Oxygen radicals from arachidonate metabolism in abnormal vascular responses

Mechanisms Associated with the Adverse Vascular Consequences of Rapid Posthypothermic Rewarming and Their Therapeutic Modulation in Rats

We previously demonstrated that rapid posthypothermic rewarming in noninjured animals was capable of damaging cerebral arterioles both at endothelial and smooth muscle levels. Such adverse consequences could be prevented with antioxidants, suggesting the involvement of free radicals. In this study, we further investigate the mechanisms associated with free radicals production by using two radical scavengers, superoxide dismutase (SOD) and catalase. Employing rats, the cerebral vascular response was evaluated at 2, 3, and 4 hours after onset of hypothermia. Before rapid rewarming, SOD treatment, but not catalase, preserved the NO-mediated dilation induced by acetylcholine (ACh). On the contrary, catalase preserved the hypercapnia-induced relaxation of the smooth muscle cells, whereas SOD offered only partial protection. Adding SOD to catalase treatment offered no additional benefit. These results suggest that rapid posthypothermic rewarming impairs ACh- and hypercapnia-induced vasodilation through different subcellular mechanisms. In the case of diminished vascular response to ACh, it appears to act on the endothelial front primarily by superoxide anions, as evidenced by its full preservation after SOD treatment. In terms of impaired dilation to hypercapnia, hydrogen peroxide and/or its derivatives are the likely candidates in targeting the smooth muscle cells. The partial protection of SOD to hypercapnia-induced dilation is believed to be the reduced amount of superoxide that would otherwise spontaneously dismutate to produce hydrogen peroxide. Although SOD exerts some indirect influence on the hydrogen peroxide production downstream, catalase apparently has no influence on upstream superoxide production.

Arachidonic acid- and prostaglandin E2-induced cerebral vasodilation is mediated by carbon monoxide, independent of reactive oxygen species in piglets

Arachidonic acid (AA) and prostaglandin (PG) E(2) stimulate carbon monoxide (CO) production, and AA metabolism is known to be associated with the generation of reactive oxygen species (ROS). This study was conducted to address the hypothesis that CO and/or ROS mediate cerebrovascular dilation in newborn pigs. Experiments were performed on anesthetized newborn pigs with closed cranial windows. Different concentrations of AA (10(-8)-10(-6) M), PGE(2) (10(-8)-10(-6) M), iloprost (10(-8)-10(-6) M), and their vehicle (artificial cerebrospinal fluid) were given. Piglets with PGE(2) and iloprost received indomethacin (5 mg/kg iv) to inhibit cyclooxygenase. AA, PGE(2), and iloprost caused concentration-dependent increases in pial arteriolar diameter. The effects of both AA and PGE(2) in producing cerebral vascular dilation and associated CO production were blocked by the heme oxygenase inhibitor chromium mesoporphyrin (2 × 10(-5) M), but not by the prostacyclin analog, iloprost. ROS inhibitor tempol (SOD mimetic) (1 × 10(-5) M) and the H(2)O(2) scavenger catalase (1,000 U/ml) also do not block these vasodilator effects of AA and PGE(2). Heme-L-lysinate-induced cerebrovascular dilation and CO production was blocked by chromium mesoporphyrin. Hypoxanthine plus xanthine oxidase, a combination that is known to generate ROS, caused pial arteriolar dilation and CO production that was inhibited by tempol and catalase. These data suggest that AA- and PGE(2)-induced cerebral vascular dilation is mediated by CO, independent of ROS.

Weight and inflammation are the major determinants of vascular dysfunction in the aortae of db/db mice

The key roles that obesity, hyperglycemia, hyperlipidemia, inflammation, and oxidative stress play in the progression of diabetes vascular complications are well recognized; however, the relative contribution and importance of these individual factors remain uncertain. At 6, 10, or 14 weeks old, blood samples and thoracic aortae were collected from db/db mice and their non-diabetic controls. Plasma samples were analyzed for glucose, 8-isoprostane, CRP, triglycerides, LDL, and HDL as markers of glycemic status, oxidative stress, inflammation, and dyslipidemia, respectively. The responses of the aortic rings to high KCl, phenylephrine (PE), acetylcholine (ACh), and sodium nitroprusside were examined. Statistical methods were used to estimate the strength of the association between plasma variables and vascular functions. Systemic inflammation occurred in db/db mice at an earlier age than did hyperglycemia or oxidative stress. Aortae of db/db showed augmented contractions to PE which were positively correlated with weight, plasma glucose, 8-isoprostane, and CRP. Also, db/db mice showed impaired endothelium-dependent ACh vasorelaxation which was negatively correlated with weight, plasma glucose, and 8-isoprostane. Multivariate analysis and stepwise modeling show that CRP is the major determinant of the contractile responses, while weight and HDL are the major determinants of ACh-induced relaxation. Among the traditional risk factors of obesity, hyperglycemia, oxidative stress, inflammation, and dyslipidemia, our study reveals that weight and inflammation are the major determinants of vascular dysfunction in the aortae of db/db mice. Our findings partially resolve the complexity of diabetes vasculopathies and suggest targeting weight loss and inflammation for effective therapeutic approaches.

Reactive oxygen-derived free radicals are key to the endothelial dysfunction of diabetes

Vascular complications are an important pathological issue in diabetes that lead to the further functional deterioration of several organs. The balance between endothelium-dependent relaxing factors and endothelium-dependent contracting factors (EDCFs) is crucial in controlling local vascular tone and function under normal conditions. Diabetic endothelial dysfunction is characterized by reduced endothelium-dependent relaxations and/or enhanced endothelium-dependent contractions. Elevated levels of oxygen-derived free radicals are the initial source of endothelial dysfunction in diabetes. Oxygen-derived free radicals not only reduce nitric oxide bioavailability, but also facilitate the production and/or action of EDCFs. Thus, the endothelial balance tips towards vasoconstrictor responses over the course of diabetes.

Endogenous adipose-derived factors diminish coronary endothelial function via inhibition of nitric oxide synthase

Adipocytokines may be the molecular link between obesity and vascular disease. However, the effects of these factors on coronary vascular function have not been discerned. Accordingly, the goal of this investigation was to delineate the mechanisms by which endogenous adipose-derived factors affect coronary vascular endothelial function. Both isolated canine coronary arteries and coronary blood flow in anesthetized dogs were studied with and without exposure to adipose tissue. Infusion of adipose-conditioned buffer directly into the coronary circulation did not change baseline hemodynamics; however, endothelial-dependent vasodilation to bradykinin was impaired both in vitro and in vivo. Coronary vasodilation to sodium nitroprusside was unaltered by adipose tissue. Oxygen radical formation did not cause the impairment because quantified dihydroethidium staining was decreased by adipose tissue and neither a superoxide dismutase mimetic nor catalase improved endothelial function. Inhibition of nitric oxide (NO) synthase with L-NAME diminished bradykinin-mediated relaxations and eliminated the subsequent vascular effects of adipose tissue. In vitro measurement of NO demonstrated that adipose tissue exposure quickly lowered baseline NO and abolished bradykinin-induced NO production. The results indicate that adipose tissue releases factor(s) that selectively impair endothelial-dependent dilation via inhibition of NO synthase-mediated NO production.

Cyclooxygenase products stimulate carbon monoxide production by piglet cerebral microvessels

Products of arachidonic acid (AA) metabolism by cyclooxygenase (Cox) are important in regulation of neonatal cerebral circulation. The brain and cerebral microvessels also express heme oxygenase (HO) that metabolizes heme to carbon monoxide (CO), biliverdin, and iron. The purpose of this study in newborn pig cerebral microvessels was to address the hypothesis that Cox products affect HO activity and HO products affect Cox activity. AA (2.0-20 microM) increased prostaglandin E2 (PGE2) measured by radioimmunoassay (RIA) and also CO measured by gas chromatography/mass spectrometry (GC/MS). Further, 10(-4) M indomethacin, which inhibited Cox, reduced both AA and heme-induced CO production. Conversely, neither exogenous 2 x 10(-6) M heme, which markedly increased CO production, nor the inhibitor of HO, chromium mesoporphyrin, altered PGE2 synthesis. Because AA metabolism by Cox generates both prostanoids and superoxides, we determined the effects of the predominant prostanoid and superoxide on CO production. Although PGE2 caused a small increase in CO production, xanthine oxidase plus hypoxanthine, which produces superoxide, strongly stimulated the production of CO by cerebral microvessels. This increase was mildly attenuated by catalase. These data suggest that Cox-catalyzed AA metabolites, most likely superoxide and/or a subsequent reactive oxygen species, increase cerebrovascular CO production. This increase seems to be caused, at least in part, by the elevation of HO-2 catalytic activity. Conversely, Cox activity is not affected by HO-catalyzed heme metabolites. These data suggest that some cerebrovascular functions attributable to Cox activity could be mediated by CO.

Early onset of subclinical atherosclerosis in women with gestational diabetes mellitus

OBJECTIVE

Common carotid artery intima-media thickness (CIMT) is a non-invasively assessed marker of subclinical atherosclerosis. Our aim in this study was to investigate CIMT in women with gestational diabetes mellitus (GDM).

METHODS

Thirty women with GDM and 40 unaffected women (as a control group) were included in the study. Blood samples were drawn from each woman in the morning after they had fasted for at least 8 h, and levels of fasting glucose, insulin, homocysteine, total cholesterol, high-density lipoprotein (HDL) cholesterol, triglycerides, low-density lipoprotein (LDL) cholesterol and very low-density lipoprotein (VLDL) cholesterol were measured, along with the CIMT in the two groups.

RESULTS

The mean triglyceride (P = 0.016) and VLDL cholesterol (P = 0.011) levels in the GDM group were significantly higher than those in the unaffected women. There were no significant differences between the groups with respect to plasma levels of total cholesterol, HDL cholesterol, LDL cholesterol and insulin. The mean homocysteine (P = 0.027) and fasting glucose (P = 0.019) levels in women with GDM were significantly higher than those in the control group. Patients with GDM had significantly higher CIMT than did the unaffected women (0.582 +/- 0.066 mm vs. 0.543 +/- 0.049 mm, P = 0.006). CIMT correlated positively with maternal age (r = 0.316, P = 0.008), body mass index (BMI) at the time of a 50-g oral glucose load test (r = 0.414, P = 0.001) and homocysteine levels (r = 0.332, P = 0.008), and fasting glucose (r = 0.265, P = 0.031) and 1-h glucose value (r = 0.410, P = 0.001) at the time of the oral glucose tolerance test. There was a positive correlation between the presence of GDM and CIMT (r = 0.372, P = 0.001). However, stepwise multiple regression analysis showed that GDM/no GDM (95% CI +0.012 to +0.076, P = 0.008) and BMI at the time of the 50-g test (95% CI +0.001 to +0.009, P = 0.011) were independent parameters related to CIMT.

CONCLUSION

Women with GDM have increased CIMT compared with unaffected women.

3-nitropropionic acid-induced changes in bilayer fluidity in synaptosomal membranes: implications for Huntington's disease

The use of 3-nitropropionic acid (3-NP) and other mitochondria inhibitors to effectuate animal models of Huntington's disease has been well established. 3-NP administration has been shown to lead to pathology similar to that of HD, including massive loss of striatal neurons associated with oxidative stress. Oxidative stress induced by 3-NP also extends to the cortex, an area where little neuron loss occurs. No mechanism as of yet accounts for selective loss of striatal neurons while sparing cortical neurons. In the present study, a nitroxide stearate lipid bilayer-specific spin-label was utilized to probe 3-NP-induced fluidity changes in striatal and cortical synaptosomal membranes. In cortical synaptosomes, membrane fluidity increased in animals previously treated with 3-NP when compared to controls injected with saline vehicle, while in striatal synaptosomes, membrane fluidity decreased in animals treated with 3-NP when compared to controls. The results of the present study suggest that oxidatively-induced changes in membrane fluidity may be involved in mechanisms by which selective striatal neuronal loss occurs in this animal model of Huntington's disease.

Effects of the nitrone radical scavengers PBN and S-PBN on in vivo trapping of reactive oxygen species after traumatic brain injury in rats

In previous studies, the authors showed that the nitrone radical scavenger alpha-phenyl-N- tert -butyl nitrone (PBN) and its sulfo-derivative, 2-sulfo-phenyl-N- tert -butyl nitrone (S-PBN), attenuated cognitive disturbance and reduced tissue damage after traumatic brain injury (TBI) in rats. In the current study, the production of reactive oxygen species (ROS) after TBI was monitored with microdialysis and the 4-hydroxybenzoic acid (4-HBA) trapping method. A single dose of PBN (30 mg/kg) or an equimolar dose of S-PBN (47 mg/kg) was administered intravenously 30 minutes before a controlled cortical contusion injury in rats. Plasma and brain tissue drug concentrations were analyzed at the end of the microdialysis experiment (3 hours after injury) and, in a separate experiment with S-PBN, at 30 and 60 minutes after injury. Traumatic brain injury caused a significant increase in ROS formation that lasted for 60 minutes after the injury as evidenced by increased 3,4-dihydroxybenzoic acid (3,4-DHBA) concentrations in the dialysate. PBN and S-PBN equally and significantly attenuated the posttraumatic increase in 3,4-DHBA formation. High PBN concentrations were found bilaterally in brain tissue up to 3 hours after injury. In contrast, S-PBN was rapidly cleared from the circulation and was not detectable in brain at 30 minutes after injury or at any later time point. The results suggest that scavenging of ROS after TBI may contribute to the neuroprotective properties observed with nitrone spin-trapping agents. S-PBN, which remained undetectable even in traumatized brain tissue, reduced ROS production to the same extent as PBN that readily crossed the blood-brain barrier. This finding supports an important role for ROS production at the blood-endothelial interface in TBI.

Reactive oxygen species in cell signaling

Reactive oxygen species (ROS) are generated as by-products of cellular metabolism, primarily in the mitochondria. When cellular production of ROS overwhelms its antioxidant capacity, damage to cellular macromolecules such as lipids, protein, and DNA may ensue. Such a state of "oxidative stress" is thought to contribute to the pathogenesis of a number of human diseases including those of the lung. Recent studies have also implicated ROS that are generated by specialized plasma membrane oxidases in normal physiological signaling by growth factors and cytokines. In this review, we examine the evidence for ligand-induced generation of ROS, its cellular sources, and the signaling pathways that are activated. Emerging concepts on the mechanisms of signal transduction by ROS that involve alterations in cellular redox state and oxidative modifications of proteins are also discussed.

Endothelial dysfunction in diabetes

Endothelial dysfunction plays a key role in the pathogenesis of diabetic vascular disease. The endothelium controls the tone of the underlying vascular smooth muscle through the production of vasodilator mediators. The endothelium-derived relaxing factors (EDRF) comprise nitric oxide (NO), prostacyclin, and a still elusive endothelium-derived hyperpolarizing factor (EDHF). Impaired endothelium-dependent vasodilation has been demonstrated in various vascular beds of different animal models of diabetes and in humans with type 1 and 2 diabetes. Several mechanisms of endothelial dysfunction have been reported, including impaired signal transduction or substrate availibility, impaired release of EDRF, increased destruction of EDRF, enhanced release of endothelium-derived constricting factors and decreased sensitivity of the vascular smooth muscle to EDRF. The principal mediators of hyperglycaemia-induced endothelial dysfunction may be activation of protein kinase C, increased activity of the polyol pathway, non-enzymatic glycation and oxidative stress. Correction of these pathways, as well as administration of ACE inhibitors and folate, has been shown to improve endothelium-dependent vasodilation in diabetes. Since the mechanisms of endothelial dysfunction appear to differ according to the diabetic model and the vascular bed under study, it is important to select clinically relevant models for future research of endothelial dysfunction.

Effects of hypoxia on isometric force, intracellular Ca(2+), pH, and energetics in porcine coronary artery

When exposed to hypoxic conditions, coronary arteries dilate, which is an important protective response. Although vessel sensitivity to oxygen is well documented, the mechanisms are not known with certainty. To further characterize the mechanisms of oxygen sensing in the coronary artery, we tested the major classes of hypotheses by measuring the effects of hypoxia on energetics, [Ca(2+)](i), K(+) channel function, and pH(i). Hypoxia relaxes porcine coronary arteries stimulated with either KCl or U46619. The extent of relaxation is dependent on both the degree and kind of stimulation. [Ca(2+)](i) was measured in endothelium-denuded arteries using fura 2-AM and ratiometric fluorescent techniques. At lower stimulus levels, hypoxia decreased both force and [Ca(2+)](i). Inhibitor studies suggest that K(Ca) and K(ATP) channels are not involved in the hypoxic relaxation, whereas K(V) channels may play a minor role, if any. Despite the hypoxia-mediated decrease in force, [Ca(2+)](i) was unchanged or increased at high levels of stimulation. Despite a marked increase in lactate content, pH(i) (measured with the ratiometric fluorescent dye BCECF) was also little affected by hypoxia. Measurement of the phosphagen and metabolite profile of freeze-clamped arteries with analytical isotachophoresis indicated that hypoxia increased lactate content by 4-fold and decreased phosphocreatine to 60% of control. However, neither ATP nor P(i) was affected by hypoxia. Interestingly, additional stimulation under hypoxia increased force but not ATP utilization, as estimated from measurements of anaerobic lactate production. Thus, surprisingly, the economy of force maintenance is increased under hypoxia. In porcine coronary artery, both Ca(2+)-dependent and, importantly, Ca(2+)-independent mechanisms are involved in hypoxic vasodilatation. For the latter, mechanisms involving either ATP, [Ca(2+)](i), pH(i), or P(i) cannot be invoked. This novel oxygen sensing mechanism involves a decreased Ca(2+) sensitivity.

Characterization of plasma magnesium concentration and oxidative stress following graded traumatic brain injury in humans

Plasma magnesium, calcium, and oxidative status were investigated in 31 male casualties with traumatic brain injury (TBI) during a 7-day posttraumatic period. The study group consisted of eight patients with mild closed head injury (Glasgow Coma Scale score [GCS] of 13-15), 10 patients with extensive penetrating head injury (GCS 4-6), and 13 patients with blast injuries but without direct head trauma. The latter group was included since previous experimental and clinical data have confirmed the development of indirect brain trauma in patients with blast injuries. Patients with multiple injuries were not included. Significant declines in plasma divalent cations were found in GCS 4-6 patients immediately after TBI and persisting for the entire 7-day study period. Similar changes in magnesium, but not calcium, were present in the GCS 13-15 and the blast injury groups, but only up until day 3 after injury. Alterations in lipid peroxidation products and superoxide anions were also observed following TBI. Increased lipid peroxidation was noted in all three groups over the entire posttraumatic period while increases in superoxide anion generation occurred transiently immediately following TBI. Thereafter, in the GCS 13-15 and blast injury groups, superoxide anions subsequently normalized, whereas in extensive head injury (GCS 4-6), superoxide anion generation significantly declined. A negative correlation between magnesium balance and oxidative stress was observed in all patients immediately after injury persisting in GCS 4-6 patients to the end of the observation period. Our findings suggest an interrelationship between magnesium changes and blood oxidants/antioxidants after TBI, which could be of both diagnostic and prognostic value in patients with neurotrauma.

Acute hyperglycemia depresses arteriolar NO formation in skeletal muscle

In the rat intestinal and cerebral microvasculatures, acute D-glucose hyperglycemia suppresses endothelium-dependent dilation to ACh without affecting endothelium-independent dilation to nitroprusside. This study determined whether acute hyperglycemia suppressed arteriolar wall nitric oxide concentration ([NO]) at rest or during ACh stimulation and inhibited nitroprusside-, ACh- or contraction-induced dilation of rat spinotrapezius arterioles. Vascular responses were measured before and after 1 h of topical 300 mg/100 ml D-glucose; arteriolar [NO] was measured with NO-sensitive microelectrodes. Arteriolar dilation to ACh was not significantly altered after superfusion of 300 mg/100 ml D-glucose. However, after hyperglycemia, arteriolar [NO] was not increased by ACh, compared with a 300 nM increase attained during normoglycemia. Arteriolar dilation to submaximal nitroprusside and muscle contractions was enhanced by hyperglycemia. These results indicated that in the rat spinotrapezius muscle, acute hyperglycemia suppressed arteriolar NO production while simultaneously augmenting vascular smooth muscle responsiveness to nitroprusside, presumably through cGMP-mediated mechanisms. In effect, this may have allowed ACh- and muscle contraction-induced vasodilation to be maintained during hyperglycemia despite an impaired NO system.

Acute hyperglycemia attenuates endothelium-dependent vasodilation in humans in vivo

BACKGROUND

Endothelial function is impaired in patients with diabetes mellitus. However, the factors contributing to this defect are currently unknown. Hyperglycemia attenuates endothelium-dependent relaxation in normal rabbit arteries in vitro and rat arterioles in vivo. Accordingly, this study examined the effect of acute hyperglycemia on endothelium-dependent vasodilation in nondiabetic humans in vivo.

METHODS AND RESULTS

Endothelium-dependent vasodilation was assessed through brachial artery infusion of methacholine chloride both before and during 6 hours of local hyperglycemia (300 mg/dL) achieved by intra-arterial infusion of 50% dextrose. Forearm blood flow was determined by plethysmography. In a group of 10 subjects, there was a trend toward attenuated methacholine-mediated vasodilation during hyperglycemia compared with euglycemia (P=.07 by ANOVA; maximal response, 13.3+/-2.8 versus 14.7+/-1.5 mL x min(-1) x 100 mL(-1), respectively). In these subjects, the systemic serum insulin levels increased significantly during the dextrose infusion (P<.001). To eliminate the confounding vasoactive effects of insulin, the protocol was repeated during systemic infusion of octreotide (30 ng x kg(-1) x min(-1)) to inhibit pancreatic secretion of insulin. In these subjects (n=10), hyperglycemia significantly attenuated the forearm blood flow response to methacholine (P<.01 by ANOVA; maximal response, 16.9+/-2.5 before versus 12.7+/-1.8 mL x min(-1) x 100 mL(-1) during hyperglycemia). Methacholine-mediated vasodilation was not attenuated by an equimolar infusion of mannitol (P>.40), nor did hyperglycemia reduce endothelium-independent vasodilation to verapamil (P>.50).

CONCLUSIONS

Acute hyperglycemia impairs endothelium-dependent vasodilation in healthy humans in vivo. This finding suggests that elevated glucose may contribute to the endothelial dysfunction observed in patients with diabetes mellitus.

Hemoglobin affects lipid peroxidation and prostaglandin E2 formation in rat corticocerebral tissues in vitro

Variations of lipid peroxidation and arachidonic acid (AA) metabolism products were found when experimental subarachnoid hemorrhage or ischemia and reperfusion were performed in an animal brain model. In a previous study, we showed that hemoglobin (Hb) produces prostaglandins when incubated in AA. To elucidate how Hb affects lipid peroxidation and AA metabolism in the CNS, we measured lipid hydroperoxides (LOOH), PGE2 and thiobarbituric acid reactant substances (TBARS) in corticocerebral homogenates and slices of rats (normal rats) after incubation with different concentrations (10(-9) to 10(-5) M) of Hb. In addition, brain cortices of indomethacin-treated (40 mg/Kg) rats (IN-treated rat) were incubated in the presence of 10(-5) M indomethacin (IN) to exclude the interference of prostaglandin enzyme synthetase. Hb was able to affect LOOH, PGE2, and TBARS production in both normal and IN-treated rat brain cortex homogenates and slices. In all cases, we found an increase in prostaglandin when 10(-8) M Hb was used, whereas no effect was noticed with 10(-9) M. On the other hand, with higher Hb concentrations (10(-6)-10(-5) M), the LOOH and PGE2 values did not reach statistical significance, and TBARS significantly increased. In all cases, when 10(-4) M scavenger or metal-chelating compounds were added to an incubation mixture with 10(-8) M Hb, PGE2 formation was inhibited, whereas no variation occurred when 10(-4) M IN was further added to IN-treated rat corticocerebral homogenate or slices. We hypothesize that in in vivo experimental neuropathologies, Hb must attain the 10(-8) M concentration in the reaction cellular microenvironment to stimulate PGE2 production, and that an evaluable part of this PGE2 production may be directly ascribable to the iron-heme oxy-redoxy activity of Hb.

Reactive glia express cytosolic phospholipase A2 after transient global forebrain ischemia in the rat

BACKGROUND AND PURPOSE

Phospholipid breakdown has been reported to be an early event in the brain after global cerebral ischemia. Our earlier observations showing the localization of cytosolic phospholipase A2 (cPLA2) to astrocytes in aged human brains and the intense glial activation observed after global forebrain ischemia prompted us to investigate the cellular localization of cPLA2 in the rat brain subjected to global ischemia.

METHODS

Immunohistochemistry was performed in sections through the dorsal hippocampus in rats subjected to 30 minutes of four- vessel occlusion. PLA2 was localized with the use of a highly selective antiserum. Double immunofluorescent localization was performed to colocalize cPLA2 with various glial cell types. cPLA2 levels were also measured by enzymatic assay and Western blot analysis.

RESULTS

A marked induction of cPLA2 was observed in activated microglia and astrocytes in the CA1 hippocampal region at 72 hours after ischemia. Only a subset of astrocytes and microglia were immunoreactive for cPLA2. Twenty-four hours after ischemia, numerous cPLA2 immunoreactive astrocytes were observed. Western blot analysis of hippocampal homogenates at 72 hours after ischemia showed induction of a 100-kD band that comigrated with purified human cPLA2, and a threefold induction in cPLA2 activity was demonstrated by enzymatic assay.

CONCLUSIONS

These results indicate that both reactive astrocytes and microglia contain elevated levels of cPLA2. Induction of cPLA2 was confined to areas of neurodegeneration and likely precedes its onset. The results suggest that reactive glia may play a role in the pathophysiology of delayed neuronal death after transient global forebrain ischemia.

Vitamin C improves endothelium-dependent vasodilation in patients with non-insulin-dependent diabetes mellitus

Endothelium-dependent vasodilation is impaired in humans with diabetes mellitus. Inactivation of endothelium-derived nitric oxide by oxygen-derived free radicals contributes to abnormal vascular reactivity in experimental models of diabetes. To determine whether this observation is relevant to humans, we tested the hypothesis that the antioxidant, vitamin C, could improve endothelium-dependent vasodilation in forearm resistance vessels of patients with non-insulin-dependent diabetes mellitus. We studied 10 diabetic subjects and 10 age-matched, nondiabetic control subjects. Forearm blood flow was determined by venous occlusion plethysmography. Endothelium-dependent vasodilation was assessed by intraarterial infusion of methacholine (0.3-10 micrograms/min). Endothelium-independent vasodilation was measured by intraarterial infusion of nitroprusside (0.3-10 micrograms/min) and verapamil (10-300 micrograms/min). Forearm blood flow dose-response curves were determined for each drug before and during concomitant intraarterial administration of vitamin C (24 mg/min). In diabetic subjects, endothelium-dependent vasodilation to methacholine was augmented by simultaneous infusion of vitamin C (P = 0.002); in contrast, endothelium-independent vasodilation to nitroprusside and to verapamil were not affected by concomitant infusion of vitamin C (P = 0.9 and P = 0.4, respectively). In nondiabetic subjects, vitamin C administration did not alter endothelium-dependent vasodilation (P = 0.8). We conclude that endothelial dysfunction in forearm resistance vessels of patients with non-insulin-dependent diabetes mellitus can be improved by administration of the antioxidant, vitamin C. These findings support the hypothesis that nitric oxide inactivation by oxygen-derived free radicals contributes to abnormal vascular reactivity in diabetes.

In vivo evidence for microvascular oxidative stress in spontaneously hypertensive rats. Hydroethidine microfluorography

The factors that predispose to the accelerated organ injury that accompanies the hypertensive syndrome have remained speculative and without a firm experimental basis. Indirect evidence has suggested that a key feature may be related to an enhanced oxygen radical production. The purpose of this study was to refine and use a technique to visualize evidence of spontaneous microvascular oxidative stress in vivo in the spontaneously hypertensive rat (SHR) compared with its normotensive control, the Wistar-Kyoto rat (WKY). We investigated the effects of adrenal glucocorticoids on the microvascular oxidative stress sequence. The mesentery was superfused with hydroethidine, a reduced, nonfluorescent precursor of ethidium bromide. In the presence of oxidative challenge, hydroethidine is transformed intracellularly into the fluorescent compound ethidium bromide, which binds to DNA and can be detected by virtue of its red fluorescence. The fluorescent light emission from freshly exteriorized and otherwise unstimulated mesentery microvessels was recorded by digital microscopy. The number of ethidium bromide-positive nuclei along the arteriolar and venular walls in SHR was found to be significantly increased above the level exhibited by WKY. The elevation in ethidium bromide fluorescence in SHR arterioles could be attenuated by a synthetic glucocorticoid inhibitor and in rats subjected to adrenalectomy. The administration of glucocorticoids after adrenalectomy by injection of dexamethasone restored the oxidative reaction in SHR arterioles. Treatment with dimethylthiourea and with a xanthine oxidase inhibitor attenuated the superoxide formation. Although a nitric oxide synthase inhibitor (NG-nitro-L-arginine methyl ester) enhanced the ethidium bromide staining in WKY, it did not affect that in SHR.(ABSTRACT TRUNCATED AT 250 WORDS)

The pathophysiology of intestinal damage: effects of luminal distention and ischemia

Intestinal edema, luminal distention, and ischemia are common pathologic processes involved in producing the intestinal damage found during surgical exploration for acute abdominal disorders in the horse. The severity of intestinal edema depends on the degree of altered intravascular forces and changes in capillary permeability. Capillary hydrostatic pressure rises as the less pliable venules and veins become occluded during intestinal obstruction. Concurrently, the production of various endogenous products that damage the vascular wall leads to increases in capillary permeability and protein exudation, causing fluid movement into the interstitium and consequent tissue edema. The information presently available indicates that luminal distention does not produce the morphologic damage observed during natural conditions. However, slight intestinal edema was observed with experimental distention of the equine small intestine. Although the effects of increased luminal pressure appear minor, in the overall scheme of intestine damage, many processes are occurring together, and the luminal distention may be additive in the production of intestinal damage. The intestinal damage occurring during natural obstructions is most likely related to both the severity of the ischemia and the subsequent reperfusion injury. Experimentally, an ischemic insult produces a consistent sequence of mucosal alterations to both the equine small and large intestine. Severity of ischemia may be the limiting factor in determining the clinical outcome in cases in which the ischemic insult is irreversible; however, if the intestinal tissue survives the ischemia, the reperfusion injury may substantially increase the damage, producing an irreversible injury. The proposed mechanisms responsible for the reperfusion injury include the presence of highly reactive cytotoxic oxygen radicals. The intestinal epithelium and vascular endothelium are both capable of producing these unstable compounds. Secondly, the influx and activation of neutrophils may also release oxygen radicals. During experimental ischemia, neutrophils gradually move to the affected area; however, during reperfusion their numbers dramatically increase and may play a significant role in producing intestinal damage. Therapy for intestinal damage involves first determining the viability of the affected intestine. All nonviable bowel should be resected and viable intestine anastomosed. The care and maintenance of intestine of questionable viability are presently based on therapy in humans and experimental information concerning the pathophysiologic mechanisms of intestinal ischemia.(ABSTRACT TRUNCATED AT 400 WORDS)

Effect of endothelial injury on the responses of isolated guinea pig pulmonary venules to reduced oxygen tension

The influence of the endothelium on pulmonary venular responses to reduced oxygen tension has not been defined. To examine this question, endothelial injury was induced in small guinea pig pulmonary artery and venule segments (effective lumen radius, 174 +/- 5 and 122 +/- 2 microns, respectively) by perfusion with either a mixture of hypoxanthine (5 mM) and xanthine oxidase (0.05 U/ml) (HX/XO) or collagenase (2 mg/ml). HX/XO significantly (p less than 0.05) reduced the relaxation of precontracted pulmonary arteries by acetylcholine (ACH), bradykinin (BK), and A-23187, and the relaxations were restored by including superoxide dismutase (40 micrograms/ml) in the HX/XO solution. However, neither HX/XO nor collagenase affected vasodilation induced by ACH, BK, and A-23187 in precontracted pulmonary venules. In contrast, HX/XO significantly (p less than 0.05) augmented the sustained contraction of pulmonary venules to hypoxia (HX/XO, 3.2 +/- 1.0 mg/mm; control, 1.0 +/- 0.5 mg/mm) and anoxia (HX/XO, 35.1 +/- 6.6 mg/mm; control, 20.3 +/- 4.0 mg/mm). Collagenase also significantly (p less than 0.05) enhanced the anoxic contractions (collagenase, 36.0 +/- 3.7 mg/mm; control, 20.9 +/- 6.8 mg/mm). Superoxide dismutase (40 micrograms/ml) and catalase (323 micrograms/ml) abolished HX-XO-induced augmentation of the hypoxic and anoxic contractions of pulmonary venules. Collagenase removed 54 +/- 8% of the venular endothelium (control, 5 +/- 1%), whereas HX/XO-exposed endothelial cells contained numerous craters. Neither gossypol (5 microM) nor methylene blue (10 microM) affected pulmonary venular contractions to reduced PO2. Endothelial damage augments the PO2-dependent contractions of the pulmonary venule, and this augmentation does not appear to be due to decreased release of endothelium-derived relaxing factor.

Oxygen radicals in CNS damage

The products of univalent reduction of oxygen, superoxide anion radical, hydrogen peroxide, and the hydroxyl radical, are capable of causing cellular damage and death. They are, therefore, logical candidates as mediators of vascular and parenchymal injury in the central nervous system (CNS). This paper reviews the sources of oxygen radicals in the CNS, their effects on cerebral vessels and on brain and spinal cord parenchyma, and the evidence which implicates oxygen radicals in various pathological conditions of the CNS.

Activated neutrophils release mediators that may contribute to myocardial injury and dysfunction associated with ischemia and reperfusion

Neutrophils accumulate in the ischemic myocardium and exacerbate postischemic cardiac dysfunction and injury. The formation of lipoxygenase metabolites of AA, derived either directly from the neutrophils or by interactions with other blood elements or cells, may promote neutrophil-mediated injury. Recognition of the roles played by neutrophils and AA metabolites in reperfusion injury may lead to the development of new therapies that can be used in conjunction with thrombolytic drugs to reduce the complications associated with restoring blood flow to the ischemic heart.