Pial arterial pressure contribution to early ischemic brain edema

Endothelin rather than 20-HETE contributes to loss of pial arteriolar dilation during focal cerebral ischemia with and without polymeric hemoglobin transfusion

Partial exchange transfusion with a cell-free hemoglobin (Hb) polymer during transient middle cerebral artery occlusion (MCAO) reduces infarct volume but fails to increase blood flow, as might be expected with the induced decrease in hematocrit. In ischemic brain, endothelin antagonists are known to produce vasodilation. In nonischemic brain, pial arterioles constrict after Hb exchange transfusion, and the constriction is blocked by an inhibitor of 20-HETE synthesis. We tested the hypothesis that a 20-HETE synthesis inhibitor and an endothelin A receptor antagonist increase pial arteriolar dilation after Hb exchange transfusion during MCAO. Pial arteriolar diameter was measured in the ischemic border region of the distal MCA border region through closed cranial windows in anesthetized rats subjected to the filament model of MCAO. During 2 h of MCAO, pial arteriolar dilation gradually subsided from 37 +/- 3 to 7 +/- 5% (+/-SE). Compared with residual dilation at 2 h of MCAO with vehicle superfusion (14 +/- 3%), loss of dilation was not prevented by superfusion of a 20-HETE synthesis inhibitor (21 +/- 5%), partial Hb exchange transfusion (7 +/- 5%) that decreased hematocrit to 23%, or a combination of the two (5 +/- 5%). However, loss of dilation was prevented by superfusion of an endothelin A receptor antagonist with (35 +/- 4%) or without (32 +/- 5%) Hb transfusion. Pial artery constriction during reperfusion was attenuated by HET0016 alone and by BQ610 with or without Hb transfusion. Systemic administration of the endothelin antagonist during prolonged MCAO increased blood flow in the border region. Thus loss of pial arteriolar dilation in the ischemic border region during prolonged MCAO depends on endothelin A receptor activation, and this effect was independent of the presence of cell-free Hb polymers in the plasma. In contrast to previous work in nonischemic brain, inhibition of oxygen-dependent 20-HETE synthesis does not significantly influence the pial arteriolar response to polymeric Hb exchange transfusion during focal ischemia.

Association of pretreatment blood pressure with tissue plasminogen activator-induced arterial recanalization in acute ischemic stroke

BACKGROUND AND PURPOSE

Elevated systolic blood pressure (SBP) and lack of early vessel recanalization are predictors of poor outcome among patients with stroke treated with systemic tissue plasminogen activator (tPA). We aimed to evaluate the potential relationship between pretreatment SBP and tPA-induced recanalization.

METHODS

Consecutive patients with acute ischemic stroke resulting from intracranial artery occlusion were treated with standard intravenous tPA and assessed with 2-MHz transcranial Doppler for arterial recanalization. Early arterial recanalization was determined with previously validated Thrombolysis in Brain Ischemia flow grading system at 120 minutes after tPA bolus. Functional outcome at 3 months was evaluated using the modified Rankin Scale.

RESULTS

A total of 351 patients received intravenous tPA (mean age: 68.7+/-13.4 years, median National Institutes of Health Stroke Scale score 16.5). Patients with complete recanalization (n=94) had lower mean pretreatment SBP values (152+/-23 mm Hg) than patients with incomplete or absent recanalization (n=257, 160+/-22 mm Hg, P=0.010). Pretreatment SBP levels were inversely associated with complete recanalization (OR per 10-mm Hg increase: 0.85; 95% CI: 0.74 to 0.98, P=0.022) after adjustment for demographics, risk factors, stroke severity, pretreatment Thrombolysis in Brain Ischemia grades, and continuous versus intermittent exposure to transcranial Doppler. Although patients with poor functional 3-month outcomes (modified Rankin Scale >2) had higher pretreatment SBP values (160+/-25 mm Hg) than functionally independent patients (154+/-20 mm Hg, P=0.027), pretreatment SBP levels were not independently associated with functional outcome on multivariable analysis. Age, complete recanalization, baseline National Institutes of Health Stroke Scale score, and time from symptom onset to tPA bolus were independent (P<0.05) predictors of 3-month outcome.

CONCLUSIONS

Higher pretreatment SBP levels are associated with poor recanalization in patients with acute stroke treated with intravenous tPA.

Impaired blood pressure increase in acute cardioembolic stroke

BACKGROUND AND PURPOSE

Studies on the prognostic significance of blood pressure (BP) increases during the acute phase of ischemic stroke give contradictory results. The aim of this study was to evaluate BP response during the acute phase in different ischemic stroke subtypes, and to assess the prognostic value, considering long-term outcome, of different BP patterns recorded.

METHODS

We included 110 ischemic stroke patients hospitalized within 6 h of the onset of symptoms. All the patients underwent 24-h monitoring on hospital admission and on day 7 after stroke. For statistical analysis the whole population was divided into cardioembolic (CE), atherothrombotic (AT) and lacunar (LAC) groups, according to TOAST (Trial of Org 10172 in Acute Stroke Treatment) criteria.

RESULTS

In both the whole population and in all subgroups systolic and diastolic BP were higher at admission than during monitoring on day 7, the lowest values being recorded in the CE subgroup. CE stroke was significantly related to lower BP (systolic and diastolic) values (P = 0.01) during the acute phase and CE patients were characterized by poorer outcome. A history of diabetes was a predictor of higher systolic and diastolic BP on the first day of monitoring; higher systolic and diastolic BP values were related to a history of hypertension and with male gender, respectively. Predictors of death by 6-months were atrial fibrillation, age and history of hypertension (P < 0.05) while higher systolic BP in the acute phase seems to represent a protective factor.

CONCLUSION

CE stroke shows a lack of BP response during the acute phase of ischemic stroke. This phenomenon is associated with a poor long-term outcome and seems not be related with cardiac co-morbidity.

Association between 24-h blood pressure monitoring variables and brain oedema in patients with hyperacute stroke

OBJECTIVE

To assess the effects of blood pressure (BP) values on oedema formation following hyperacute stroke.

DESIGN

Prospective observational study.

SETTING AND PATIENTS

Acute stroke-unit in University hospital. A total of 240 consecutive first-ever ischaemic or haemorrhagic stroke patients were recruited within 3 h of ictus. METHODS Casual and 24-h BP values were measured. Known stroke risk factors and clinical findings on admission were documented. Patients were imaged with computed tomography (CT) scan within 24 h from stroke onset and 5 days later in order to determine the presence of brain oedema. Patients who received antihypertensive medication during the BP monitoring were excluded.

RESULTS

The main outcome measure was brain oedema formation, which was present in 78 (32.5%) patients. The 24-h systolic (SBP), diastolic (DBP) and mean BP values, 24-h pulse pressure and heart rate values were significantly higher in patients with brain oedema than in the reference group (stroke patients without brain swelling). On multiple variable analysis, containing clinical, demographic and BP monitoring variables, 24-h SBP remained significantly (P = 0.019) associated with brain oedema. The odds ratio for oedema formation associated with each 10-mmHg increase in 24 h SBP was 1.25 (95% confidence intervals: 1.04-1.51). During the first 27 h after onset SBP course showed a spontaneous decline in the reference group, which was not documented in patients with brain oedema.

CONCLUSION

Elevated 24-h SBP values in the acute stroke period are associated with subsequent brain oedema formation.

Ischaemic brain oedema

Ischaemic brain oedema appears to involve two distinct processes, the relative contribution and time course of which depend on the duration and severity of ischaemia, and the presence of reperfusion. The first process involves an increase in tissue Na+ and water content accompanying increased pinocytosis and Na+, K+ ATPase activity across the endothelium. This is apparent during the early phase of infarction and before any structural damage is evident. This phenomenon is augmented by reperfusion. A second process results from a more indiscriminate and delayed BBB breakdown that is associated with infarction of both the parenchyma and the vasculature itself. Although, tissue Na+ level still seems to be the major osmotic force for oedema formation at this second stage, the extravasation of serum proteases is an additional potentially deleterious factor. The relative importance of protease action is not yet clear, however, degradation of the extracellular matrix conceivably leads to further BBB disruption and softening of the tissue, setting the stage for the most pronounced forms of brain swelling. A number of factors mediate or modulate ischaemic oedema formation, however, most current information comes from experimental models, and clinical data on this microcosmic level is lacking. Clinically significant brain oedema develops in a delayed fashion after large hemispheric strokes and is a cause of substantial mortality. Neurological signs appear to be at least as good as direct ICP measurement and neuroimaging in detecting and gauging the secondary damage produced by stroke oedema. The neuroimaging characteristics of the stroke, specifically the early involvement of greater than half of the MCA territory, are, however, highly predictive of the development of severe oedema over the subsequent hours and days. None of the available medical therapies provide substantial relief from the oedema and raised ICP, or at best, they are temporizing in most cases. Hemicraniectomy appears most promising as a method of avoiding death from brain compression, but the optimum timing and manner of patient selection are currently being investigated. All approaches to massive ischaemic brain swelling are clouded by the potential for survival with poor functional outcome. It is possible to manage blood pressure, serum osmolarity by way of selective fluid administration, and a number of other systemic factors that exaggerate brain oedema. Broad guidelines for treatment of stroke oedema can therefore be given at this time.

Induced hypertension treatment to improve cerebral ischemic injury after transient forebrain ischemia

The effect of induced hypertension treatment on cerebral ischemia is still controversial. We investigated the preferred blood pressure manipulation level and pressor agent required to reduce cerebral ischemic injury following transient forebrain ischemia induced by bilateral occlusion of the common carotid arteries in anesthetized gerbils. Following 60-min cerebral ischemia, we evaluated the preferred blood pressure manipulation level and pressor agent required to treat cerebral ischemic injury after reperfusion by examining the effects of different levels of mean arterial blood pressure (MABP), increased with phenylephrine or angiotensin II or decreased by blood withdrawal, on cerebral blood flow (CBF), survival ratio, cerebral edema, and brain energy metabolism following transient forebrain ischemia in gerbils. Mild phenylephrine-induced hypertension treatment (21+/-4 mmHg) during post-cerebral ischemia-reperfusion improved the survival ratio and reduced cerebral edema, which was also associated with an increase in local CBF and a recovery of brain energy metabolism. However, intense phenylephrine-induced hypertension, angiotensin II-induced hypertension, or hypotension worsen the survival rate and produced extra cerebral edema, that were also associated with deterioration of brain energy metabolism. These results demonstrate that a mild induced hypertension with phenylephrine (21+/-4 mmHg above the baseline level) results in reduction of the cerebral edema and improves the survival ratio and brain energy metabolism. Furthermore, angiotensin II may have neurotoxic effect to use as the pressor agent for induced hypertension after cerebral ischemia.

Early postischemic hyperperfusion: pathophysiologic insights from positron emission tomography

Early postischemic hyperperfusion (EPIH) has long been documented in animal stroke models and is the hallmark of efficient recanalization of the occluded artery with subsequent reperfusion of the tissue (although occasionally it may be seen in areas bordering the hypoperfused area during arterial occlusion). In experimental stroke, early reperfusion has been reported to both prevent infarct growth and aggravate edema formation and hemorrhage, depending on the severity and duration of prior ischemia and the efficiency of reperfusion, whereas neuronal damage with or without enlarged infarction also may result from reperfusion (so-called "reperfusion injury"). In humans, focal hyperperfusion in the subacute stage (i.e., more than 48 hours after onset) has been associated with tissue necrosis in most instances, but regarding the acute stage, its occurrence, its relations with tissue metabolism and viability, and its clinical prognostic value were poorly understood before the advent of positron emission tomography (PET), in part because of methodologic issues. By measuring both CBF and metabolism, PET is an ideal imaging modality to study the pathophysiologic mechanism of EPIH. Although only a few PET studies have been performed in the acute stage that have systematically assessed tissue and clinical outcome in relation to EPIH, they have provided important insights. In one study, about one third of the patients with first-ever middle cerebral artery (MCA) territory stroke studied within 5 to 18 hours after symptom onset exhibited EPIH. In most cases, EPIH affected large parts of the cortical MCA territory in a patchy fashion, together with abnormal vasodilation (increased cerebral blood volume), "luxury perfusion" (decreased oxygen extraction fraction), and mildly increased CMRO2, which was interpreted as postischemic rebound of cellular metabolism in structurally preserved tissue. In that study, the spontaneous outcome of the tissue exhibiting EPIH was good, with late structural imaging not showing infarction. This observation was supported by another PET study, which showed, in a few patients, that previously hypoperfused tissue that later exhibited hyperperfusion after thrombolysis did not undergo frank infarction at follow-up. In both studies, clinical outcome was excellent in all patients showing EPIH except one, but in this case the hyperperfused area coexisted with an extensive area of severe hypoperfusion and hypometabolism. These findings from human studies therefore suggest that EPIH is not detrimental for the tissue, which contradicts the experimental concept of "reperfusion injury" but is consistent with the apparent clinical benefit from thrombolysis. However, PET studies performed in the cat have shown that although hyperperfusion was associated with prolonged survival and lack of histologic infarction when following brief (30-minute) MCA occlusion, it often was associated with poor outcome and extensive infarction when associated with longer (60-minute) MCA occlusion. It is unclear whether this discrepancy with human studies reflects a shorter window for tissue survival after stroke in cats, points to the cat being more prone to reperfusion injury, or indicates that EPIH tends not to develop in humans after severe or prolonged ischemia because of a greater tendency for the no-reflow phenomenon, for example. Nevertheless, the fact that the degree of hyperperfusion in these cat studies was related to the severity of prior flow reduction suggests that hyperperfusion is not detrimental per se. Preliminary observations in temporary MCA occlusion in baboons suggest that hyperperfusion developing even after 6 hours of occlusion is mainly cortical and associated with no frank infarction, as in humans. Overall, therefore, PET studies in both humans and the experimental animal, including the baboon, suggest that hyperperfusion is not a key factor in the development of tissue infarction and that it may be a harmless phenomenon

Cardiac output in patients with acute stroke

It is well known that blood pressure is elevated during acute stroke. Despite its importance for cerebral haemodynamics, cardiac output (CO) has been determined only in individual cases during acute stroke. We measured CO and blood pressure in patients with no history of heart disease who suffered from acute stroke (n = 30) and in a control group comparable with regard to age, gender and cardiac health (n = 30). CO, blood pressure and heart rate were significantly (P < 0.01) higher in the group of stroke patients than in the control group. There was a tendency for more time to have elapsed between the onset of symptoms and measurements, the higher the CO [b = 0.08 l/min per hour (-0.01; 0.17)]. Adjusted for age in a multiple regression model, the regression coefficient was significant (CO = 10.35 +0.094 x time -0.077 x age). The present study shows for the first time that patients with a healthy cardiovascular system who suffer from acute stroke have a higher CO than a group of comparable controls.

Blood pressure during the first minutes of focal cerebral ischemia

STUDY OBJECTIVE

To determine whether blood pressure declines spontaneously during the first minutes and hours of focal cerebral ischemia.

DESIGN

Multiple blood pressure measurements as part of an urgent stroke therapy trial (treatment within 90 minutes of stroke onset).

SETTING

Thirteen hospitals in three metropolitan communities.

PARTICIPANTS

Sixty-nine patients (mean age, 65 +/- 9 years) with acute ischemic stroke who were participants in a phase I urgent stroke therapy trial of recombinant tissue plasminogen activator.

MAIN OUTCOME MEASURE

Blood pressures recorded at the scene of stroke by life-squad personnel, in the emergency department, and in the ICU.

RESULTS

The mean time from stroke onset to the time of first blood pressure measurement was 19 +/- 13 minutes. Twenty-four of the 69 patients in the urgent stroke therapy trial had an initial systolic blood pressure of at least 160 mm Hg. Of these, 23 had a significant decline in systolic and diastolic blood pressure during the first 90 minutes after the onset of stroke (mean change in systolic pressure, -29 +/- 22 mm Hg, P < .001; mean change in diastolic pressure, -10 +/- 14 mm Hg, P < .01). No patients received antihypertensive therapy during the time in which the decline in blood pressure was noted.

CONCLUSION

Mildly or moderately elevated blood pressure frequently declines spontaneously during the first minutes and hours of focal cerebral ischemia and generally does not require urgent pharmacologic treatment.

Relationship between blood flow and blood-brain barrier permeability of sodium and albumin in focal ischaemia of rats: a triple tracer autoradiographic study

Local cerebral blood flow, the permeability of the blood-brain barrier to sodium and serum albumin, and the content of electrolytes were investigated in rats before and at 4 h and 24 h following permanent occlusion of the middle cerebral artery (MCA). Measurements were carried out by triple tracer autoradiography, using 131I-iodoantipyrin, 22NaCl and 125I-iodinated bovine serum albumin, respectively. Regional sodium and albumin transfer coefficients were calculated by multiple time point analysis, and correlated with the corresponding flow and tissue electrolyte values. In sham operated controls regional sodium and albumin transfer coefficients ranged between 2.16-2.30 x 10(-3) and 0.22-0.48 x 10(-3) ml/min per g, respectively. Four hours after MCA occlusion sodium and albumin transfer coefficients were unchanged although tissue sodium content was already increased. After 24 h the sodium-but not albumin-transfer coefficient increased 2-3 fold but the rise in tissue sodium content was slower than after 4 h. At both ischaemia times the unidirectional sodium influx was substantially higher than the actual changes of tissue sodium content. The development of stroke oedema is, therefore, not limited by the alterations of barrier permeability.

Incidence of silent lacunar lesion in normal adults and its relation to cerebral blood flow and risk factors

BACKGROUND AND PURPOSE

There are few reports comparing incidence of silent lacunar lesions detected by magnetic resonance imaging and cerebral blood flow in neurologically normal adults.

METHODS

We studied the incidence of such lesions and its relation to cerebral blood flow and risk factors in 246 neurologically normal adults (145 men, mean age 62 years; 101 women, mean age 60 years) who received health screening examinations of the brain.

RESULTS

Thirty-two subjects (13%) had possible silent lacunar lesions (66% of these were recognized by both T1- and T2-weighted image). The regional cerebral blood flow measured by the xenon-133 inhalation method was significantly lower in subjects with silent lacunes than in those without (p less than 0.02). Cerebral blood flow was mildly but significantly decreased in those with silent lacunes (p less than 0.05). Periventricular hyperintensity was closely related to silent lacune (p less than 0.01). However, there was no significant difference in cerebral blood flow between subjects with and without apparent periventricular hyperintensity.

CONCLUSIONS

Silent lacunar lesion was closely related to decrease of cerebral circulation and may be an important risk factor for symptomatic cerebrovascular disease.

Time- and pressure-dependent changes in blood-brain barrier permeability after temporary middle cerebral artery occlusion in rats

After 180 min of temporary middle cerebral artery occlusion in rats, the affect of phenylephrine-induced hypertension on blood-brain barrier permeability was assessed. One of the following blood-pressure regimens was maintained during either a 30- or 120-min period of reperfusion: (a) 30/Norm, 30 min of normotensive reperfusion was allowed; (b) 30/HTN, mean arterial blood pressure was increased by 35 mm Hg during 30 min of reperfusion; (c) 120/Norm, 120 min of normotensive reperfusion was allowed; or (d) 120/HTN, mean arterial blood pressure was increased by 35 mm Hg during 120 min of reperfusion. Evans blue (30 mg/kg) was given, and brains were analyzed for Evans blue by spectrophotometry. Evans blue (microgram/g brain tissue, mean +/- SD) was greater (P less than 0.05) in both hypertensive groups versus their time matched normotensive groups (30/HTN: 80 +/- 16 versus 18 +/- 6 in the 30/Norm group; 120/HTN: 17 +/- 6 versus 8 +/- 3 in the 120/Norm group). In addition, Evans blue was greater (P less than 0.05) in both 30-min groups versus their pressure matched 120-min groups (30/Norm: 18 +/- 6 versus 8 +/- 3 in the 120/Norm group; 30/HTN: 80 +/- 16 versus 17 +/- 6 in the 120/HTN group). The data are consistent with previous studies which have demonstrated an opening of the blood-brain barrier at the onset of reperfusion. In addition, the data support a hypothesis that changes in blood-brain barrier permeability are more sensitive to hypertension in the early period of reperfusion.

Delayed institution of hypertension during focal cerebral ischemia: effect on brain edema

The effect of induced hypertension instituted after a 2-h delay following middle cerebral artery occlusion (MCAO) on brain edema formation and histochemical injury was studied. Under isoflurane anesthesia, the MCA of 14 spontaneously hypertensive rats was occluded. In the control group (n = 7), the mean arterial pressure (MAP) was not manipulated. In the hypertensive group (n = 7), the MAP was elevated by 25-30 mm Hg beginning 2 h after MCAO. Four hours after MCAO, the rats were killed and the brains harvested. The brains were sectioned along coronal planes spanning the distribution of ischemia produced by MCAO. Specific gravity (SG) was determined in the subcortex and in two sites in the cortex (core and periphery of the ischemic territory). The extent of neuronal injury was determined by 2,3,5-triphenyltetrazolium staining. In the ischemic core, there was no difference in SG in the subcortex and cortex in the two groups. In the periphery of the ischemic territory, SG in the cortex was greater (less edema accumulation) in the hypertensive group (1.041 +/- 0.001 vs 1.039 +/- 0.001, P less than 0.05). The area of histochemical injury (as a percent of the cross-sectional area of the hemisphere) was less in the hypertensive group (33 +/- 3% vs 21 +/- 2%, P less than 0.05). The data indicate that phenylephrine-induced hypertension instituted 2 h after MCAO does not aggravate edema in the ischemic core, that it improves edema in the periphery of the ischemic territory, and that it reduces the area of histochemical neuronal dysfunction.