Effects of moderate hyperglycemia on the temporal profile of brain tissue intracellular pH and [Mg2+] after global cerebral ischemia in rats.

In an attempt to understand the mechanisms by which preischemic plasma glucose (pg) worsens neurologic and neuropathologic outcomes, we investigated the effect of moderate preischemic hyperglycemia (200 mg/dl < mean plasma glucose < 360 mg/dl) on postischemic energy metabolism, tissue intracellular pH (pHi) and tissue free intracellular pMg (= -log[Mg2+]) over a one week period after transient global cerebral ischemia in the rat. In vivo 31P nuclear magnetic resonance spectroscopy was performed prior to and daily up to 1 week (wk) in rats after 12 min of forebrain ischemia, induced by bicarotid occlusion concurrent with systemic hypotension. Preischemic plasma glucose significantly affected 1 wk postischemic survival (p = 0.05, Fisher's exact test). The temporal profile of the brain tissue pHi was significantly different (p < 0.03) between the moderate hyperglycemic (H-1wk, n = 7, mean pg = 266.0 +/- 47.3 mg/dl) and the normoglycemic (N-1wk, n = 8, mean pg = 91.2 +/- 23.7 mg/dl) ischemic animals over 1 wk. Postischemic tissue alkalosis was measured at 24 (p = < 0.006) and 48h (p = 0.001) postischemia in the N-1wk group. A single marginally significant (p = 0.011) mean pHi upshift was measured at 72h postischemia in the H-1wk group. The mean change in pHi at 24h postischemia from the baseline values in moderate hyperglycemic animals that survived only 48h after ischemia (H-48h, n = 6, mean pg = 298.8 +/- 70.1 mg/dl) was significantly lower (p = 0.02) than that of the N-1wk ischemic animals.(ABSTRACT TRUNCATED AT 250 WORDS)

Acute elevation and recovery of intracellular [Mg2+] following human focal cerebral ischemia.

We used 31P magnetic resonance spectroscopy (MRS) to investigate changes in brain intracellular [Mg2+] following human focal cerebral ischemia. Mean brain pMg (where pMg = -log[Mg2+]) was significantly lower in the ischemic focus of all stroke patients (pMg = 3.34 +/- 0.28, n = 45, p < 0.01) when compared with normal controls (pMg = 3.50 +/- 0.08, n = 25). Ischemic brain pMg was also significantly reduced when the pH of the stroke region was acidotic (pH < 6.90, pMg = 3.07 +/- 0.44, n = 11, p < 0.01) and when the phosphocreatine index (PCrI = PCr/[PCr+Pi (inorganic phosphate)]) was reduced (PCrI < 0.47, pMg = 3.12 +/- 0.42, n = 13, p < 0.01). Mean brain pMg was significantly reduced at days 0 to 1 (acute) poststroke (pMg = 3.32 +/- 0.28, n = 26, p < 0.01) and at days 2 to 3 (subacute) poststroke (pMg = 3.38 +/- 0.28, n = 21, p = 0.03). There was also a significant (p < 0.01) correlation between decreased pMg and increased relative signal intensity of Pi (normalized by total phosphate signal, Pi/TP) for all stroke groups studied. During the temporal evolution of stroke, pH returned to normal levels by days 2 to 3, and pMg returned to normal by days 4 to 10 (subacute). PCrI and Pi/TP returned toward normal levels after 10 days (chronic), at a time when ischemic brain pH had become significantly alkalotic (pH = 7.10 +/- 0.24, n = 15, p < 0.01). Elevation of ischemic brain [Mg2+] is temporally linked to the acidotic phase of human stroke as well as the breakdown of energy metabolism. These acute changes in [Mg2+] may contribute to, or be a marker for, cellular injury.

Post-ischemic brain tissue alkalosis suppressed by U74006F.

We monitored chronically (for 1 week) the effect of the 21-aminosteroid U74006F, a potent lipid peroxidation inhibitor, on the pH profile of the rat brain following transient forebrain ischemia. Eight rats were treated initially with 3 mg/kg i.v. of U74006F 1 min after reperfusion. A second dose of 1.5 mg/kg i.v. was given 60 min after reperfusion. A vehicle group (n = 9) was treated in the same manner, using the same volume of the vehicle solution, 20 mM citric acid, 3 mM sodium citrate, and 8 mM NaCl. Statistically significant interaction between group and time (P = 0.003) was detected for pH. Brain pH of the vehicle treated animals were significantly higher than the U74006F treated group at 24 h (P = 0.009) and 48 h (P = 0.009) of reperfusion. Chronic post-ischemic brain tissue alkalosis at 24 h (pH 7.22 +/- 0.12) and 48 h (pH 7.25 +/- 0.11) post-ischemia, observed among the vehicle treated animals (and untreated animals), was suppressed by treatment with U74006F. These results suggest a coupling between post-ischemic brain tissue alkalosis and free radical induced lipid peroxidation.

Human focal cerebral ischemia: evaluation of brain pH and energy metabolism with P-31 NMR spectroscopy.

The authors investigated early human focal ischemia with phosphorus-31 nuclear magnetic resonance spectroscopy at 1.89 T to characterize the temporal evolution and relationship of brain pH and phosphate energy metabolism. Data from 65 symptomatic patients were prospectively studied; none of the patients had had ischemic stroke in the internal carotid artery territory before. Twenty-eight neurologically normal individuals served as control subjects. Serial ischemic brain pH levels indicated a progression from early acidosis to subacute alkalosis. When acidosis was present there was a significant elevation in the relative signal intensity of inorganic phosphate (Pi) and significant reductions in signal intensities of alpha-adenosine triphosphate (ATP) and gamma-ATP compared with those of control subjects. Ischemic brain pH values directly correlated with the relative signal intensity of phosphocreatine (PCr) and the PCr index and inversely correlated with the signal intensity of Pi. There was a general lack of correlation between either ischemic brain pH or phosphate energy metabolism and the initial clinical stroke severity. The data suggest a link between high-energy phosphate metabolism and brain pH, especially during the period of ischemic brain acidosis, and the authors propose that effective acute stroke therapy should be instituted during this period.

Assessment of magnesium concentrations by 31P NMR in vivo.

31P NMR spectra obtained in vivo reveal the presence of a few reasonably well defined chemical species, namely, ATP, orthophosphate (Pi), and, in brain, phosphocreatine. The chemical shifts of these resonances respond to changes in concentrations of ions such as H+ and Mg2+ in a manner that depends on both the chemical shifts intrinsic to individual complexes and the formation or binding constants for the several complexes. Values of the appropriate formation constants are well established in the literature. We have derived estimates of the chemical shifts intrinsic to the individual complexes by analyzing high resolution spectra of solutions whose composition brackets the domain of physiological relevance. This provides information sufficient to estimate intracellular concentrations of H+ and Mg2+ from chemical shifts seen with in vivo spectra. The primary finding is an estimate of 0.3 mM for the concentration of free magnesium in human brain. Differing values are obtained from other tissues.

The effects of post-ischemic hypothermia on the neuronal injury and brain metabolism after forebrain ischemia in the rat.

We investigated the effect of moderate post-ischemic hypothermia on neuropathological outcome and cerebral high energy phosphate metabolism, intracellular pH and Mg2+ concentration in the rat. Three groups of animals were investigated: (1) Wistar rats subjected to 12 min of forebrain ischemia under normothermic conditions (n = 17), (2) rats subjected to the identical procedure of ischemia, except that 30 degrees C hypothermia was induced post-ischemia and maintained for 2 h of reperfusion (n = 6), and (3) control hypothermic rats not subjected to ischemia (n = 4). In vivo 31P NMR spectroscopy was performed prior to ischemia, and at intervals up to 168 h after ischemia. Histological analysis of brain tissues was performed 7 days after ischemia. No significant differences in cortical and hippocampal neuronal damage was detected between the two experimental groups. Significantly lower pH values were detected in the hypothermic ischemic animals at 24 h (P = 0.0001) and 48 h (P = 0.018) post-ischemia compared to the normothermic ischemic animals. Normothermic ischemic animals exhibited significantly lower [Mg2+] at 72 h (P less than 0.006) compared to the pre-ischemia level. Our data indicate that post-ischemic hypothermia modifies the profiles of post-ischemic brain tissue pH and Mg2+ concentration, and this modification is not associated with histopathological outcome 7 days after ischemia.

Magnetic resonance spectroscopy in cerebral ischemia.

Magnetic resonance spectroscopy (MRS) has been a fundamental and invaluable tool in the fields of chemistry and physics for over 40 years and has only been applied directly to the field of medicine in the last decade. MRS has contributed significant information on ischemic brain metabolism in the clinical patient. The potential of spectroscopy now extends to the diagnostic monitoring of metabolic change, in identifying markers of a therapeutic window, and establishing prognosis and outcome. This article presents a review of MRS studies of cerebral ischemia in clinical patients.

Chronic changes in the brain Mg2+ concentration after forebrain ischemia in the rat.

Brain Mg2+ ion concentrations, [Mg2+], were evaluated in three groups of animals subjected to either 8 minutes (n = 10), or 12 minutes (n = 10) of near-complete forebrain ischemia, or sham operation (n = 10), from their 31P NMR spectra. No significant differences were observed in [Mg2+] among sham operated animals prior to or at any time point after surgery. In the 8-min ischemia group, mean [Mg2+] were significantly lower at 48 (0.28 +/- 0.06 mM, p = 0.014) and 72 (0.29 +/- 0.07 mM, p = 0.005) hours post-ischemia when compared to their mean pre-ischemia levels (0.39 +/- 0.08 mM). [Mg2+] was restored to pre-ischemia values at 96 hours after induction of ischemia. In the 12 min ischemia group, [Mg2+] were lower at all time points post-ischemia when compared to their pre-ischemia levels. Our data shows that forebrain ischemia causes a chronic decline of cerebral Mg2+ concentration, and the observed reduction of this cation can be partially attributed to concurrent brain tissue alkalosis.

Time course of postischemic intracellular alkalosis reflects the duration of ischemia.

We investigated the long-term (up to 1 week) relationships between the duration of cerebral ischemia and postischemic energy metabolic profile, pH, and tissue edema in the rat. Ten rats each were subjected to 8 or 12 min of forebrain ischemia induced by bicarotid occlusion concurrent with systemic hypotension, and the results were compared with those of 10 sham-operated rat controls. In vivo 31P nuclear magnetic resonance spectroscopy was performed prior to ischemia and at intervals up to 168 h after ischemia. Cerebral edema (measured by specific gravity) was assessed prior to ischemia and at 24, 72, and 168 h after ischemia. The data revealed significant differences in the brain tissue pH profile over time between the ischemic groups (p less than 0.03). The 12-min ischemic animals exhibited brain tissue alkalosis (pH = 7.27 +/- 0.12) at 24 h compared with both sham (pH = 7.09 +/- 0.08) at 24 h and preischemic (pH = 7.06 +/- 0.04) pH values. The pH remained alkalotic (pH = 7.23 +/- 0.15) through the 48-h time period. In contrast, in the 8-min group, the onset of alkalosis was delayed until 48 h after ischemia (pH = 7.24 +/- 0.15), and pH remained alkalotic for only 24 h. No difference in high-energy phosphate metabolism was detected between groups. A different time dependence of tissue pH and specific gravity changes after 12 min of ischemia was detected. The present study suggests that the duration of an ischemic event marks the time of onset of brain tissue alkalosis and its duration and that cerebral edema alone cannot explain the pH changes.

Chronic cerebral intracellular alkalosis following forebrain ischemic insult in rats.

We measured cerebral intracellular pH using in vivo phosphorus-31 nuclear magnetic resonance spectroscopy during 1 week after forebrain ischemia or sham operation in eight and seven rats, respectively. Mean maximum pH was significantly higher (p less than 0.003) in the ischemic group than in the sham-operated group (7.34 +/- 0.03 and 7.19 +/- 0.02, respectively). The difference between mean maximum pH and baseline pH (7.08 +/- 0.01 in each group) was significantly greater (p less than 0.02) in the ischemic group than in the sham-operated group. In the ischemic group, alkalosis occurred primarily after 48-72 hours of recirculation. We speculate that brain tissue alkalosis occurring chronically after ischemia is associated with delayed ischemic neuronal death.