Oxygen radicals in cerebral ischemia: the 2001 Willis lecture

The sequential univalent reduction of oxygen generates superoxide, hydrogen peroxide, and hydroxyl radical. The generation of hydroxyl radical is dependent on catalysis by ferrous iron. In addition, superoxide and nitric oxide produce peroxynitrite, which spontaneously generates hydroxyl radical independently of iron-mediated catalysis. These agents have a variety of cellular actions, which render them suitable candidates as mediators of tissue destruction and cellular death. In the intact brain, superoxide and its derivatives cause vasodilation, mediated by opening of potassium channels, altered vascular reactivity, breakdown of the blood-brain barrier, and focal destructive endothelial lesions. These abnormalities are also seen in early reperfusion following brain ischemia. During reperfusion there is a marked transient increase in superoxide production. Vasodilation, abnormal vascular reactivity, and blood-brain barrier breakdown are inhibited by eliminating superoxide. Superoxide production during reperfusion may be initiated by glutamate via activation of alpha-amino-3-hydroxy-5-methylisoxasolepropionic acid (AMPA) receptors. These experimental findings have important implications for human cerebral ischemia. Agents directed at eliminating oxygen radicals must be administered before or in the early stages of reperfusion following ischemia. The therapeutic window appears to be narrow and limited to, at most, a few hours. The inhibition of AMPA receptors may be a promising approach to inhibit the production of oxygen radicals during ischemia-reperfusion of the brain.

Dimethylsulfoxide and ethanol, commonly used diluents, prevent dilation of pial arterioles by openers of K(ATP) ion channels

Ethanol and dimethylsulfoxide are commonly used as diluents for water-insoluble drugs. Both are antioxidants. An earlier study of cats presented pharmacological evidence indicating that oxidants could open the K(ATP) ion channel in cerebral surface arterioles [pial arterioles] and that antioxidants including dimethylsulfoxide and L-cysteine prevented opening of these channels. Ethanol was not tested. The present study extends the older observations to a second species, the rat, and examines ethanol as well as dimethylsulfoxide and L-cysteine. A microscope and image splitter were used to measure arteriolar diameters under a closed cranial window in pentobarbital-anesthetized, paralyzed rats. Drugs were topically applied. Dose-dependent dilations produced by two well-established openers of the K(ATP) ion channel were inhibited in dose-dependent manner by ethanol at doses from 0.01% to 0.075%. Above this dose, the effect disappeared. Dilation by sodium nitroprusside was not affected. Dimethylsulfoxide and L-cysteine inhibited dilation produced by pinacidil. Dimethylsulfoxide inhibited pinacidil in a dose-dependent manner at doses from 0.01% to 0.2%. L-Cysteine inhibited pinacidil. Since all the inhibitory drugs have antioxidant properties, their effect may be a reflection of that property as suggested in an earlier paper. Ethanol and dimethylsulfoxide inhibited in doses frequently present when these agents are used as solvents. When investigators use these solvents to dissolve water-insoluble, topically applied drugs, we suggest that they first test the possibility that their observations are being made under conditions in which opening of the K(ATP) ion channel is inhibited.

Evidence for a K(ATP) ion channel link in the inhibition of hypercapnic dilation of pial arterioles by 7-nitroindazole and tetrodotoxin

7-Nitroindazole, an inhibitor of neuronal nitric oxide synthase, reportedly inhibits hypercapnic dilation, but tetrodotoxin, an inhibitor of neuronal transmission, reportedly does not. Thus, evidence does not uniformly support the hypothesis of a neurogenic link to the hypercapnic response. Others suggest the hypercapnic response is mediated by a K(ATP) ion channel. In the following studies, we observed that topically administered tetrodotoxin inhibited dilations produced by hypercapnia. In addition, topical tetrodotoxin and either topical or intraperitoneal 7-nitroindazole, inhibited dilations produced by the K(ATP) channel openers, cromakalim and pinacidil. Inhibition of hypercapnic dilation and inhibition of dilation by the openers of the K(ATP) channel was immediately reversed by either L-lysine or L-arginine, amino acids previously shown to facilitate opening of the channel. The data strongly supports the previous conclusion that there is a K(ATP) ion channel link in the response of pial arterioles to hypercapnia. The location of the channel is not established by these data, nor is it known whether the action of tetrodotoxin on the channel was direct or indirect.

Fluid percussion injury transiently increases then decreases brain oxygen consumption in the rat

The oxygen consumption (VO2 microL/h/mg) of sham and of traumatized rat brains within 30 min and 6 h after a lateral fluid percussion injury (FPI) was measured with the Cartesian microrespirometer. Brain slices were cut at the plain of injury and site-specific 20-60-microg cores of tissue were transferred to the microrespirometer. In sham brains, the cortical VO2 (CVO2) was 13.78+/-0.64 and the hippocampal VO2 (HPVO2) was 11.20+/-0.58 microL/h/mg (p<0.05). Within 30 min of the injury, the respective values of 16.89+/-0.55 and 14.91+/-0.06 were significantly increased (p<0.05). The combined VO2 (CVO2, HPVO2) of 12.49+/-0.06 microL/h/mg in shams was significantly less than the combined VO2 of 15.90+/-0.59 microL/h/mg at 30 min post FPI (p<0.001). The maximal CVO2 of 19.49+/-1.10 microL/h/mg and the maximal HPVO2 of 15.98+/-0.99 microL/h/mg were both obtained from the ipsilateral side of the injury. Whereas the contralateral cortical value for injured brains was not significantly different from that of the shams, both ipsilateral and contralateral hippocampal values were significantly greater than that of the shams in response to injury (p<0.05). By 6 h postinjury, the combined VO2 had dropped to 10.01+/-0.84 microL/h/mg but was not significantly lower than the sham values. The data indicate that normal CVO2 is greater than normal HPVO2. The FPI produces significant increases in both CVO2 and HPVO2. Also, while the immediate increase in CVO2 appears to be injury-site dependent, that is, regional, the increase in HPVO2 appears to be global.

Chronic estrogen treatment increases levels of endothelial nitric oxide synthase protein in rat cerebral microvessels

BACKGROUND AND PURPOSE

A number of studies indicate that the female gonadal hormone, estrogen, confers protection against cerebrovascular disorders such as stroke. One postulated mechanism for these effects of estrogen is an action on the enzyme endothelial nitric oxide synthase (eNOS), which produces the vasodilatory molecule NO. We have investigated the hypothesis that estrogen increases expression of eNOS in cerebral microvessels of male and female rats.

METHODS

We measured levels of eNOS protein by Western blot in cerebral microvessels isolated from 7 groups of animals: females, ovariectomized females, ovariectomized females treated with estrogen, males, castrated males, castrated males treated with estrogen, and castrated males treated with testosterone.

RESULTS

Ovariectomized female rats treated with estrogen had 17. 4-fold greater levels of eNOS protein in cerebral microvessels than ovariectomized females, and intact females had 16.6-fold greater levels than ovariectomized females (P<0.01). In intact females, cerebral microvessel eNOS protein levels were 9.2-fold higher than those of intact males (P<0.05). Levels of eNOS protein in castrated males, castrated males treated with testosterone, and males were not different from each other. Estrogen treatment of castrated animals resulted in an 18.8-fold increase in cerebral microvessel eNOS protein (P<0.05).

CONCLUSIONS

Chronic estrogen treatment increases levels of eNOS protein in cerebral microvessels of male and female rats. This increase in eNOS protein correlates with our previous functional findings indicating that estrogen exposure increases NO modulation of cerebrovascular reactivity in both male and female animals. Upregulation of eNOS expression may contribute to the neuroprotective effect of estrogen.

Blockade of ATP-sensitive potassium channels in cerebral arterioles inhibits vasoconstriction from hypocapnic alkalosis in cats

BACKGROUND AND PURPOSE

Recent studies have shown that the cerebral arteriolar dilation from hypercapnic acidosis is blocked by agents which inhibit KATP channels. These findings suggested that this response is due to opening of KATP channels. Because the repose to CO2 is a continuum, with hypercapnic acidosis causing vasodilation and hypocapnic alkalosis causing vasoconstriction, it would be expected that the response to hypocapnic alkalosis would be due to closing of KATP channels. There are no studies of the effect of inhibition of KATP channels on the response to hypocapnic alkalosis.

METHODS

We investigated the effect of 3 agents that in earlier studies were found to inhibit KATP channels--NG-nitro-L-arginine, hydroxylysine, and glyburide--on the cerebral arteriolar constriction caused by graded hypocapnia induced by hyperventilation in anesthetized cats equipped with cranial windows.

RESULTS

Hypocapnic alkalosis caused dose-dependent vasoconstriction that was inhibited completely by each of the 3 inhibitors of KATP channels. The blockade induced by these agents was eliminated in the presence of topical L-lysine (5 micromol/L).

CONCLUSIONS

The findings show that agents which inhibit ATP-sensitive potassium channels in cerebral arterioles inhibit the vasoconstriction from hypocapnic alkalosis. These and earlier results showing that inhibition of KATP channels inhibited dilation from hypercapnic acidosis demonstrate that the response to CO2 in cerebral arterioles is mediated by the opening and closing of KATP channels.

Antioxidants inhibit ATP-sensitive potassium channels in cerebral arterioles

BACKGROUND AND PURPOSE

Hydrogen peroxide and peroxynitrite are capable of generating hydroxyl radical and are commonly suspected as sources of this radical in tissues. It would be useful to distinguish the source of hydroxyl radical in pathophysiological conditions and to clarify the mechanisms by which antioxidants modify vascular actions of oxidants.

METHODS

We investigated the effect of three antioxidants--dimethylsulfoxide (DMSO), salicylate, and L-cysteine--on the cerebral arteriolar dilation caused by topical application of hydrogen peroxide and peroxynitrite in anesthetized cats equipped with cranial windows. We also tested the effect of these antioxidants on the vasodilation caused by pinacidil and cromakalim, two known openers of ATP-sensitive potassium channels.

RESULTS

DMSO was more effective in inhibiting dilation from hydrogen peroxide, whereas salicylate and L-cysteine were more effective in inhibiting dilation from peroxynitrite. All three antioxidants inhibited dilation in concentrations that were remarkably low (< 1 mmol/L). All three antioxidants inhibited vasodilation from two known potassium channel openers, pinacidil and cromakalim. Their effect was specific because they did not affect dilation from adenosine or nitroprusside.

CONCLUSIONS

The findings show that antioxidants block ATP-sensitive potassium channels in cerebral arterioles. This appears to be the mechanism by which antioxidants inhibit the dilation from hydrogen peroxide and peroxynitrite and not through scavenging of a common intermediate, ie, hydroxyl radical. The differences between effectiveness in inhibiting dilation from hydrogen peroxide and peroxynitrite by various antioxidants suggest that hydrogen peroxide and peroxynitrite act at two different sites, one in a water-soluble environment and the other in a lipid-soluble environment.

Cerebral arteriolar dilations by KATP channel activators need L-lysine or L-arginine

We investigated the effects of various amino acids on responses to ATP-sensitive potassium (KATP) channel openers in anesthetized cats equipped with cranial windows. The application of pinacidil by superfusion caused transient vasodilation, whereas there was sustained vasodilation from the application of stationary solution of pinacidil. In the presence of L-arginine or L-lysine, pinacidil by superfusion led to sustained vasodilation, suggesting that the rapid flow of fluid displaced these amino acids from binding on the channel and that such binding was essential for opening the channel. NG-nitro-L-arginine blocked responses to pinacidil, and this blockade was reversed by L-lysine or L-arginine but not by D-arginine, D-lysine, methyl-L-arginine, glycine, L-histidine, dimethylarginine, dimethyl-L-arginine, or hydroxylysine. The blockade of responses to pinacidil induced by glyburide was also reversed completely by L-arginine or L-lysine but not by D-arginine, suggesting that these amino acids act on the sulfonylurea receptor. Hydroxylysine but not methyl-L-lysine, dimethylarginine, or dimethyl-L-arginine blocked responses to pinacidil. The findings show that KATP channels in cerebral arterioles need L-lysine or L-arginine to open in response to agonists.

A pilot study of the cost of educating undergraduate medical students at Virginia Commonwealth University

PURPOSE

To develop a model isolating the annual per-student cost of, and the fund sources for, educating undergraduate medical students at the Virginia Commonwealth University Medical College of Virginia School of Medicine.

METHOD

For 1994-95, hours that faculty spent in direct scheduled contact with students and time that students spent in direct scheduled contact with faculty were inventoried. Student, faculty, and resident contact hours for clinical clerkships and electives were estimated. Faculty contact hours and average faculty workload profiles were used to compute the number of full-time-equivalent faculty positions required to deliver the undergraduate medical curriculum. Support staff and operating budget requirements were based on the number of required faculty, and actual salary averages were used to compute faculty and staff costs. Other institutional costs that indirectly support undergraduate medical education were estimated. Using faculty contact hours and actual cost data, fund sources that support undergraduate medical education were identified.

RESULTS

Medical school faculty spent more than 89,000 scheduled hours teaching 674 undergraduate medical students. The faculty-student ratio was 1:3.35. Residents spent nearly 79,000 hours training undergraduate medical students. The total annual cost of undergraduate medical education was $69,992 per student. State funds contributed less than a third of the required financial resources; faculty clinical practice funds provided nearly half.

CONCLUSION

Although there are inherent complexities, isolating the cost and fund sources of undergraduate medical education is an essential first step toward providing categorical funding. The model developed during the study provides a basis for assigning costs, allocating resources among instructional programs, and predicting incremental costs (or savings) and revenue requirements. The model may be of use to other medical schools contemplating new strategies for financing undergraduate medical education.

Arginine analogues inhibit responses mediated by ATP-sensitive K+ channels

Because arginine analogues have been reported to block the vasodilator response to hypercapnia, we investigated the effect of nitro-L-arginine (L-NNA) on the dilation of pial arterioles to arterial hypercapnia induced by inhalation of 3, 5, and 7% CO2 in anesthetized cats equipped with cranial windows. L-NNA at 250 microM, but not at lower concentrations, significantly reduced hypercapnia-induced dilation. This effect could be reversed by L-arginine. However, hypercapnic hyperemia is not the result of increased guanosine 3',5'-cyclic monophosphate via the usual NO-mediated activation of guanylate cyclase, because application of LY-83583, which blocks guanylate cyclase, did not alter the vessel response to CO2. L-NNA at 250 microM also abolished the pial arteriolar dilation in response to cromakalim, minoxidil, and pinacidil, three known openers of ATP-sensitive K+ channels, and this effect could be reversed by L-arginine. Application of glyburide, which blocks ATP-sensitive K+ channels, also reduced the response to CO2. Subsequent application of L-NNA in these experiments had no additional effect. Vasodilation induced by sodium nitroprusside and 3-morpholinosydnonimine, two known NO donors, was unaffected by glyburide. NG-monomethyl-L-arginine had effects similar to those of L-NNA in the cat and rat at concentrations as low as 20 microM. Our findings suggest that arginine analogues inhibit hypercapnic vasodilation by blocking ATP-sensitive K+ channels, independently of activation of guanylate cyclase via increased production of NO. Furthermore, the data suggest that ATP-sensitive K+ channels may have an arginine site that influences their function.

Mechanisms of cerebral vasodilation by superoxide, hydrogen peroxide, and peroxynitrite

We investigated the role of potassium channels in the vasodilator action of hydrogen peroxide, peroxynitrite, and superoxide on cerebral arterioles. We studied the effect of topical application of these agents in anesthetized cats equipped with cranial windows. Hydrogen peroxide and peroxynitrite induced dose-dependent dilation that was inhibited by glyburide, an inhibitor of ATP-sensitive potassium channels. Superoxide, generated by xanthine oxidase acting on xanthine in the presence of catalase, also induced dose-dependent dilation of cerebral arterioles that was unaffected by glyburide but inhibited completely by tetraethylammonium chloride, an inhibitor of calcium-activated potassium channels. The vasodilations from hydrogen peroxide, peroxynitrite, or superoxide were unaffected by inhibition of soluble guanylate cyclase with LY-83583. The findings provide pharmacological evidence that hydrogen peroxide and peroxynitrite reversibly dilate cerebral arterioles by activating ATP-sensitive potassium channels, probably through an oxidant mechanism, whereas superoxide dilates cerebral arterioles by opening calcium-activated potassium channels. Activation of soluble guanylate cyclase is not a mediator of the vasodilator action of these agents in cerebral arterioles.

Nitric oxide and S-nitroso-L-cysteine as endothelium-derived relaxing factors from acetylcholine in cerebral vessels in cats

BACKGROUND AND PURPOSE

The predominant view is that the endothelium-derived relaxing factor generated by acetylcholine from blood vessels is nitric oxide. However, there is evidence suggesting that certain nitric oxide-containing compounds such as nitrosothiols resemble the endothelium-derived relaxing factor generated by acetylcholine more closely than does nitric oxide itself. Accordingly, we compared the effects of nitric oxide and S-nitroso-L-cysteine on cerebral arteriolar caliber in relation to the associated increments in nitrite concentration in the effluent.

METHODS

Acetylcholine, nitric oxide, and S-nitroso-L-cysteine were administered by continuous superfusion in oxygen-free solution through the space under a cranial window in anesthetized cats. Nitrite concentration was measured in the effluent. The degree of vasodilation induced was evaluated in relation to the increment in nitrite concentration.

RESULTS

All agents induced dose-dependent vasodilation and dose-dependent increments in nitrite concentration in the effluent. For any given degree of vasodilation, the increments in nitrite concentration were equivalent during acetylcholine or S-nitroso-L-cysteine infusion, whereas the nitrite concentrations were 10 times higher during nitric oxide infusion. After administration of nitroarginine, a competitive inhibitor of nitric oxide synthesis from arginine, there was depression in the vasodilation as well as the increment in nitrite concentration induced by acetylcholine.

CONCLUSIONS

S-Nitroso-L-cysteine resembles endothelium-derived relaxing factor from acetylcholine more closely than does nitric oxide.

Nitric oxide and nitrosothiols in cerebrovascular and neuronal regulation

BACKGROUND

Currently prevailing concepts concerning the endothelium-dependent relaxant effect of acetylcholine and other endothelium-dependent agonists are that it is mediated by the generation from arginine of nitric oxide, which is then released into the extracellular space, diffuses to the vascular smooth muscle, and activates soluble guanylate cyclase by combining with the iron of the heme component of the enzyme.

RESULTS AND CONCLUSIONS

Recent studies show that in the cerebral circulation these traditional concepts need to be modified in two major areas. First, the activation of soluble guanylate cyclase by nitric oxide, nitroglycerin, or nitroprusside is indirectly mediated via release of calcitonin gene-related peptide from sensory nerve fibers. This peptide then activates soluble guanylate cyclase by an unknown mechanism. Second, the endothelium-derived relaxing factor from cerebral arterioles is not nitric oxide but a nitric oxide-containing compound, very likely a nitrosothiol. Nitrosothiols activate soluble guanylate cyclase in cerebral arterioles by direct action independent of calcitonin gene-related peptide. The participation of nitric oxide, nitrosothiols, or both in the regulation of basal cerebral vascular tone, in flow-dependent dilation, in the vascular responses to CO2, and in response to activation of the N-methyl-D-aspartic acid receptor are considered.

Effect of local change in O2 saturation of hemoglobin on cerebral vasodilation from hypoxia and hypotension

We tested the effect of certain newly synthesized allosteric modifiers of hemoglobin on the dilation induced by arterial hypoxia, arterial hypotension, and arterial hypercapnia in cerebral arterioles of anesthetized cats equipped with cranial windows for the observation of the cerebral microcirculation. The allosteric modifiers of hemoglobin are isomers of 2-(aryloxy)-2-methylpropionic acid. They shift the oxygen dissociation of hemoglobin to the right, thereby facilitating the local release of oxygen. When these compounds were applied topically by superfusion at a rate of 1 ml/min in a concentration of 0.1 mM, they had no significant effect on baseline arteriolar diameter but reduced significantly the vasodilation from arterial hypoxia and arterial hypotension. They did not influence the vasodilation from arterial hypercapnia. Spectrophotometric measurements of optical densities from pial veins 50-80 microns in diameter indicated that the superfusion with the allosteric compounds reduced hemoglobin oxygen saturation both during room air breathing and during hypoxia. We conclude that the vasodilations from arterial hypoxia and arterial hypotension are mediated by local oxygen-dependent mechanisms. The allosteric modifiers of hemoglobin may be useful as tools in investigating oxygen-dependent mechanisms.

Enhanced oxygenation in vivo by allosteric inhibitors of hemoglobin saturation

The in vivo effects on hemoglobin (Hb)-O2 affinity and tissue PO2 were investigated after intraperitoneal administration of 2-[4-(((dichloroanilino)-carbonyl)methyl)phenoxyl]-2-methyl propionic acid (RSR4; 150 mg/kg) or its 3,5-dimethyl derivative (RSR13; 300 mg/kg) in C3Hf/Sed mice. The Hb-O2 dissociation curve was plotted from tail vein blood samples using an O2 dissociation analyzer before and up to 160 min after compound administration. Twenty to 40 min after injection, the PO2 at 50% saturation of hemoglobin (Hb P50) increased by a mean of 25% (range 18-31%) after RSR4 and 53% (range 36-76%) after RSR13. Tissue PO2 was continuously measured using an O2 microelectrode in thigh muscle before and up to 40 min after RSR4 or RSR13 injection. Twenty to 40 min after administration, tissue PO2 increased by a mean of 78% (range 30-127%) after RSR4 and 66% (range 39-97%) after RSR13 administration in anesthetized mice. No change in tissue PO2 was seen in anesthetized controls.

Effect of neonatal capsaicin treatment on neurogenic pulmonary edema from fluid-percussion brain injury in the adult rat

The frequent occurrence of acute death from pulmonary failure in experimental head injury studies on Sprague-Dawley rats prompted an investigation into the manner in which acute neurogenic pulmonary edema develops in these animals as a result of an applied fluid pressure pulse to the cerebral hemispheres. Studies were performed in adult animals using histamine H1 and H2 blocking agents, or in adult animals treated as neonates with capsaicin to destroy unmyelinated C-fibers. Recordings were made of either the pulmonary arterial or the right ventricular pressure, and the left atrial and femoral arterial pressures before, during, and after injury to provide a record of the hemodynamic response throughout the development of neurogenic pulmonary edema. Head injury triggered the almost immediate development of pressure transients with and without neurogenic pulmonary edema. All rats, regardless of treatment, reacted with nearly identical systemic arterial pressure responses; however, the pulmonary responses followed a time course that was independent of systemic arterial pressure changes. Acute neurogenic pulmonary edema was always associated with a substantial increase in pulmonary arterial and left atrial pressures; conversely, pressure increases of similar magnitude were not always associated with edema. Histamine H1 and H2 blockers significantly reduced the pulmonary pressure surges only in rats free of neurogenic pulmonary edema. All capsaicin-treated rats showed suppressed pulmonary pressure responses, normal lung water content, elevated lung surface tension, and significantly reduced levels of immunoreactive substance P in the spinal cord and vagus nerve. While the pressures cannot clarify how edema influences the observed hemodynamics, they do not support the view that edema is the direct consequence of pulmonary hypertension. It is proposed that neurogenic pulmonary edema is a functional disturbance provoked by adverse stimuli from outside the lungs and that in the rat the primary afferent fiber is essential to the production of this entity.

Hydroxyl radical-dependent inactivation of guanylate cyclase in cerebral arterioles by methylene blue and by LY83583

BACKGROUND AND PURPOSE

Methylene blue and 6-anilino,5,8-quinolinedione (LY83583) are used extensively to block activation of guanylate cyclase. Both agents generate oxygen radicals. Therefore, it appeared profitable to investigate whether the generation of oxygen radicals by these agents is responsible for the blockade of responses to nitrodilators that act via activation of guanylate cyclase to relax vascular smooth muscle and cause vasodilation.

METHODS

We tested in anesthetized cats equipped with cranial windows responses to topical application of nitroglycerin, nitroprusside, and adenosine before and during topical application of methylene blue (5 microM). Responses to the vasoactive agents were tested during application of methylene blue after permeabilization of the cell membrane with a detergent to allow methylene blue to enter vascular smooth muscle. Responses were also tested in the presence of superoxide dismutase, catalase, deferoxamine, or dimethyl sulfoxide to scavenge reactive products of oxygen metabolism or to eliminate catalytic iron. In additional experiments we tested the effects of topical application of nitroprusside or adenosine before and after application of LY83583. The responses to the vasoactive agents were also tested in the presence of superoxide dismutase, catalase, or dimethyl sulfoxide in addition to LY83583. We also tested responses to calcitonin gene-related peptide before and in the presence of LY83583 with or without superoxide dismutase.

RESULTS

Methylene blue eliminated the arteriolar dilation in response to nitroprusside and nitroglycerin after permeabilization of the cell membrane with a detergent but not before. The responses to adenosine were unaffected. The blockade induced by methylene blue was reversed by superoxide dismutase, catalase, or dimethyl sulfoxide but not by deferoxamine. LY83583 blocked responses to nitroprusside but not to adenosine. The blockade was eliminated by superoxide dismutase, catalase, or dimethyl sulfoxide. LY83583 blocked the vasodilation induced by calcitonin gene-related peptide. This blockade was reversed by superoxide dismutase.

CONCLUSIONS

Methylene blue and LY83583 prevent the activation of soluble guanylate cyclase by nitrodilators or by calcitonin gene-related peptide by generating oxygen radicals. The mediator of this response is the hydroxyl radical. Methylene blue does not enter the vascular smooth muscle of cerebral arterioles unless the cell membrane is permeabilized.

Improving the outcome of severe head injury with the oxygen radical scavenger polyethylene glycol-conjugated superoxide dismutase: a phase II trial

Formation of the oxygen radical superoxide anion is one of the final events of several metabolic pathways in the cascade that leads to delayed neuronal death after traumatic or ischemic brain injury. In the laboratory, scavenging of the superoxide anion with native superoxide dismutase (SOD) or polyethylene glycol (PEG)-conjugated SOD (PEG-SOD) has been shown to be beneficial in several types of traumatic and ischemic injury. Accordingly, PEG-SOD was utilized in a randomized controlled Phase II trial to evaluate its safety and efficacy in severely head-injured patients with a Glasgow Coma Scale score of 8 or less. At two institutions, 104 patients were randomly assigned to receive either placebo or PEG-SOD (2000, 5000, or 10,000 U/kg) intravenously as a bolus, an average of 4 hours after injury. Prognostic factors were evenly distributed in the four groups, except for mean age which was significantly higher in the group receiving 10,000 U/kg than in the placebo group (mean age 34 years vs. 25 years). No complications attributed to the study medication were noted. The average intracranial pressure (ICP) was similar in the four groups, but the percentage of time during which ICP was above 20 mm Hg was less in the groups receiving 5000 or 10,000 U/kg of PEG-SOD. Patients in the group receiving 10,000 U/kg also required less mannitol for ICP control than the placebo group. Outcome was assessed using the Glasgow Outcome Scale at 3 and 6 months postinjury in 91 and 93 patients, respectively, by blinded observers not involved in the clinical management of the patients. At 3 months, 44% of patients in the placebo group were vegetative or had died, while only 20% of patients in the group receiving 10,000 U/kg of PEG-SOD were in these outcome categories (p < 0.03, multiple logistic regression test); at 6 months, these figures were 36% and 21%, respectively (p = 0.04). Differences in outcome between the placebo group and either of the other two dosage groups were not statistically significant. It is concluded that PEG-SOD was generally well tolerated and appears promising in improving outcome after severe head injury. A larger, multicenter, Phase III trial, using a higher dose (20,000 U/kg) compared to placebo and to 10,000 U/kg of PEG-SOD is planned.

The role of oxygen radicals in the pathobiology of traumatic brain injury

This manuscript considers some of the most prominent consequences of traumatic brain injury (TBI), namely vascular and axonal change, and evaluates the role of damaging oxygen radicals in their pathogenesis. To this end, existing as well as new data derived from traumatically injured experimental animals and humans was employed. Experimental animals were subjected to fluid-percussion brain injury. Some animals were equipped with cranial windows to allow for the functional assessment of the pial vasculature, while others received various exogenous tracers to assess blood-brain barrier status. In order to identify traumatically induced axonal change, some animals were also processed for the light and electron microscopic visualization of antibodies targeted to the neurofilament subunits. Similar immunocytochemical strategies were employed in the postmortem study of humans who had sustained severe TBI. Through these approaches, TBI was recognized to result in vascular abnormalities ranging from impaired vascular responsiveness to altered blood-brain barrier status. Typically, these vascular abnormalities continued for several hours postinjury and showed evolution which correlated with the production of damaging oxygen radicals. Importantly, the use of radical scavengers reversed these vascular abnormalities and provided protection. Traumatically induced axonal damage was also associated with evolving posttraumatic change. This involved the continued posttraumatic disassembly and misalignment of the intra-axonal neurofilament subunits which caused impaired axoplasmic transport leading to axonal swelling and detachment. Although these intra-axonal changes did not appear to be directly caused by oxygen radicals, it is suggested that the presence of oxygen radicals may exacerbate the progression of these reactive events.

Effects in cats of inhibition of nitric oxide synthesis on cerebral vasodilation and endothelium-derived relaxing factor from acetylcholine

BACKGROUND AND PURPOSE

We investigated the chemical identity of the endothelium-derived relaxing factor generated by acetylcholine in cerebral microvessels by studying the effects and mechanism of action of inhibitors of nitric oxide synthesis from arginine on the vasodilation and endothelium-derived relaxing factor production induced by topical application of acetylcholine in cerebral arterioles.

METHODS

We determined cerebral arteriolar dilation and endothelium-derived relaxing factor production by bioassay in anesthetized cats equipped with cranial windows during superfusion of 10(-7) M acetylcholine before and after administration of either NG-monomethyl L-arginine or NG-nitro-L-arginine, two inhibitors of nitric oxide synthesis.

RESULTS

NG-Nitro-L-arginine abolished the vasodilation from acetylcholine and eliminated the production of endothelium-derived relaxing factor in the bioassay experiments. NG-Monomethyl L-arginine had no effect on the response to acetylcholine in the absence of pretreatment. However, after pretreatment with the detergent sodium dodecyl sulfate to increase cell membrane permeability, the inhibitor had effects identical to those of NG-nitro-L-arginine. L-Arginine reversed the effects of the inhibitors of nitric oxide synthesis. Neither inhibitor affected baseline vascular caliber, nor did they generate a vasoconstrictor agent in the bioassay experiments. The two inhibitors of nitric oxide synthesis did not affect the response to nitroprusside or adenosine, showing that the effect on responses to acetylcholine was specific. Also, the blockade of the response to acetylcholine induced by the inhibitors of nitric oxide synthesis was unaffected by treatment with superoxide dismutase and catalase, showing that the effect was not mediated by oxygen radicals.

CONCLUSION

The endothelium-derived relaxing factor generated by acetylcholine in cerebral arterioles of cats is either nitric oxide or a nitric oxide-containing substance. The effect of these inhibitors on the response to acetylcholine is mediated by inhibition of the synthesis of nitric oxide. There is no involvement of radicals, and no vasoconstrictor agent is generated.

Oxygen radicals in cerebral ischemia

Superoxide production was measured as the superoxide dismutase (SOD)-inhibitable portion of nitro blue tetrazolium (NBT) reduction after cerebral ischemia-reperfusion in anesthetized cats equipped with cranial windows. Significant superoxide production was found in the early reperfusion period and continued for more than 1 h after ischemia. Superoxide was not detected in control animals not subjected to ischemia, during ischemia, and at 120 min of reperfusion. After ischemia, the vasoconstrictor response to arterial hypocapnia was reduced. This effect was prevented by pretreatment with SOD plus catalase or by deferoxamine. The response to topical acetylcholine was converted to vasoconstriction after ischemia. The normal vasodilator response reappeared spontaneously at 120 min of reperfusion. The vasodilator response to acetylcholine was preserved in animals pretreated with SOD plus catalase. Blood-brain barrier permeability to labeled albumin and horseradish peroxidase was increased after ischemia. These effects were minimized by pretreatment with SOD and catalase. We conclude that superoxide generation occurs during reperfusion after cerebral ischemia for a fairly long period and that superoxide and its derivatives are responsible at least in part for the vasodilation and the abnormal reactivity as well as for the increase in blood-brain barrier permeability to macromolecules seen after ischemia. Furthermore, the findings suggest that the agent responsible for the vascular abnormalities is hydroxyl radical generated via the iron-catalyzed Haber-Weiss reaction.

Cytochemical detection of superoxide in cerebral inflammation and ischemia in vivo

We used a cytochemical technique for the detection of superoxide in cerebral inflammation and ischemia-reperfusion in anesthetized cats. The technique is based on the oxidation of Mn2+ to Mn3+ by superoxide; Mn3+, in turn, oxidizes diaminobenzidine. The oxidized diaminobenzidine forms an osmiophilic electron-dense product that is detected by electron microscopy. The reagents, manganese chloride (2 mM) and diaminobenzidine (2 mg/ml), were placed topically on the brain surface of anesthetized cats equipped with cranial windows. Inflammation was induced by topical carrageenan with or without phorbol 12-myristate 13-acetate to activate leukocytes. In inflammation, superoxide was detected in the plasma membrane and in the phagocytic vacuoles of leukocytes. In ischemia-reperfusion, superoxide was identified in the meninges in association with blood vessels. It was located primarily in the extracellular space and occasionally in endothelial and vascular smooth muscle cells. In both inflammation and ischemia, the reaction product was eliminated by superoxide dismutase or by the omission of either manganese or diaminobenzidine. It was unaffected by sodium azide, which inhibits peroxidases. No superoxide was detected in the brain parenchyma. The findings confirm the generation of superoxide is cerebral ischemia-reperfusion and show that it is produced in cerebral vessels.

Superoxide production in experimental seizures in cats

BACKGROUND AND PURPOSE

Seizures cause cerebrovascular responses similar to those seen in conditions such as acute hypertension, ischemia/reperfusion, or fluid-percussion brain injury, which are associated with the generation of superoxide. Accordingly, we studied production of superoxide in experimental seizures.

METHODS

Superoxide production was measured in anesthetized cats equipped with double cranial windows using the superoxide dismutase-inhibitable reduction of nitro blue tetrazolium as a measure of superoxide production. Seizures were induced by intravenous bicuculline. The contribution of hypertension associated with seizures was studied by maintaining arterial blood pressure constant by bleeding.

RESULTS

Significant superoxide dismutase-inhibitable reduction of nitro blue tetrazolium indicative of superoxide production was found during seizures with or without control of arterial blood pressure (1.10 +/- 0.27 and 1.29 +/- 0.16 nmol/l/min, respectively).

CONCLUSIONS

The results show that experimental seizures are associated with superoxide generation that is independent of the rise in arterial blood pressure. It is likely that superoxide generation is due to the metabolic changes that occur during seizures.