A new model of oxidative stress in rat pups.

BACKGROUND: With current evidence, no specific oxygen concentration can yet be recommended in the resuscitation of the depressed term neonate. OBJECTIVES: To design a neonatal rat model of resuscitation that mimics birth hypoxia and allows the study of the effects of resuscitation on outcome. METHODS: Several key determinants were established utilizing P12 Sprague-Dawley rat pups. These include the ventilatory settings necessary to maintain normocarbic conditions and the amount and duration of hypoxia required to cause significant disruption of oxidative metabolism in the subjects' brains. Biochemical and cellular markers of oxidative injury were then compared in response to normoxic versus hyperoxic resuscitation. RESULTS: Oxidative stress is produced in 12-day-old intubated rat pups with 15 min of 5% oxygen followed by 30 min of 100% oxygen or room air. Oxidized glutathione levels increased immediately after hypoxia and resuscitation then returned to control values at 24 h regardless of the resuscitate. Reduced glutathione levels were, however, significantly decreased 24 h after resuscitation with pure oxygen compared with the room air-resuscitated group (391 +/- 35 vs. 508 +/- 71 nmol/ml; p = 0.037). Stress from either resuscitate did not translate into evidence of oxidative modification detected by immunocytochemistry at 30 days. CONCLUSIONS: We have demonstrated the ability to ventilate, create hypoxic stress, and resuscitate neonatal rats. While resuscitation with 21 or 100% oxygen results in a transient increase in oxidative glutathione levels, the oxygen-resuscitated group alone demonstrated a reduction in reduced glutathione 24 h later. Furthermore, these pups can then be returned to their dams for rearing, allowing ongoing evaluation of long-term effects of hypoxia and various modes of resuscitation.

Neuroprotection in diet-induced ketotic rat brain after focal ischemia.

Neuroprotective properties of ketosis may be related to the upregulation of hypoxia inducible factor (HIF)-1alpha, a primary constituent associated with hypoxic angiogenesis and a regulator of neuroprotective responses. The rationale that the utilization of ketones by the brain results in elevation of intracellular succinate, a known inhibitor of prolyl hydroxylase (the enzyme responsible for the degradation of HIF-1alpha) was deemed as a potential mechanism of ketosis on the upregulation of HIF-1alpha. The neuroprotective effect of diet-induced ketosis (3 weeks of feeding a ketogenic diet), as pretreatment, on infarct volume, after reversible middle cerebral artery occlusion (MCAO), and the upregulation of HIF-1alpha were investigated. The effect of beta-hydroxybutyrate (BHB), as a pretreatment, via intraventricular infusion (4 days of infusion before stroke) was also investigated following MCAO. Levels of HIF-1alpha and Bcl-2 (anti-apoptotic protein) proteins and succinate content were measured. A 55% or 70% reduction in infarct volume was observed with BHB infusion or diet-induced ketosis, respectively. The levels of HIF-1alpha and Bcl-2 proteins increased threefold with diet-induced ketosis; BHB infusions also resulted in increases in these proteins. As hypothesized, succinate content increased by 55% with diet-induced ketosis and fourfold with BHB infusion. In conclusion, the biochemical link between ketosis and the stabilization of HIF-1alpha is through the elevation of succinate, and both HIF-1alpha stabilization and Bcl-2 upregulation play a role in ketone-induced neuroprotection in the brain.

Biochemical methods to assess the coupling of brain energy metabolism in control and disease states.

Mitochondrial dysfunction has been increasingly shown as a critical process that makes certain areas of the brain more susceptible not only to neurological disease but also to aging. Quantitative histochemistry is a series of procedures for measuring select metabolites in discrete regions of the brain, as they exist in vivo. The development of this method has been useful in establishing energy imbalance following ischemia but more recently has become useful in studying those processes related to the mitochondria which make the brain more susceptible to a variety of neurological insults. The relatively inexpensive cost to assay a given brain metabolite makes this methodology useful in the interpretation of molecular and biochemical responses in terms of the condition of the tissue following a neurological insult.

Regional metabolic status of the E-18 rat fetal brain following transient hypoxia/ischemia.

Increasing evidence indicates that fetal metabolic stress may result in a variety of post-natal perturbations during brain development. The goal of the study was to determine the duration of hypoxia/ischemia that would elicit a demonstrable regional depression of metabolism in the fetal brain and further to examine several end-points to determine if the metabolic stress affects the developing brain. The uterine artery and uterine branch of the ovarian artery were occluded with aneurysm clamps for a period of 45 min, the clips removed and the metabolites in five regions of the perinatal brain were measured at 0, 2 and 6 h of reflow. Regional P-creatine, ATP and glucose levels were significantly depleted at the end of the 45 min occlusion. The levels of glycogen and glutamate at the end of the occlusion indicated a decreasing trend which was not significant. The concentration of citrate remained essentially unchanged at the end of the occlusion. To ensure that the insult was not lethal to the tissue, the recovery of the metabolites was examined at 2 and 6 h of reflow and generally the concentrations of the high-energy phosphates and glucose were normal or near-normal by 6 h of reperfusion in the five regions of the brain examined. The changes in the metabolites indicate that 45 min of hypoxia/ischemia is an appropriate model for studying neonatal development after fetal metabolic stress.

Adenosine treatment delays postischemic hippocampal CA1 loss after cardiac arrest and resuscitation in rats.

Resuscitation from cardiac arrest results in reperfusion injury that leads to increased postresuscitation mortality and delayed neuronal death. One of the many consequences of resuscitation from cardiac arrest is a derangement of energy metabolism and the loss of adenylates, impairing the tissue's ability to regain proper energy balance. In this study, we investigated the effects of adenosine (ADO) on the recovery of the brain from 12 min of ischemia using a rat model of cardiac arrest and resuscitation. Compared to the untreated group, treatment with adenosine (7.2 mg/kg) initiated immediately after resuscitation increased the proportion of rats surviving to 4 days and significantly delayed hippocampal CA1 neuronal loss. Brain blood flow was increased significantly in the adenosine-treated rats 1 h after cardiac arrest and resuscitation. Adenosine-treated rats exhibited less edema in cortex, brainstem and hippocampus during the first 48 h of recovery. Adenosine treatment significantly lowered brain temperature during recovery, and a part of the neuroprotective effects of adenosine treatment could be ascribed to adenosine-induced hypothermia. With this dose, adenosine may have a delayed transient effect on the restoration of the adenylate pool (AXP = ATP + ADP + AMP) 24 h after cardiac arrest and resuscitation. Our findings suggested that improved postischemic brain blood flow and ADO-induced hypothermia, rather than adenylate supplementation, may be the two major contributors to the neuroprotective effects of adenosine following cardiac arrest and resuscitation. Although adenosine did not prevent eventual CA1 neuronal loss in the long term, it did delay neuronal loss and promoted long-term survival. Thus, adenosine or specific agonists of adenosine receptors should be evaluated as adjuncts to broaden the window of opportunity in the treatment of the reperfusion injury following cardiac arrest and resuscitation.

Neuronal migration is transiently delayed by prenatal exposure to intermittent hypoxia.

BACKGROUND: Neonatal neurodevelopment is influenced by a variety of external factors, although the mechanisms responsible are poorly understood. Prenatal hypoxia, from physiological or chemical sources, can have no discernible effect, or can result in a broad spectrum of abnormalities. METHODS: To mimic some of the maternal effects of smoking, we developed a model that investigates the effects of intermittent hypoxia (IH), with or without concurrent nicotine in timed pregnant Sprague-Dawley rats. RESULTS: We found no significant differences between litter sizes or birthweight of pups from any treatment group, but animals exposed to IH (with or without nicotine) showed long term diminished body weights. Animals subjected to IH consistently showed a transient delay in neuronal migration early in the postpartum period, which was amplified by concurrent nicotine administration. We observed increased c-Abl protein levels in animals from the IH treatment groups. Multiple proteins involved in the intricate control of neuronal migration were also altered in response to this treatment, primarily the downstream targets of c-Abl: Cdk5, p25, and the cytoskeletal elements neurofilament H and F-actin and catalase. Catalase activity and protein levels, already elevated in response to IH, were further amplified by simultaneous nicotine exposure. CONCLUSIONS: This new model provides a novel system for investigating the effects of low grade IH in the developing brain and suggests that concurrent nicotine further aggravates many of the deleterious effects of IH.

Pc 4 photodynamic therapy of U87-derived human glioma in the nude rat.

BACKGROUND AND OBJECTIVES: As a potential therapy for malignant glioma, we tested the phthalocyanine photosensitizer Pc 4 for: (1) rapid clearance from the vasculature, (2) specificity for glioma, and (3) tumoricidal photosensitizing capability. STUDY DESIGN/MATERIALS AND METHODS: Parenchymal injection of U87 cells into athymic rat brains (N = 100) was followed after 12 days by tail vein injection of 0.5 mg/kg Pc 4. After 1 day, the tumor was illuminated with either 5 (N = 11) or 30 (N = 16) J/cm(2) red light at 672 nm. Sacrifice was 1 day later. The brains from these 27 animals underwent H&E (necrosis) and TUNEL assay (apoptosis) histology. Pc 4 concentration of explanted brains and tumors (N = 16), and all blood samples (N = 52) were determined by HPLC-MS 1 day post Pc 4 administration. RESULTS: Tumor-specific apoptosis was almost uniformly seen; however, necrosis was found mostly in the high-light-dose group. Pc 4 concentration in bulk tumor averaged 3.8 times greater than in normal brain. CONCLUSIONS: These results warrant expanding this pre-clinical study to seek effective baseline Pc 4 drug- and light-doses and infusion-to-photoirradiation timing that would be necessary for a Pc 4-mediated PDT clinical trial for glioma patients.

Adaptation to chronic hypoxia during diet-induced ketosis.

It is recognized that brain oxygen deprivation results in increased glycolysis and lactate accumulation. Moreover, glucose metabolism is altered during starvation or diet, resulting in increased plasma ketones (acetoacetate + beta-hydroxybutyrate; BHB). We investigated glucose and lactate adaptation to hypoxia in concurrence with diet-induced ketosis. Male Wistar rats were fed standard (STD), ketogenic (high fat; KG), or carbohydrate-rich (low fat; CHO) diets for 3 wks and then exposed to hypobaric (0.5 ATM) or normobaric atmosphere for 3 wks while on their diets. Lactate, ketones, and glucose concentrations were measured in plasma (mM) and brain tissue (mmol/g). Plasma and tissue ketone levels were elevated up to 12-fold in the KG fed groups compared with other groups (STD and CHO), with the hypoxic KG group reaching the highest levels (2.6 +/- 1.3 mM and 0.3 +/- 0.1 mmol/g; mean +/- SD). Tissue lactate levels in the hypoxic ketotic rats (4.7 +/- 1.3 mM) were comparable with normoxic STD (5.0 +/- 0.7 mM) and significantly lower (ANOVA P < .05) than the hypoxic STD rats (6.1 +/- 1.0 mM). These data indicate that adaptation to hypoxia did not interfere with ketosis, and that ketosis during hypoxia may lower lactate levels in brain, suggesting decreased glycolysis or increased glucose disposal.

Comparison of glucose influx and blood flow in retina and brain of diabetic rats.

Diabetes is associated with extensive microvascular pathology and decreased expression of the glucose transporter (GLUT-1) in retina, but not brain. To explore the basis of these differences, the authors simultaneously measured glucose influx (micromol x g(-1) x min(-1)) and blood flow (mL x g(-1) x min(-1)) in retina and brain cortex of nondiabetic control rats (normoglycemic and acute-hyperglycemic) and in rats with streptozotocin-induced diabetes (with or without aminoguanidine (AMG) treatment) using a single-pass, dual-label indicator method. In addition, tissue glucose and adenosine triphosphate (nmol/mg dry weight) levels were measured. Glucose influx in retina exceeded that of cortex by about threefold for both the nondiabetic and diabetic groups. In contrast, blood flow in retina was significantly lower than in cortex by about threefold for each group. Retinal and cortical glucose influx in the diabetic rats was lower than in the nondiabetic acute-hyperglycemic group, but not in the normoglycemic group. Blood flow in these tissues remained relatively unchanged with glycemic conditions. The glucose levels in the diabetic retina (aminoguanidine untreated and aminoguanidine treated) were fourfold to sixfold greater than the nondiabetic retina. The cortical glucose levels remained unchanged in all groups. These data suggest that the accumulation of glucose in the diabetic retina cannot be explained by increased endothelial-glucose uptake or increased vascular membrane permeability.

Compromised metabolic recovery following spontaneous spreading depression in the penumbra.

Spreading depression (SD) has been demonstrated following focal ischemia, and the additional workload imposed by SD on a tissue already compromised by a marked reduction in blood flow may contribute to the evolution of irreversible damage in the ischemic penumbra. SD was elicited in one group of rats by injecting KCl directly into a frontal craniectomy and the wave of depolarization was recorded in two craniectomies 3 and 6 mm posterior to the first one. In a second group, the middle cerebral artery was occluded using the monofilament technique and a recording electrode was placed 5 mm lateral to the midline and 0.2 mm posterior to bregma. To determine the metabolic response in the penumbral region of the cortex ipsilateral to the occlusion, brains from both groups were frozen in situ when the deflection of the SD was maximal. The spatial metabolic response of SD in the ischemic cortex was compared to that in the non-ischemic cortex. Coronal sections of the brains were lyophilized, pieces of the dorsolateral cortex were dissected and weighed, and analyzed for ATP, P-creatine, inorganic phosphate (Pi), glucose, glycogen and lactate at varying distances anterior and posterior to the recording electrode. ATP and P-creatine levels were significantly decreased at the wavefront in both groups and the levels recovered after passage of the wavefront in the normal brain, but not in the ischemic brain. Glucose and glycogen levels were significantly decreased and lactate levels significantly increased in the tissue after the passage of the wavefront. While the changes in the glucose-related metabolites persisted during recovery even in anterior portions of the cortex in both groups in the aftermath of the SD, the magnitude of the changes was greater in the penumbra than in the normal cortex. SD appears to impose an equivalent increase in energy demands in control and ischemic brain, but the ability of the penumbra to recover from the insult is compromised. Thus, increasing the energy imbalance in the penumbra after multiple SDs may hasten the deterioration of the energy status of the tissue and eventually contribute to terminal depolarization and cell death, particularly in the penumbra.

Changing metabolic and energy profiles in fetal, neonatal, and adult rat brain.

The regional energy status and the availability of metabolic substrates during brain development are important, since a variety of fetal metabolic insults have been increasingly implicated in the evolution of neonatal brain disorders. The response of the brain to a metabolic insult is determined, in large part, by the ability to utilize the various substrates for intermediary metabolism in order to maintain energy stores within the tissue. To ascertain if metabolic conditions of the fetal brain make it more or less vulnerable to a stress, the high-energy phosphates and glucose-related compounds were examined in five regions of the embryonic day 18 (E-18) fetal brain. Glucose and glycogen levels in the E-18 fetal brain were generally higher in the cerebellum and its neuroepithelium than in the hippocampus, cerebral cortex, and its neuroepithelium. Regional lactate and high-energy phosphate concentrations were essentially the same in the five regions. Subsequently, the metabolic profile was examined in the cerebral cortex and striatum from E-18, postpartum day 7 (P-7) and adult rats. At the various stages of development, there were only minimal differences in the high-energy phosphate levels in the striatum and cortex. Glucose levels, the primary substrate in the adult brain, were essentially unchanged throughout development. In contrast, lactate was significantly elevated by 6- and 2-fold over those in the adult brain in the E-18 and P-7 striatum and cortex, respectively. Another alternative substrate, beta-hydroxybutyrate, was also significantly elevated at E-18 and increased more than 2-fold at P-7, but was barely detectable in the adult cortex and striatum. Finally, glucose and lactate levels were examined in cerebrospinal fluid, blood, and brain from the E-18 brain to determine if a gradient among the compartments exists. The levels of both lactate and glucose exhibited a concentration gradient in the E-18 fetus: blood > cerebrospinal fluid > brain parenchyma. The results indicate that energy state in the fetal brain is comparable to that in the neonates and the adults, but that the availability of alternative substrates for intermediary metabolism change markedly with development. The age-dependent substrate specificity for intermediary metabolism could affect the response of the fetal brain to a metabolic insult.

Activation of caspase-12, an endoplasmic reticulum resident caspase, after permanent focal ischemia in rat.

The endoplasmic reticulum (ER) is emerging as a contributory component of cell death after ischemia. Since caspase-12 has been localized to the ER and is a novel signal for apoptosis, we examined the message levels and protein expression of caspase-12 after cerebral ischemia in vivo. Animals underwent permanent middle cerebral artery occlusion (MCAO) and were sacrificed 24 h after ischemia. Protein analysis revealed a significant increase in caspase-12 and a corresponding up-regulation of caspase-12 mRNA in the ischemia group compared with that in the sham group. Immunohistochemical analysis revealed diffuse positive immunostaining of caspase-12 throughout the striatum and cerebral cortex in animals that underwent ischemia, with more intense caspase-12 immunostaining in the striatum than in the cortex after ischemia. These results demonstrate that cerebral ischemia initiates an ER-based stress response that results in the transcriptional up-regulation and corresponding increased expression of caspase-12 protein, and may provide a new area for therapeutic intervention to ameliorate outcomes following stroke.

Caspase-9 inhibition after focal cerebral ischemia improves outcome following reversible focal ischemia.

Cerebral ischemia initiates a program of cell death known as apoptosis. Early steps in these death promoting events are the release of cytochrome c from the mitochondria and activation of caspase-9. The purpose of this report is to determine if the administration of a specific caspase-9 inhibitor, Z-Leu-Glu(Ome)-His-Asp(Ome)-FMK x TFA (Z-LEHD-FMK) would attenuate apoptosis and the resultant brain injury after ischemia. Adult Wistar rats underwent 3 h of temporary middle cerebral artery occlusion (MCAO) followed by 24 h of reperfusion. An intraventricular injection of 4.8 microg of Z-LEHD-FMK was given 15-min postreperfusion. Administration of the caspase-9 inhibitor, Z-LEHD-FMK, to the experimental group (n = 12) reduced total infarction volume by 49% (p < 0.05) and improved neurological outcome by 63% (p < 0.01) as compared to the control group (n = 12). Western blot analysis of animals that underwent ischemia-reperfusion showed the appearance of the active form of caspase-9. Inhibition of caspase-9, the apical caspase in cytochrome-c-dependent apoptosis, is an effective intervention to attenuate neurological injury after focal ischemia.

Delayed changes in regional brain energy metabolism following cerebral concussion in rats.

Traumatic brain injury (TBI) results in an acute altered metabolic profile of brain tissue which resolves within hours of initial insult and yet some of the functional deficits and cellular perturbations persist for days. It is hypothesized that a delayed change in energy status does occur and is a factor in the neural tissue's ability to survive and regain function. Regional metabolic profile and glucose consumption were determined at either 1 or 3 days following two different intensities of parasagittal fluid-percussion (F-P). A significant decrease in both 1CMRgluc and levels of ATP and P-creatine was evident in the hemisphere ipsilateral to the trauma at 1 day after the insult. The effect was greater in the cortical than the subcortical regions and was more pronounced at the higher trauma intensity. Normalization of glucose consumption and energy levels was essentially complete by 3 days. It would appear that the delayed metabolic changes at 1 day postinsult cannot be explained by a secondary ischemia since the changes in the metabolite profile do not elicit an increase in the consumption of glucose. These changes in energy metabolites may account for and contribute to the chronic neurological deficits following TBI.

Alterations in matrix metalloproteinase-9 levels and tissue inhibitor of matrix metalloproteinases-1 expression in a transforming growth factor-beta transgenic model of hydrocephalus.

The development of spontaneous hydrocephalus in mouse models resulting from the overexpression of transforming growth factor-beta (TGFbeta-1) has been previously described, although the mechanism by which this occurs remains obscure. It has been previously demonstrated that increased expression of TGFbeta has consequences for the levels of matrix metalloproteinases (MMPs) and their specific inhibitors (tissue inhibitors of MMPs, or TIMPs). These remodeling proteins play an important role in extracellular matrix (ECM) maintenance through degradation and deposition of ECM components. The present study investigated the relationship between elevated levels of TGFbeta-1, the ECM modulators TIMP-1 and MMP-9, and development of hydrocephalus in the neonatal mouse. In newborn pups, TIMP-1 mRNA levels were equal between animals expressing the TGFbeta-1 transgene and littermates without the transgene. However, immunohistochemistry of littermate pups shows that the distribution of TIMP-1 was changed from homogeneous with large punctate concentrations of signal to uniform, dense staining in hydrocephalic animals carrying the TGFbeta-1 transgene. The mRNA levels of MMP-9 were decreased in the transgenic animals, as were the activity levels MMP-9. These results suggest that the remodeling protein MMP-9 and its specific inhibitor, TIMP-1, may contribute to the spontaneous development of hydrocephalus in this transgenic model by altering the ECM environment.

Ischemic cell death: dynamics of delayed secondary energy failure during reperfusion following focal ischemia.

Reperfusion injury is believed to contribute to the pathophysiology of ischemic cell death, but the precipitating factors have yet to be completely elucidated. The goal of this study was to examine if reflow-induced secondary energy failure is a component in the events that lead to cell death following increasing periods of middle cerebral artery (MCA) occlusion in Wistar rats. Discrete sections within the MCA distribution were dissected and analyzed for high-energy phosphates and glucose. Regional cerebral blood flow was determined by [14C]-iodoantipyrine technique in representative groups. The levels of ATP + P-creatine were initially depressed at the end of the focal ischemia and the concentrations in the penumbra were unchanged for up to 8 h after 2 h of ischemia which contrasts with response in the ischemic core, striatum, and penumbra where the HEP generally recovered to values near those of control only to decrease with increasing periods of reflow. The possibility of a rebound ischemia in secondary energy failure (SEF) was precluded by regional CBF values and concentrations of glucose that were significantly higher than the threshold for an ischemic effect. The depletion of cellular energy stores following SEF strongly indicates that the evolution of infarct during reflow results from loss of ATP and its synthesis.