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NEUROHUMORAL CONTROL OF CARDIOVASCULAR FUNCTION

Contribution of adenosine A_2A and A_2B receptors and heme oxygenase to AMPA-induced dilation of pial arterioles in rats

Department of Anesthesiology and Critical Care Medicine, Johns Hopkins University, Baltimore, Maryland

Submitted 26 October 2005 ; accepted in final form 23 March 2006

	ABSTRACT

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Nitric oxide (NO) has been implicated in mediation of cerebral vasodilation during neuronal activation and, specifically, in pharmacological activation of N-methyl-D-aspartate (NMDA) and kainate receptors. Possible mediators of cerebral vasodilation to -amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) have not been well studied in mature brain, although heme oxygenase (HO) activity has been implicated in newborn pigs. In anesthetized rats, 5 min of topical superfusion of 30 and 100 µM AMPA on the cortical surface through a closed cranial window resulted in increases in pial arteriolar diameter. The dilatory response to AMPA was not inhibited by superfusion of an NO synthase inhibitor, a cyclooxygenase-2 inhibitor, or a cytochrome P-450 epoxygenase inhibitor, all of which have been shown to inhibit the cortical blood flow response to sensory activation. However, the 48 ± 13% dilation to 100 µM AMPA was attenuated 56–71% by superfusion of the adenosine A_2A receptor antagonist ZM-241385, the A_2B receptor antagonist alloxazine, and the HO inhibitor chromium mesoporphyrin. Combination of the latter three inhibitors did not attenuate the dilator response more than the individual inhibitors, whereas an AMPA receptor antagonist fully blocked the vasodilation to AMPA. These results indicate that cortical pial arteriolar dilation to AMPA does not require activation of NO synthase, cyclooxygenase-2, or cytochrome P-450 epoxygenase but does depend on activation of adenosine A_2A and A_2B receptors. In addition, CO derived from HO appears to play a role in the vascular response to AMPA receptor activation in mature brain by a mechanism that is not additive with that of adenosine receptor activation.

carbon monoxide; cerebral circulation; cyclooxygenase; epoxygenase; neurovascular coupling; nitric oxide

Application of AMPA to the cortical surface increases local O₂ consumption (47), but mediators of the vascular response to AMPA have not been well studied. Pial arterioles have been shown to dilate in response to topical application of NMDA and kainate, and this dilation is attenuated by inhibition of nitric oxide (NO) synthase (14–16, 27). However, the effect of NO synthase inhibition on pial arteriolar dilation to AMPA has not been reported in adult cerebral cortex, although CO generated from heme oxygenase (HO) has been implicated in the pial arteriolar response to AMPA in newborn pigs (45). In adult brain, HO may play a role in cerebral vasodilation to kainate-induced seizures (29).

In the present study, the response of pial arterioles to topical application of AMPA was investigated in vivo in mature rats. The potential role of NO synthase was determined by use of the inhibitor N-nitro-L-arginine (L-NNA), and the role of HO was determined by the use of the inhibitor chromium mesoporphyrin (CrMP). Other mediators were also evaluated. Because pial arteriolar dilation to glutamate and to sciatic nerve stimulation was reported to be attenuated by the adenosine A_2A receptor antagonist 4-(2-[7-amino-2-(2-furyl)[1,2,4]triazolo[2,3-a][1,3,5]triazin-5-ylamino]ethyl)phenol (ZM-241385) (21, 28), the contribution of adenosine A_2A receptors was assessed. In addition to the high-affinity A_2A receptors, low-affinity A_2B receptors can also contribute to pial arteriolar dilation to adenosine (31, 46). The A_2B receptor antagonist alloxazine was used to discern the potential role of adenosine A_2B receptors. Furthermore, cyclooxygenase-2 (COX-2) and cytochrome P-450 epoxygenase metabolites of arachidonic acid have been implicated in the cortical blood flow response to somatosensory activation (33, 40, 41). Moreover, the epoxygenase inhibitor N-methylsulfonyl-6-(2-propargyloxyphenyl)hexanamide (MS-PPOH) blocks the local blood flow response to intrastriatal microdialysis perfusion of NMDA (6). Therefore, the effects of MS-PPOH and the COX-2 inhibitor N-[2-(cyclohexyloxy)-4-nitrophenyl]-methanesulfonamide (NS-398) on the pial arteriolar response to AMPA were also tested.

	MATERIALS AND METHODS

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Surgical procedures. All procedures were approved by the Johns Hopkins University Animal Care and Use Committee. Anesthesia was induced in male Wistar rats (300 g) with 4% halothane in O₂-enriched air and maintained with 1.5–2% halothane during surgery and 1.5% halothane during the experimental protocol. The lungs were mechanically ventilated through a tracheostomy. The inspired gas contained 30–40% O₂. A catheter was inserted through a tail artery for arterial blood pressure monitoring and blood sampling for analysis of pH, PCO₂, and PO₂.

Pial arteriolar diameter was measured through a closed cranial window by intravital microscopy (4, 18). With the rat in the prone position in a head holder, the skull was exposed, the periosteum was removed, and a 3- to 4-mm-wide craniotomy was made over the left parietal cortex. A plastic ring was secured with dental acrylic to the skull surrounding the craniotomy. The exposed dura mater was kept moist with artificial cerebrospinal fluid (aCSF) containing (in mM): 151 Na⁺, 3 K⁺, 1.3 Ca²⁺, 0.6 Mg²⁺, 134 Cl^–, 24.6 HCO₃^–, 6 urea, and 3.7 glucose. The dura was incised, gently retracted, and cut to expose the pial surface. The window was filled with warmed aCSF, and a glass coverslip was cemented to the plastic ring. The plastic ring had an inflow and outflow port, a port for monitoring pressure, and a thermistor for monitoring fluid temperature.

Experimental protocol. After 45 min from completion of surgery, the window was flushed over a 5-min period with aCSF, and baseline measurements were obtained. In different groups of rats, the window was then superfused with 1 mM L-NNA (n = 7), 100 µM NS-398 (n = 8), or 20 µM MS-PPOH (n = 6). A control group was superfused with 0.1% ethanol vehicle (n = 8). In a second experiment, the window was superfused with 15 µM CrMP (n = 7), 1 µM ZM-241385 (n = 7), 1 µM alloxazine (n = 7), CrMP + ZM-241385 + alloxazine (n = 7), or the AMPA receptor antagonist 2,3-dihydroxy-6-nitro-7-sulfamoylbenzo(f)quinoxaline(NBQX, n = 5). A control group was superfused with 0.01% DMSO vehicle (n = 7).

L-NNA at 1 mM has been shown to inhibit cortical NO synthase activity and the blood flow response to sensory stimulation within 1 h of administration (22, 41). Therefore, all inhibitors/antagonists were superfused for 1 h before testing of vascular reactivity to ensure sufficient time for penetration into underlying cerebral cortex and a consistent exposure time for all inhibitors/antagonists. The rate of superfusion was 0.1 ml/min for the first 20 min and 0.05 ml/min for the last 40 min of superfusion before testing of the agonist. The height of the outflow catheter tip was adjusted to maintain pressure in the window at 5 mmHg during superfusion. NS-398 at 100 µM has been shown to effectively inhibit the cortical blood flow response to whisker stimulation, but not to hypercapnia, acetylcholine, or bradykinin (33). The inhibition constant for epoxygenase activity in vitro by MS-PPOH is 13 µM (51). MS-PPOH at 20 µM has been shown to inhibit the blood flow response to neural activation and to NMDA administration without inhibition of NO synthase activity (6, 40, 41). CrMP at 15 µM has been shown to inhibit HO activity and to have little effect on NO synthase or guanylyl cyclase activity (3, 25). Because CrMP is sensitive to light, care was taken to keep the CrMP infusion syringe and catheter wrapped in opaque material and to add carbon black to the acrylic cement of the window. ZM-241385 at 1 µM has been shown to inhibit pial arteriolar dilation to topical adenosine, to a selective A_2A receptor agonist, and to glutamate in vivo (31, 46). Alloxazine at 1 µM has been shown to inhibit pial arteriolar dilation to topical adenosine and to a selective A_2B receptor agonist in vivo (46).

Measurements of arterial blood gases, blood pressure, and arteriolar diameter were repeated 1 h after the start of superfusion with the corresponding drug inhibitor. Pial arteriolar reactivity to AMPA superfusion was studied with two doses that produced significant, dose-dependent increases in diameter within 5 min of superfusion. AMPA (30 µM) + the same drug inhibitor was superfused at a rate of 0.2 ml/min for 5 min and then washed out for 25 min at a rate of 0.1 ml/min with aCSF containing the respective drug inhibitor. The fluid volume in the window was 0.15 ml. Arteriolar diameter was measured at 1, 1.5, 2, 2.5, 3, 3.5, 4, 4.5, 5, 7, 10, 15, 20, and 30 min after the start of AMPA superfusion. After the 25-min washout period, arterial blood gases were measured. A higher dose of AMPA (100 µM) + the respective drug inhibitor was superfused for 5 min and then washed out for 25 min with the respective inhibitor/antagonist, and measurements were repeated as described above. At the end of the experiment, vascular reactivity to an NO donor was examined by superfusion of the window with 0.3 µM sodium nitroprusside at a rate of 0.1 ml/min for 10 min.

To contrast the effect of L-NNA on the response to AMPA with the known effect of L-NNA on the response to NMDA, the pial arteriolar response to 100 µM NMDA superfusion was tested before and after application of 1 mM L-NNA in a group of eight rats.

Statistical analysis. For each intervention, the percent change in diameter was calculated for each arteriole ranging in baseline diameter from 20 to 100 µm. Statistical analysis was performed using the average percent change of one to four pial arterioles per rat, such that the sample size is the number of rats. Changes in diameter of pial arterioles after 1 h of superfusion of each drug inhibitor/antagonist were compared with baseline values by paired t-test. For each dose of AMPA, the percent change in diameter over time was compared among inhibitor/antagonist groups by two-way ANOVA with repeated measures. If there were an overall treatment effect, additional two-way ANOVA with repeated measures was performed between the control group and each individual inhibitor/antagonist group. If this ANOVA indicated a significant treatment effect or treatment-time interaction, individual time points were compared with the control group by application of the false discovery rate procedure for multiple t-tests (12). In addition, the maximum percent diameter response was compared among groups by one-way ANOVA, and comparisons were made with the control group by Dunnett's test. Values are means ± SD. The level of significance was set at P < 0.05.

	RESULTS

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Superfusion of the cranial window with 30 and 100 µM AMPA produced dose-dependent increases in pial arteriolar diameter (Fig. 1). After superfusion of 1 mM L-NNA, the response to AMPA was not significantly reduced. In contrast, L-NNA decreased the dilator response to 100 µM NMDA.

View larger version (13K): [in this window] [in a new window]   Fig. 1. Maximum percent increase in pial arteriolar diameter during superfusion of 30 and 100 µM -amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) in control group (n = 8) and a group superfused with N-nitro-L-arginine (L-NNA, n = 7). Values are means ± SD. There was no significant effect of L-NNA on the AMPA response. In another group (n = 8), L-NNA reduced the dilator response to 100 µM N-methyl-D-aspartate (NMDA). *P < 0.05 vs. control.

View larger version (14K): [in this window] [in a new window]   Fig. 2. Maximum percent increase in pial arteriolar diameter during superfusion of 30 and 100 µM AMPA in control group (n = 8), a group superfused with 100 µM NS-398 (n = 8), and a group superfused with 20 µM N-methylsulfonyl-6-(2-propargyloxyphenyl)hexanamide (MS-PPOH, n = 6). Values are means ± SD. There was no significant effect of NS-398 or MS-PPOH on the AMPA response.

View larger version (19K): [in this window] [in a new window]   Fig. 3. Maximum percent increase in pial arteriolar diameter during superfusion of 30 and 100 µM AMPA in control group (n = 7), a group superfused with 15 µM chromium mesoporphyrin (CrMP, n = 7), a group superfused with 1 µM ZM-241385 (n = 7), a group superfused with 1 µM alloxazine (n = 7), a group superfused with CrMP + ZM-241385 + alloxazine (Combined, n = 7), and a group superfused with 30 µM 2,3-dihydroxy-6-nitro-7-sulfamoylbenzo(f)quinoxaline (NBQX, n = 5). Values are means ± SD. *P < 0.05 vs. control.

View larger version (12K): [in this window] [in a new window]   Fig. 4. Time course of percent change of pial arteriolar diameter during 5 min of superfusion of 100 µM AMPA in 0.01% DMSO control group and group superfused with 15 µM CrMP. Values are means ± SD (n = 7). *P < 0.05 vs. control at the same time. Superfusion of AMPA started at 0 min at a rate of 0.2 ml/min through a cranial window with a volume of 0.15 ml. Washout of AMPA with 0.01% DMSO or CrMP in artificial cerebrospinal fluid (aCSF) started at 5 min at a rate of 0.1 ml/min. Note nonlinear time scale during washout.

View larger version (12K): [in this window] [in a new window]   Fig. 5. Time course of percent change of pial arteriolar diameter during 5 min of superfusion of 100 µM AMPA in 0.01% DMSO control group and a group superfused with 1 µM ZM-241385. Values are means ± SD (n = 7). *P < 0.05 vs. control at the same time point. Superfusion of AMPA started at 0 min. Washout of AMPA with 0.01% DMSO or ZM-241385 in aCSF started at 5 min. Note nonlinear time scale during washout.

View larger version (12K): [in this window] [in a new window]   Fig. 6. Time course of percent change of pial arteriolar diameter during 5 min of superfusion of 100 µM AMPA in 0.01% DMSO control group and a group superfused with 1 µM alloxazine. Values are means ± SD (n = 7). *P < 0.05 vs. control at the same time. Superfusion of AMPA started at 0 min. Washout of AMPA with 0.01% DMSO or alloxazine in aCSF started at 5 min. Note nonlinear time scale during washout.

View larger version (13K): [in this window] [in a new window]   Fig. 7. Time course of percent change of pial arteriolar diameter during 5 min of superfusion of 100 µM AMPA in 0.01% DMSO control group and a group superfused with 15 µM CrMP + 1 µM ZM-241385 + 1 µM alloxazine. Values are means ± SD (n = 7). *P < 0.05 vs. control at the same time. Superfusion of AMPA started at 0 min. Washout of AMPA with 0.01% DMSO or drug combination in aCSF started at 5 min. Note nonlinear time scale during washout.

View larger version (12K): [in this window] [in a new window]   Fig. 8. Time course of percent change of pial arteriolar diameter during 5 min of superfusion of 100 µM AMPA in 0.01% DMSO control group (n = 7) and a group superfused with 30 µM NBQX (n = 5). Values are means ± SD. *P < 0.05 vs. control at the same time. Superfusion of AMPA started at 0 min. Washout of AMPA with 0.01% DMSO or NBQX in aCSF started at 5 min. Note nonlinear time scale during washout.

View larger version (14K): [in this window] [in a new window]   Fig. 9. Percent increase in pial arteriolar diameter during superfusion of 0.3 µM sodium nitroprusside in the 0.1% ethanol (EtOH) control group and groups superfused with L-NNA, NS-398, and MS-PPOH in the 1st experiment and in the 0.01% DMSO control group and groups superfused with ZM-241385, alloxazine, CrMP, CrMP + ZM-241385 + alloxazine (Combined), and NBQX in the 2nd experiment. Values are means ± SD. There were no differences from the control groups.

	DISCUSSION

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The nonselective adenosine receptor antagonist theophylline has been shown to partially inhibit cerebral vasodilation in response to whisker stimulation (13) and topical application of glutamate (21). Superfusion of rat cortical slices with glutamate or AMPA is capable of generating release of adenosine (11, 19). Adenosine dilates pial arterioles and intraparenchymal arterioles primarily through the A₂ receptor family (10, 20, 32). Further work by others (31, 46) has demonstrated that ZM-241385 inhibited pial and penetrating arteriolar dilation to low concentrations of adenosine, whereas alloxazine provided greater inhibition than ZM-241385 at high concentrations of adenosine. Availability of highly selective A_2B receptor antagonists is limited. Alloxazine is approximately one order of magnitude more selective for A_2B than for A_2A receptors (8), whereas ZM-241385 is nearly two orders of magnitude more selective for A_2A than for A_2B receptors (36, 37, 43). In cardiac myocytes, 1 µM alloxazine inhibited by 50% the contractile response to 5'-(N-ethylcarboxamido)-adenosine (NECA), an A₂ receptor agonist that appears to have selectivity for A_2B receptors, whereas this dose of alloxazine exerted only a slight inhibition of the response to the A_2A receptor agonist CGS-21660 (26). In pial arterioles, 1 µM alloxazine completely blocked dilation in vivo to NECA at low doses at which the dilation was not inhibited by 1 µM ZM-241385 (46). Thus, at the doses used in vivo, ZM-241385 and alloxazine are expected to show selectivity for the corresponding receptor subtypes. If the response to AMPA were mediated by A_2A, and not by A_2B, receptors, the inhibitory effect of alloxazine on the dilatory response would be expected to be much smaller than that of ZM-241385. The similarity of the magnitude of the inhibition of the dilation to AMPA with ZM-241385 and alloxazine suggests involvement of both receptor subtypes. A contribution of both receptor subtypes to the same functional response in the same cell type has precedent in cardiac myocytes (26). However, because the effect of alloxazine on pial arteriolar dilation to an A_2A receptor agonist was not tested, an effect of alloxazine on A_2A receptors cannot be completely excluded in the present study.

Involvement of A_2A receptors in the vascular response to AMPA is consistent with the work of others showing that ZM-241385 inhibits pial arteriolar dilation to sciatic nerve stimulation and glutamate superfusion (21, 28). However, involvement of A_2B receptors was not necessarily expected because of their lower affinity for adenosine. Moreover, vasodilation by A_2B receptor activation partially depends on NO synthesis (46), whereas NO synthesis inhibition had no effect on AMPA-evoked dilation in the present experiments. An alternative possibility is based on reports that activation of adenosine A_2B receptors on astrocytes increases intracellular Ca²⁺ (2, 24, 42), and increases in astrocyte Ca²⁺ can be coupled to vasodilation (17, 54). Perhaps astrocyte A_2B receptors are part of a signaling pathway coupling AMPA receptor activation to vascular dilation, whereas A_2A receptors largely mediate the direct effects of adenosine on pial arteriolar smooth muscle.

Because ZM-241385 and alloxazine did not completely block the dilatory response to AMPA, mediators other than adenosine might be involved. One potential mediator is CO derived from HO activity. HO activity has been implicated in cerebral vasodilation associated with seizures evoked by systemic administration of kainate in rats (29) and bicuculline administration in newborn pigs (44). However, seizure activity releases abundant amounts of glutamate, which can then activate all glutamate receptor subtypes. Our results with the HO inhibitor CrMP indicate that HO activity also participates in pial arteriolar dilation during AMPA receptor activation. At high concentrations, CrMP can inhibit NO synthase and guanylyl cyclase, but 15 µM CrMP (present study) had no significant effect on NO synthase and guanylyl cyclase (3). In addition, NO synthase inhibition in the present study did not have the same effect as CrMP on the vascular response to AMPA. In newborn pigs, glutamate is postulated to act on glutamate receptors in the endothelium and stimulate endothelial HO (38, 39). However, there is little evidence of functional vascular glutamate receptors in adult brain (5, 14, 15, 30). The constitutive isoform of HO, HO-2, is enriched in neurons (50). Thus it is presumed that AMPA acted on neuronal receptors to stimulate HO-2 activity in neurons to generate diffusible CO in the present study on adult rats.

Although CO may cause dilation by increasing cGMP in vascular smooth muscle, it also exerts a primary effect directly on Ca²⁺-sensitive K⁺ channels (23, 52). Adenosine is thought to relax arteriolar smooth muscle by increasing cAMP. The present findings that CrMP, ZM-241385, and alloxazine each inhibit the AMPA response individually by >50% suggest that there may be some interaction in the signaling pathways. Indeed, when the three inhibitors were combined, there was no further inhibition of the response compared with that obtained with each individual drug. The lack of an additive effect with combined inhibition also supports an interaction of adenosine- and CO-signaling pathways. Whether adenosine and CO are regulated sequentially (e.g., CO stimulates release of adenosine or adenosine receptor activation stimulates release of CO) or adenosine receptor activation and CO act cooperatively in permitting the opening of K⁺ channels is not known.

The finding that none of the inhibitor drugs that were tested alone or in combination completely eliminated the dilatory response to AMPA raised the possibility that AMPA might be partially acting via a non-AMPA receptor mechanism. However, the AMPA receptor antagonist NBQX blocked the response, and the response after NBQX was significantly less than the response to CrMP + ZM-241385 + alloxazine. Thus the vasodilation by AMPA is mediated by AMPA receptors, and an additional mechanism appears to be responsible for the residual dilation after inhibition of HO and adenosine A_2A and A_2B receptors.

Pial arteriolar vasodilation in response to topical NMDA is dependent on NO synthesis and is presumed to be linked to a coupling of neuronal NO synthase to an NMDA receptor macromolecular complex (9). It is unclear whether pial arteriolar dilation in response to activation of other ionotropic glutamate receptors is also dependent directly on NO generation. Kainate produces pial arteriolar dilation that is attenuated by L-NNA (15). However, it is possible that a high level of activation of kainate receptors can cause release of glutamate, which could exert a secondary effect of NMDA receptor activation (48). The present results demonstrate that a dose of L-NNA that was sufficient to inhibit NMDA-dependent dilation had no effect on the dilation evoked by AMPA. This result was somewhat unexpected, inasmuch as previous work from this laboratory showed that infusion of AMPA into a microdialysis probe in the hippocampus increased the nitroarginine-inhibitable conversion of arginine to citrulline (7). Perhaps differences in the properties of hippocampal and cortical neurons and glia result in a different coupling of AMPA receptors to NO production, or delivery of AMPA by the microdialysis route led to enhanced glutamate release and secondary activation of NMDA receptors. Regional differences are also present between the cerebral cortex and the cerebellum, where NO plays a greater role in AMPA-dependent neurovascular coupling (53). Therefore, the present finding, showing a lack of NO dependence in AMPA-evoked dilation, might be limited to cortical pial arterioles.

Metabolites of COX-2 (33), but not COX-1 (34), have been implicated in cortical vasodilation by whisker stimulation. NS-398 at 100 µM, similar to that presently used, suppressed the response to whisker stimulation 50%, with no further decrement at 300 µM. However, NS-398 had no significant effect on the pial arteriolar response to AMPA in the present study. Similarly, the cytochrome P-450 epoxygenase inhibitor MS-PPOH at a concentration that suppressed the cortical hyperemia response to whisker and forepaw stimulation (40, 41) had no effect on the response to AMPA. These comparisons imply that stimulation of these two arachidonic acid pathways sufficient to result in vasodilation during functional activation is not mediated by AMPA receptor stimulation. However, our results are restricted to extraparenchymal pial arterioles. Intraparenchymal arterioles may be subjected to greater control by arachidonic acid metabolites. For example, the cytochrome P-450 2C11 epoxygenase is expressed in rat astrocytes (1, 41), and intraparenchymal vessels surrounded by astrocytes may be under greater influence of epoxyeicosatrienoic acid generated by cytochrome P-450 2C11. Moreover, COX-1 activity has recently been implicated in coupling between astrocyte foot processes and intraparenchymal vasodilation (49).

In summary, the present study provides evidence that activation of cortical AMPA receptors produces pial arteriolar dilation that is partially mediated by adenosine A_2A and A_2B receptors. In addition, CO, rather than NO, appears to participate in the dynamic response to AMPA activation. Adenosine receptor activation and CO act in a nonadditive manner, thereby implying that their signaling is processed in series or in a nonlinear interaction on target proteins such as K⁺ channels. The lack of effect of NO synthase inhibition on the cortical pial vascular response to AMPA differs from the effect of NMDA in the cortex and from the role of AMPA on vasodilation in the cerebellum. Therefore, activation of specific glutamate receptor subtypes regulates cerebrovascular dilation by distinct pathways in distinct brain regions.

	GRANTS

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This work was supported by National Heart, Lung, and Blood Institute Grant HL-59996.

	ACKNOWLEDGMENTS

 
The authors thank Tzipora Sofare for editorial assistance.

	FOOTNOTES

 

Address for reprint requests and other correspondence: R. C. Koehler, Dept. of Anesthesiology and Critical Care Medicine, The Johns Hopkins Medical Institutions, 600 North Wolfe St./Blalock 1404-E, Baltimore, MD 21287-4961 (e-mail: rkoehler{at}jhmi.edu)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

^* H. Ohata and S. Cao contributed equally to this work.

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