptor channels. Effects on IP3 receptor channels are both direct and indirect via elevation of IP3 levels.     

Effect of peritonitis on gallbladder smooth muscle contractility in guinea pigs

BACKGROUND: The mechanisms involved in the impaired gallbladder contractile response in peritonitis are unknown. The aim of this study was to determine the effect of peritonitis on the contraction and relaxation responses to different agonists in gallbladder smooth muscle in guinea pig. MATERIALS AND METHODS: Peritonitis was induced by cecal ligation and puncture (CLP) in 10 guinea pigs. Another group of 10 guinea pigs underwent a sham operation and acted as controls. Twenty-four hours after the operation, the guinea pigs were killed, and gallbladder strips were placed in organ bath. The contraction responses to KCl, carbachol, and histamine, and relaxation responses to cyclooxygenase inhibitors (indomethacin, nimesulide, and DFU) on KCl-induced contractions were recorded. RESULTS: There was no significant difference between the contractile responsiveness to KCl, but maximum contractile responses (E(max)) to carbachol and histamine were significantly reduced. Indomethacin, nimesulide, and DFU concentration dependently inhibited on KCl-induced contractions of gallbladder smooth muscle. E(max) values of indomethacin, nimesulide, and DFU were significantly reduced in the peritonitis group compared with controls (P < 0.05). The inhibitor effects of nimesulide and DFU were considerably similar, but inhibitor effect of indomethacin was significantly less than that measured for nimesulide and DFU in both control and peritonitis groups (P < 0.05). CONCLUSIONS: The contraction responses to carbachol and histamine and relaxation responses to COX inhibitors on gallbladder smooth muscle are significantly decreased by peritonitis. Although the mechanism of the decrease in contraction and relaxation responses in CLP-induced peritonitis is completely unknown, we speculate that impaired smooth muscle responses may be related to an alteration in the regulation of receptor/postreceptor excitation-response coupling and/or through changes on Ca(2+) influx.     

Effects of sodium metabisulphite on guinea pig contractile airway smooth muscle responses in vitro.

BACKGROUND--Sodium metabisulphite (MBS) is known to induce bronchoconstriction in asthmatic patients. The effects of MBS on guinea pig airway smooth muscle and on neurally mediated contraction in vitro have been examined. METHODS--Tracheal and bronchial airway segments were placed in oxygenated buffer solution and electrical field stimulation was performed in the presence of indomethacin (10(-5) M) and propranolol (10(-6) M) for the measurement of isometric tension. Atropine (10(-6) M) was added to bronchial tissues. RESULTS--Concentrations of MBS up to 10(-3) M had no direct effect on airway smooth muscle contraction and did not alter either tracheal smooth muscle contraction induced by electrical field stimulation at all frequencies or acetylcholine-induced tracheal smooth muscle contraction. There was a similar response in the absence of epithelium, except for potentiation of the response induced by electrical field stimulation at 0.5 Hz (24 (10)% increase). However, MBS (10(-5), 10(-6) and 10(-7) M) augmented neurally-mediated non-adrenergic non-cholinergic contractile responses in the bronchi (13.3 (3.2)%, 23.8 (9.6)%, and 6.4 (1.6)%, respectively). MBS had no effect on the contractile response induced by substance P, but at higher concentrations (10(-3) M and 10(-4) M) it caused a time-dependent attenuation of responses induced by either electrical field stimulation or exogenously applied acetylcholine or substance P. CONCLUSIONS--MBS had no direct contractile responses but enhanced bronchoconstriction induced by activation of non-cholinergic neural pathways in the bronchus, probably through increased release of neuropeptides. At high concentrations MBS inhibited contractile responses initiated by receptor or neural stimulation.     

Dual effects of hexanol and halothane on the regulation of calcium sensitivity in airway smooth muscle

BACKGROUND: Contraction of airway smooth muscle is regulated by receptor-coupled mechanisms that control the force developed for a given cytosolic calcium concentration (i.e., calcium sensitivity). Halothane antagonizes acetylcholine-induced increases in calcium sensitivity by inhibiting GTP-binding (G)-protein pathways. The authors tested the hypothesis that hexanol, like halothane, inhibits agonist-induced increases in calcium sensitivity in airway smooth muscle by inhibiting G-protein pathways. METHODS: Calcium sensitivity was assessed using alpha-toxin-permeabilized canine tracheal smooth muscle. In selected experiments, regulatory myosin light chain phosphorylation was also determined by Western blotting in the presence and absence of 10 mm hexanol and/or 100 microm acetylcholine. RESULTS: Hexanol (10 mm) and halothane (0.76 mm) attenuated acetylcholine-induced calcium sensitization by decreasing regulatory myosin light chain phosphorylation during receptor stimulation. Hexanol also inhibited increases in calcium sensitivity due to direct stimulation of heterotrimeric G-proteins with tetrafluoroaluminate but not with 3 microm GTPgammaS, consistent with prior results obtained with halothane. In contrast, in the absence of receptor stimulation, both compounds produced a small increase in calcium sensitivity by a G-protein-mediated increase in regulatory myosin light chain phosphorylation that was not affected by pertussis toxin treatment. CONCLUSIONS: The authors noted dual effects of hexanol and halothane. In the presence of muscarinic receptor stimulation, hexanol, like halothane, decreases calcium sensitivity by interfering with heterotrimeric G-protein function. However, in the absence of muscarinic receptor stimulation, hexanol and halothane slightly increase calcium sensitivity by a G-protein-mediated process not sensitive to pertussis toxin. Hexanol may represent a useful experimental tool to study the effect of anesthetics on heterotrimeric G-protein function.     

Effects of primary alcohols on airway smooth muscle

BACKGROUND: The investigation examined whether primary alcohols could be used as tools to explore the mechanism of anesthetic actions in airway smooth muscle (ASM). The hypothesis was that, like volatile anesthetics, the primary alcohols relax intact ASM by decreasing intracellular Ca2+ concentration ([Ca2+]i) and by inhibiting agonist-induced increases in the force developed for a given [Ca2+]i (Ca2+ sensitivity). METHOD: The effects of butanol, hexanol, and octanol on isometric force in canine tracheal smooth muscle were examined. The effects of hexanol on [Ca2+]i (measured with fura-2) and the relationship between force and [Ca2+]i were studied during membrane depolarization provided by KCl and during muscarinic stimulation provided by acetylcholine. RESULTS: The primary alcohols relaxed ASM contracted by KCl or acetylcholine in a concentration-dependent manner, with potency increasing as chain length increased. The alcohols could completely relax the strips, even during maximal stimulation with 10 microM acetylcholine (median effective concentrations of 28 +/- 12, 1.3 +/- 0.4, and 0.14 +/- 0.05 mM [mean +/- SD] for butanol, hexanol, and octanol, respectively). Hexanol decreased both [Ca2+]i and force in a concentration-dependent manner. Hexanol decreased Ca2+ sensitivity during muscarinic stimulation but had no effect on the force-[Ca2+]i relationship in its absence. CONCLUSIONS: Primary alcohols produce reversible, complete relaxation of ASM, with potency increasing as chain length increases, by decreasing [Ca2+]i and inhibiting increases in Ca2+ sensitivity produced by muscarinic receptor stimulation. These actions mimic those of volatile anesthetics on ASM, a circumstance suggesting that the primary alcohols may be useful tools for further exploring mechanisms of anesthetic effects on ASM.     

Effects of propofol on guinea pig respiratory smooth muscle

The effects of propofol on the tone of guinea pig respiratory smooth muscle was studied both in vitro and in vivo. In vitro, the activity of propofol on tracheal smooth muscle was investigated using a force displacement transducer for isometric tension responses. Isoproterenol was used as the control. Concentration-response curves to propofol and isoproterenol were obtained using a cumulative dose schedule. Propofol (0.32–10.24 μg·ml⁻¹) relaxed the tracheal smooth muscle in a concentration-dependent manner, but was less potent than isoproterenol (equipotent molar ratio 29 000∶1). This effect of propofol was not affected by prior administration of atropine, propranolol, prazocin, or yohimbine, and it did not appear to be mediated via calcium antagonism. The solvent for propofol (10% intralipid) had no effect on the tracheal smooth muscle in vitro. The in vivo study measured the effect of propofol on lung pressure in deeply anesthetized guinea pigs using histamine induced bronchoconstriction. Propofol (1–4.5 mg·kg⁻¹, i.v.) exhibited neither relaxant nor constrictor effects. It is possible that the effects of propofol observed in vitro are due to nonspecific action, while the finding of no effect in vivo could be due to different tissue sensitivity to propofol, i.e., tracheal smooth muscle may be more responsive than bronchial smooth muscle. Propofol does not seem to have any deleterious effects on airway smooth muscle.     

Differential effects of halothane on airway nerves and muscle

Effects of halothane on the excitation-contraction coupling or neuro-effector transmission in the dog tracheal muscle were observed in vitro in an attempt to clarify the cellular mechanisms involved in anesthetic-induced bronchodilation. Double sucrose gap, microelectrode, and tension recording methods were used. Application of halothane evoked an initial induction of phasic contraction with no alteration in the electrical membrane properties, and secondarily a reduction in muscle tone with membrane hyperpolarization. Halothane suppressed the amplitude of the twitch contractions evoked by indirect (nerve mediated) or direct muscle stimulation, the degree of suppression being greater with the former stimulation. The threshold membrane depolarization required for the generation of tension development was increased. In the presence or absence of TEA, halothane completely suppressed the generation of an action potential or a local response in the muscle membrane, following stimulation by outward current pulses. Therefore, halothane has complex actions on Ca++ economy in the tracheal smooth muscle cell, i.e., initial release of Ca++ from the store sites followed by inactivation or a reduction in free calcium ions in the cytoplasm, and/or suppression of the influx of Ca++ across the cell membrane. Low concentrations of halothane (less than or equal to 1%) suppressed the amplitude of excitatory junction potential (EJP) without altering the membrane potential, membrane resistance, or muscle sensitivity to acetylcholine. Therefore, this anesthetic probably suppresses the release of transmitter from the nerve terminals. Halothane also suppressed the facilitation phenomena of EJP during repetitive nerve stimulation. These direct inhibitory effects of halothane on smooth muscle cells and excitatory neuro-effector transmission could account for the potent bronchodilator action of this anesthetic.     

Effects of volatile anaesthetic agents on enhanced airway tone in sensitized guinea pigs

Background. Although volatile anaesthetics afford protectionagainst bronchospasm, their potential to reverse a sustainedconstriction of hyperreactive airways has not been characterized.Accordingly, we investigated the ability of halothane, isoflurane,sevoflurane and desflurane to reverse lung constriction inducedby prolonged stimulation of the muscarinic receptors in guineapigs sensitized to ovalbumin. Methods. Pulmonary input impedance (ZL) was measured using forcedoscillations in five groups of ovalbumin-sensitized, mechanicallyventilated guinea pigs. ZL was measured under baseline conditions,during steady-state bronchoconstriction induced by an i.v. infusionof methacholine (MCh), and after administration of one of thevolatile agents at 1 MAC after the induction of a steady-statebronchoconstriction. Airway resistance (Raw), and parenchymaltissue resistive and elastic coefficients were extracted fromZL by model fitting. Results. All four volatile agents exhibited an initial relaxationof the MCh-induced airway constriction followed by gradual increasesin Raw. The bronchodilatory effect of isoflurane was the mostpotent (–28.9 (SE 5.5)% at 2 min, P<0.05) and lastedlongest (7 min); sevoflurane and halothane had shorter and moremoderate effects (–21.1 (3.9)%, P<0.05, and –6.1(1.7)%, P<0.05, respectively, at 1 min). Desflurane causedhighly variable changes in Raw, with a tendency to enhance airwaytone. Conclusions. Volatile agents can reverse sustained MCh-inducedairway constriction only transiently in sensitized guinea pigs.Isoflurane proved most beneficial in temporally improving lungfunction in the presence of a severe constriction of allergicinflamed airways. Desflurane displayed potential to induce furtherairway constriction. Br J Anaesth 2004; 92: 254–60     

异丙酚对哮喘豚鼠离体气管平滑肌张力的作用

目的 探讨异丙酚对哮喘豚鼠离体气管平滑肌张力的作用及其作用机制。方法 48只健康豚鼠随机分为哮喘组(n=28)和正常组(n=20),卵蛋白致敏法建立哮喘豚鼠模型,每只豚鼠制备5-7个气管平滑肌环,依据悬挂平滑肌环的营养液中处理因素不同将气管平滑肌环随机分为control亚组、10％Intralipid亚组、10、30、100、300μmol/L Propofol亚组,通过与气管环相连的力-位移换能器记录其张力变化,采用悬挂平滑肌环的营养液中无Ca2+的方法测定异丙酚对Ryanodine受体介导的细胞内Ca2+释放的影响。结果 (1)100μmol/L异丙酚显著舒张哮喘豚鼠静息气管平滑肌。四种浓度异丙酚对乙酰胆碱所致气管平滑肌收缩呈剂量依赖的舒张作用。(2)四种浓度异丙酚预适应可剂量依赖性抑制乙酰胆碱所致气管平滑肌收缩。哮喘组30μmol/L异丙酚预适应使乙酰胆碱所致的气管平滑肌依内钙性收缩由(37.7±2.8)％降为(27.7±1.9)％,依外钙性收缩由(62.3±4.5)％降为(51.5±3.5)％,与control亚组比较差异有显著性(P<0.01)。(3)四种浓度异丙酚抑制乙酰胆碱所致气管平滑肌依内钙性收缩作用,与无Ryanodine作用组比较,差异无显著性(P>0.05)。结论临床相关浓度异丙酚预适应显著抑制乙酰胆碱收缩哮喘豚鼠离体气管平滑肌的作用,其作用机制与Rvanodine受体介导     

Effects of ketamine on K+-contracture in isolated vascular smooth muscle from rabbit

The effects of ketamine on contraction induced by depolarization of cell membrane (high K+-induced contracture) were studied in isolated vascular smooth muscle from rabbit portal vein. Ketamine in concentrations above 5 x 10(-4) M caused relaxation in phasic contraction, and above 10(-4) M caused relaxation in tonic contraction. These effects of ketamine at concentrations of between 10(-5) to 10(-3) M were dose dependent and reversible. In concentration above 10(-5) M, ketamine decreased the contractile response (tonic contraction) induced by 2.5 mM Ca2+ after the temporary contracture in Ca2+-free, high K+ solution. The contractile responses to norepinephrine (10(-6) M) or serotonin (10(-6) M) were also inhibited by ketamine. From these findings, it is concluded that ketamine decreases contractile responses due to transmembrane Ca2+ influx after depolarization of cell membrane and may decrease the contractile responses in concentration above 5 x 10(-4) due to Ca2+ release inhibition from sarcoplasmic reticulum.     

Halothane increases smooth muscle protein phosphatase in airway smooth muscle

BACKGROUND: Halothane relaxes airway smooth muscle, in part, by decreasing the force produced for a given intracellular [Ca(2+)] (i.e., Ca(2+) sensitivity) during muscarinic stimulation, an effect produced by a decrease in regulatory myosin light-chain (rMLC) phosphorylation. The authors tested the hypothesis that halothane reduces rMLC phosphorylation during muscarinic stimulation at constant intracellular [Ca(2+)] by increasing smooth muscle protein phosphatase (SMPP) activity, without changing myosin light-chain kinase (MLCK) activity. METHODS: Enzyme activities were assayed in beta-escin permeabilized strips of canine tracheal smooth muscle. Under conditions of constant intracellular [Ca(2+)], the rate of rMLC phosphorylation was measured by Western blotting during inhibition of SMPP with microcystin-LR (to assay MLCK activity) or during inhibition of MLCK by wortmannin and adenosine triphosphate depletion (to assay SMPP activity). The effect of halothane (0.8 mm) on enzyme activities and isometric force during stimulation with 0.6 microm Ca(2+) and 10 microm acetylcholine was determined. RESULTS: Halothane produced a 14 +/- 8% (mean +/- SD) decrease in isometric force by significantly reducing rMLC phosphorylation (from 32 +/- 9% to 28 +/- 9%). Halothane had no significant effect on any parameter of a monoexponential relation fit to the data for the MLCK activity assay. In contrast, halothane significantly decreased the half-time for rMLC dephosphorylation in the SMPP activity assay (from 0.74 +/- 0.28 min to 0.44 +/- 0.10 min), indicating that it increased SMPP activity. CONCLUSIONS: Halothane decreases Ca(2+) sensitivity and rMLC phosphorylation in airway smooth muscle during muscarinic receptor stimulation by increasing SMPP activity, without affecting MLCK, probably by disrupting receptor G-protein signaling pathways that inhibit SMPP.     

Glutathione depletion enhances subanesthetic halothane hepatotoxicity in guinea pigs.

Reduced glutathione has a potential role in protecting the liver against the reactive acyl acid chloride intermediate generated during the oxidative biotransformation of halothane. Glutathione is also important in maintaining the integrity of an injured cell. Thus, the effect of decreased hepatic glutathione concentrations on covalent binding of halothane metabolic intermediates to hepatic protein and lipid and the resultant hepatic injury were investigated in male, outbred Hartley guinea pigs. The animals were injected with either 1.6 g.kg-1 dl-buthionine-S,R-sulfoximine to deplete hepatic glutathione or vehicle-control solution 24 h before exposure to 0.1% (subanesthetic) halothane for 4 h (fractional inspired oxygen tension = 0.40). Buthionine sulfoximine pretreatment depleted liver glutathione concentrations by 85% at the time of halothane exposure, without affecting the degree of halothane biotransformation or causing hepatic injury. Glutathione depletion caused a significant increase in the level of organic fluorine covalently bound to hepatic protein but not lipid after halothane exposure. Glutathione-depleted animals also exhibited a significant enhancement of hepatotoxicity after halothane exposure; plasma isocitrate dehydrogenase activity was 25-fold greater than the increase observed 48 h after exposure in animals treated with vehicle plus halothane, and the incidence and severity of hepatic injury were significantly greater, as observed by light microscopic examination of tissue 96 h after exposure. These findings are in agreement with a previously proposed mechanism of halothane-associated hepatotoxicity in guinea pigs and indicate that hepatic glutathione status may play an important role in the susceptibility of patients to halothane-induced liver injury.     

Effects of ketamine on the cardiac papillary muscle of normal hamsters and those with cardiomyopathy

The effect of ketamine (10(-5) and 10(-4) M) on the intrinsic contractility of left ventricular papillary muscle from normal hamsters and those with cardiomyopathy (BIO 82.62, 6-month old) was investigated. At these concentrations, ketamine induced a positive inotropic effect on normal papillary muscle, as shown by an increase in maximum unloaded shortening velocity (+19 +/- 4 and +34 +/- 5%, P less than 0.05), active isometric force (+32 +/- 8 and +57 +/- 11%, P less than 0.05), and peak power output (+40 +/- 8 and +80 +/- 16%, P less than 0.05), and induced a slight decrease in sarcoplasmic reticulum function. Ketamine had no effect on the curvature of the total force-velocity curve, suggesting that it does not modify myothermal economy. Contractility of papillary muscle from hamsters with cardiomyopathy was less than that of controls, as shown by the decrease in isometric active force (-41%, P less than 0.02), peak power output (-33%, P less than 0.05), and sarcoplasmic reticulum function. The positive inotropic effect of ketamine on papillary muscle from hamsters with cardiomyopathy was less marked than in controls and almost suppressed in some cases: only the maximum unloaded shortening velocity was significantly increased with 10(-5) M ketamine (+7 +/- 6%, P less than 0.05), whereas no significant changes were observed in active isometric force (+14 +/- 8 and +13 +/- 11%; nonsignificant [NS]) and peak power output (+9 +/- 5 and +13 +/- 8%; NS) with ketamine (10(-5) and 10(-4) M, respectively).(ABSTRACT TRUNCATED AT 250 WORDS)