Caspase inhibitor affords neuroprotection with delayed administration in a rat model of neonatal hypoxic-ischemic brain injury.

Programmed cell death (apoptosis) is a normal process in the developing nervous system. Recent data suggest that certain features seen in the process of programmed cell death may be favored in the developing versus the adult brain in response to different brain injuries. In a well characterized model of neonatal hypoxia-ischemia, we demonstrate marked but delayed cell death in which there is prominent DNA laddering, TUNEL-labeling, and nuclei with condensed chromatin. Caspase activation, which is required in many cases of apoptotic cell death, also followed a delayed time course after hypoxia-ischemia. Administration of boc-aspartyl(OMe)-fluoromethylketone, a pan-caspase inhibitor, was significantly neuroprotective when given by intracerebroventricular injection 3 h after cerebral hypoxia-ischemia. In addition, systemic injections of boc-aspartyl(OMe)-fluoromethylketone also given in a delayed fashion, resulted in significant neuroprotection. These findings suggest that caspase inhibitors may be able to provide benefit over a prolonged therapeutic window after hypoxic-ischemic events in the developing brain, a major contributor to static encephalopathy and cerebral palsy.

Hydroxyethyl starch reduces leukocyte adherence and vascular injury in the newborn pig cerebral circulation after asphyxia.

BACKGROUND AND PURPOSE: Hydroxyethyl starch (HES) has beneficial effects on ischemic brain injury; however, its mechanism of action remains unclear. The present study was undertaken to test the hypothesis that HES can attenuate increases in leukocyte adherence and vascular permeability in the cerebral vasculature after global cerebral ischemia induced by asphyxia. METHODS: Pial venular leukocyte adherence and permeability to sodium fluorescein were quantified in anesthetized newborn piglets by in situ fluorescence videomicroscopy through closed cranial windows during basal conditions and during 2 hours of reperfusion after global ischemia induced by 9 minutes of asphyxia. Experimental animals received HES after the asphyxial insult (10% HES 257/0.47, 600 mg/kg IV bolus 5 minutes after asphyxia, followed by 600 mg/kg per hour IV drip during reperfusion; n=9). RESULTS: A progressive and significant (P:<0.05) increase in adherent leukocytes was observed during the initial 2 hours of reperfusion after asphyxia compared with nonasphyxial controls. In this model, vascular injury, as determined by significant (P:<0.05) increases in fluorescein permeability at 2 hours of reperfusion, is largely dependent on adherent leukocytes. HES significantly reduced (P:<0.05) leukocyte adherence at 1 hour and 2 hours of reperfusion and reduced fluorescein permeability at 2 hours. HES did not change hematocrit or alter pial arteriolar diameter. CONCLUSIONS: These findings indicate that a vascular anti-inflammatory action may underlie the beneficial effects of HES in global cerebral ischemia secondary to asphyxia. Since this compound is well tolerated by patients, future preclinical and clinical studies may reveal improvements in functional outcome with the early introduction of this or similar agents after perinatal asphyxia or global ischemia.

Differences in vulnerability to permanent focal cerebral ischemia among 3 common mouse strains.

BACKGROUND AND PURPOSE: Genetically engineered mice are used to study the role of single genes in cerebral ischemia, but inherent, strain-dependent differences in neuronal vulnerability may affect experimental end points. To examine this possibility, tissue injury resulting from focal ischemia and its relationship to cerebral hemodynamics were determined in 3 common mutant mouse strains. METHODS: Permanent middle cerebral artery ligation was performed in male C57BL/6J, Balb/C, and 129X1/SvJ mice. Mean arterial blood pressure, blood gases, basal and postischemic cortical blood flow ([(14)C]iodoantipyrine autoradiography and laser-Doppler flowmetry), posterior communicating artery patency, and infarct size were determined. RESULTS: Basal cortical blood flow did not differ among strains. Ten minutes after middle cerebral artery ligation, relative red cell flow in the ischemic cortex was 6% to 7% of preischemic flow in every strain. Despite similar hemodynamics, cortical infarcts in Balb/C mice were 3-fold larger than those in 129X1/SvJ and C57BL/6J mice; infarct size in the latter 2 strains was not significantly different. The posterior communicating artery was either poorly developed or absent in >90% of the Balb/C and C57BL/6J but in <50% of the 129X1/SvJ mice. CONCLUSIONS: The extent of ischemic injury differed markedly between the 3 strains. The presence and patency of posterior communicating arteries, although variable among strains, did not affect preischemic or postischemic cortical blood flow or bear any relationship to ischemic injury. Therefore, intrinsic factors, other than hemodynamic variability, may contribute to the differences in ischemic vulnerability among strains. These findings underscore the importance of selecting genetically matched wild-type controls.

Adenosine and metabolic regulation of coronary blood flow in dogs with renal hypertension.

It has been demonstrated that resting coronary vascular resistance is elevated with chronic hypertension and concomitant cardiac hypertrophy. The present study employed a model of 6-week, one-kidney, one wrapped Page hypertension to determine if the ability of the heart to match an increase in oxygen demand with an increase in oxygen supply (coronary blood flow) is impaired, and to determine if these vasoregulatory abnormalities are attributable to inadequate adenosine release. Studies were performed in a pentobarbital anesthetized, open-chest canine preparation using a pericardial infusate method to determine adenosine release. Results showed that dobutamine (a beta-receptor agonist) induced increases in myocardial oxygen consumption (MVO2) over a physiological range (8-30 ml O2 X min-1 X 100 g-1) that were accompanied by an increase in coronary blood flow (CBF) with no change in oxygen extraction. The relationship between MVO2 and CBF was not different between the normotensive (NTC) and hypertensive (RHT) animals. Pericardial infusate adenosine (PI ADO) concentrations were not different for the same MVO2 and CBF, and the relationships for MVO2 vs PI ADO as well as PI ADO vs CBF were unaltered by hypertension. However, the relationship between PI ADO and coronary vascular resistance (CVR) was altered in the RHT group such that a given PI ADO concentration was associated with a significantly higher CVR. These data suggest that, over the range of MVO2 studied, there are no limitations in metabolic regulation of the coronary circulation of RHT animals, and that the higher CVR encountered in the RHT group is not the result of a reduced release of the endogenous vasodilator, adenosine.

Effect of 2-chloroadenosine on cerebrovascular reactivity to hypercapnia in newborn pig.

The effect of local administration of vasodilative concentrations of the adenosine receptor agonist 2-chloroadenosine (2-CADO) on the hyperemic responses of the pial and parenchymal microcirculations to graded hypercapnia was determined. The cranial window and brain microdialysis-hydrogen clearance techniques were utilized in two groups of isoflurane-anesthetized newborn pigs to measure changes in pial diameters and local CBF, respectively, in response to graded hypercapnia in the absence and presence of 2-CADO. Progressive size-dependent dilations of pial arterioles [small = 41 +/- 7 microns (mean +/- SD), intermediate = 78 +/- 13 microns, and large = 176 +/- 57 microns in diameter] occurred in response to graded hypercapnia alone (PaCO2 = 58 and 98 mm Hg) and to superfusions of 2-CADO (10(-5) M) during normocapnia; the magnitude of the dilative response to each of these stimuli was inversely proportional to vessel size. When hypercapnia was induced concomitantly with 2-CADO superfusion, the dilative effects of each stimulus were directly additive. Similarly, local microdialysis infusion of 10(-5) M 2-CADO, which doubled CBF during normocapnia, did not affect the hyperemic response of the parenchymal circulation to graded hypercapnia (PaCO2 = 69 and 101 mm Hg). Our findings are consistent with the participation of adenosine in the mediation of cerebral hypercapnic hyperemia. If, however, adenosine is not involved in this dilative response, our results indicate that concomitant vascular and neuromodulatory actions induced by adenosine receptor stimulation do not affect the mechanism responsible for the hypercapnic hyperemic response.

Effect of dipyridamole on cerebral extracellular adenosine level in vivo.

The effect of dipyridamole, an adenosine transport inhibitor, on cerebral extracellular adenosine concentration remains to be determined. To examine this issue, bilateral brain dialysis samples were obtained from piglet frontal cortex before, during, and after 5 min of cerebral ischemia; 10(-4) M dipyridamole was administered through one dialysis probe. On the control side, dialysate adenosine concentration increased 5.7-fold during ischemia and 15-fold during the first 5 min of reperfusion; it returned to control levels after 15 min of reperfusion. Relative to the control side, dipyridamole caused a twofold increase in basal dialysate adenosine concentration and increased dialysate adenosine concentration at 10 and 15 min of reperfusion, but no increase in dialysate adenosine occurred during and immediately after ischemia. The results indicate that, in the piglet brain, cerebral ischemia markedly elevates intracerebral extracellular adenosine concentration and that dipyridamole increases extracellular adenosine levels.

Platelet-activating factor mediates ischemia-induced leukocyte-endothelial adherence in newborn pig brain.

The authors examined the involvement of platelet-activating factor (PAF) in mediating leukocyte adherence to brain postcapillary pial venules and altering blood-brain barrier (BBB) permeability during basal conditions and during reoxygenation after asphyxia in newborn piglets. Intravital epifluorescence videomicroscopy, closed cranial windows, and labeling of leukocytes with rhodamine 6G allowed us to obtain serial measurements of adherent leukocytes within postcapillary venules. Blood-brain barrier breakdown was determined by optical measures of cortical extravascular fluorescence intensity after intravenous sodium fluorescein. Superfusion of PAF over the cortex induced a dose-dependent increase in leukocyte adherence to cerebral venules and leakage of fluorescein; with 1 micromol/L PAF, the magnitude of adherence and BBB breakdown was similar to that seen during reoxygenation after 9 minutes of asphyxia. Both adherence and loss of BBB integrity resulting from either exogenous PAF or asphyxia-reoxygenation could be significantly attenuated by intravenous administration of WEB 2086, a PAF receptor antagonist. Window superfusion of superoxide dismutase with PAF attenuated PAF-induced increases in adherence and associated fluorescein leakage. These findings indicate that PAF exhibits proinflammatory effects in piglet brain and that PAF contributes to leukocyte adherence and BBB breakdown after cerebral ischemia. These PAF effects are mediated by increases in superoxide radical generation.

Nitric oxide mediates cerebral ischemic tolerance in a neonatal rat model of hypoxic preconditioning.

Neuroprotection against cerebral ischemia can be realized if the brain is preconditioned by previous exposure to a brief period of sublethal ischemia. The present study was undertaken to test the hypothesis that nitric oxide (NO) produced from the neuronal isoform of NO synthase (NOS) serves as a necessary signal for establishing an ischemia-tolerant state in brain. A newborn rat model of hypoxic preconditioning was used, wherein exposure to sublethal hypoxia (8% oxygen) for 3 hours renders postnatal day (PND) 6 animals completely resistant to a cerebral hypoxic-ischemic insult imposed 24 hours later. Postnatal day 6 animals were treated 0.5 hour before preconditioning hypoxia with the nonselective NOS inhibitor L-nitroarginine (2 mg/kg intraperitoneally). This treatment, which resulted in a 67 to 81% inhibition of calcium-dependent constitutive NOS activity 0.5 to 3.5 hours after its administration, completely blocked preconditioning-induced protection. However, administration of the neuronal NOS inhibitor 7-nitroindazole (40 mg/kg intraperitoneally) before preconditioning hypoxia, which decreased constitutive brain NOS activity by 58 to 81%, was without effect on preconditioning-induced cerebroprotection, as was pretreatment with the inducible NOS inhibitor aminoguanidine (400 mg/kg intraperitoneally). The protective effects of preconditioning were also not blocked by treating animals with competitive [3-(2-carboxypiperazin-4-yl)propyl-1-phosphonate; 5 mg/kg intraperitoneally] or noncompetitive (MK-801; 1 mg/kg intraperitoneally) N-methyl-D-aspartate receptor antagonists prior to preconditioning hypoxia. These findings indicate that NO production and activity are critical to the induction of ischemic tolerance in this model. However, the results argue against the involvement of the neuronal NOS isoform, activated secondary to a hypoxia-induced stimulation of N-methyl-D-aspartate receptors, and against the involvement of the inducible NOS isoform, but rather suggest that NO produced by the endothelial NOS isoform is required to mediate this profound protective effect.

Hypoglycemic hyperemia in retina of newborn pigs. Involvement of adenosine.

PURPOSE: To determine whether retinal blood flow increases in response to perinatal hypoglycemia and whether the vasodilator adenosine is involved in mediating the hyperemic response. METHODS: Retinal fluorescein videoangiography was undertaken in intact eyes of isoflurane-anesthetized piglets using intracarotid injections of sodium fluorescein. Angiograms were recorded to videotape and analyzed off-line by image analysis software to determine stimulus-induced changes in mean arteriovenous transit times, and arteriolar and venular diameters, from which retinal blood flow was calculated. Two groups of animals were rendered hypoglycemic (blood glucose = 19 +/- 1 mg/dl) by insulin (25 IU/kg, intravenously), and angiograms were obtained at 10-minute intervals for 0.5 hour of hypoglycemia. One group (n = 5) served as controls. In the other (n = 5), the nonspecific adenosine receptor antagonist 8-phenyltheophylline (8PT) was administered intravenously approximately 15 minutes before hypoglycemia to examine the role of adenosine in the hemodynamic response to hypoglycemia. RESULTS: Acute hypoglycemia was associated with an increase in mean retinal blood flow of 94 +/- 18% (P < 0.002). However, in animals pretreated with 8PT, this hyperemic response was severely attenuated, primarily by an effect on arteriovenous transit time. In these latter animals, mean retinal blood flow only increased 19 +/- 10% in response to hypoglycemia (P = 0.13 versus normoglycemic baseline; P = 0.007 versus untreated hypoglycemic animals). All other hemodynamic variables were similar between animal groups. CONCLUSIONS: Acute hypoglycemia causes a compensatory increase in retinal blood flow in the perinatal period. Because the adenosine receptor antagonist 8PT attenuated this hyperemic response, it is concluded that adenosine is involved in eliciting the increase in retinal blood flow that accompanies hypoglycemia.

Adenosine-mediated autoregulation of retinal arteriolar tone in the piglet.

PURPOSE: To determine if the purine vasodilator adenosine participates in mediating autoregulatory dilations of the retinal microcirculation in vivo. METHODS: The retinal microcirculation of isoflurane-anesthetized newborn pigs was observed by videomicroscopy (x310). Systemic hypoxia (PaO2 = 24 +/- 1 mm Hg; n = 8) or hemorrhagic hypotension (MABP = 41 +/- 1 mm Hg; n = 5) was induced, and the effect of intravitreal microsuffusion of 0.4 nmol of the adenosine receptor antagonist 8-sulfophenyltheophylline (8SPT) on retinal arteriolar dilations resulting from these stimuli were measured. The effect of potentiation of endogenous interstitial adenosine concentrations with 0.2 nmol 4-nitrobenzyl-6-thioinosine (NBTI) on the response to hypotension (MABP = 43 +/- 2 mm Hg; n = 4) was also determined. RESULTS: The significant vasodilatative response of the retinal arterioles to systemic hypoxia (36 +/- 8% increase in diameter above baseline; P = 0.0012) was attenuated 55% (P < 0.0001) by the adenosine antagonist 8SPT. Similarly, the significant arteriolar vasodilation induced by systemic hypotension (29 +/- 3% increase in diameter; P < 0.0001) was inhibited 76% by 8SPT (P = 0.0002). When adenosine reuptake was inhibited with NBTI, the arteriolar dilation induced by hypotension (32 +/- 5% increase in diameter; P = 0.0234) was potentiated 100% (P = 0.0117). CONCLUSIONS: Our finding that inhibition or potentiation of endogenous adenosine action uniquely affected retinal arteriolar dilatative responses to hypoxia and hypotension suggests that adenosine is a key participant in mediating autoregulatory adjustments in retinal blood flow in the eye of the newborn.

KATP channels mediate adenosine-induced hyperemia in retina.

PURPOSE: The authors and others have shown previously that the purine nucleoside adenosine is a potent vasodilator in the retinal microcirculation, mediating increases in retinal blood flow (RBF) in response to several autoregulatory stimuli. The current experiments were undertaken to elucidate the involvement of adenosine triphosphate (ATP)-sensitive potassium (KATP) channels and the adenylate cyclase--cyclic adenosine monophosphate (cAMP) second-messenger system in the transduction of adenosine's hyperemic response. METHODS: Retinal fluorescein angiograms were videorecorded in isoflurane-anesthetized newborn pigs, and changes in arteriovenous transit times and retinal arteriolar and venular diameters were used to estimate stimulus-induced changes in RBF. RESULTS: Intravitreal perivascular microsuffusion of 5 nmol and 50 nmol adenosine caused dose-dependent increases in RBF of 79% +/- 4% (P < 0.05; n = 5) and 323% +/- 61% (P < 0.05; n = 5), respectively. The KATP channel antagonist glibenclamide (0.5 nmol and 5 nmol) caused a significant, dose-dependent attenuation of the hyperemic response to 5 nmol adenosine. The specificity of glibenclamide for blocking KATP channels was demonstrated by its ability to block by 94% +/- 6% (P < 0.05; n = 5) the increase in RBF (94% +/- 7%; P < 0.05) elicited by the intravitreal microsuffusion of the KATP channel agonist cromakalim (5 nmol), whereas it had no effect on the 103% +/- 12% increase in RBF (P < 0.05; n = 5) induced by the nitric oxide donor sodium nitroprusside (15 nmol). Adenosine-induced hyperemia was not potentiated by forskolin (1.7 nmol; n = 4), an adenylate cyclase activator, and was not attenuated by dideoxyadenosine (5 nmol; n = 4), an adenylate cyclase inhibitor. In addition, no significant increases in RBF could be elicited by 2.5 to 25 nmol 8-bromo-cAMP (n = 4), a membrane-permeable cAMP analog. CONCLUSIONS: These results in the piglet indicate that adenosine increases blood flow in the retina by activating KATP channels, not by increasing in cyclic AMP secondary to adenylate cyclase activation. They also underscore the potential importance of KATP channels in the transduction of retinal vasodilatative responses to other agonists.

Preconditioning provides complete protection against retinal ischemic injury in rats.

PURPOSE: The objectives of this study were to examine whether preconditioning can decrease ischemic damage to the retina, by electroretinographic assessment of visual function and by histologic examination of retinal structure; to investigate the time course of the effectiveness of preconditioning; and to determine whether protein synthesis is involved. METHODS: Retinal ischemia was produced for 60 minutes in anesthetized Sprague-Dawley rats. Recovery after ischemia was measured by electroretinography for a maximum period of 7 days. Retinal sections that were sliced 1 micron thick were examined 7 days after ischemia. Retinal ischemia for 5 minutes constituted the preconditioning stimulus. To assess the time course of preconditioning, animals first underwent preconditioning and then 60 minutes of ischemia 1, 24, 72, or 168 hours later; or they underwent a 5-minute sham experiment and 60 minutes of ischemia 24 hours later. An additional group of rats received 0.4 mg/kg cycloheximide, the protein synthesis inhibitor, intraperitoneally before preconditioning and underwent 60 minutes of ischemia 24 hours later. RESULTS: In contrast to the nonpreconditioned rats, preconditioned rats had complete recovery of the a- and b-waves compared with preischemic baseline amplitudes, and ischemia-induced histologic damage was completely prevented when preconditioning was performed 24 or 72 hours (but not 168 hours) before ischemia. Separation of preconditioning and 60 minutes of ischemia by 1 hour caused an even greater impairment of functional retinal recovery compared with that seen in sham-preconditioned rats. Severe histologic damage was also noted. Block of protein synthesis by cycloheximide completely attenuated the protective effect of preconditioning. CONCLUSIONS: Preconditioning induces profound retinal tolerance to ischemia in vivo. The absence of a protective effect of preconditioning when there was a 1-hour or a 168-hour separation between the preconditioning stimulus and ischemia and the inhibition of preconditioning by cycloheximide support the hypothesis that a transient change in protein expression is necessary to provide this protection.

Time-dependent effects of theophylline on myocardial reactive hyperaemias in the anaesthetized dog.

1. The effects of a loading dose of theophylline (5 mg kg-1 i.v.) on the hyperaemias resulting from short-term (15 and 30 s) interruptions in coronary blood flow and intracoronary adenosine were studied at given intervals over a 2 h period in the anaesthetized dog. 2. These hyperaemic responses were affected differently by theophylline and each effect was time-dependent. The reactive hyperaemic response progressively decreased after drug delivery, reaching 46% of control at 2 h. In contrast, after a maximal attenuation to 23% of control 5 min after theophylline, the hyperaemia resulting from intracoronary adenosine progressively increased over the same period, reaching 64% of control 2 h after the loading dose. 3. Two-compartment model results based on plasma theophylline measurements and the time course of theophylline accumulation in pericardial infusates, suggested that complete drug distribution throughout the heart may require at least 20 min following a single intravenous dose. 4. If it is assumed that theophylline blocks coronary vascular adenosine receptors, these pharmacokinetics are consistent with the time-dependent pattern of response attenuation we observed for the adenosine-induced hyperaemias, but they cannot entirely explain the pattern of response attenuation observed for the occlusion-induced hyperaemias. The continued increase in attenuation of this response after complete drug distribution suggests an additional pharmacodynamic action of theophylline. 5. We conclude that a single therapeutic dose of theophylline results in distinct time-dependent pharmacological effects with respect to the ability of the coronary vasculature to dilate in response to temporary interruptions in oxygen supply and in response to exogenously administered adenosine. These effects deserve consideration in both experimental studies in which adenosine antagonists are used to assess adenosine action in vivo, and in clinical practice where theophylline pharmacotherapy for pulmonary disorders is commonplace.

Endogenous glutathione protects cerebral endothelial cells from traumatic injury.

Blood-brain barrier breakdown and edema, indicative of cerebrovascular injury, are characteristic pathophysiologic outcomes following head trauma. These injuries result from both primary mechanical damage and from secondary events initiated by the traumatic insult. Free radicals are recognized as mediators of secondary injury in a number of trauma models. In this study, we used a novel in vitro model of traumatic microvascular injury to test the hypothesis that endogenous glutathione protects cerebral endothelial cells from secondary autooxidative injury following mechanical trauma. Porcine brain cerebral endothelial cells were grown in tissue culture wells with Silastic membrane bottoms, and cellular injury was induced by displacing the membrane different distances with user-defined pressure pulses from a customized device. The resultant endothelial cell injury 2 h following stretch was determined by measuring lactate dehydrogenase in the culture media. Significant stretch-dependent increases in endothelial injury were elicited that depended in a nonlinear fashion on the degree of membrane displacement. Depletion of intracellular glutathione with buthionine sulfoximine (1 mM) increased the extent of traumatic endothelial cell injury by 17-56%, particularly at low to moderate levels of traumatic injury (30-40% of total endothelial cell LDH release). Conversely, traumatic injury was reduced by 22-45% when endothelial cell glutathione levels were augmented threefold (to 140+/-8 nmol/mg protein) by preincubating cells with 2 mM glutathione; the extent of protection was inversely proportional to the extent of the traumatic stretch. Traumatic endothelial cell injury was also significantly and dose-dependently attenuated (up to 40%) by treatment with the xanthine oxidase inhibitor oxypurinol (50 and 100 microM). These results demonstrate that cerebral endothelial cells are the targets of hydrogen peroxide-mediated injury secondary to trauma-induced superoxide radical formation via the xanthine oxidase pathway. The neutralization of peroxides by the endogenous glutathione redox cycle provides endothelial cells a finite capacity to reduce free radical-mediated traumatic injury; this cycle may be amenable to therapeutic manipulation to mitigate posttraumatic edema and other manifestations of vascular dysfunction.

Cerebral protection by hypoxic preconditioning in a murine model of focal ischemia-reperfusion.

Sublethal periods of hypoxia or ischemia can induce adaptive mechanisms to protect against subsequent lethal ischemic insults in a process known as ischemic preconditioning. In the present study, we developed a murine model of cerebral preconditioning using several common strains of adult mice. Animals were exposed to sublethal hypoxia (11% oxygen for 2 h) 48 h prior to a 90 min period of transient focal middle cerebral artery occlusion, induced by an intraluminal filament; injury was assessed 24 h later by TTC staining. Infarct volume in hypoxia-preconditioned animals was reduced 46%, 58%, and 64% in C57Bl/6, 129SvEv, and Swiss-Webster ND4 mice relative to their respective untreated controls. This non-invasive murine model of ischemic tolerance should be useful for elucidating the molecular basis of this protection using transgenic and knockout mice.

Neurochemical and morphological responses to acutely and chronically implanted brain microdialysis probes.

The purpose of this study was to compare, in rats, brain microdialysis results obtained using microdialysis probes implanted acutely for 2 h versus probes implanted chronically for 24 h in the caudate. Specific comparisons included: (1) dialysate purine and amino acid profiles during cerebral ischemia; (2) diffusional characteristics of the microdialysis probe; and (3) tissue morphology surrounding the probe. During ischemia, the increase in dialysate levels of adenosine, inosine, and hypoxanthine was less pronounced from probes implanted chronically, while dialysate xanthine levels increased to a greater extent. An increase in dialysate amino acid neurotransmitters during cerebral ischemia was observed in the acutely implanted probes within 10 min of the onset of cerebral ischemia; in the chronically implanted probes this increase did not occur until after 50 min of severe ischemia. Both in vitro and in vivo tests revealed a diffusional barrier in chronically implanted probes. Moreover, the tissue surrounding chronically implanted probes exhibited a high degree of inflammation, and fibrin deposits were substantial. In addition, uric acid levels (an indicator of tissue injury) sampled from chronically implanted probes were 7-fold greater than levels sampled from acutely implanted probes. These data raise concerns about the use of chronically implanted microdialysis probes for the measurement of purine and amino acid profiles during cerebral ischemia.

Enhancing adenosine A1 receptor binding reduces hypoxic-ischemic brain injury in newborn rats.

Hypoxia increases brain adenosine concentrations, which provides neuroprotection through activation of central adenosine A1 receptors. This study was carried out to determine whether PD 81,273, which increases adenosine's binding to A1 receptors, would reduce hypoxia-induced brain injury. PD 81,273 (3 mg/kg, i.p.) decreased by about 50% the weight loss of the left cerebral hemisphere caused by hypoxia-ischemia in neonatal rats. Thus, enhancing adenosine's binding to the A1 receptor decreases hypoxic brain damage.

Adenosine transport inhibition ameliorates postischemic hypoperfusion in pigs.

Cerebral ischemia is often followed by a period of delayed hypoperfusion that may contribute to tissue injury. We tested the hypothesis that augmentation of interstitial adenosine can improve tissue perfusion under this condition 10 min global ischemia was produced in two groups of isoflurane-anesthetized newborn pigs by occlusion of subclavian and brachiocephalic arteries, and changes in local cortical blood flow and cortical interstitial purine metabolites were measured using the combined hydrogen clearance-microdialysis technique. In one group, the dialysis probe was perfused with artificial cerebrospinal fluid buffer containing nitrobenzyl-thioinosine (NBT1, 100 mumol/l), a competitive inhibitor of adenosine transport. In the untreated group (n = 9), baseline cortical blood flow (39 +/- 3 ml/min/100 g) was depressed by 51 +/- 5% and 42 +/- 6% at 40 and 60 min, respectively, of postischemic reperfusion. NBTI increased baseline interstitial adenosine levels 2.4-fold which increased baseline cortical blood flow 1.5-fold to 60 +/- 4 ml/min/100 g, and increased both absolute adenosine levels as well as adenosine as a percentage of total purine metabolites throughout ischemia and reperfusion. As a result, the extent of postischemic hypoperfusion was significantly lessened in NBTI-treated animals (n = 9), with reductions in cortical blood flow of only 28 +/- 3% and 24 +/- 5% at 40 and 60 min of reperfusion, respectively. These results indicate that inhibition of adenosine transport by NBTI elevates interstitial adenosine concentration during and following cerebral ischemia, and concomitantly improves cortical perfusion in the post-ischemic period. The latter effect may contribute to the documented neuroprotective efficacy of adenosinergic therapy in cerebral ischemia.

Xanthine oxidase-derived superoxide causes reoxygenation injury of ischemic cerebral endothelial cells.

Oxygen free radicals, generated by cerebral ischemia, have been widely implicated in the damage of vascular endothelium. Endothelial cells have been proposed as a significant source of oxygen free radicals. In the present study, we developed an anoxia-reoxygenation (AX/RO) model using pure cultures of cerebral endothelial cells (CECs) isolated from piglet cortex to measure CEC oxygen free radical production and determine its role in AX/RO-induced CEC injury. CEC injury, as measured by lactate dehydrogenase efflux into the culture medium, increased progressively with the duration of anoxic exposure, becoming significant after 10 h. Reoxygenation significantly increased CEC anoxic injury in a time-dependent manner. A 55% increase in oxygen free radical production, determined by fluorescence detection of dihydroethidium oxidation, was measured at the end of 4-h reoxygenation in CECs subjected to AX/RO conditions that killed 40% of the cells. Blockade of oxygen free radical production with superoxide dismutase (SOD; 250 and 1000 U/ml) or oxypurinol (50 and 200 microM), a potent xanthine oxidase inhibitor, reduced this injury by 32-36% and 30-39%, respectively. Results from our in vitro model indicate that CECs produce significant amounts of oxygen free radicals following ischemia, primarily from the xanthine oxidase pathway. These radicals ultimately have a cytotoxic effect on the very cells that produced them. Thus, reductions in oxygen free radical-mediated vascular injury may contribute to improvements in neurophysiologic outcome following treatment with oxygen free radical inhibitors and scavengers.

Local cerebral blood flow response to locally infused 2-chloroadenosine during hypotension in piglets.

Brain interstitial adenosine increases during hypotension in piglets. If adenosine is to participate in the regulation of neonatal cerebral blood flow (CBF) during hypotension, it must retain its vasodilatory action under that condition. To examine this issue, we studied the effects of locally infused 2-chloroadenosine (2-CADO), a stable adenosine analog, on local CBF in the piglet frontal cortex during normotension and graded hemorrhagic hypotension. We used the modified brain microdialysis/hydrogen clearance technique to simultaneously infuse 2-CADO into the frontal cortex and measure local CBF from the same area. When 2-CADO from 10(-8) M to 10(-3) M was infused under control conditions (n = 7), CBF increased 61% at 10(-5) M, 167% at 10(-4) M, and 210% at 10(-3) M. In hypotension experiments, local infusion of 10(-5) M 2-CADO (n = 8) caused significant increases in CBF (P less than 0.05) under control conditions (MABP = 65 mmHg) and at hypotensive blood pressures of 55 mmHg and 44 mmHg, respectively. At a blood pressure of 33 mmHg, however, infusion of the analog failed to increase CBF. Local infusion of 10(-3) M 2-CADO also produced a similar change in CBF during graded hypotension. These results indicate that 2-CADO dilates intracerebral vessels during normotension, and mild and moderate hypotension, and support the hypothesis that endogenous adenosine mediates autoregulatory adjustments of CBF during hypotension in newborn piglets.