Sevoflurane increases lumbar cerebrospinal fluid pressure in normocapnic patients undergoing transsphenoidal hypophysectomy.

BACKGROUND: The data on the effect of sevoflurane on intracranial pressure in humans are still limited and inconclusive. The authors hypothesized that sevoflurane would increase intracranial pressure as compared to propofoL METHODS: In 20 patients with no evidence of mass effect undergoing transsphenoidal hypophysectomy, anesthesia was induced with intravenous fentanyl and propofol and maintained with 70% nitrous oxide in oxygen and a continuous propofol infusion, 100 microg x kg(-1) x min(-1). The authors assigned patients to two groups randomized to receive only continued propofol infusion (n = 10) or sevoflurane (n = 10) for 20 min. During the 20-min study period, each patient in the sevoflurane group received, in random order, two concentrations (0.5 times the minimum alveolar concentration [MAC] and 1.0 MAC end-tidal) of sevoflurane for 10 min each. The authors continuously monitored lumbar cerebrospinal fluid (CSF) pressure, blood pressure, heart rate, and anesthetic concentrations. RESULTS: Lumbar CSF pressure increased by 2+/-2 mmHg (mean+/-SD) with both 0.5 MAC and 1 MAC of sevoflurane. Cerebral perfusion pressure decreased by 11+/-5 mmHg with 0.5 MAC and by 15+/-4 mmHg with 1.0 MAC of sevoflurane. Systolic blood pressure decreased with both concentrations of sevoflurane. To maintain blood pressure within predetermined limits (within+/-20% of baseline value), phenylephrine was administered to 5 of 10 patients in the sevoflurane group (range = 50-300 microg) and no patients in the propofol group. Lumbar CSF pressure, cerebral perfusion pressure, and systolic blood pressure did not change in the propofol group. CONCLUSIONS: Sevoflurane, at 0.5 and 1.0 MAC, increases lumbar CSF pressure. The changes produced by 1.0 MAC sevoflurane did not differ from those observed in a previous study with 1.0 MAC isoflurane or desflurane.     

Sevoflurane Increases Lumbar Cerebrospinal Fluid Pressure in Normocapnic Patients Undergoing Transsphenoidal Hypophysectomy

Background: The data on the effect of sevoflurane on intracranial pressure in humans are still limited and inconclusive. The authors hypothesized that sevoflurane would increase intracranial pressure as compared to propofol.

Methods: In 20 patients with no evidence of mass effect undergoing transsphenoidal hypophysectomy, anesthesia was induced with intravenous fentanyl and propofol and maintained with 70% nitrous oxide in oxygen and a continuous propofol infusion, 100 [micro sign]g [middle dot] kg-1 [middle dot] min-1. The authors assigned patients to two groups randomized to receive only continued propofol infusion (n = 10) or sevoflurane (n = 10) for 20 min. During the 20-min study period, each patient in the sevoflurane group received, in random order, two concentrations (0.5 times the minimum alveolar concentration [MAC] and 1.0 MAC end-tidal) of sevoflurane for 10 min each. The authors continuously monitored lumbar cerebrospinal fluid (CSF) pressure, blood pressure, heart rate, and anesthetic concentrations.

Results: Lumbar CSF pressure increased by 2 +/- 2 mmHg (mean +/- SD) with both 0.5 MAC and 1 MAC of sevoflurane. Cerebral perfusion pressure decreased by 11 +/- 5 mmHg with 0.5 MAC and by 15 +/- 4 mmHg with 1.0 MAC of sevoflurane. Systolic blood pressure decreased with both concentrations of sevoflurane. To maintain blood pressure within predetermined limits (within +/- 20% of baseline value), phenylephrine was administered to 5 of 10 patients in the sevoflurane group (range = 50-300 [micro sign]g) and no patients in the propofol group. Lumbar CSF pressure, cerebral perfusion pressure, and systolic blood pressure did not change in the propofol group.     

Fentanyl Augments the Blockade of the Sympathetic Response to Incision (MAC-BAR) Produced by Desflurane and Isoflurane: Desflurane and Isoflurane MAC-BAR without and with Fentanyl

Background: Heart rate (HR) or mean arterial blood pressure (MAP) may increase in response to incision despite the absence of a motor response. The authors hypothesized that the MAC-BAR (minimum alveolar concentration of an anesthetic that blocks adrenergic response to incision) for isoflurane would exceed that for desflurane, and that fentanyl would decrease the MAC-BAR for each anesthetic in a dose-dependent manner.

Methods: Seventy-one patients were randomly allocated to one of six groups: desflurane or isoflurane without fentanyl or with 1.5 or 3 micro gram/kg fentanyl given intravenously 5 min before surgical incision. Anesthesia was induced with 2 mg/kg propofol given intravenously, and tracheal intubation facilitated with 0.1 mg/kg given intravenously. The first patient in each group received 1 MAC (end-tidal) of the inhaled anesthetic in 60% nitrous oxide (0.55 MAC), balance oxygen, maintained for at least 10 min before incision. The response was considered positive if the HR or MAP increased 15% or more. If the response was positive, the end-tidal concentration given to the next patient was 0.3 MAC greater; if the response was negative, the end-tidal concentration was 0.3 MAC less. The MAC-BAR level was calculated as the mean of four independent cross-over responses in each group.

Results: Desflurane and isoflurane anesthesia with 60% nitrous oxide did not change HR (P > 0.05) and decreased MAP (P < 0.05) before incision. Plasma epinephrine and norepinephrine concentrations after anesthesia and before incision were normal in all groups. The MAC-BAR level, without fentanyl, did not differ (P > 0.05) between desflurane (1.30 +/- 0.34 MAC [mean +/- SD]) and isoflurane (1.30 +/- 0.18 MAC). Fentanyl given at 1.5 micro gram/kg intravenously equivalently (P > 0.05) reduced the MAC-BAR for desflurane (to 0.40 +/- 0.18 MAC; P <0.05) and isoflurane (to 0.55 +/- 0.00 MAC; P < 0.05), but a further increase in fentanyl to 3 micro gram/kg caused no greater decrease in the MAC-BAR for desflurane (0.48 +/- 0.16 MAC) and isoflurane (0.40 +/- 0.30 MAC).     

A comparison of desflurane and isoflurane in patients undergoing coronary artery surgery

Animal studies indicate that desflurane and isoflurane have similar hemodynamic effects when administered in equipotent anesthetic concentrations. The authors compared desflurane and isoflurane, used as primary anesthetics for patients undergoing elective coronary artery bypass surgery whose left ventricular ejection fractions were greater than 0.34. After induction of anesthesia with thiopental (dose 180 +/- 45 mg [mean +/- standard deviation]) and fentanyl, 10 micrograms.kg-1, either desflurane or isoflurane was administered to maintain systolic blood pressure within 70-120% of, and heart rates less than 120% of, the patients' average preoperative values. If adjusting the end-tidal anesthetic concentration within the range of 0-2.0 MAC could not maintain these predefined hemodynamic limits, additional fentanyl or vasoactive drugs were used. Induction and maintenance of anesthesia was accompanied by a significant decrease in mean arterial pressure in both groups (desflurane 97 +/- 12 mmHg at control, decreasing to 71 +/- 5 mmHg during skin preparation; isoflurane 95 +/- 9 mmHg at control, 74 +/- 9 mmHg during skin preparation). One minute after sternotomy, mean arterial pressure in the isoflurane group had returned to control, 97 +/- 9 mmHg, which was significantly greater than in the desflurane group, 87 +/- 12 mmHg. Systolic arterial pressure was also significantly greater in the isoflurane group 1 min after intubation, during skin preparation, and 1 min after sternotomy. Otherwise, the hemodynamic effects of these volatile agents were similar. There were no differences between groups in the incidence of ECG changes indicative of myocardial ischemia prior to cardiopulmonary bypass, perioperative myocardial infarction, or perioperative mortality.(ABSTRACT TRUNCATED AT 250 WORDS)     

The cerebral functional, metabolic, and hemodynamic effects of desflurane in dogs

The effects of 0.5-2.0 MAC (3.6-15%) desflurane on cerebral function, metabolism, and hemodynamics and on systemic metabolism and hemodynamics were examined in dogs. Desflurane produced a significant dose-related decrease in cerebral vascular resistance from 1.53 +/- 0.21 mmHg.ml-1.min.100 g at 0.5 MAC to 0.50 +/- 0.03 mmHg.ml-1.min.100 g at 2.0 MAC desflurane. This was accompanied by an increase in cerebral blood flow (CBF) from 61 +/- 7 ml.min-1.100 g-1 at 0.5 MAC to 78 +/- 3 ml.min-1.100 g-1 at 1.5 MAC desflurane. At 2.0 MAC desflurane CBF was 52 +/- 2 ml.min-1.100 g-1 but was associated with a decrease in mean arterial pressure (MAP) to 43 +/- 2 mmHg. When MAP was increased to 73 +/- 3 mmHg with phenylephrine, CBF increased to 87 +/- 3 ml.min-1.100 g-1 at this concentration. At 0.5 MAC desflurane, intracranial pressure (ICP) was 15 +/- 5 mmHg, higher than normal, but did not change significantly with increasing concentrations of desflurane. Increasing concentrations of desflurane initially produced on the EEG the common pattern sequence of increasing depth of anesthesia with decreasing frequency and increasing amplitude progressing to burst suppression and then at 2.0 MAC desflurane to regular attenuation with interruption by periodic polyspiking, a pattern similar to that seen with isoflurane. At both 1.5 and 2.0 MAC the EEG pattern initially observed at that concentration changed to one with faster background activity with time.(ABSTRACT TRUNCATED AT 250 WORDS)     

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 micro gram) and phenylephrine (150 micro gram) 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.     

Comparison of the systemic and coronary hemodynamic actions of desflurane, isoflurane, halothane, and enflurane in the chronically instrumented dog

The systemic and coronary hemodynamic effects of desflurane were compared to those of isoflurane, halothane, and enflurane in chronically instrumented dogs. Since autonomic nervous system function may significantly influence the hemodynamic actions of anesthetics in vivo, a series of experiments also was performed in the presence of pharmacologic blockade of the autonomic nervous system. Eight groups comprising a total of 80 experiments were performed on 10 dogs instrumented for measurement of aortic and left ventricular pressure, the peak rate of increase of left ventricular pressure (dP/dt), subendocardial segment length, coronary blood flow velocity, and cardiac output. Systemic and coronary hemodynamics were recorded in the conscious state and after 30 min equilibration at 1.25 and 1.75 MAC desflurane, isoflurane, halothane, and enflurane. Desflurane (+79 +/- 12% change from control) produced greater increases in heart rate than did halothane (+44 +/- 12% change from control) or enflurane (+44 +/- 9% change from control) at 1.75 MAC. Desflurane preserved mean arterial pressure to a greater degree than did equianesthetic concentrations of isoflurane. This result was attributed to a smaller effect on peripheral vascular resistance as compared to isoflurane and greater preservation of myocardial contractility as evaluated by peak positive left ventricular dP/dt and the rate of increase of ventricular pressure at 50 mmHg (dP/dt50) compared to other volatile anesthetics. Increases in diastolic coronary blood flow velocity (+19 +/- 6 and +35 +/- 12% change from control at 1.75 MAC, respectively) and concomitant decreases in diastolic coronary vascular resistance (-41 +/- 12 and -58 +/- 6% change from control at 1.75 MAC, respectively) were produced by desflurane and isoflurane. In the presence of autonomic nervous system blockade, the actions of desflurane and isoflurane were nearly identical with the exception of coronary vasodilation. After autonomic nervous system blockade, isoflurane increased coronary blood flow velocity, but desflurane did not. Furthermore, both desflurane and isoflurane continued to produce less depression of myocardial contractility than did halothane and enflurane. In summary, at equianesthetic concentrations, desflurane and isoflurane produced similar hemodynamic effects; however, in the absence of drugs that inhibit autonomic reflexes, desflurane had less negative inotropic activity and produced less decrease in arterial pressure. The coronary vasodilator actions of desflurane and isoflurane within the limitations of this model were not similar. When the increase in heart rate and rate-pressure product produced by desflurane were prevented in dogs with autonomic nervous system blockade, desflurane produced no change in coronary blood flow velocity.     

Influence of volatile anesthetics on myocardial contractility in vivo: desflurane versus isoflurane

The direct effects of desflurane on myocardial contractility in vivo have not been characterized. Therefore, the purpose of this investigation was to systematically examine the effects of desflurane on myocardial contractile function and compare these actions to equianesthetic concentrations of isoflurane in chronically instrumented dogs. Contractility was evaluated using an established index of inotropic state, the preload recruitable stroke work (PRSW) versus end-diastolic segment length (EDL) relationship. Since autonomic nervous system tone may influence the hemodynamic effects of the volatile anesthetics in vivo, experiments were performed in the presence of pharmacologic blockade of the autonomic nervous system. Two groups of experiments were performed with seven dogs instrumented for measurement of aortic and left ventricular pressure, the maximum rate of increase of left ventricular pressure (dP/dt), subendocardial segment length, coronary blood flow velocity, and cardiac output. After autonomic nervous system blockade, ventricular pressure-segment length loops were generated using preload reduction via partial inferior vena caval occlusion. The PRSW versus EDL relation was calculated from the pressure-length loops. Dogs were then anesthetized with 1.0 or 1.5 MAC desflurane or isoflurane in a random fashion, and measurements were repeated after 30 min of equilibration at each anesthetic concentration. The PRSW versus EDL slope reflected similar changes in contractile state when desflurane or isoflurane was administered (53 +/- 4 during control to 26 +/- 4 erg.cm-2 x 10(-3).mm-1 at 1.5 MAC desflurane, and 57 +/- 5 during control to 31 +/- 3 erg.cm-2 x 10(-2).mm-1 at 1.5 MAC isoflurane). In conclusion, desflurane and isoflurane produced equivalent direct decreases in myocardial contractility.     

A Comparison of Baroreflex Sensitivity during Isoflurane and Desflurane Anesthesia in Humans

Background: Desflurane anesthesia has been associated with heart rate (HR) and sympathetic nerve activity (SNA) responses that differ from those during isoflurane anesthesia. Whether these differences might be due to better preservation by desflurane of the baroreceptor reflex control of HR or SNA in humans was examined.

Methods: Baroreflex sensitivity was assessed in 18 volunteers anesthetized with either desflurane or isoflurane. Measurements of HR, blood pressure (BP), and efferent SNA (percutaneous recordings from the peroneal nerve) were made, and baroreflex sensitivity was evaluated at conscious baseline and during 0.5, 1.0, and 1.5 MAC anesthesia. Baroreflex responses were triggered by bolus intravenous injections of nitroprusside (100 micro gram) and phenylephrine (150 micro gram). The linear portions of the baroreflex curves relating HR to mean arterial pressure and relating SNA to diastolic pressure were determined to obtain cardiac and sympathetic baroslopes, respectively.

Results: Cardiac (HR) baroslopes were equally diminished at increasing MAC of both anesthetics. Sympathetic baroslopes were preserved at 0.5 MAC isoflurane but diminished at 0.5 MAC desflurane. Higher MAC produced equal depression of sympathetic baroslopes with both anesthetics.     

The effect of desflurane and isoflurane on cerebrospinal fluid pressure in humans with supratentorial mass lesions.

Desflurane, a new volatile anesthetic, produces cerebral vasodilation. The purpose of this study was to compare the effects of 1 MAC desflurane with those of isoflurane on cerebrospinal fluid pressure (CSFP) in patients with supratentorial mass lesions and a mass effect on computerized tomography (CT scan). Twenty adult patients undergoing craniotomy for removal of supratentorial mass lesions were studied. Ten patients received desflurane and 10 patients received isoflurane. Prior to induction of anesthesia, a radial artery catheter was inserted and a 19-G needle was inserted into the lumbar subarachnoid space to measure CSFP. Baseline arterial blood gases and CSFP were measured with the patient awake and unmedicated. Anesthesia was induced with thiopental (6-9 mg/kg) and muscle relaxation achieved with vecuronium (0.2 mg/kg). The lungs of all patients were hyperventilated to achieve an arterial CO2 tension of 24-28 mmHg. Anesthesia was maintained with 1 MAC volatile anesthetic, either 7.0% desflurane or 1.2% isoflurane in an air:O2 mixture to maintain an inspired O2 fraction (FIO2) of 0.50. Patients were not administered any other anesthetic until the dura was incised. Mean arterial pressure was kept within 20% of the patient's mean ward values with the use of esmolol or phenylephrine. CSFP, mean arterial pressure, end-tidal CO2 concentration (PETCO2), hemoglobin O2 saturation, and cerebral perfusion pressure were recorded with the patient awake, immediately postinduction with thiopental, postintubation, after institution of the volatile anesthetic, and every 5 min until the dura was incised. There was no difference in the mean (+/- SD) awake CSFP between the desflurane (11 +/- 4 mmHg) and the isoflurane (10 +/- 2 mmHg) groups.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cerebral blood flow velocity increases when propofol is changed to desflurane, but not when isoflurane is changed to desflurane in children

BACKGROUND: Children may exhibit delayed emergence following maintenance of anesthesia with propofol or isoflurane. Desflurane is often used towards the end of procedures to facilitate emergence. This study evaluated the effect on middle cerebral artery blood flow velocity (Vmca) in anesthetized children when propofol or isoflurane was substituted with desflurane. METHODS: Forty-two healthy children aged 1-6 years were enrolled. A standardized anesthetic induction was used. Anesthesia was maintained with remifentanil (0.5 microg.kg(-1) bolus followed by an infusion of 0.2 microg.kg(-1).min(-1)) and a randomly selected sequence of propofol/desflurane/propofol, desflurane/propofol/desflurane, isoflurane/desflurane/isoflurane or desflurane/isoflurane/desflurane. Propofol was administered to maintain a steady-state serum concentration of 3 microg.ml(-1). Desflurane and isoflurane were administered at age-corrected 1 MAC. Hemodynamic stability was maintained. Transcranial Doppler sonography was used to measure Vmca. Hemodynamic variables as well as Vmca were measured 30 min after skin incision and repeated 30 min after each change in anesthetic maintenance agent. RESULTS: The mean age and weight was 2.3 +/- 1.3 years and 13.0 +/- 3.7 kg, respectively. The Vmca (mean) increased by 35% from 37.7 +/- 10.5 cm s(-1) to 57.8 +/- 14.6 cm s(-1) (P < 0.0001) when propofol was changed to desflurane but was unaffected when desflurane replaced isoflurane. CONCLUSION: When propofol is changed to desflurane, cerebral blood flow velocity increases significantly in normal children. This cerebral vasodilatory effect may have important implications in the neurosurgical setting.     

Desflurane and isoflurane improve neurological outcome after incomplete cerebral ischaemia in rats

We have investigated the effects of isoflurane and desflurane on neurological outcome in a rat model of incomplete cerebral ischaemia. We studied 40 non-fasted male Sprague-Dawley rats, anaesthetized, intubated and ventilated mechanically with isoflurane and nitrous oxide in oxygen (FlO2 0.3). Arterial and venous catheters were inserted for measurement of arterial pressure, drug administration and blood sampling. A biparietal electroencephalogram (EEG) was recorded continuously using subdermal platinum electrodes. At completion of surgery, administration of isoflurane was discontinued (with the exception of those animals receiving isoflurane as treatment) and rats were allowed an equilibration period of 30 min according to the following procedure: group 1 (n = 10), 66% nitrous oxide in oxygen and fentanyl (bolus 10 micrograms kg-1 i.v. followed by infusion at a rate of 25 micrograms kg-1 h-1); group 2 (n = 10), 1.0 MAC of isoflurane in oxygen (FlO2 0.3) and air; groups 3 and 4 (n = 10 per group), 1.0 MAC or 1.5 MAC of desflurane in oxygen (FlO2 0.3) and air, respectively. Ischaemia was produced by combined unilateral common carotid artery ligation and haemorrhagic hypotension to 35 mm Hg for 30 min. Functional neurological deficit was evaluated for 3 days after cerebral ischaemia. At baseline, brain electrical activity was higher with fentanyl-nitrous oxide, 1.0 MAC of isoflurane and 1.0 MAC of desflurane (groups 1-3) compared with 1.5 MAC of desflurane (group 4). Neurological outcome was improved in isoflurane and desflurane anaesthetized animals (groups 2-4), regardless of the concentration used compared with fentanyl-nitrous oxide anaesthesia (group 1). The increase in plasma epinephrine and norepinephrine concentrations during ischaemia was significantly higher in fentanyl-nitrous oxide anaesthetized animals (group 1) compared with animals who received volatile anaesthetics (groups 2-4). These data suggest that cerebral protection produced by isoflurane and desflurane appears to be related to reduction in sympathetic activity rather than suppression of cerebral metabolic rate.      

地氟醚、异氟醚和七氟醚对脑血流速率的影响

目的　通过经颅多普勒超声 (TCD)监测大脑中动脉 (MCA)血流速率 ,观察地氟醚、异氟醚和七氟醚三种吸入麻醉药对平均血流速率 (Vm)的影响。方法　 42例 18～ 6 0岁、ASAⅠ～Ⅱ级、择期非颅脑手术病人 ,随机接受地氟醚、异氟醚或七氟醚吸入麻醉。机械通气维持PETCO2 在 40± 1mmHg。当呼气末吸入麻醉药浓度分别为 :1 0MAC平衡 15分钟后 ,快速 (2分钟内 )从 1 0MAC升高至 1 5MAC即时 ,1 5MAC平衡 15分钟后 ,以及稳定于 1 5MAC并且维持和 1 0MAC平衡下相似的MAP时 ,记录Vm、MAP和心率。结果　 (1)吸入浓度从 1 0MAC上升至 1 5MAC ,且MAP维持相同水平的情况下 ,地氟醚和异氟醚使Vm增加非常显著 (分别从 5 6cm/s上升至 6 1cm/s,从47cm/s上升至 5 2cm/s,P <0 0 1) ,而七氟醚无显著变化 (从 6 0cm/s至 6 0cm/s,P >0 0 5 )。 (2 )当吸入浓度快速从 1 0MAC上升至 1 5MAC时 ,地氟醚使血压升高、心率增快 ,同时 ,脑血流速率显著增加 (从 5 6cm/s上升至 6 1cm/s,P <0 0 1)。而异氟醚和七氟醚在MAP显著下降的同时使Vm无显著变化 (从 47cm/s升至 49cm/s,P >0 0 5 ) ,或显著下降 (从 6 0cm/s降至 5 6cm/s,P <0 0 1)。结论　 (1)吸入浓度从 1 0MAC增加到 1 5MCA时 ,地氟醚、异氟醚使脑血流速率显著增加 ,而七氟醚作     

Comparison of the haemodynamic actions of desflurane/N2O and isoflurane/N2O anaesthesia in vascular surgical patients

Background: The purpose of this study was to compare heart rate and arterial blood pressure response to desflurane/N₂O vs isoflurane/N₂O anaesthesia in a randomised clinical trial performed in patients before vascular surgery.
Methods: To evaluate associated changes in the autonomic nervous system with maintenance of anaesthesia, we used power spectral analysis (PSA) of heart rate and blood pressure and measured plasma catecholamine concentrations. Twenty-five patients whose trachea had been intubated after propofol induction were given either desflurane or isoflurane at 1 and 1.5 MAC in N₂O (60%) in a random manner.
Results: At an anaesthetic depth of up to 1.5 MAC, arterial blood pressure, indices of sympathetic activity derived from PSA, decreased with both anaesthetics, while heart rate and plasma catecholamine concentrations did not significantly change. Plasma renin activity significantly increased at 1.5 MAC anaesthesia in both groups.
Conclusions: We conclude that sympathetic hyperactivity previously reported during desflurane anaesthesia in healthy volunteers is not frequent in clinical practice in elderly vascular surgical patients under desflurane/N₂O anaesthesia, since it occurs at an anaesthetic depth which cannot be reached in these patients because of the lowering arterial blood pressure effects of desflurane, which are similar to those of isoflurane.     

The influence of isoflurane on the vascular reflex response to lung inflation in dogs.

Positive pressure ventilation can affect hemodynamic stability by neuroreflex-mediated activity. Inhalational anesthesia is known to attenuate the arterial baroreflex function; however, little information is known about the effect of volatile anesthetics on the lung inflation reflex. The influence of isoflurane on static lung inflation reflex-induced changes in venous capacitance and systemic resistance was investigated in dogs. After controlling carotid sinus pressure at 50 mmHg and initiating total cardiopulmonary bypass, the lungs were inflated to tracheal pressures of 10 and 20 mmHg. The systemic vascular resistance index (SVRI) decreased by 0.04 +/- 0.03 and 0.13 +/- 0.03 mmHg.kg.min.ml-1 during tracheal inflation pressures of 10 and 20 mmHg, respectively. There as an accompanying change in systemic vascular capacitance index (SVCI) by 1.0 +/- 0.65 and 3.3 +/- 0.82 ml.kg-1 during tracheal inflation pressures of 10 and 20 mmHg. The addition of isoflurane decreased the reflex vascular response to lung inflation in a dose-dependent manner. A concentration of 1 MAC isoflurane administered via the cardiopulmonary bypass machine attenuated the change in SVRI to tracheal inflation pressures of 10 and 20 mmHg by 75% and 67%, respectively. Isoflurane at 1 MAC also reduced the reflex capacitance response to tracheal pressures of 10 and 20 mmHg by 36% each. Lung inflation-induced changes in SVRI and SVCI were abolished at isoflurane concentrations of 2 MAC. We conclude that under the conditions of this study, 1 MAC isoflurane was shown to attenuate lung reflex-induced changes in SVRI and SVCI and that at higher isoflurane concentrations (2 MAC) these reflex-induced changes were not seen.     

Cerebrovascular reactivity to carbon dioxide is preserved during hypocapnia in children anesthetized with 1.0 MAC, but not with 1.5 MAC desflurane

PURPOSE: Maintenance of cerebrovascular reactivity to CO(2) (CCO(2)R) is important during neurosurgical anesthesia. This study was designed to determine the effect of different desflurane concentrations on CCO(2)R in children. METHODS: Children undergoing urological surgery were enrolled. Anesthesia was induced with sevoflurane in air/oxygen. After intubation, sevoflurane was switched to desflurane. Analgesia was provided with an epidural neuraxial block. Mechanical ventilation was adjusted to an initial EtCO(2) of 30 mmHg. Exogenous CO(2) was used to achieve an EtCO(2) of 40 and 50 mmHg. Patients were randomized to the sequence of desflurane concentration (1.0 and 1.5 MAC) and the EtCO(2). Transcranial Doppler was used to measure middle cerebral artery blood flow velocity (Vmca). Five minutes were allowed to reach steady state after each change in EtCO(2) and 15 min after changing the desflurane concentration. RESULTS: Sixteen patients were studied. The mean age and weight were 3.5 +/- 1.5 yr and 14.4 +/- 3.1 kg, respectively. Mean arterial pressure remained stable throughout the study, while at an EtCO(2) of 50 mmHg, heart rate decreased at both desflurane concentrations (P < 0.05). At 1.0 MAC, Vmca increased from 30 to 40 mmHg (P < 0.05), but not from 40 to 50 mmHg EtCO(2). At 1.5 MAC, Vmca increased between 30 and 50 mmHg (P < 0.05). CONCLUSION: CCO(2)R is preserved during hypocapnia in children anesthetized with 1.0 MAC, but not with 1.5 MAC desflurane. The lack of further increase in Vmca at higher EtCO(2) concentrations implies that desflurane may cause significant cerebral vasodilatation in children. This may have important implications in children with reduced intracranial compliance.     

Ventilatory Response to Hypoxia in Humans: Influences of Subanesthetic Desflurane

Background: At low dose, the halogenated anesthetic agents halothane, isoflurane, and enflurane depress the ventilatory response to isocapnic hypoxia in humans. In the current study, the influence of subanesthetic desflurane (0.1 minimum alveolar concentration [MAC]) on the isocapnic hypoxic ventilatory response was assessed in healthy volunteers during normocapnia and hypercapnia.

Methods: A single hypoxic ventilatory response was obtained at each of 4 target end-tidal partial pressure of oxygen concentrations: 75, 53, 44, and 38 mmHg, before and during 0.1 MAC desflurane administration. Fourteen subjects were tested at a normal end-tidal partial pressure of carbon dioxide (43 mmHg), with 9 subjects tested at an end-tidal carbon dioxide concentration of 49 mmHg (hypercapnia). The hypoxic sensitivity (S) was computed as the slope of the linear regression of inspired minute ventilation (VI) on (100 - SP O2). Values are mean +/-SE.

Results: Sensitivity was unaffected by desflurane during normocapnia (control: S = 0.45+/-0.071 *symbol* min *symbol* sup -1 *symbol* % sup -1 vs. 0.1 MAC desflurane: S = 0.43+/-0.09 1 *symbol* min sup -1 *symbol* % sup -1). With hypercapnia S decreased by 30% during desflurane inhalation (control: S = 0.74+/-0.091 *symbol* min sup -1 *symbol* %1 vs. 0.1 MAC desflurane: S = 0.53+/-0.06 1 *symbol* min sup -1 *symbol* % sup -1; P < 0.05).     

The response of the canine cerebral circulation to hyperventilation during anesthesia with desflurane

Arterial CO2 tension (PaCO2) is an important factor controlling cerebral blood flow (CBF) and cerebral vascular resistance (CVR) in animals and humans. The normal responsiveness of the cerebral vasculature to PaCO2 is approximately 2 ml.min-1.100 g-1.mmHg-1. This study examined the effect of desflurane, a new volatile anesthetic, on the responsiveness of the cerebral vasculature to changes in PaCO2. Mean arterial pressure (MAP), CBF, CVR, intracranial pressure (ICP), and cerebral metabolic rate for O2 (CMRO2) were measured in five dogs anesthetized with desflurane (0.5-1.5 MAC) at normocapnia (PaCO2 = 40 mmHg) and at two levels of hypocapnia (PaCO2 = approximately 30 and approximately 20 mmHg). Under desflurane anesthesia, similar changes in CBF and CVR occurred with hyperventilation at all MAC levels of desflurane. At 0.5 MAC, CBF decreased significantly, from 81 +/- 6 to 40 +/- 3 ml.min-1.100 g-1 (P less than 0.05, mean +/- SE) when PaCO2 was decreased from 40 to 24 mmHg; i.e., the CBF decreased approximately 2.6 ml.min-1.100 g-1.mmHg-1. At 1.0 MAC desflurane, CBF decreased significantly, from 79 +/- 10 to 43 +/- 5 ml.min-1.100 g-1 with hyperventilation (2.0 ml.min-1.100 g-1.mmHg-1); at 1.5 MAC desflurane, CBF decreased from 65 +/- 6 to 38 +/- 2 ml.min-1.100 g-1 with hyperventilation (1.6 ml.min-1.100 g-1.mmHg-1). Despite the significant decreases in CBF with hyperventilation, there was no significant change in ICP. Dose-dependent decreases in MAP were observed with increasing concentrations of desflurane but were not significantly affected by ventilation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hemodynamic Responses to Intravascular Injection of Epinephrine-containing Epidural Test Doses in Adults during General Anesthesia

Background: Epidural anesthesia is sometimes initiated during general anesthesia, yet few data exist concerning efficacy of epinephrine-containing test doses.

Methods: Thirty-six patients were randomized to receive either 0.5 MAC isoflurane, 1 MAC isoflurane, or 0.5 MAC each (1 MAC total) of isoflurane and nitrous oxide. Each subject received intravenous saline followed by three test doses containing 45 mg lidocaine with 7.5, 15, and 30 micro gram epinephrine in a randomized, double-blind fashion. Heart rate and systolic, diastolic, and mean blood pressures were measured for 5 min after injection. Positive hemodynamic criteria identifying intravascular injection were determined from peak increases in hemodynamics during administration of saline. Dose-effect relationships between epinephrine and peak increases in hemodynamics were assessed with linear regression. Minimum required doses of epinephrine to produce peak positive hemodynamic increases on average were determined from linear regression.

Results: Positive hemodynamic criteria were identified as increases in heart rate greater or equal to 8 beats/min, systolic blood pressure greater or equal to 13 mmHg, diastolic blood pressure greater or equal to 7 mmHg, and mean blood pressure greater or equal to 9 mmHg. Significant dose-effect relationships were observed for epinephrine and peak increases in hemodynamics (correlation coefficients ranged from 0.61-0.91). Minimum required doses of epinephrine ranged from 6 to 19 micro gram depending on hemodynamic measurement and anesthetic group.     

Desflurane-mediated Neurocirculatory Activation in Humans: Effects of Concentration and Rate of Change on Responses

Background: Rapid increases in the inspired concentration of desflurane have been associated with sympathetic activation, tachycardia, hypertension, and in select cases, myocardial ischemia. The current study examined the effects of the rate of change of the desflurane concentration on the sympathetic and hemodynamic responses to desflurane and sought to determine whether a finite concentration (end-tidal) of desflurane consistently initiated these responses.

Methods: After Institutional Review Board approval, 23 healthy male volunteers were instrumented for electrocardiogram (heart rate (HR)), intraarterial blood pressure, and peroneal nerve microneurography (sympathetic nerve activity (SNA)). Subjects were given propofol (2.5 mg/kg) and vecuronium (0.15 mg/kg), and their lungs were mechanically ventilated for 30 min at a minimum alveolar concentration of 0.5 MAC with either desflurane or isoflurane (random assignment). The end-tidal concentration was increased at either 1% per min (n = 7) or 0.5% per min (n = 7) for desflurane or 0.16% per min (n = 9) for isoflurane (MAC-multiple comparable to 1% per min desflurane group) until 1.5 MAC was reached. HR, blood pressure, and SNA were averaged over 1-min segments from 0.5 to 1.5 MAC levels.

Results: Awake neurocirculatory variables did not differ among the three groups. At 0.5 MAC, blood pressure had decreased (12-15%) and HR increased (12-20%) similarly in both groups. SNA decreased 77% in the isoflurane group but was not significantly changed in the desflurane groups. In the desflurane groups, the threshold (end-tidal concentration associated with a 10% increase in the measured variable) ranged between 4% and 10% for HR and between 4% and 7.7% for SNA. In the isoflurane group, the threshold occurred between 1.0% and 1.6% for HR and between 0.7% and 1.3% for SNA. The rate of change did not affect the threshold concentration or the peak HR increase in the desflurane groups. In contrast, SNA responses to desflurane were directly proportional to the rate of change.