Methods : Chronically prepared nonpregnant and pregnant sheep were randomized to receive an intravenous infusion of 0.52% levobupivacaine, 0.52% bupivacaine, or 0.50% ropivacaine at a constant rate of 0.1 ml [middle dot] kg-1 [middle dot] min-1 until circulatory collapse. The investigators were blinded to the identity of the local anesthetic. Physiologic parameters, including cardiac rhythm, were monitored throughout the study. Arterial blood samples were obtained before infusion and at the onset of toxic manifestations. These were analyzed for total and free serum drug concentrations as well as arterial blood p H and gas tensions.
Results : The doses of all three drugs required to produce convulsions were lower in pregnant than nonpregnant animals. However, as the infusion continued, there were no significant differences between pregnant and nonpregnant ewes in the dose of drug required to produce more advanced manifestations of toxicity: hypotension, apnea, and circulatory collapse. The mean cumulative dose and serum concentration at each toxic manifestation was lowest for bupivacaine, intermediate for levobupivacaine, and highest for ropivacaine in both pregnant and nonpregnant animals. For all three local anesthetics, there were no significant differences between pregnant and nonpregnant ewes in total and free serum drug concentrations, except that at circulatory collapse, these were higher in pregnant animals. 相似文献
Methods: Fifty-six awake Wistar rats were assigned to seven groups of eight. All groups received a continuous intravenous infusion of lidocaine at a rate of 4 mg *symbol* kg sup -1 *symbol* min sup -1 until generalized convulsions occurred. The control group (group C) received plain lidocaine. The acute hypertensive groups received lidocaine with epinephrine (group E), norepinephrine (group N), or phenylephrine (group P) to increase mean arterial blood pressure (MAP) to 150 plus/minus 5 mm Hg. Sodium nitroprusside (SNP) was added to prevent an increase in mean arterial pressure in the remaining three groups (vasopressor-SNP groups).
Results: The acute hypertensive groups required significantly smaller cumulative doses of lidocaine to produce convulsions compared with control (C - 41.5 plus/minus 2.9 > E - 24.1 plus/minus 2.7, N = 27.1 plus/minus 2.8, P = 26.7 plus/minus 2.5 mg *symbol* kg sup -1; values are mean plus/minus SD, P < 0.01) In addition, plasma lidocaine concentrations (C = 11.0 plus/minus 0.7 > E = 7.4 plus/minus 0.5, N = 7.9 plus/minus 0.6, P = 8.1 plus/minus 0.8 micro gram *symbol* ml sup -1, P < 0.01) and brain lidocaine concentrations (C = 50.9 plus/minus 4.5 > E = 32.6 plus/minus 4.2, N - 34.5 plus/minus 4.8, P - 37.1 plus/minus 4.5 micro gram *symbol* g sup -1, P < 0.01) were less in the acute hypertensive groups at the onset of convulsions. In the vasopressor-SNP groups, the plasma and brain lidocaine concentrations at the onset of convulsions returned to the control values, although epinephrine and norepinephrine, but not phenylephrine, still decreased cumulative convulsant doses of lidocaine significantly (P < 0.01) compared with control (E + SNP = 30.8 plus/minus 2.9 < N + SNP = 34.8 plus/minus 2.8, P < 0.01) < P + SNP = 40.2 plus/minus 3.0 mg *symbol* kg sup -1, P < 0.01). The brain/plasma concentration ratios were similar for the seven groups. 相似文献
Methods: As pericranial temperature was varied between 39 and 25 degrees Celsius in normocapnic halothane-anesthetized rats, CMRG (using14 Carbon-deoxyglucose) or the time to depolarization (using a glass microelectrode in the cortex) after a Potassium sup + -induced cardiac arrest was measured. In other studies, CMRG and depolarization times were measured in normothermic animals (37.7 plus/minus 0.2 degree Celsius) anesthetized with high-dose pentobarbital or isoflurane (both producing burst suppression on the electroencephalogram) or in halothane-anesthetized animals whose temperatures were reduced to 27.4 plus/minus 0.3 degree Celsius. These three states were designed to produce equivalent CMRG values.
Results: As temperature was reduced from 39 to 25 degrees Celsius, CMRG decreased from 66 to 21 micro Meter *symbol* 100 g sup -1 *symbol* min1 (Q10 = 2.30), and depolarization times increased from 76 to 326 s. In similarly anesthetized animals at approximately 27 degrees Celsius, CMRG was 32 plus/minus 4 micro Meter *symbol* 100 g sup -1 *symbol* min sup -1 (mean plus/minus SD), whereas in normothermic pentobarbital- and isoflurane-anesthetized rats, CMRG values were 33 plus/minus 3 and 37 plus/minus 4 micro Meter *symbol* 100 g1 *symbol* min sup -1, respectively (P = 0.072 by one-way analysis of variance). Despite these similar metabolic rates, the times to depolarization were markedly different: for hypothermia it was 253 plus/minus 29 s, for pentobarbital 109 plus/minus 24 s, and for isoflurane 130 plus/minus 28 s (P < 0.0001). 相似文献
Methods: We studied 96 otherwise healthy children, 8-13 yr old, undergoing minor surgery. They received, at random, oral clonidine 2 or 4 micro gram *symbol* kg sup -1 or placebo 105 min before scheduled induction of anesthesia. Part I (n = 48, 16 per group): When hemodynamic parameters after insertion of a venous catheter had been confirmed to be stable, atropine was administered in incremental doses of 2.5, 2.5, and 5 micro gram *symbol* kg sup -1 every 2 min. The HR and blond pressure were recorded at 1-min intervals. Part II (n = 48, 16 per group): After the recording of baseline hemodynamic values, successive doses of atropine (5 micro gram *symbol* kg sup -1 every 2 min, to 40 micro gram *symbol* kg sup -1), were administered until HR increased by 20 beats *symbol* min sup -1. The HR and blood pressure were recorded at 1-min intervals.
Results: Part I: The increases in HR in response to a cumulative dose of atropine 10 micro gram *symbol* kg sup -1 were 33 plus/minus 3%, 16 plus/minus 3%, and 8 plus/minus 2% (mean plus/minus SEM) in children receiving placebo, clonidine 2 micro gram *symbol* kg sup -1, and clonidine 4 micro gram *symbol* kg sup -1, respectively (P < 0.05). Part II: The HR in the control group increased by more than 20 beats *symbol* min sup -1 in response to atropine 20 micro gram *symbol* kg sup -1 or less. In two patients in the clonidine 4 micro gram *symbol* kg sup -1 group, HR did not increase by 20 beats *symbol* min sup -1 even after 40 micro gram *symbol* kg sup -1 of atropine. 相似文献
Methods: Using a randomized, double-blind study design, 60 ASA physical status 1 or 2 term parturients presenting for elective cesarean section received either 0.5% bupivacaine (150 mg) or 0.5% ropivacaine (150 mg) epidurally in appropriate fractionated doses over a 10-min period. Onset, duration, and regression of sensory and motor blockade were noted until complete resolution was observed. Quality of intraoperative anesthesia and abdominal wall muscle relaxation were noted. Maternal plasma concentrations of local anesthetic were determined before anesthetic administration and 5, 10, 20, 30, and 60 min and 2, 3, 6, 8, 12, and 24 h after drug injection in 20 subjects. Umbilical cord blood was obtained at time of delivery for acid-base values and determination of the free and total plasma concentration of local anesthetic. Neonates also were examined for neurobehavioral assessments by Scanlon's and Neurologic and Adaptive Capacity Scores at 2 and 24 h after delivery.
Results: All patients received satisfactory anesthesia for operation. The onset, duration, and regression of sensory blockade were similar for both groups. Onset of degree 1 and 2 motor blockade was faster, and duration of degree 1 motor block was longer in the group receiving bupivacaine. Hemodynamic sequelae were similar between groups. All neonates had 5-min Apgar scores of 7 or greater and normal acid-base values and neurobehavioral assessments. Pharmacokinetic analysis showed that the Cmax was similar for both drugs (1.3 plus/minus 0.09 for ropivacaine and 1.1 plus/minus 0.09 micro gram/ml for bupivacaine). The T1/2 of the terminal decline in plasma concentration was shorter for ropivacaine versus bupivacaine (5.2 plus/minus 0.60 versus 10.9 plus/minus 1.08 h, respectively; P < 0.01). The free (i.e., unbound) concentrations of ropivacaine were approximately twice those of bupivacaine in both maternal and neonatal blood at the time of delivery. The ratio of umbilical vein to maternal vein concentration of unbound drug was 0.72 for ropivacaine and 0.69 for bupivacaine. 相似文献
Methods: After an overnight fast, six adolescents between 12 and 17 yr of age were infused with tracer doses of [6,6-sup 2 H2]glucose for 2 h before undergoing anesthesia, and the infusion was continued after induction, until the beginning of surgery. Plasma glucose concentration was monitored throughout, and free fatty acids, lactate, insulin, and glucagon concentrations were measured before and during anesthesia.
Results: Despite the use of a glucose-free maintenance solution, plasma glucose concentration increased slightly but significantly 5 min after induction (5.3 plus/minus 0.4 vs. 4.5 plus/minus 0.4 mmol *symbol* 1 sup -1 , P < 0.05). This early increase corresponded to a significant increase in endogenous glucose production over basal conditions (4.1 plus/minus 0.4 vs. 3.6 plus/minus 0.2 mg *symbol* kg sup -1 *symbol* min sup -1, P < 0.05), with no concomitant change in peripheral glucose utilization. Fifteen minutes after induction, both glucose utilization and production rates decreased steadily and were 20% less than basal values by 35 min after induction (2.9 plus/minus 0.3 vs. 3.6 plus/minus 0.2 mg *symbol* kg sup -1 *symbol* min sup -1, P < 0.05). Similarly, glucose metabolic clearance rate decreased by 25% after 35 min. Despite the increase in blood glucose concentration, anesthesia resulted in a significant decrease in plasma insulin concentration. 相似文献
Methods: Thirteen neurosurgical patients underwent cardiopulmonary bypass and deep hypothermic circulatory arrest to facilitate clip application to a giant or otherwise high-risk cerebral aneurysm. Electroencephalographic burst suppression was established before bypass with an infusion of propofol, and the infusion was continued until the end of surgery. Hemodynamic and echocardiographic measurements were made before and during the prebypass propofol infusion and again after bypass. Emergence time also was determined.
Results: Prebypass propofol at 243 plus/minus 57 micro gram *symbol* kg sup -1 *symbol* min sup -1 decreased vascular resistance from 34 plus/minus 8 to 27 plus/minus 8 units without changing heart rate, arterial or filling pressures, cardiac index, stroke volume, or ejection fraction. Propofol blood concentration was 8 plus/minus 2 micro gram/ml. Myocardial wall motion appeared hyperdynamic at the end of cardiopulmonary bypass, and all patients were weaned therefrom without inotropic support. After bypass, vascular resistance decreased further, and cardiovascular performance was improved compared to baseline values. Nine of the 13 patients emerged from anesthesia and were able to follow commands at 3.1 plus/minus 1.4 h. Three others had strokes and a fourth had cerebral swelling. 相似文献
Methods: New Zealand White rabbits, anesthetized with fentanyl and diazepam, were maintained during cardiopulmonary bypass (CPB) at a brain temperature of 17 degrees Celsius with alpha-stat (group A, n = 9) or pH-stat (group B, n = 9) management. Measurements of brain temperature, systemic hemodynamics, arterial and cerebral venous blood gases and oxygen content, cerebral blood flow (CBF) (radiolabeled microspheres), and cerebral metabolic rate for oxygen (CMRO2) (Fick) were made in each animal at 65 and 95 min of CPB. To control for arterial pressure and CBF differences between techniques, additional rabbits underwent CPB at 17 degrees Celsius. In group C (alpha-stat, n = 8), arterial pressure was decreased with nitroglycerin to values observed with pH-stat management. In group D (pH-stat, n = 8), arterial pressure was increased with angiotensin II to values observed with alpha-stat management. In groups C and D, CBF and CMRO2 were determined before (65 min of CPB) and after (95 min of CPB) arterial pressure manipulation.
Results: In groups A (alpha-stat) and B (pH-stat), arterial pressure; hemispheric CBF (44 plus/minus 17 vs. 21 plus/minus 4 ml *symbol* 100 g sup -1 *symbol* min sup -1 [median plus/minus quartile deviation]; P = 0.017); and CMRO2 (0.54 plus/minus 0.13 vs. 0.32 plus/minus 0.10 ml Oxygen2 *symbol* 100 g sup -1 *symbol* min sup -1; P = 0.0015) were greater in alpha-stat than in pH-stat animals, respectively. As a result of arterial pressure manipulation, in groups C (alpha-stat) and D (pH-stat) neither arterial pressure (75 plus/minus 2 vs. 78 plus/minus 2 mm Hg) nor hemispheric CBF (40 plus/minus 10 vs. 48 plus/minus 6 ml *symbol* 100 g sup -1 *symbol* min sup -1; P = 0.21) differed between alpha-stat and pH-stat management, respectively. Nevertheless, CMRO2 was greater in alpha-stat than in pH-stat animals (0.71 plus/minus 0.10 vs. 0.45 plus/minus 0.10 ml Oxygen2 *symbol* 100 g sup -1 *symbol* min sup -1, respectively; P = 0.002). 相似文献
Methods: After a control period, pregnant ewes that were fitted with instruments for long-term monitoring were randomized to receive a two-step intravenous infusion of levobupivacaine, bupivacaine, or ropivacaine, in a blinded manner, for 1 h. Maternal and fetal hemodynamics were monitored during the study. Arterial blood samples were drawn at 30 and 60 min of infusion from the mother and fetus to determine the acid-base status (60 min only) and serum drug concentrations. The fetal brain, heart, liver, lungs, adrenal glands, and kidneys were obtained to measure tissue drug levels.
Results: Maternal blood pressure, central venous and intraamniotic pressures, acid-base status and uterine blood flow were unaffected by any drug infusion. In contrast to the other two local anesthetics, the infusion of bupivacaine was associated with a small but significant decrease in the ewe's heart rate. At the end of the study, the heart rate in the bupivacaine-treated animals was significantly less than in the animals treated with the other two drugs. All fetuses were in good condition at the start of study, and none of the local anesthetics affected fetal well-being. No significant differences were found among the three drugs in the maternal serum, fetal serum, fetal tissue concentrations, and tissue:serum concentration ratios. 相似文献
Methods: Baseline acetylcholine threshold concentrations were determined 3-5 days before initiation of the investigation. The response to the acetylcholine challenge was defined as hyperreactive, if forced expiratory volume in 1 s decreased by at least 20%. In addition, the acetylcholine threshold for a 100% increase in airway resistance was obtained by body plethysmography. On seven different days, the acetylcholine challenge was repeated at the end of a 30-min intravenous infusion period of three doses of lidocaine (1, 3, and 6 mg *symbol* min sup -1) or bupivacaine (0.25, 0.75, and 1.5 mg *symbol* min sup -1), during saline placebo infusion, respectively. Acetylcholine-threshold concentrations were presented with the respective plasma concentrations of the local anesthetic.
Results: The infusion of lidocaine and bupivacaine resulted in plasma concentrations (means+/-SD) of 0.29+/-0.11, 1.14 +/-0.39, and 2.02+/-0.5 micro gram *symbol* ml sup -1 for lidocaine and 0.11+/-0.04, 0.31+/-0.09, and 0.80 +/-0.18 micro gram *symbol* ml sup -1 for bupivacaine, respectively. Compared to baseline, the acetylcholine threshold for a 20% decrease of forced expiratory volume in 1 s as well as the threshold for a 100% increase in total airway resistance increased significantly with increasing plasma concentrations of both local anesthetics. Compared to placebo, acetylcholine threshold was almost quadrupled for lidocaine and tripled for bupivacaine with the highest plasma concentration of each local anesthetic. 相似文献
Methods: In six human subjects, respiratory muscle activity in the parasternal intercostal, abdominal, and diaphragm muscles was measured using fine-wire electromyography electrodes. Chest wall motion was determined by respiratory impedance plethysmography. Electromyography activities and chest wall motion were measured during hyperpnea produced by carbon dioxide rebreathing while the subjects were awake and during 1 MAC halothane anesthesia.
Results: Halothane anesthesia significantly reduced the slope of the response of expiratory minute ventilation to carbon dioxide (from 2.88 plus/minus 0.73 (mean plus/minus SE) to 2.01 plus/minus 0.45 l *symbol* min sup -1 *symbol* mmHg sup -1). During the rebreathing period, breathing frequency significantly increased while awake (from 10.3 plus/minus 1.4 to 19.7 plus/minus 2.6 min sup -1, P < 0.05) and significantly decreased while anesthetized (from 28.8 plus/minus 3.9 to 21.7 plus/minus 1.9 min sup -1, P < 0.05). Increases in respiratory drive to the phrenic motoneurons produced by rebreathing, as estimated by the diaphragm electromyogram, were enhanced by anesthesia. Anesthesia attenuated the response of parasternal electromyography and accentuated the response of the transversus abdominis electromyography to rebreathing. The compartmental response of the ribcage to rebreathing was significantly decreased by anesthesia (from 1.83 plus/minus 0.58 to 0.48 plus/minus 0.13 l *symbol* min sup -1 *symbol* mmHg sup -1), and marked phase shifts between ribcage and abdominal motion developed in some subjects. However, at comparable tidal volumes, the ribcage contribution to ventilation was similar while awake and anesthetized in four of the six subjects. 相似文献
Methods: Five volunteers were each studied on 4 days: (1) control; (2) a target blood propofol concentration of 2 micro gram/ml; (3) a target concentration of 4 micro gram/ml; and (4) a target concentration of 8 micro gram/ml. On each day, we increased skin and core temperatures sufficiently to provoke sweating. Skin and core temperatures were subsequently reduced to elicit peripheral vasoconstriction and shivering. We mathematically compensated for changes in skin temperature by using the established linear cutaneous contributions to the control of sweating (10%) and to vasoconstriction and shivering (20%). From these calculated core-temperature thresholds (at a designated skin temperature of 35.7 degrees Celsius), the propofol concentration- response curves for the sweating, vasoconstriction, and shivering thresholds were analyzed using linear regression. We validated this new method by comparing the concentration-dependent effects of propofol with those obtained previously with an established model.
Results: The concentration-response slopes for sweating and vasoconstriction were virtually identical to those reported previously. Propofol significantly decreased the core temperature triggering vasoconstriction (slope = 0.6 plus/minus 0.1 degree Celsius *symbol* micro gram sup -1 *symbol* ml sup -1; r2 = 0.98 plus/minus 0.02) and shivering (slope = 0.7 plus/minus 0.1 degree Celsius *symbol* micro gram sup -1 *symbol* ml sup -1; r2 = 0.95 plus/minus 0.05). In contrast, increasing the blood propofol concentration increased the sweating threshold only slightly (slope = 0.1 plus/minus 0.1 degree Celsius *symbol* micro gram sup -1 *symbol* ml sup -1; r2 = 0.46 plus/minus 0.39). 相似文献
Methods: In experiment A, 16 anesthetized New Zealand white rabbits were randomized to one of two pulsatile CPB groups based on pump systolic ejection period (100 and 140 ms, respectively). Each animal was perfused at 37 degrees Celsius for 30 min at each of two pulse rates (150 and 250 pulse/min, respectively). This scheme created four different arterial pressure waveforms. At the end of each perfusion period, arterial pressure waveform, arterial and cerebral venous oxygen content, CBF (microspheres), and CMRO2 (Fick) were measured. In experiment B, 22 rabbits were randomized to pulsatile (100-ms ejection period, 250 pulse/min) or nonpulsatile CPB at 37 degrees Celsius. At 30 and 60 min of CPB, physiologic measurements were made as before.
Results: In experiment A, CBF and CMRO2 were independent of ejection period and pulse rate. Thus, all four waveforms were physiologically equivalent. In experiment B, CBF did not differ between pulsatile and nonpulsatile CPB (72 plus/minus 6 vs. 77 plus/minus 9 ml *symbol* 100 g sup -1 *symbol* min1, respectively (median plus/minus quartile deviation)). CMRO2 did not differ between pulsatile and nonpulsatile CPB (4.7 plus/minus 0.5 vs. 4.1 plus/minus 0.6 ml Oxygen2 *symbol* 100 g sup -1 *symbol* min1, respectively) and decreased slightly (0.4 plus/minus 0.4 ml Oxygen2 *symbol* 100 g sup -1 *symbol* min1) between measurements. 相似文献