The effects of sevoflurane, isoflurane, halothane, and enflurane on hemodynamic responses during an inhaled induction of anesthesia via a mask in humans

A rapid increase in isoflurane or desflurane concentration induces tachycardia and hypertension and increases-plasma catecholamine concentration. Little information is available as to whether sevoflurane, halothane, and enflurane induce similar responses during anesthesia induction via mask. Fifty ASA physical status I patients, aged 20-40 yr, and scheduled for elective minor surgery, received one of four volatile anesthetics: sevoflurane, isoflurane, halothane, or enflurane. Anesthesia was induced with thiamylal, followed by inhalation of 0.9 minimum alveolar anesthetic concentration (MAC) of the anesthetic in 100% oxygen via mask. The inspired concentration of anesthetic was increased by 0.9 MAC every 5 min to a maximum of 2.7 MAC. Heart rate (HR) and systolic blood pressure (SBP) were measured before and every minute for 15 min during anesthetic inhalation. In the sevoflurane and isoflurane groups, venous blood samples were drawn to determine the concentrations of plasma epinephrine and norepinephrine 3 min after each increase in anesthetic concentration. Sustained increments in HR were observed after increases in inspired isoflurane concentration to 1.8 MAC and 2.7 MAC (peak changes of 15 +/- 3 and 17 +/- 3 bpm, respectively). Isoflurane also increased SBP transiently after the inspired concentration was increased to 2.7 MAC (peak change of 10 +/- 4 mm Hg). Enflurane increased HR after the inspired concentration was increased to 2.7 MAC (peak change of 9 +/- 2 bpm). In contrast, changes in sevoflurane and halothane concentrations did not induce hyperdynamic responses. Plasma norepinephrine concentration in the isoflurane group was significantly higher than that in the sevoflurane group during 2.7 MAC (P = 0.022). We propose that there is a direct relationship between airway irritation of the anesthetic and immediate cardiovascular change during an inhaled induction of anesthesia.     

The effects of propofol, isoflurane, and sevoflurane on oxygenation and shunt fraction during one-lung ventilation

Propofol's effect on hypoxic pulmonary vasoconstriction during one-lung ventilation (OLV) has not been determined. Twenty patients who had long-term OLV for esophageal surgery were allocated randomly to one of two study groups; one in which isoflurane administration preceded propofol, and another in which sevoflurane administration preceded propofol. Arterial and mixed venous blood samples and hemodynamics were measured as follows: before OLV, during OLV, OLV at 4 cm of positive end-expiratory pressure (PEEP), OLV after conversion from volatile anesthetics to propofol, OLV at 4 cm of PEEP, and after OLV. After the application of 4 cm of PEEP during propofol anesthesia, PaO2 increased significantly in both groups. The shunt fraction (Qs/Qt) increased significantly after the initiation of OLV in both groups and decreased significantly after the conversion from volatile anesthetics to propofol in both groups. Propofol can be used safely during OLV because PaO2 increased after the application of 4 cm of PEEP during propofol anesthesia, and Qs/Qt decreased significantly after the conversion from inhaled anesthetics to propofol anesthesia. IMPLICATIONS: During one-lung ventilation, the arterial partial pressure of oxygen values with propofol were greater than those with isoflurane and sevoflurane, and shunt fraction values with propofol were lower than those with both volatile anesthetics. Propofol improved oxygenation and shunt fraction during one-lung ventilation compared with volatile anesthetics.     

Preservation of the ration of cerebral blood flow/metabolic rate for oxygen during prolonged anesthesia with isoflurane, sevoflurane, and halothane in humans

BACKGROUND: In several animal studies, an increase in cerebral blood flow (CBF) produced by volatile anesthetics has been reported to resolve over time during prolonged anesthesia. It is important to investigate whether this time-dependent change of CBF takes place in humans, especially in clinical situations where surgery is ongoing under anesthesia. In this study, to evaluate the effect of prolonged exposure to volatile anesthetics (isoflurane, sevoflurane, and halothane), the CBF equivalent (CBF divided by cerebral metabolic rate for oxygen (CMRO2) was determined every 20 min during anesthesia lasting more than 4h in patients. METHODS: Twenty-four surgical patients were assigned to three groups at random to receive isoflurane, sevoflurane, or halothane (8 patients each). End-tidal concentration of the selected volatile anesthetic was maintained at 0.5 and 1.0 MAC before surgery and then 1.5 MAC for the 3 h of surgical procedure. Normothermia and normocapnia were maintained. Mean arterial blood pressure was kept above 60 mmHg, using phenylephrine infusion, if necessary. CBF equivalent was calculated every 20 min as the reciprocal of arterial-jugular venous oxygen content difference. RESULTS: CBF equivalent at 0.5 MAC of isoflurane, halothane, and sevoflurane was 21 +/- 4, 20 +/- 3, and 21 +/- 5 ml blood/ml oxygen, respectively. All three examined volatile anesthetics significantly (P<0.01) increased CBF equivalent in a dose-dependent manner (0.5, 1.0, 1.5 MAC). AT 1.5 MAC, the increase of CBF equivalent with all anesthetics was maintained increased with minimal fluctuation for 3 h. The mean value of CBF equivalent at 1.5 MAC in the isoflurane group (45 +/- 8) was significantly (P<0.01) greater than those in the halothane (32 +/- 8) and sevoflurane (31 +/- 8) groups. Electroencephalogram was found to be relatively unchanged during observation periods at 1.5 MAC. CONCLUSIONS: These results demonstrate that CBF/CMRO2 ratio is markedly increased above normal and maintained during prolonged inhalation of volatile anesthetics in humans. It is impossible to determine whether these data indicate a stable CBF or whether CBF and CMRO2 are changing in parallel during the observation period. The unchanging electroencephalographic pattern suggests that the former possibility is more likely and that the increase of CBF produced by volatile anesthetics is maintained over time without decay, which has been reported in several animal studies. It also is suggested that isoflurane possesses greater capability to maintain global CBF relative to CMRO(2) than does halothane or sevoflurane. time.)     

Twenty-four-hour rhythms of plasma catecholamines and their relation to cardiovascular parameters in healthy young men

Diurnal and ultradian rhythms of plasma norepinephrine and epinephrine and their role in the regulation of cardiovascular parameters were investigated over 24 h of recumbency in a group of five men. Catecholamines were measured at 10 min intervals, and blood pressure and heart rate were recorded continuously. Norepinephrine and epinephrine rapidly fluctuated in each subject, with no obvious diurnal rhythm. Spectral analysis suggested two ultradian rhythms with periods of around 12 h and 50-100 min for both catecholamines. The pulse detection programs PULSAR and CLUSTER revealed 20-30 pulses/24 h for norepinephrine and epinephrine, with a significant correlation between the two rhythms (r = 0.63-0.80, P < 0.001). Neither the frequency nor the amplitude of these rapid fluctuations differed between day and night. Arousal in the morning caused a small increase in plasma catecholamines and getting out of bed a large increase. Thus changes in posture and activity are the main influences on the diurnal variations of plasma catecholamines reported previously, while the ultradian rhythms of sympathoadrenomedullary activity appear to be of intrinsic origin. Blood pressure and heart rate exhibited a diurnal rhythm with a nightly decrease. Arousal and rising from bed increased blood pressure and heart rate significantly. Although the amplitude of the rapid fluctuations of plasma catecholamines at times exceeded those caused by postural changes in the morning, when both plasma norepinephrine and epinephrine levels correlated highly with all cardiovascular parameters, correlations were not significant during recumbency. Thus the intrinsic ultradian fluctuations of plasma catecholamines appear not to be involved in the control of cardiovascular parameters during recumbency, and the increase in blood pressure and heart rate in the morning appears to be controlled by direct sympathetic neural input to the heart and vasculature in response to changes in activity and posture rather than by an endogenous surge of plasma catecholamines.     

Desflurane, sevoflurane, and isoflurane impair canine left ventricular-arterial coupling and mechanical efficiency

BACKGROUND: The effects of desflurane, sevoflurane, and isoflurane on left ventricular-arterial coupling and mechanical efficiency were examined and compared in acutely instrumented dogs. METHODS: Twenty-four open-chest, barbiturate-anesthetized dogs were instrumented for measurement of aortic and left ventricular (LV) pressure (micromanometer-tipped catheter), dP/dtmax, and LV volume (conductance catheter). Myocardial contractility was assessed with the end-systolic pressure-volume relation (Ees) and preload recruitable stroke work (Msw) generated from a series of LV pressure-volume diagrams. Left ventricular-arterial coupling and mechanical efficiency were determined by the ratio of Ees to effective arterial elastance (Ea; the ratio of end-systolic arterial pressure to stroke volume) and the ratio of stroke work (SW) to pressure-volume area (PVA), respectively. RESULTS: Desflurane, sevoflurane, and isoflurane reduced heart rate, mean arterial pressure, and left ventricular systolic pressure. All three anesthetics caused similar decreases in myocardial contractility and left ventricular afterload, as indicated by reductions in Ees, Msw, and dP/dtmax and Ea, respectively. Despite causing simultaneous declines in Ees and Ea, desflurane decreased Ees/Ea (1.02 +/- 0.16 during control to 0.62 +/- 0.14 at 1.2 minimum alveolar concentration) and SW/PVA (0.51 +/- 0.04 during control to 0.43 +/- 0.05 at 1.2 minimum alveolar concentration). Similar results were observed with sevoflurane and isoflurane. CONCLUSIONS: The present findings indicate that volatile anesthetics preserve optimum left ventricular-arterial coupling and efficiency at low anesthetic concentrations (< 0.9 minimum alveolar concentration); however, mechanical matching of energy transfer from the left ventricle to the arterial circulation degenerates at higher end-tidal concentrations. These detrimental alterations in left ventricular-arterial coupling produced by desflurane, sevoflurane, and isoflurane contribute to reductions in overall cardiac performance observed with these agents in vivo.     

Ambulatory blood pressure, nocturnal blood pressure reduction and plasma catecholamines

OBJECTIVE AND DESIGN: Controversial data have been reported on plasma catecholamines in hypertensives. Aims of this study were to find whether 24-hour ambulatory blood pressure was correlated with circulating catecholamines and to investigate whether nocturnal blood pressure reduction was associated with baseline plasma catecholamines. Samples for catecholamine determination were obtained in 34 consecutive male subjects after a 30-minute rest and before ambulatory blood pressure monitoring. RESULTS: Hypertensive patients (n = 22; 24-hour blood pressure: 145 +/- 14/94 +/- 6 mm Hg) showed similar norepinephrine and epinephrine levels when compared with normotensives (n = 12; 24-hour blood pressure: 124 +/- 6/81 +/- 6 mm Hg), and higher dopamine values (hypertensives: 64.6 +/- 58; normotensives: 26.2 +/- 31 pg/ml; p < 0.05). A positive correlation was observed between dopamine and diastolic nocturnal blood pressure (p < 0.05) while a negative correlation was found between dopamine and nocturnal diastolic blood pressure reduction (p < 0.025). No significant relationship was observed between both norepinephrine and epinephrine, and 24-hour blood pressures. CONCLUSIONS: Since previous reports have documented malfunctioning of dopaminergic system in hypertension, the higher levels of circulating plasma dopamine found in hypertensive patients in the present study may account for a peripheral compensatory increase. The correlation between dopamine and nocturnal blood pressure fall seems to indicate that the impairment of dopaminergic system may influence the 24-hour blood pressure profile, affecting the nocturnal blood pressure reduction.     

Relationships between Müller cells and neurons in a primitive tetrapod, the Australian lungfish

BACKGROUND: The cardiovascular side effects of volatile anesthetics are one of the chief causes of postoperative complications in children, and infants seem to be at the greatest risk for this. This study compared cardiovascular changes at equipotent concentrations of sevoflurane and halothane in infants. METHODS: Thirty infants classified as American Society of Anesthesiologists physical status I or II who required elective surgery were randomized to receive either halothane or sevoflurane for inhalation induction. Cardiovascular and echocardiographic data were recorded in both groups at baseline and at end-tidal concentrations of 1 and 1.5 minimum alveolar concentration (MAC). RESULTS: Sevoflurane did not alter heart rate or cardiac index at all concentrations compared with awake values. Sevoflurane significantly decreased blood pressure and systemic vascular resistance compared with awake values at all concentrations. Shortening fraction and rate-corrected velocity of circumferential fiber shortening decreased at 1.5 but not at 1 MAC. Myocardial contractility assessed by stress-velocity index and stress-shortening index decreased significantly at all concentrations, but did not fall into the abnormal range at any concentration. Halothane caused a greater decrease in heart rate, shortening fraction, stress-shortening index, velocity of circumferential fiber shortening, stress-velocity index, and cardiac index at all concentrations than did sevoflurane. CONCLUSION: Sevoflurane causes a lesser decrease in cardiac output than does halothane in infants.     

Generalised mitochondrial cytopathy is an absolute contraindication to orthotopic liver transplant in childhood

OBJECTIVE: To compare mask anesthesia induction and recovery characteristics between 2 inhalant anesthetic agents: isoflurane and sevoflurane. ANIMALS: 16 clinically normal, young adult Beagles. PROCEDURE: Using a cross-over design, dogs were randomly selected to receive sevoflurane or isoflurane via a face mask and a circle anesthetic system. Vaporizer setting concentrations were increased in stepwise, equal minimum alveolar concentrations (MAC) for each anesthetic until the vaporizer setting of 2.6% for isoflurane or 4.8% for sevoflurane (2 MAC) was reached. Concentration was kept constant until the dog had a negative tail clamp response and was intubated. End-tidal concentration was maintained at 1.8 to 2.0% or 3.3 to 3.8% for isoflurane or sevoflurane, respectively (1.4 to 1.6 MAC) for 30 minutes. Dogs were allowed to recover with only tail clamp stimulation until a positive response was obtained. Extubation was performed when a spontaneous swallow reflex was observed. Dogs were allowed to achieve sternal recumbency and stand unassisted without further stimulation. RESULTS: Sevoflurane induction resulted in shorter time to loss of palpebral reflex, negative tail clamp response, and time to tracheal intubation, and was of better quality than isoflurane induction. Both anesthetics were associated with rapid and smooth recovery. CONCLUSIONS: Sevoflurane mask induction is faster and of better quality, compared with isoflurane, in adult dogs. Recovery time and quality are comparable. CLINICAL RELEVANCE: On the basis of these results, sevoflurane is a suitable inhalant anesthetic for mask induction and recovery in adult dogs and appears to have some advantages over isoflurane, including faster and smoother mask induction.     

Novel protein toxin-based strategy for development of cytotoxic T lymphocyte vaccines

Unexplained episodic hypertension, hypotension, or orthostatic intolerance, tachycardia, anxiety, and flushing in 21 patients were investigated for the possibility of hypovolemia by blood volume and individual plasma catecholamines (including autocrine paracrine-born dopamine), determinations baseline, in response to upright posture and catecholamines only during the episodic blood pressure swings. Blood volume was determined by Cr51 fixed to patients' hemoglobin, free norepinephrine, epinephrine, and dopamine with dopamine sulfate following sulfatase hydrolysis, radioenzymatically. The recumbent mean 27.4+/-3% (SE) blood volume decrease from predicted values accentuating to 33.5+/-4% upright was associated with normal baseline plasma free norepinephrine, epinephrine, dopamine, dopamine sulfate, plasma renin activity, and aldosterone with normal mean postural responses from all patients except a hyperresponsive compared to controls (p < 0.04), plasma renin activity increase from 0.657+/-0.1 to 4.47+/-1.8 ng/mL/hr. During the hypertensive, hypotensive, or tachycardic episodes the moderate increase of free norepinephrine and epinephrine (p < 0.04) (but not free dopamine) contrasted with an increase of dopamine sulfate from 2.5+/-0.9 to clearly pathological values of 16.8+/-8.3 ng/mL (p < 0.0003 on % increase of individual values). We conclude that the normal (but to the degree of hypovolemia inappropriately low orthostatism- and episodes-associated sympathetic arousal) is outpaced by considerable episodic dopamine sulfate surges, reflecting extraneuronal dopamine discharge. Whether this increase contributes to the increased natriuresis directly or by inhibiting aldosterone response to renin-angiotensin, perpetuating hypovolemia, remains to be established.     

Interaction between anesthetics and the sodium-hydrogen exchange inhibitor HOE 642 (cariporide) in ischemic and reperfused rat hearts

BACKGROUND: Sodium (Na+)-hydrogen (H+) exchange (NHE) inhibitors are effective cardioprotective agents. The potent NHE inhibitor HOE 642 (cariporide) is being evaluated clinically in high-risk patients, including those having coronary artery bypass. Volatile anesthetics are also cardioprotective, most likely via different mechanisms. The potential interaction between anesthetics and HOE 642 was investigated. METHODS: Electrically paced isolated rat hearts were perfused at constant flow. Left ventricular developed pressure and end-diastolic pressure were monitored as determinants of function. Hearts were subjected to 60 min each of total ischemia followed by reperfusion. Isoflurane (0.93 minimum alveolar concentration [MAC]), sevoflurane (1.03 MAC), or sufentanil (1.2 nM) was added 15 min before ischemia and throughout reperfusion, either alone or in combination with HOE 642 (5 microM). The effect of HOE 642 alone was also studied. At the end of reperfusion, hearts were freeze-clamped for subsequent determination of tissue metabolites. RESULTS: In control hearts, left ventricular developed pressure recovered to 40% of preischemia values, whereas left ventricular end-diastolic pressure increased by 650% after reperfusion. Sevoflurane, isoflurane, or HOE 642 alone significantly enhanced left ventricular developed pressure recovery to more than 90%, although recovery with HOE 642 was more rapid and accompanied by significantly reduced left ventricular end-diastolic pressure. HOE 642 plus volatile anesthetics produced additive effects, with left ventricular developed pressure recovering by more that 100%, although left ventricular end-diastolic pressure was not further reduced. Sufentanil had no effect in terms of developed pressure, but protection with HOE 642 was maintained. HOE 642 with or without volatile anesthetics also preserved adenosine triphosphate levels. CONCLUSIONS: Isoflurane, sevoflurane, and HOE 642 enhance ventricular recovery, but the effect of HOE 642 is also associated with reduced contracture and adenosine triphosphate preservation. A combination of the NHE inhibitor and either volatile agent confers additive and superior protection, which could be relevant for the establishment of ideal cardioprotective strategies during surgery.     

Apoptosis in the chick wing bud and the permanence of FGF-2 rescue

The concentrations of plasma epinephrine (E) and norepinephrin (N) measured at rest in bullfrogs (Rana catesbeiana) were 12.0 and 8.2 nmol liter-1 respectively: the ratio of [E]/[N] was 1.33 (+/- SE 0.35). Adrenal glands contained high concentrations of epinephrine (2,923 nmole g wet weight-1) and norepinephrine (6,194), at a ratio of 0.46 (+/- SE 0.04) [E]/[N]. This differs from the measured plasma ratio and endogenous release ratios of about 2 for [E]/[N] reported for other Rana species, although the 95% confidence interval of our plasma ratio (0.97) spans the range of values from 0.36 to 2.3, including the observed plasma ratio of 0.46. Therefore, resting plasma catecholamine levels generally reflect the proportional adrenal content of catecholamines. Plasma epinephrine and norepinephrine concentrations significantly increased after activity to 50.4 and 18.1 nmol liter-1, respectively. The ratio of epinephrine to norepinephrine ([E]/[N]) also increased (but not significantly) to 8.53 (+/- SE 4.23), suggesting a shift away from some adrenal tone at rest to sympathetic nerve dominance with activity. Graded hemorrhage led to further increases in plasma epinephrine concentration and [E]/[N] but not norepinephrine, indicating sympathetic but not adrenal involvement. The in vitro epinephrine sensitivity of vascular beds indicates recruitment of the dorsal aorta vascular beds before the pulmocutaneous vascular bed. The minimum sensitivity of vascular beds to perfused epinephrine (10(4) nmol liter-1) was at higher concentrations than maximal plasma concentrations measured during hemorrhage. The bullfrog is less tolerant of hemorrhage than the cane toad Bufo marinus. The major difference in the catecholamine response of these two species was the massive contribution of adrenal catecholamines with severe hemorrhage in toads, which is absent in bullfrogs. This suggests that the enhanced hemorrhage and dehydration tolerance of toads may in part be the result of their greater adrenal gland development and activity.     

Time-dependent changes in heart rate and pupil size during desflurane or sevoflurane anesthesia

To better characterize alterations in autonomic function associated with prolonged anesthesia, we tested the hypothesis that the time-dependent effects of sevoflurane and desflurane differ. We studied seven male volunteers, each anesthetized for 8 h with 1.25 minimum alveolar anesthetic concentration desflurane on one study day and with 8 h sevoflurane on another. These volunteers did not undergo surgery and were minimally stimulated during the study. Measurements included blood pressure, heart rate, pupillary size and light reactivity, concentrations of serum catecholamines, and carbon dioxide production. Over time, heart rate and pupil size increased significantly. During 6 of the 14 anesthetics (45%), heart rate at some point exceeded 95 bpm; similarly, pupil size at some time exceeded 5 mm during 8 anesthetics (57%). In contrast, plasma catecholamine concentrations and carbon dioxide production remained unchanged, and blood pressure remained nearly constant. There are thus substantial time-dependent changes in autonomic functions during prolonged anesthesia, even in unstimulated, nonsurgical volunteers, but we could not detect a difference in these changes during desflurane compared with sevoflurane anesthesia. Implications: Pupil size and heart rate changes are used to guide the delivery of anesthesia. In volunteers, pupil size and heart rate increased with increasing duration of constant desflurane or sevoflurane anesthesia. Thus, anesthetic duration alters heart rate and pupil size independent of surgery and changes in anesthetic delivery.     

Context-sensitive half-times and other decrement times of inhaled anesthetics

The length of anesthetic administration influences the rate at which concentrations of anesthetics decrease after their discontinuation. This is true for both intravenous (I.V.) and inhaled anesthetics. This has been explored in detail for I.V. anesthetics using computer simulation to calculate context-sensitive half-times (the time needed for a 50% decrease in anesthetic concentration) and other decrement times (such as the times needed for 80% or 90% decreases in anesthetic concentration). However, decrement times have not been reported for inhaled anesthetics. In this report, published pharmacokinetic parameters and computer simulation were used to compare the context-sensitive half-times and the 80% and 90% decrement times of the expected central nervous system concentrations for enflurane, isoflurane, sevoflurane, and desflurane. The context-sensitive half-times for all four anesthetics are small (<5 min) and do not increase significantly with increasing duration of anesthesia. The 80% decrement times of both sevoflurane and desflurane are also small (<8 min) and do not increase significantly with duration of anesthesia. However, the 80% decrement times of isoflurane and enflurane increase significantly after approximately 60 min of anesthesia, reaching plateaus of approximately 30 and 35 min. The 90% decrement time of desflurane increased slightly from 5 min after 30 min of anesthesia to 14 min after 6 h of anesthesia. It remained significantly less than the 90% decrement times of sevoflurane, isoflurane, and enflurane, which reached values of 65 min, 86 min, and 100 min, respectively, after 6 h of anesthesia. IMPLICATIONS: The major differences in the rates at which desflurane, sevoflurane, isoflurane, and enflurane are eliminated occur in the final 20% of the elimination process.     

Adrenomedullary secretion of epinephrine is increased in mild essential hypertension

To assess whether patients with mild essential hypertension have excessive activities of the sympathoneuronal and adrenomedullary systems, we examined total body and forearm spillovers and norepinephrine and epinephrine clearances in 47 subjects with mild essential hypertension (25 men, 22 women, aged 38.1 +/- 6.7 years) and 43 normotensive subjects (19 men, 24 women, aged 36.5 +/- 5.9 years). The isotope dilution method with infusions of tritiated norepinephrine and epinephrine was used at rest and during sympathetic stimulation by lower body negative pressure at -15 and -40 mm Hg. Hypertensive subjects had a higher arterial plasma epinephrine concentration (0.20 +/- 0.01 nmol.L-1: mean +/- SE) than normotensive subjects (0.15 +/- 0.01) (P < .01). The increased arterial plasma epinephrine levels appeared to be due to a higher total body epinephrine spillover rate in the hypertensive subjects (0.23 +/- 0.02 nmol.min-1.m-2) than the normotensive subjects (0.18 +/- 0.01) (P < .05) and not to a decreased plasma clearance of epinephrine. The arterial plasma norepinephrine level, total body and forearm norepinephrine spillover rates, and plasma norepinephrine clearance were not altered in the hypertensive subjects. The responses of the catecholamine kinetic variables to lower body negative pressure were not consistently different between normotensive and hypertensive individuals. These data indicate that individuals with mild essential hypertension (1) have elevated arterial plasma epinephrine concentrations that are due to an increased total body epinephrine spillover rate, indicating an increased adrenomedullary secretion of epinephrine; (2) have no increased generalized sympathoneuronal activity and no increased forearm norepinephrine spillover; and (3) have similar responses of both the sympathoneuronal and adrenomedullary systems to sympathetic stimulation by lower body negative pressure.     

Norepinephrine and epinephrine release and adrenergic mediation of smoking-associated hemodynamic and metabolic events

We studied the effects of cigarette smoking, sham smoking and smoking during adrenergic blockade in 10 subjects to determine whether smoking released the sympathetic neurotransmitter norepinephrine, as well as the adrenomedullary hormone epinephrine, and whether smoking-associated hemodynamic and metabolic changes were mediated through adrenergic mechanisms. Smoking-associated increments in mean (+/- S.E.M.) plasma norepinephrine (227 +/- 23 to 324 +/- 39 pg per milliliter, P less than 0.01) and epinephrine (44 +/- to 113 +/- 27 pg per milliliter, P less than 0.05) were demonstrated. Smoking-associated increments in pulse rate, blood pressure, blood glycerol and blood lactate/pyruvate ratio were prevented by adrenergic blockade; increments in plasma growth hormone and cortisol were not. Since significant smoking-associated increments, in pulse rate, blood pressure and blood lactate/pyruvate ratio, preceded measurable increments in plasma catecholamine concentrations, but were adrenergically mediated, these changes should be attributed to norepinephrine released locally from adrenergic axon terminals within the tissues rather than to increments in circulating catecholamines.     

Recovery from sevoflurane anesthesia: a comparison to isoflurane and propofol anesthesia

BACKGROUND: Sevoflurane has a lower blood:gas partition coefficient than isoflurane, which may cause a more rapid recovery from anesthesia; it also might cause faster emergence times than for propofol-based anesthesia. We evaluated a database that included recovery endpoints from controlled, randomized, prospective studies sponsored by Abbott Laboratories that compared sevoflurane to isoflurane or propofol when extubation was planned immediately after completion of elective surgery in adult patients. METHODS: Sevoflurane was compared to isoflurane in eight studies (N=2,008) and to propofol in three studies (N=436). Analysis of variance was applied using least squares method mean values to calculate the pooled mean difference in recovery endpoints between primary anesthetics. The effects of patient age and case duration also were determined. RESULTS: Sevoflurane resulted in statistically significant shorter times to emergence (-3.3 min), response to command (-3.1 min), orientation (-4.0 min) and first analgesic (-8.9 min) but not time to eligibility for discharge (-1.7 min) compared to isoflurane (mean difference). Times to recovery endpoints increased with increasing case duration with isoflurane but not with sevoflurane (patients receiving isoflurane took 4-5 min more to emerge and respond to commands and 8.6 min more to achieve orientation during cases longer than 3 hr in duration than those receiving sevoflurane). Patients older than 65 yr had longer times to orientation, but within any age group, orientation was always faster after sevoflurane. There were no differences in recovery times between sevoflurane and propofol. CONCLUSIONS: Recovery from sevoflurane was 3-4 min faster than with isoflurane in all age groups, and the difference was magnified in longer-duration surgical cases (> 3 hr).     

Cardiotoxicity of chlorodibromomethane and trichloromethane in rats and isolated rat cardiac myocytes

The cardiovascular effects were investigated after acute and subacute treatment with chlorodibromomethane (CDBM; 0.4 to 3.2 mmol/kg p.o.), trichloromethane (TCM; 0.31 and 1.25 mmol/kg p.o.) and mixtures of CDBM and TCM (acute, 0.8 mmol CDBM/kg + 1.25 mmol TCM/kg p.o.; subacute, 0.4 mmol CDBM/kg + 0.31 mmol TCM/kg p.o.) in conscious and urethane anaesthetized male Wistar rats (n = 6-10 per treatment). Furthermore it was observed whether cardiovascular responses were modified in CDBM or TCM treated rats after administration of exogenous catecholamines (epinephrine, 1 microg/kg; norepinephrine, 2 microg/kg) and underpinned with in vitro alterations of Ca2+ dynamics in cardiac myocytes. The present findings demonstrated that single and subacute oral administration of CDBM or TCM and mixtures of CDBM and TCM resulted in arrhythmogenic and negative chronotropic and dromotropic effects in conscious and urethane anaesthetized rats. The atrioventricular conduction time and the intraventricular extension time were extended. A slight shortening of the repolarization velocity was observed. The myocardial contractility was depressed and the heart was sensitized to the arrhythmogenic effects of epinephrine. After catecholamine injection the adrenergic cardiovascular responses in urethane anesthetized rats were modified: increased hypertensive epinephrine and norepinephrine action as well as augmentation of negative chronotropic and negative dromotropic cardiac effects of catecholamines were observed. The positive inotropic adrenergic response was diminished. The present in vivo findings, myocardial depression after acute CDBM treatment, as determined by different indices of contractility, correlate well with the observed inhibitory actions of CDBM on Ca2+ dynamics in isolated cardiac myocytes. All cardiovascular alterations found after CDBM or TCM treatment were not intensified after treatment with mixtures of CDBM and TCM. The effects observed were distinctly stronger after TCM (1.25 and 0.31 mmol/kg) treatment compared to CDBM (0.8 and 0.4 mmol/kg) treatment.     

Extent of autonomic activation following cerebral ischemia is different in hypertensive and normotensive humans

OBJECTIVES: To evaluate whether the extent of autonomic activation following brain infarction differs between hypertensive and normotensive humans, and to investigate the role of the insular cortex for this sympathetic activation. DESIGN: Prospective, hospital-based study. SETTING: Department of Neurology of a university medical center. SUBJECTS: Forty-two patients with essential hypertension and 45 patients who were normotensive. MAIN OUTCOME MEASURES: Extent of autonomic activation following stroke as indicated by circadian blood pressure patterns, serum norepinephrine levels, and cardiovascular variables. RESULTS: Normotensive patients with insular infarction showed a significantly reduced circadian blood pressure variation and a higher frequency of nocturnal blood pressure increase compared with patients suffering from essential hypertension and insular stroke. These findings were also associated with higher serum norepinephrine concentrations and more frequent electrocardiographic abnormalities. No significant changes in these variables were seen between normotensive and hypertensive patients without insular involvement. CONCLUSIONS: Our findings suggest a difference in cortical control of autonomic function between hypertensive and normotensive patients after stroke and point to a possible role of the insular cortex in the pathogenesis of essential hypertension.     

Desflurane-mediated sympathetic activation occurs in humans despite preventing hypotension and baroreceptor unloading

BACKGROUND: Increasing concentrations of desflurane result in progressive decreases in blood pressure (BP) and, unlike other currently marketed, potent volatile anesthetics, heightened sympathetic nervous system activity. This study aimed to determine whether baroreflex mechanisms are involved in desflurane-mediated sympathetic excitation. METHODS: Healthy volunteers were anesthetized with desflurane (n = 8) or isoflurane (n = 9). Heart rate (HR; measured by electrocardiograph), blood pressure (BP; measured by arterial catheter), and efferent sympathetic nerve activity (SNA; obtained from percutaneous recordings from the peroneal nerve) were monitored. Baroreflex sensitivity was evaluated at baseline while volunteers were conscious and during 0.5, 1, and 1.5 minimum alveolar concentration (MAC) anesthesia via bolus injections of nitroprusside (100 microg) and phenylephrine (150 microg) to decrease and increase BP. To prevent the BP decline with increasing depths of anesthesia, phenylephrine was infused to maintain mean BP at the 0.5 MAC level. RESULTS: The HR, BP, and SNA were similar between the groups at the conscious baseline measurement. Efferent SNA did not change during higher MAC of isoflurane, but it increased progressively as desflurane concentrations were increased beyond 0.5 MAC, despite maintaining BP at the 0.5 MAC value with phenylephrine infusions (P < 0.05). Cardiac baroslopes (based on changes in HR) were progressively and similarly decreased with increasing concentrations of isoflurane and desflurane (P < 0.05). Sympathetic baroslopes (based on SNA) decreased with increasing isoflurane concentrations but were maintained with increasing concentrations of desflurane; the response was significantly different between groups. CONCLUSIONS: The increase in basal levels of SNA with increasing concentrations of desflurane persisted despite "fixing" BP and thus is probably not due to hypotension and unloading of the baroreceptors. Further, the preservation of reflex increases in SNA to nitroprusside during desflurane indicates that desflurane preserves one component of the baroreflex in humans when BP is "fixed."     

Effect of isoflurane and sevoflurane on evoked potentials and EEG

Evoked potentials and EEG are used to monitor the central nervous system and the depth of anesthesia in anesthetized patients. In this study, we examined EEG, VEP, SEP and ABR at various concentrations of isoflurane or sevoflurane, and evaluated the influence of volatile agents and their usefulness for the monitoring of the depth of anesthesia. With increasing concentrations of isoflurane and sevoflurane, AE (frequency which account for 80% of total voltage) showed dose-related reduction and EEG showed a trend toward a slower wave and higher amplitude. With increasing concentrations of isoflurane and sevoflurane, P100 of VEP showed a significant dose-related reduction in its amplitude and increase in its latency. So we could not record P100 at the level of the anesthesia of 1.0 MAC with 66% N2O. N20 of SEP can be easily recorded at any depth of anesthesia. And the trend showed consistent dose-related changes in amplitude and latency. With increasing concentrations of isoflurane and sevoflurane, wave III and V of ABR increased significantly in latency, but the changes were very small. In conclusion, the effect of isoflurane and that of sevoflurane on evoked potentials and EEG are similar with each other and with other volatile agents. SEP is the most consistent and reliable factor to monitor the depth of anesthesia neurophysiologically.