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Clinical Science  |   May 1998
Comparison of the Effect of Etomidate and Desflurane on Brain Tissue Gases and pH during Prolonged Middle Cerebral Artery Occlusion 
Author Notes
  • (Hoffman) Associate Professor, Department of Anesthesiology.
  • (Charbel) Assistant Professor, Department of Neurosurgery.
  • (Edelman) Assistant Professor, Department of Anesthesiology.
  • (Misra) Resident, Department of Neurosurgery.
  • (Ausman) Professor and Chairman, Department of Neurosurgery.
Article Information
Clinical Science
Clinical Science   |   May 1998
Comparison of the Effect of Etomidate and Desflurane on Brain Tissue Gases and pH during Prolonged Middle Cerebral Artery Occlusion 
Anesthesiology 5 1998, Vol.88, 1188-1194. doi:
Anesthesiology 5 1998, Vol.88, 1188-1194. doi:
TEMPORARY brain artery occlusion may be required to facilitate cerebrovascular surgery and to decrease the risk of bleeding. This carries a risk of ischemic brain injury and infarction if occlusion times are prolonged. Treatment with etomidate before brain artery occlusion may allow an occlusion time of 14 min with a good recovery. [1] This is consistent with the hypothesis that anesthetic agents that suppress brain electrical activity decrease brain metabolic demand and attenuate ischemic injury. [2] Recent studies in rats suggest, however, that treatment with etomidate produces greater ischemic injury compared with thiopental or halothane. [3,4] Inhalation anesthetic agents, including isoflurane and desflurane, can suppress brain electrical activity, produce cerebrovasodilation, and enhance brain tissue oxygenation in animal and human studies. [5–9] This raises the possibility that an anesthetic agent such as desflurane may attenuate ischemic changes during prolonged periods of brain artery occlusion by decreasing metabolic demand and enhancing tissue perfusion. The purpose of this study was to compare the effects of etomidate and desflurane on brain tissue oxygen pressure (PO2), brain tissue carbon dioxide pressure (PCO2), and pH changes in patients with middle cerebral artery (MCA) occlusion longer than 15 min.
Methods
The clinical review board at our institution approved this study. Patients gave informed consent for brain tissue monitoring and randomization of anesthetic treatment. Before the start of surgery, patients were randomly selected to receive either etomidate or desflurane to produce suppression of electroencephalogram. Eleven patients were scheduled for an extracerebral artery to intracerebral artery bypass. Nine of these patients had a superficial temporal artery-to-MCA bypass, and two patients had a carotid artery-to-MCA bypass using a vein graft, which required temporary occlusion of the MCA (Table 1). Patient 2 in the etomidate group had a superficial temporal artery-to-MCA bypass when the internal carotid artery was removed during excision of a left sphenoid meningioma. One patient (desflurane patient 6) had a giant MCA aneurysm, which had bled 6 days before surgery. All other patients had a presurgical diagnosis of cerebral occlusive disease. This was determined by neurologic symptoms of regional ischemia and confirmed by single-photon emission computed tomography scans and cerebral angiography.
Table 1. Baseline Arterial Gases and pH, Clip Time, Hypoxia Time, Acidosis Time, and Outcome 
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Table 1. Baseline Arterial Gases and pH, Clip Time, Hypoxia Time, Acidosis Time, and Outcome 
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Patients fasted overnight, and blood glucose was measured intermittently throughout the case and maintained at < 200 mg/dl with insulin treatment if necessary. Anesthesia was induced with 3–5 mg/kg thiopental and 10–15 micro gram/kg fentanyl, and muscle paralysis was achieved with 100 micro gram/kg vecuronium for tracheal intubation. Patients in group I were ventilated with 0.5% isoflurane (n = 6) and in group 2 with 3% desflurane (n = 6) with a fraction of inspired carbon dioxide (FIO2) of 0.4 and the balance nitrogen. A radial artery catheter was inserted for direct measurement of arterial pressure using a Marquette monitor (Milwaukee, WI) and for arterial blood gas samples. Arterial PCO2was adjusted to 35–40 mmHg. End-tidal CO2and anesthetic gas concentration were monitored by a Datex Ultima (Helsinki, Finland). An esophageal temperature probe was inserted, and temperature was allowed to decrease to 34 [degree sign]C during the surgical procedure. Two-channel bifrontal electroencephalography was performed from electrodes placed on the forehead over both hemispheres with the nasion as the reference using an A-1000 Electroencephalography monitor (Aspect, Natick, MA). During a burst suppression electroencephalogram pattern, this monitor indicates the percentage of the electroencephalographic signal that is quiescent.
The patient was placed supine in a park bench position with the head in pins and turned. After a pterional craniotomy and dural reflection, a Paratrend 7 probe (Diametrics Medical, Minneapolis, MN), which measures PO2, PCO2, pH, and temperature, was inserted by the neurosurgeon. The probe was always placed in the same region in the midfrontal gyrus, close to the frontal operculum. The probe is 0.5 mm in diameter and must be inserted 4 cm for all of the sensors to be in brain tissue. [10] The brain surface surrounding the tissue was covered with sterile gauze to prevent light contamination of the sensors. The PO2, PCO2, and pH sensors were calibrated using precision gases before insertion into the tissue, and a 30-min equilibration period was allowed after insertion before recording baseline values. Tissue gases and pH are reported with body temperature corrected to 37 [degree sign] Celsius. Tissue hypoxia was defined as P (O)2< 10 mmHg and acidosis as pH < 7.0 during the time of MCA occlusion. A laser Doppler flow probe (Vasamedics, St. Paul, MN) was placed on the cortex surface adjacent to the Paratrend probe in three patients in the etomidate group and two patients in the desflurane group.
Before MCA occlusion, patients in group 1 (n = 6) received etomidate as 0.1–0.15 mg/kg intravenous bolus doses to induce and maintain burst suppression electroencephalogram. Electroencephalographic quiescence of 50% was maintained. Isoflurane was continued during the treatment with etomidate. In group 2, end-tidal desflurane concentration was increased to 9% to produce the same burst suppression pattern. [9] Arterial blood pressure was maintained at baseline levels or higher in both groups with intravenous phenylephrine infusion during the period of burst suppression electroencephalogram. In both groups, MCA occlusion was produced 10–20 min after the start of burst suppression electroencephalogram. Arterial blood gas was measured at the start of recording, and all other variables, including blood pressure, electroencephalogram, end-tidal gases, and Paratrend measurements were recorded by computer every 10 s using a Labview program (National Instruments, Austin, TX).
Each patient was evaluated 3–5 days after surgery to determine if a new ischemic injury occurred. An ischemic injury was determined if the patient showed a new neurologic deficit that was confirmed by an infarct on the postoperative computed tomographic scan.
Statistics tests of normality and equal variance were performed initially on each data set to determine whether parametric or nonparametric analyses should be performed. Comparisons of treatments within each group were made by repeated-measures analysis of variance with Tukey's post hoc tests or a repeated-measures analysis of variance on ranks with Dunnett's tests used for post hoc comparison if the data were not parametric. Statistical comparisons of changes in PO2, PCO2, and pH during MCA occlusion between etomidate and desflurane groups were made using t tests or a rank sum test. A Pearson product-moment correlation was used to evaluate the relation between temperature and the length of hypoxia or acidosis during MCA occlusion.
Results
There was no difference in blood pressure, arterial blood gas levels, and pH or brain temperature between the etomidate and desflurane treatment groups during baseline conditions (Table 1). A burst suppression electroencephalogram was seen in all patients during treatment with etomidate or desflurane for brain protection with 50% electrical silence.
An example of tissue changes in patient 4 in the etomidate group is shown in Figure 1. This patient showed a decrease in laser Doppler flow and PO2after treatment with etomidate alone. Middle cerebral artery occlusion further decreased flow and PO2and produced an increase in PCO2and a decrease in pH to 6.6 after 18 min of temporary clipping.
Figure 1. Brain tissue PO2, PCO2, pH, and blood flow during etomidate and middle cerebral artery occlusion in patient 4. Each tracing is identified in the graph. Laser Doppler flow and pH are shown with bold lines. At the time of treatment with etomidate, PO(2) and blood flow decreased without a change in pH or PCO2. Middle cerebral artery occlusion produced a further decrease in PO(2) and blood flow and an increase in PCO2and acidosis. This patient showed a severe neurologic deficit postoperatively.
Figure 1. Brain tissue PO2, PCO2, pH, and blood flow during etomidate and middle cerebral artery occlusion in patient 4. Each tracing is identified in the graph. Laser Doppler flow and pH are shown with bold lines. At the time of treatment with etomidate, PO(2) and blood flow decreased without a change in pH or PCO2. Middle cerebral artery occlusion produced a further decrease in PO(2) and blood flow and an increase in PCO2and acidosis. This patient showed a severe neurologic deficit postoperatively.
Figure 1. Brain tissue PO2, PCO2, pH, and blood flow during etomidate and middle cerebral artery occlusion in patient 4. Each tracing is identified in the graph. Laser Doppler flow and pH are shown with bold lines. At the time of treatment with etomidate, PO(2) and blood flow decreased without a change in pH or PCO2. Middle cerebral artery occlusion produced a further decrease in PO(2) and blood flow and an increase in PCO2and acidosis. This patient showed a severe neurologic deficit postoperatively.
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An example of patient 3 in the desflurane group is shown in Figure 2. Treatment with 9% desflurane produced an immediate increase in laser Doppler flow, PO2, and pH and a decrease in PCO(2). Middle cerebral artery occlusion decreased PO2to hypoxic levels but produced only modest, transient ischemic changes in P (CO)2and pH.
Figure 2. Brain tissue PO2, PCO2, pH, and blood flow during 9% desflurane and middle cerebral artery occlusion in patient 3. Desflurane increased blood flow, PO2, and pH and decreased tissue PCO2. Middle cerebral artery occlusion produced a decrease in tissue PO2without a change in pH or P (CO)2. This patient had a good recovery.
Figure 2. Brain tissue PO2, PCO2, pH, and blood flow during 9% desflurane and middle cerebral artery occlusion in patient 3. Desflurane increased blood flow, PO2, and pH and decreased tissue PCO2. Middle cerebral artery occlusion produced a decrease in tissue PO2without a change in pH or P (CO)2. This patient had a good recovery.
Figure 2. Brain tissue PO2, PCO2, pH, and blood flow during 9% desflurane and middle cerebral artery occlusion in patient 3. Desflurane increased blood flow, PO2, and pH and decreased tissue PCO2. Middle cerebral artery occlusion produced a decrease in tissue PO2without a change in pH or P (CO)2. This patient had a good recovery.
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Treatment with etomidate produced a decrease in tissue PO2in five of six patients but no change in tissue PCO2or pH (Figure 3). During MCA occlusion, four of six patients had tissue hypoxia (PO2< 10 mmHg) or acidosis (pH < 7.0) for 12–50 min. Tissue PCO2and pH data were not available for patient 1 in the etomidate group because of inadequate light shielding. All four etomidate-treated patients who had extended periods of tissue hypoxia and acidosis during MCA occlusion had new neurologic deficits after surgery.
Figure 3. Tissue PO2, pH, and PCO2in etomidate-treated patients. Data are shown during baseline conditions, during treatment with etomidate, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. PCO2and pH data for patient 1 were not available. The decrease in PO2and pH during middle cerebral artery occlusion was significant compared with baseline values (P < 0.05).
Figure 3. Tissue PO2, pH, and PCO2in etomidate-treated patients. Data are shown during baseline conditions, during treatment with etomidate, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. PCO2and pH data for patient 1 were not available. The decrease in PO2and pH during middle cerebral artery occlusion was significant compared with baseline values (P < 0.05).
Figure 3. Tissue PO2, pH, and PCO2in etomidate-treated patients. Data are shown during baseline conditions, during treatment with etomidate, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. PCO2and pH data for patient 1 were not available. The decrease in PO2and pH during middle cerebral artery occlusion was significant compared with baseline values (P < 0.05).
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Elevating the concentration of desflurane from 3% to 9% increased tissue PO2and pH and decreased PCO2(Figure 4). Middle cerebral artery occlusion produced tissue hypoxia in two patients but not acidosis. The decrease in pH during MCA occlusion in patients treated with etomidate (median =-0.32) was different from the small increase seen in desflurane-treated patients (median = 0.05, P < 0.05). Changes in PO2and PCO2were not different between the two groups. There was no relation between the brain temperature at the time of MCA occlusion and the length of hypoxia or acidosis with both groups considered together. No desflurane-treated patient showed a new neurologic deficit.
Figure 4. Tissue PO2, pH, and PCO2in desflurane-treated patients. Data are shown during baseline conditions, during treatment with desflurane, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. Desflurane treatment increased PO2and pH and decreased PCO2(P < 0.05). Middle cerebral artery occlusion produced no significant change in any parameter.
Figure 4. Tissue PO2, pH, and PCO2in desflurane-treated patients. Data are shown during baseline conditions, during treatment with desflurane, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. Desflurane treatment increased PO2and pH and decreased PCO2(P < 0.05). Middle cerebral artery occlusion produced no significant change in any parameter.
Figure 4. Tissue PO2, pH, and PCO2in desflurane-treated patients. Data are shown during baseline conditions, during treatment with desflurane, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. Desflurane treatment increased PO2and pH and decreased PCO2(P < 0.05). Middle cerebral artery occlusion produced no significant change in any parameter.
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Discussion
These results are consistent with a previous report that the use of etomidate in the setting of cerebral ischemia may lead to a decrease in tissue PO2. [11] Ischemic changes were seen here in PCO2and pH in etomidate-treated patients during MCA occlusion, and a new ischemic injury was seen in these patients. This agrees with the work of Samson et al., [1] who reported that even when etomidate is used, lengths of brain artery occlusion > 14 min produced a high incidence of ischemic injury and a 100% infarction rate with durations of occlusion > 30 min. In contrast to etomidate, 9% desflurane increased PO2and pH in this study, and MCA occlusion produced hypoxia but no acidosis. Because both etomidate and desflurane may have decreased brain electrical activity and metabolic demand, we believe the contrast between changes in tissue gases and pH with each agent may be due to differences in tissue perfusion.
It has been reported that etomidate suppresses electroencephalographic activity, decreases cerebral oxygen demand, and attenuates neuronal injury during ischemia. [12–17] Other reports, however, have questioned the ability of etomidate to protect the brain from ischemia, particularly when high doses are used that produce electroencephalographic quiescence but also can produce hemolysis. [3,4,18–20] Drummond et al. [4] speculated that etomidate may increase ischemia by decreasing release of nitric oxide and attenuating collateral blood flow. Etomidate may produce this effect by inhibition of nitric oxide synthesis or by nitric oxide binding by free hemoglobin. This was supported by a more recent study in rats showing that treatments that enhance nitric oxide attenuate ischemic injury associated with etomidate. [3] Milde et al. [12] reported that sagittal sinus oxygen saturation decreases with etomidate treatment because of decreases in cerebral blood flow. Although our results and those of others indicate that the cerebrovasoconstrictor effects of etomidate do not produce ischemic changes alone, [21,22] tissue oxygenation may be decreased. [11,12] 
In contrast to etomidate, desflurane increases cerebral blood flow when blood pressure is supported. [5] This, combined with a decrease in electroencephalographic activity and oxygen demand, may improve tissue oxygenation. [7] No one has examined the ischemic protection with desflurane in animals, however. Our results support the conclusion that desflurane enhances tissue perfusion and improves tissue metabolic status in regions at risk for ischemia. The attenuation of ischemic acidosis during MCA occlusion may be due to enhanced collateral circulation mediated by leptomeningeal vascular communications. CO2clearance may attenuate acidosis even when oxygenation is decreased because diffusion of CO2in tissue proceeds more readily than it does with oxygen. [23] It should also be noted, however, that there are potential disadvantages of using desflurane during cerebral ischemia, including impaired auto-regulation and a possible decrease in cerebral blood flow if blood pressure is not maintained, [24,25] an increase in production of cerebrospinal fluid, and an increase in cerebrospinal fluid pressure. [26,27] 
There are several weaknesses in this study. First, the etomidate-treated group received 0.5% isoflurane for baseline anesthesia, whereas the desflurane group received 3% desflurane. The baseline levels of PO2, PCO2, and pH were similar between the two groups, however. Only 12 patients were evaluated in this study: this presents a problem with statistical evaluation of the inconsistent effect of etomidate on tissue PO2. Because we only selected patients for this study who underwent MCA occlusion for > 15 min, however, the current study required 2 yr to complete. In a previous study, we observed that treatment with etomidate decreased tissue PO2, but this effect was also inconsistent. [11] Based on our findings here that patients with adequate collateral arteries are less likely to develop hypoxia with etomidate, we suggest that the variable effects of etomidate on PO2are related to the adequacy of collateral circulation.
It is possible that increases in tissue PO2may be due to changes in the concentration of desflurane rather than tissue P (O)2. We do not know if desflurane can change the current, and therefore the PO2measurement, by a direct action at the Clark electrode. Other measures of tissue metabolic status, including decreases in PCO2and increases in pH during desflurane, would be consistent with an increase in oxygenation. In addition, we have observed similar increases in tissue PO2with treatment with desflurane with a fiberoptic measure of tissue PO2rather than a Clark electrode (our unpublished results). This suggests that the elevation in PO2seen with increases in desflurane is due to enhanced oxygenation.
It should be noted that the PO2, PCO2, and pH sensors of the Paratrend probe are separated by 1 to 2 cm within the tissue. [10] The spatial disparity in sensor position suggests that ischemia may be observed in one region but not in another. This may explain the onset of tissue hypoxia but no increase in PCO2or acidosis seen in desflurane-treated patients. This is not likely, however, because CO2easily diffuses throughout brain tissue. [23] We also found that etomidate alone could decrease tissue PO2to low levels without ischemic changes in PCO2or pH. This suggests that a decrease in PO2without a change in pH can occur readily in brain tissue. This may be due to a moderate decrease in cerebral blood flow, which limits oxygen availability but not CO2clearance.
These results show that etomidate decreases tissue PO(2) before MCA occlusion. Middle cerebral artery occlusion longer than 15 min produced tissue hypoxia, hypercapnia, and acidosis in four of six etomidate-treated patients. Desflurane used for brain protection increases tissue PO2and inhibits acidosis during MCA occlusion. Because both etomidate and desflurane produced similar levels of electroencephalographic suppression, it is likely that the possible differences in tissue metabolic status during MCA occlusion are due to the effect of each agent on collateral perfusion.
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Figure 1. Brain tissue PO2, PCO2, pH, and blood flow during etomidate and middle cerebral artery occlusion in patient 4. Each tracing is identified in the graph. Laser Doppler flow and pH are shown with bold lines. At the time of treatment with etomidate, PO(2) and blood flow decreased without a change in pH or PCO2. Middle cerebral artery occlusion produced a further decrease in PO(2) and blood flow and an increase in PCO2and acidosis. This patient showed a severe neurologic deficit postoperatively.
Figure 1. Brain tissue PO2, PCO2, pH, and blood flow during etomidate and middle cerebral artery occlusion in patient 4. Each tracing is identified in the graph. Laser Doppler flow and pH are shown with bold lines. At the time of treatment with etomidate, PO(2) and blood flow decreased without a change in pH or PCO2. Middle cerebral artery occlusion produced a further decrease in PO(2) and blood flow and an increase in PCO2and acidosis. This patient showed a severe neurologic deficit postoperatively.
Figure 1. Brain tissue PO2, PCO2, pH, and blood flow during etomidate and middle cerebral artery occlusion in patient 4. Each tracing is identified in the graph. Laser Doppler flow and pH are shown with bold lines. At the time of treatment with etomidate, PO(2) and blood flow decreased without a change in pH or PCO2. Middle cerebral artery occlusion produced a further decrease in PO(2) and blood flow and an increase in PCO2and acidosis. This patient showed a severe neurologic deficit postoperatively.
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Figure 2. Brain tissue PO2, PCO2, pH, and blood flow during 9% desflurane and middle cerebral artery occlusion in patient 3. Desflurane increased blood flow, PO2, and pH and decreased tissue PCO2. Middle cerebral artery occlusion produced a decrease in tissue PO2without a change in pH or P (CO)2. This patient had a good recovery.
Figure 2. Brain tissue PO2, PCO2, pH, and blood flow during 9% desflurane and middle cerebral artery occlusion in patient 3. Desflurane increased blood flow, PO2, and pH and decreased tissue PCO2. Middle cerebral artery occlusion produced a decrease in tissue PO2without a change in pH or P (CO)2. This patient had a good recovery.
Figure 2. Brain tissue PO2, PCO2, pH, and blood flow during 9% desflurane and middle cerebral artery occlusion in patient 3. Desflurane increased blood flow, PO2, and pH and decreased tissue PCO2. Middle cerebral artery occlusion produced a decrease in tissue PO2without a change in pH or P (CO)2. This patient had a good recovery.
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Figure 3. Tissue PO2, pH, and PCO2in etomidate-treated patients. Data are shown during baseline conditions, during treatment with etomidate, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. PCO2and pH data for patient 1 were not available. The decrease in PO2and pH during middle cerebral artery occlusion was significant compared with baseline values (P < 0.05).
Figure 3. Tissue PO2, pH, and PCO2in etomidate-treated patients. Data are shown during baseline conditions, during treatment with etomidate, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. PCO2and pH data for patient 1 were not available. The decrease in PO2and pH during middle cerebral artery occlusion was significant compared with baseline values (P < 0.05).
Figure 3. Tissue PO2, pH, and PCO2in etomidate-treated patients. Data are shown during baseline conditions, during treatment with etomidate, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. PCO2and pH data for patient 1 were not available. The decrease in PO2and pH during middle cerebral artery occlusion was significant compared with baseline values (P < 0.05).
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Figure 4. Tissue PO2, pH, and PCO2in desflurane-treated patients. Data are shown during baseline conditions, during treatment with desflurane, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. Desflurane treatment increased PO2and pH and decreased PCO2(P < 0.05). Middle cerebral artery occlusion produced no significant change in any parameter.
Figure 4. Tissue PO2, pH, and PCO2in desflurane-treated patients. Data are shown during baseline conditions, during treatment with desflurane, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. Desflurane treatment increased PO2and pH and decreased PCO2(P < 0.05). Middle cerebral artery occlusion produced no significant change in any parameter.
Figure 4. Tissue PO2, pH, and PCO2in desflurane-treated patients. Data are shown during baseline conditions, during treatment with desflurane, and for peak or minimum changes after middle cerebral artery occlusion, with lines connecting individual patients. Desflurane treatment increased PO2and pH and decreased PCO2(P < 0.05). Middle cerebral artery occlusion produced no significant change in any parameter.
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Table 1. Baseline Arterial Gases and pH, Clip Time, Hypoxia Time, Acidosis Time, and Outcome 
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Table 1. Baseline Arterial Gases and pH, Clip Time, Hypoxia Time, Acidosis Time, and Outcome 
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