1 INSERM 438 Unit and 2 Department of Anaesthesia, The University of Grenoble School of Medicine, Grenoble, France*Corresponding author: INSERM U438, Pavillon B, Hôpital Albert Michallon, BP 217, F-38043 Grenoble, France
Accepted for publication: April 9, 2002
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Abstract |
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Methods. Six anaesthetized rats were subjected to incremental reduction in the fraction of inspired oxygen: 0.35, 0.25, 0.15, and 0.12. At each episode, CBV was determined in five regions of each hemisphere after injection of a contrast agent: superficial and deep neocortex, striatum, corpus callosum and cerebellum. A control group (n=6 rats) was studied with the same protocol without contrast agent, to determine blood oxygenation level dependent (BOLD) contribution to the MRI changes.
Results. Each brain region exhibited a significant graded increase in CBV during the two hypoxic episodes: 1027% of control values at 70% SaO2, and 2638% at 55% SaO2. There was no difference between regions in their response to hypoxia. The mean CBV of all regions increased from 3.6 (SD 0.6) to 4.1 (0.6) ml (100 g)1 and to 4.7 (0.7) ml (100 g)1 during the two hypoxic episodes, respectively (Scheffé F-test; P<0.01). Over this range, CBV was inversely proportional to SaO2 (r2=0.80). In the absence of the contrast agent, changes due to the BOLD effect were negligible.
Conclusions. These findings imply that hypoxic hypoxia significantly raises CBV in different brain areas, in proportion to the severity of the insult. These results support the notion that the vasodilatory effect of hypoxia is deleterious in patients with reduced intracranial compliance.
Br J Anaesth 2002; 89: 28793
Keywords: blood, volume, cerebral; brain, magnetic resonance imaging; complications, hypoxia
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Introduction |
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Materials and methods |
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where is the gyromagnetic ratio, and B0 is the magnetic field in the absence of sample.
It has been shown that deoxygenated haemoglobin acts as a natural intravascular contrast agent, which is the basis for the BOLD image contrast.12 This may interfere with the accuracy of CBV measurements during hypoxia.13 Therefore, a second group of rats (Group 2, n=6 rats) was studied during the same protocol without the contrast agent, to delineate the influence of the BOLD effect on the images obtained with contrast agent.
Animal preparation
Preparation of animals was similar in the two groups and conformed to the guidelines of the French Government (decree No 87-848 of October 19, 1987, licenses 006683 and A38071). Anaesthesia was induced with 4% halothane and then maintained with an intraperitoneal injection of thiopental (40 mg kg1). One percent lidocaine was injected subcutaneously for local anaesthesia at all surgical sites. After tracheostomy, rat lungs were mechanically ventilated with 65% nitrous oxide, 35% oxygen using a rodent ventilator (Model 683, Harvard Apparatus Inc., South Natick, MA, USA). Ventilation was adjusted to maintain PaCO2 at 35 mm Hg. FIO2 was continuously monitored (MiniOX I analyzer, Catalyst Research Corporation, Owings Mills, MD, USA). A 0.7 mm indwelling catheter was inserted into the left femoral artery to monitor mean arterial blood pressure (MABP) via a chart recorder (8000S, Gould Electronic, Ballainvilliers, France). Blood gases (PaO2 and PaCO2), arterial saturation of haemoglobin in oxygen (SaO2), arterial pH and haemoglobin content (Hb) were analysed in arterial blood samples of less than 0.1 ml (ABL 510, Radiometer, Copenhagen, Denmark). Another 0.7 mm indwelling catheter was inserted into the left femoral vein to continuously infuse normal saline containing epinephrine (1.5 µg ml1) and sodium bicarbonate (0.025 mmol ml1) at a rate of 2 ml h1 throughout the study. Epinephrine was required to prevent the adverse effects of combined anaesthesia and hypoxic hypoxia on the cardiovascular system. Sodium bicarbonate was used to prevent arterial acidosis. Cannulation of the femoral vein was also required for the injection of the contrast agent (Group 1). Rectal temperature was maintained at 37.5 (0.5)°C by using a heating pad placed under the abdomen. Blood gases and arterial pH were corrected for rectal temperature.
Experimental protocol
Animals were subjected to a stepwise lowering of FIO2: 0.35, 0.25, 0.15 and 0.12. The basic cycle was started after more than 30 min of equilibration at FIO2 of 0.35 (control). The initial criteria for exclusion from the study were: MABP <100 mm Hg, arterial pH <7.30, PaO2 <100 mm Hg, arterial haemoglobin content <10 g dl1. Subsequent episodes were then first induced by lowering the inhaled oxygen for FIO2=0.25, then by replacing the oxygen by air (FIO2 of 0.15 and 0.12). During these four episodes, fractions of inspired nitrous oxide were 0.65, 0.75, 0.25 and 0.40, respectively. Each episode lasted 10 min: a 5 min equilibrium period followed by NMR acquisition and determination of MABP and arterial blood sampling. Preliminary studies showed that PaO2 reached a steady value within 5 min. When the cycle of measurements ended the rat was killed by administration of an overdose of thiopental (50 mg kg1).
MRI measurement
MRI was performed with a SMIS console (SMIS Ltd, Guildford, UK) equipped with a 2.35 T, 40 cm diameter horizontal bore magnet (Bruker Spectrospin, Wissembourg, France) and a 20 cm diameter actively shielded gradient coil (Magnex Scientific Ltd., Yarnton, Oxford, UK). The rat was prone, its head secured via ear bars, and a 30 mm diameter surface coil was located directly above the brain. After radiofrequency coil matching and tuning, the magnetic field homogeneity was adjusted to obtain a linewidth for water less than 0.5 parts per million (ppm) in the brain. Six adjacent horizontal slices (from 2 mm below bregma) were chosen from a T1 transverse scout image. A series of images for each slice at different echo times was acquired using a multi gradient-echo sequence with an interecho interval of 4.2 ms (repetition time TR=2 s; first echo time TE=7.6 ms; number of slices=6; field of view=35x35 mm; slice thickness=1 mm; 64x32 image matrix; number of averages=2). Acquisition of all images of the six slices took about 3 min.
In Group 1 (measurement of CBV), superparamagnetic iron oxide particles (200 µmol iron kg1 body mass of AMI 227, Sinerem®; Guerbet, Aulnay-sous-Bois, France) were injected intravenously 30 min after the start of the experiment (FIO2 of 0.35). Images were acquired before (n=24 echoes, pre-contrast image) and 3 min after injection (n=12 echoes, post-contrast image). Acquisition of post-contrast images was then repeated at the end of each subsequent PaO2 episode (FIO2 of 0.25, 0.15 and 0.12).
Data analysis
Image processing and determination of regional CBV were performed using an Ultrasparc workstation (Sun Micro systems, Pasadena, CA, USA). In Group 1, for each PaO2 episode, T*2 images were calculated by a least squares monoexponential fit of the signal intensity vs the echo time on a pixel by pixel basis. Differences in relaxation rates in each pixel were then calculated according to the formula:
with T*2 pre and T*2 post being the decay time constants before and after administration of the contrast agent (Group 1), respectively. The R*2 values were obtained from the T*2 post-contrast values during the four successive episodes. Five regions of interest (ROI) were defined in the two hemispheres: superficial and deep neocortex, corpus callosum, striatum and cerebellum. Selection of regions was made on slice 1 for superficial neocortex, on slice 2 for deep neocortex, on slice 3 for corpus callosum, and on slice 5 for striatum and cerebellum, by comparing the images to an anatomical atlas.14 Large
R*2 values (>200 s1) assigned to large vessels were discarded. A correction for clearance of the contrast agent from the plasma (elimination half-time
4.5 h) was applied since the post-contrast experiments lasted
60 min. This correction is described elsewhere.15
In Group 2, R*2 BOLD was calculated using equation (2), where T*2 pre and T*2 post are the decay time constants during control and subsequent episodes, respectively. Assuming a similar BOLD effect within the selected brain regions for each episode, a mean value of T*2 post was then determined from T*2 values obtained in the five brain regions.
R*2 BOLD has been used to correct the
R*2 values measured in Group 1 for the changes in deoxygenated haemoglobin concentration during hypoxia:16
Regional CBV, expressed as the percentage of blood volume in each voxel, or ml (100 g)1 tissue, was then determined according to equation (1). For an injection of AMI-227 of 200 µmol of iron kg1 of body mass, =0.571 ppm at 2.35T in large vessels.17 We assumed that the average haematocrit in the brain microcirculation was 0.83 of that in large vessels,4 5 resulting in a
value of 0.688. Finally, we assumed that the brain haematocrit remains constant during hypoxic hypoxia, as previously shown in most brain areas.6
Statistical analysis
Data were expressed as mean (SD). Analysis for statistical significance of changes during the successive episodes was performed using one-way analysis of variance (ANOVA) for repeated measurements (StatView SE program, SAS Institute Inc., Cary, NC, USA). Each value at a given episode was compared to that obtained at another episode using the Scheffé F-test post-hoc test. To look for a regional difference in the responsiveness to hypoxia, interaction between brain regions and episodes was assessed using a two-way ANOVA (brain regionxepisode) for repeated measurements. Differences between the two hemispheres was tested using a non-parametric Wilcoxon signed rank test. If no significant difference was found between the two hemispheres, pooled data were subjected to the analysis. A stepwise regression analysis was used to estimate the respective influence of SaO2 and of other factors (MABP, PaCO2) on the CBV changes for each episode. Statistical significance was set at P<0.05.
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Results |
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To quantify the error due to the BOLD effect in these changes, R*2 BOLD values were measured in Group 2 (no contrast agent). In this group,
R*2 BOLD values were +0.48 (2.04), +1.02 (2.37), and +2.36 (2.66) s1, at FIO2 of 0.25, 0.15 and 0.12, respectively. These values corresponded respectively to 0.7%, 1.3% and 2.8% of those observed in Group 1. The increase in R*2 BOLD was significant at FIO2 of 0.12 only (P<0.05).
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Discussion |
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Methodological critique
The use of exogenous contrast agent allowed us to monitor regional CBV changes during graded hypoxic hypoxia. Such techniques have been successfully used to investigate cerebrovascular changes in the brain during challenges such as hypercapnia, ischaemia or functional stimulation.15 18 19 Equation (1), used to determine absolute CBV, is based on a highly simplified model of the brain vessel architecture.10 Despite this approximation, control values of regional CBV (2.84.3 ml (100 g)1) obtained are in reasonable agreement with other studies in rats using different techniques5 9 or bolus tracking MRI.20
Deoxygenated haemoglobin, acting as an endogenous paramagnetic contrast agent, contributes to the difference in magnetic susceptibility between blood vessels and surrounding tissue.12 During hypoxic hypoxia, the increase in deoxygenated haemoglobin affects in a linear manner the changes in R*2 with respect to the control state.13 21 We found a 23 s1 increase in R*2 when SaO2 fell to 55%, in close agreement with those studies. Because of the large doses of contrast agent used in the present study,
R*2 changes due to those in deoxyhaemoglobin concentration accounted for less than 5% of the CBV changes.
Despite epinephrine, the greatest level of hypoxic hypoxia used in this study (FIO2 of 0.12) was associated with hypocapnia and a decrease in MABP, which might have interfered with CBV changes. For example, using a similar MRI procedure, we found that marked hypocapnia (PaCO2 25 mm Hg) resulted in a decrease in regional CBV of 1217% in normoxic rats.22 However, the present change in PaCO2 was of smaller magnitude. In a recent study using MRI contrast imaging, an increase of only 10% in regional CBV was reported during progressive haemorrhagic hypotension in rats (MABP between 40 and 10 mm Hg).23 The lack of a significant influence of MABP and PaCO2 on the CBV (see stepwise regression analysis) indicates that both parameters probably have only minor effects on the present CBV changes.
Another potential confounding factor in the CBV changes was the associated change in inspired concentration of nitrous oxide (FIN2O) during the successive episodes. Since nitrous oxide is a potent cerebrovasodilator,24 any change in its concentration might have interfered with our results. However, significant increase in CBV was found during the two hypoxic episodes in which the fraction of inspired nitrous oxide was lowered (FIN2O of 0.25 and 0.40). Consequently, it is possible that the CBV changes would have been larger if the nitrous oxide fraction had been maintained constant.
CBV response to hypoxic hypoxia
The present study shows that CBV is significantly increased by 15% at SaO2 70% (PaO2 55 mm Hg) and this rise reaches
30% at SaO2 55% (PaO2 40 mm Hg). These findings are in accordance with other studies which reported a gradual change in CBF during graded hypoxic hypoxia.1 2 A gradual change in cerebral haemodynamics is seen as the oxygen content is lowered; this tends to maintain a constant oxygen supply to brain.25
We found that a stepwise reduction of the FIO2 raised regional CBV by 2638% in all brain areas at SaO2 of 55%. It is recognized that the CBV values in normoxia differ among brain regions.4 In the present study, similar regional CBV responses to hypoxia were found in all regions, in agreement with studies measuring the CBF response to hypoxia.26 This suggests that the hypoxic stimulus may affect the various brain regions in a comparable manner regardless of their baseline blood flow or blood volume. Recently, DArceuil and co-workers8 reported a 4050% increase in cortical CBV at SaO2 of 40% in neonatal rabbits. In addition, under moderate hypoxia and hypercapnia, a 50% increase in CBV was found in the cortex of newborn piglets.27 In moderately hypoxic rats, a 30% increase in cortical CBV was reported by Shockley and LaManna.9 Although these results were obtained with various techniques (MRI, autoradiography, or optical methods), they are in agreement with our measurements of the changes in CBV found in both superficial and deep neocortical regions at comparable levels of hypoxia.
However, other studies have reported smaller CBV changes during hypoxia. Bereczki and co-workers6 found that moderate hypoxia (PaO2 40 mm Hg) increased microvascular volume by <20% in most areas of rat brain. However, in that study results were obtained in parenchymal microvessels with diameter <50 µm, still having small baseline regional CBV values (0.42.2 ml (100 g)1). CBV measured with the gradient-echo pulse sequence, used here, is less sensitive to vessel size, and reflects total CBV after the injection of a large dose of contrast agent.11 19 Considering that large vessels, with estimated diameter >200 µm, were excluded (see Materials and methods), the present changes in CBV should include pial arterioles, parenchymal arterioles, and venules. Therefore, if most of the CBV changes during hypoxia do indeed occur in these vessels, it is not surprising that methods detecting microvascular changes are associated with smaller changes.
In contrast, it has been reported that hypoxic hypoxia (SaO2 7075%) increased CBV by only 58% in human studies,7 28 instead of the 15% we found in rats. These differences may result from differences in the status (awake vs anaesthetized), species, or methods used for measuring CBV. There is no evidence that cerebrovascular responses to hypoxia should have been increased by the use of thiopental in rats. The well-known depressive effect of thiopental on brain metabolism would reduce baseline CBV, but the per cent response to hypoxia is not different from awake animals.29 Similarly, there is no reason to suspect a greater sensitivity to hypoxia in rats in comparison with humans. Therefore, differences between methods in their ability to detect CBV changes might be possible. For example, Fortune and co-workers7 used single-photon emission computed tomography (SPECT) with 99m-Tc-labelled erythrocytes. In addition to its limited spatial resolution (4 cm in that study), the unavoidable problem with SPECT is extracranial contamination by labelled cells, possibly resulting in a large attenuation of CBV changes during respiratory challenges. The study by Hampson and colleagues28 used near-infrared spectroscopy (NIRS), whose reliability for determining CBV changes during hypoxia has not been established. It is thus possible that the changes in human CBV in response to hypoxia may have been underestimated.
Clinical implications
Identifying a relationship between the severity of a hypoxic insult and the range of CBV changes is of particular clinical relevance in patients with compromised intracranial compliance (i.e. head-injured patients). Any vasodilatory stimulus, for example hypoxic hypoxia, can aggravate intracranial hypertension and reduce cerebral perfusion pressure in such patients.30 In addition, the most severe degree of hypoxia led to the largest increase in CBV, showing no limit in cerebrovascular capacity for vasodilation within this range of hypoxia. If these experimental data are applicable in humans, our results indicate that a fall of SaO2 to 70% progressively increases the CBV by 15%. This is considerably more than the 7% blood volume change required to raise ICP to the threshold of 20 mm Hg in head-injured patients.31 Our results therefore underline the deleterious consequences of transient episodes of hypoxic hypoxia on cerebral haemodynamics in such patients.
In summary, the present study shows that graded hypoxic hypoxia results in significant increase in CBV in proportion to the severity of the insult. CBV changes were not significantly different between the various brain regions investigated. We conclude that hypoxic hypoxia can significantly contribute to increased intracranial pressure in subjects with reduced intracranial compliance.
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Acknowledgements |
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References |
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