Mannitol therapy in perinatal hypoxic-ischemic brain damage in rats

An update to the Monro-Kellie doctrine to reflect tissue compliance after severe ischemic and hemorrhagic stroke

High intracranial pressure (ICP) can impede cerebral blood flow resulting in secondary injury or death following severe stroke. Compensatory mechanisms include reduced cerebral blood and cerebrospinal fluid volumes, but these often fail to prevent raised ICP. Serendipitous observations in intracerebral hemorrhage (ICH) suggest that neurons far removed from a hematoma may shrink as an ICP compliance mechanism. Here, we sought to critically test this observation. We tracked the timing of distal tissue shrinkage (e.g. CA1) after collagenase-induced striatal ICH in rat; cell volume and density alterations (42% volume reduction, 34% density increase; p < 0.0001) were highest day one post-stroke, and rebounded over a week across brain regions. Similar effects were seen in the filament model of middle cerebral artery occlusion (22% volume reduction, 22% density increase; p ≤ 0.007), but not with the Vannucci-Rice model of hypoxic-ischemic encephalopathy (2.5% volume increase, 14% density increase; p ≥ 0.05). Concerningly, this 'tissue compliance' appears to cause sub-lethal damage, as revealed by electron microscopy after ICH. Our data challenge the long-held assumption that 'healthy' brain tissue outside the injured area maintains its volume. Given the magnitude of these effects, we posit that 'tissue compliance' is an important mechanism invoked after severe strokes.

Impairment of blood brain barrier is related with the neuroinflammation induced peripheral immune status in intracerebroventricular colchicine injected rats: An experimental study with mannitol

The neurodegeneration in AD patients may be associated with changes of peripheral immune responses. Some peripheral immune responses are altered due to neuroinflammation in colchicine induced AD (cAD) rats. The leaky blood brain barrier (BBB) in cAD-rats may be involved in inducing peripheral inflammation, though there is no report in this regard. Therefore, the present study was designed to investigate the role of BBB in cADrats by altering the BBB in a time dependent manner with injection (i.v.) of mannitol (BBB opener). The inflammatory markers in the brain and serum along with the peripheral immune responses were measured after 30 and 60min of mannitol injection in cAD rats. The results showed higher inflammatory markers in the hippocampus and serum along with alterations in peripheral immune parameters in cAD rats. Although the hippocampal inflammatory markers did not further change after mannitol injection in cAD rats, the serum inflammatory markers and peripheral immune responses were altered and these changes were greater after 60min than that of 30min of mannitol injection. The present study shows that the peripheral immune responses in cAD rats after 30 and 60min of mannitol injection are related to magnitude of impairment of BBB in these conditions. It can be concluded from this study that impairment of BBB in cAD rats is related to the changes of peripheral immune responses observed in that condition.

Optimal Route for Mesenchymal Stem Cells Transplantation after Severe Intraventricular Hemorrhage in Newborn Rats

Recently, we showed that intracerebroventricular (IC) transplantation of human umbilical cord blood (UCB)-derived mesenchymal stem cells (MSCs) significantly attenuates posthemorrhagic hydrocephalus (PHH) and brain damage after severe IVH in newborn rats. This study was performed to determine the optimal route for transplanting MSCs for severe IVH by comparing IC transplantation, intravenous (IV) transplantation, and IV transplantation plus mannitol infusion. Severe IVH was induced by injecting 100 uL of blood into each ventricle of Sprague-Dawley rats on postnatal day 4 (P4). After confirming severe IVH with brain magnetic resonance imaging (MRI) at P5, human UCB-derived MSCs were transplanted at P6 by an IC route (1×10⁵), an IV route (5×10⁵), or an IV route with mannitol infused. Follow-up brain MRIs and rotarod tests were performed. At P32, brain tissue samples were obtained for biochemical and histological analyses. Although more MSCs localized to the brain after IC than after IV delivery, both methods were equally effective in preventing PHH; attenuating impaired rotarod test; increasing the number of TUNEL-positive cells, inflammatory cytokines, and astrogliosis; and reducing corpus callosal thickness and myelin basic protein expression after severe IVH regardless of mannitol co-infusion. Despite the superior delivery efficacy with IC than with the IV route, both IC and IV transplantation of MSCs had equal therapeutic efficacy in protecting against severe IVH. These findings suggest that the less invasive IV route might be a good alternative for clinically unstable, very preterm infants that cannot tolerate a more invasive IC delivery of MSCs.

Perspectives on neonatal hypoxia/ischemia-induced edema formation

Neonatal hypoxia/ischemia (HI) is the most common cause of developmental neurological, cognitive and behavioral deficits in children, with hyperoxia (HHI) treatment being a clinical therapy for newborn resuscitation. Although cerebral edema is a common outcome after HI, the mechanisms leading to excessive fluid accumulation in the brain are poorly understood. Given the rigid nature of the bone-encased brain matter, knowledge of edema formation in the brain as a consequence of any injury, as well as the importance of water clearance mechanisms and water and ion homeostasis is important to our understanding of its detrimental effects. Knowledge of the pathological process underlying the appearance of dysfunctional outcomes after development of cerebral edema after neonatal HI in the developing brain and the molecular events triggered will allow a rational assessment of HHI therapy for neonatal HI and determine whether this treatment is beneficial or harmful to the developing infant.

Oxygen resuscitation does not ameliorate neonatal hypoxia/ischemia-induced cerebral edema

Neonatal hypoxia/ischemia (HI) is a common cause of cognitive and behavioral deficits in children with hyperoxia treatment (HHI) being the current therapy for newborn resuscitation. HI induces cerebral edema that is associated with poor neurological outcomes. Our objective was to characterize cerebral edema after HI and determine the consequences of HHI (40% or 100% O(2)). Dry weight analyses showed cerebral edema 1 to 21 days after HI in the ipsilateral cortex; and 3 to 21 days after HI in the contralateral cortex. Furthermore, HI increased blood-brain barrier (BBB) permeability 1 to 7 days after HI, leading to bilateral cortical vasogenic edema. HHI failed to prevent HI-induced increase in BBB permeability and edema development. At the molecular level, HI increased ipsilateral, but not contralateral, AQP4 cortical levels at 3 and up to 21 days after HI. HHI treatment did not further affect HI-induced changes in AQP4. In addition, we observed developmental increases of AQP4 accompanied by significant reduction in water content and increase permeability of the BBB. Our results suggest that the ipsilateral HI-induced increase in AQP4 may be beneficial and that its absence in the contralateral cortex may account for edema formation after HI. Finally, we showed that HI induced impaired motor coordination 21 days after the insult and HHI did not ameliorate this behavioral outcome. We conclude that HHI treatment is effective as a resuscitating therapy, but does not ameliorate HI-induced cerebral edema and impaired motor coordination.

Factors associated with adverse outcomes in children with diabetic ketoacidosis-related cerebral edema

OBJECTIVE

To investigate the relation between outcomes of children with diabetic ketoacidosis (DKA)-related cerebral edema and baseline clinical features and therapeutic interventions for treatment of cerebral edema.

STUDY DESIGN

All children </=18 years old with DKA and cerebral edema (n = 61) were retrospectively identified from 10 pediatric centers between 1982 and 1997. Demographic, biochemical, and therapeutic data were collected. Ordinal logistic regression analysis was used to identify factors associated with the clinical outcome (death or persistent vegetative state; mild to moderate neurological disability; or normal) after adjusting for known risk factors for the development of cerebral edema as well as the degree of neurologic depression at the time of diagnosis of cerebral edema.

RESULTS

Seventeen (28%) children died or survived in a vegetative state; 8 (13%) survived with mild to moderate neurologic disabilities; and 36 (59%) survived without sequelae. Factors associated with poor outcomes included greater neurologic depression at the time of diagnosis of cerebral edema, a high initial serum urea nitrogen concentration, and intubation with hyperventilation to a PCO (2) <22 mm Hg.

CONCLUSIONS

After adjusting for potential confounding variables and the degree of neurologic compromise at the initiation of therapy, intubation with hyperventilation is associated with adverse outcomes of DKA-related cerebral edema. Greater neurologic depression at the time of diagnosis of cerebral edema and a higher initial serum urea nitrogen concentration are also associated with poor outcome.

Molecular and biochemical mechanisms of perinatal brain injury

Hypoxic-ischemic injury to the prenatal and perinatal brain is a major contributor to morbidity and mortality to infants, often leading to mental retardation, seizures, and cerebral palsy. The susceptibility of the immature CNS to hypoxia-ischemia is largely dependent on the temporal and regional status of critical developmental processes, as well as on the regulation of cerebral blood flow and metabolism. The molecular and biochemical mechanisms of acute injury to the neonatal brain in experimental rodent and murine models of hypoxic-ischemic and ischemic injury, including disturbances of intracellular homeostasis, role of glutamate receptors, free radicals and transitional ions, as well as the modifying role of gene expression to cell death/survival will be reviewed in this chapter.

Methylprednisolone and vitamin E therapy in perinatal hypoxic-ischemic brain damage in rats

To study the efficacy of methylprednisolone/vitamin E in reducing cerebral edema and improving the ultimate neuropathological outcome in perinatal cerebral hypoxia-ischemia, 40 seven-day postnatal rats were subjected to right common carotid artery ligation followed by exposure to 8% oxygen at 37 degrees C for 3 h. The animals were divided into groups. Twenty rat pups received an intraperitoneal injection of 30 mg/kg body weight methylprednisolone and vitamin E (100 U/kg) immediately following cerebral hypoxia-ischemia. Control animals received either no therapy (n = 10) or an equivalent volume of normal saline (n = 10). After 72 h of recovery from hypoxia-ischemia, the animals were killed and their brains were examined to measure the water contents in the right and left hemispheres (29 rat pups), whereas the others were killed at 21 days for neuropathological examination. Methylprednisolone/vitamin E-treated rats had significantly less water content in the right hemisphere (87.08 +/- 0.28%, mean +/- S.E.M.) than saline-treated animals (89.07 +/- 0.37%, mean +/- S.E.M., P < 0.0001). Methylprednisolone/vitamin E significantly reduced water content in the right hemisphere of the brain. Neuropathological study was performed on nine rat pups. The brains of four methylprednisolone/vitamin E- and five saline-treated pups were examined at the end of the 21-day recovery period. Two groups of the right cerebral cortex included thinning of the cortex. Significantly less damage was seen in the methylprednisolone/vitamin E-treated pups. Our study suggests that trials of methylprednisolone/vitamin E might be effective if they are given to the mother at risk of fetal hypoxia during labor or to the hypoxic infant right after delivery in preventing hypoxic brain damage.

The concept of chemical neurotransmission--variations on the theme

The present concept of chemical neurotransmission occurring purely through synaptic transmission has dominated neurobiological thinking for about the last 40 years. According to this conventional view neurotransmitters are substances that are synthesized within the neurones, liberated into the synaptic cleft after stimulation of the nerve, and that finally elicit a biologically plausible response in the postsynaptic target cell or the nerve terminal itself. This concept undoubtedly comprises the main body of interneuronal chemical signalling. However, a large amount of evidence, obtained during the last two decades, suggests that there are a number of parallel mechanisms, which may essentially participate in neuronal signalling, or at least modulate it. Thus, the recent progress of research has provided the following compelling evidence: 1) a large variety of substances, some of them synthesized in non-neuronal cells, actually participate actively in neuronal signalling; 2) functional connections in brain are not determined by the synaptic connections only; 3) glial cells have an active and fundamental role in signal transmission; and 4) the signalling properties and mechanisms of each neurone are constantly under functional and structural regulation. The aim of this review is to present shortly some of the central concepts and/or mechanisms that have risen during the last two decades. Also the functional and/or clinical relevance of these mechanisms is addressed briefly.

Effects of the 21-amino steroid tirilazad mesylate (U-74006F) on brain damage and edema after perinatal hypoxia-ischemia in the rat

Using 7-d-old rat pups, the neuroprotective efficacy of the lipid peroxidation inhibitor tirilazad mesylate (U-74006F) was tested in a model of perinatal hypoxic-ischemic (HI) brain damage. The experimental protocol was divided into five parts: 1) pre- plus post-HI treatment or 2) only post-HI treatment with tirilazad (7.5 mg/kg intraperitoneally) or vehicle with evaluation of hemispheric weight deficit 14 d after the insult; 3) post-HI treatment with tirilazad or vehicle with histopathologic evaluation 14 d after the insult; 4) pre- plus post-HI treatment; or 5) posthypoxic treatment with tirilazad or vehicle with evaluation of brain edema 20 h after the insult. In the pre- plus post-HI treatment group, the mean left hemispheric weight deficit was 20.7% +/- 17.8 (mean +/- SD) in tirilazad-treated rats and 27.5% +/- 20.4 in vehicle-treated rats (p = 0.032). Corresponding values for the post-HI treated animals were 19.6% +/- 16.0 and 28.6% +/- 15.4 (p = 0.043). Histopathologic injury assessed as pathology score on a scale of 0-5 was less extensive in tirilazad-treated animals compared with controls (p = 0.038). There was a significant increase in water content in the HI hemisphere compared with the contralateral (hypoxic) hemispheres in tirilazad- and vehicle-treated animals. This increase of water content in the HI hemispheres did not differ between tirilazad- and vehicle-treated animals. The lipid peroxidation inhibitor tirilazad administered after perinatal HI reduced brain damage by 30%, but no effect was found on early postinsult edema.

Developmental changes in the sensitivity of the neonatal rat brain to hypoxic/ischemic injury

Developmental changes in the response of the neonatal rat brain to hypoxic/ischemic injury were examined. Hypoxic/ischemic injury was produced by unilateral carotid ligation followed by exposure to hypoxia in 1- (D1), 3- (D3), 5- (D5) and 7-day-old (D7) rats. Injury was produced in most D7 animals exposed to > or = 120 min of 7.6 or 8% oxygen after carotid ligation. The extent of neuronal injury was variable, ranging from focal neuronal death to massive infarction. In D5 and D3 animals, there was a progressive decline in the extent of neuronal injury in response to hypoxia/ischemia. In the younger animals, bilateral injury was occasionally seen. Sham-operated animals exposed to hypoxia alone had numbers of karyorrhectic neurons similar to normal control animals in all age groups. The underlying developmental changes which account for these differences are not yet known but are likely to be multiple.

Cerebral glucose and energy utilization during the evolution of hypoxic-ischemic brain damage in the immature rat

The cerebral metabolic rate for glucose (CMRg1) and cerebral energy utilization (CEU) were assessed in immature rats during recovery from cerebral hypoxia-ischemia. CMRg1 was determined using a modification of the Sokoloff technique with 2-deoxy-[14C]glucose (2-DG) as the radioactive tracer. CEU was determined using the Lowry decapitation technique. Seven-day postnatal rats underwent unilateral common carotid artery ligation, followed 4 h thereafter by exposure to 8% oxygen at 37 degrees C for 3 h. At 1, 4, or 24 h of recovery, the rat pups underwent those procedures necessary for the measurement of either CMRg1 or CEU. At 1 h of recovery, the CMRg1 of the cerebral hemisphere ipsilateral to the carotid artery occlusion was 97% of the control rate (8.7 mumol 100 g-1 min-1) but was only 48% of the control in the contralateral hemisphere. At 4 h of recovery, the CMRg1 was increased 49% above baseline in the ipsilateral hemisphere, decreasing thereafter to 84% of the control at 24 h. The CMRg1 of the contralateral hemisphere normalized by 4 h of recovery. An inverse correlation between endogenous concentrations of ATP or phosphocreatine and CMRg1 in the ipsilateral hemisphere was apparent at 4 h of recovery. CEU in the ipsilateral cerebral hemisphere was 64 and 46% of the control (3.47 mmol approximately P/kg/min) at 1 and 24 h, respectively (p < 0.05) and 77% of the control at 4 h of recovery. CEU in the contralateral hemisphere was unchanged from the control at all measured intervals. Correlation of the alterations in CMRg1 with those in CEU at the same intervals indicated that substrate supply exceeds energy utilization during early recovery from hypoxia-ischemia. The discrepancy combined with a persistent disruption of the cerebral energy state implies the existence of an uncoupling of mitochondrial oxidative phosphorylation as one mechanism for the occurrence of perinatal hypoxic-ischemic brain damage.

Nature, time-course, and extent of cerebral edema in perinatal hypoxic-ischemic brain damage

To ascertain the nature, time-course, and extent of the cerebral edema that accompanies perinatal hypoxic-ischemic brain damage, 7-day postnatal rats were subjected to unilateral right common carotid artery ligation followed by exposure to hypoxia with 8% oxygen for up to 3 hours. Some rat pups were sacrificed during hypoxia-ischemia or recovery for determination of cerebral hemispheric water content and percentage of brain swelling. Other animals were sacrificed and their brains processed either for determination of cerebral cortical edema and infarct volume or for horseradish peroxidase staining. The results indicated that cerebral edema occurs even during the course of hypoxia-ischemia and that the extent and duration of edema formation during the recovery period is dependent upon the severity of tissue injury. The data also disclosed a direct, linear correlation between infarct volume and the extent of cerebral edema. Accordingly, the greater the severity of cerebral edema, the proportionately greater the extent of infarction. Horseradish peroxidase staining, a reflection of vasogenic edema, occurred in 17 of 19 brains in a distribution which corresponded closely to the distribution of neuropathologic alterations observed histologically. The findings indicate that cerebral edema can occur in the absence of consequent infarction and that when infarction does occur, the associated edema contributes little or nothing to the severity of the ultimate brain damage.

The kappa opioid-related anticonvulsants U-50488H and U-54494A attenuate N-methyl-D-aspartate induced brain injury in the neonatal rat

The neuroprotective effects of the kappa opioid-related anticonvulsants U-50488H and U-54494A were tested in a model of N-methyl-D-aspartate (NMDA)-induced brain injury in the neonatal rat. Seven-day-old rat pups were injected intracerebrally with 7.5 nmol NMDA. Five days later, the ensuing unilateral hemisphere weight reduction was measured and used to assess the severity of insult. Control animals (n = 85) exhibited a 21.7 +/- 0.5% hemisphere weight reduction. Animals treated with U-54494A in split doses before and after NMDA administration showed significant neuroprotection at 10, 15, and 20 mg/kg, with the maximum effect observed at 15 mg/kg (33.8% protection). Animals treated with U-50488H on a similar dosing schedule showed significant neuroprotection at all doses tested, with peak protection observed at 30 mg/kg (51.8% protection). Both compounds exhibited a neuroprotective effect when hemisphere cross-sectional area and hippocampal histology were assessed. Treatment with U-54494A after NMDA administration also afforded neuroprotection at various doses, as measured by hemisphere weight disparity, with peak protection occurring at a dose of 20 mg/kg (32.4% protection). These data show that both U-50488H and U-54494A afford neuroprotection against NMDA-induced neuronal injury in the neonatal rat brain.

Neuropathology of remote hypoxic-ischemic damage in the immature rat

This study was undertaken to determine: (a) the duration of hypoxia required to produce brain damage in immature rats with unilateral carotid artery ligation (Levine technique); (b) the regions of immature brain most vulnerable to hypoxia-ischemia (HI); and (c) the neuropathology of the remote HI insult. To this end, 7-day postnatal rats, subjected to unilateral carotid artery ligation combined with hypoxia of varying durations (45, 60, 75 or 90 min), were killed at 30 days of postnatal age and their brains examined by light microscopy. The results indicated that a longer duration of HI was more likely to produce brain lesions and that the extent and severity of the lesions closely correlated with the length of HI. Shorter intervals of HI primarily damaged the cerebral cortex and hippocampus, while longer periods resulted in more extensive damage and were often associated with cavitary lesions of the cerebral hemisphere. Comparison of HI brain damage produced by the Levine technique in immature and adult rats suggested that in immature rats: (a) the cavitary lesions were common; (b) the non-cavitary cortical lesions had a tendency to show a vertical band-like distribution - a pattern never seen in adults; and (c) the lesions often showed mineralization. The similarities between these experimentally produced HI cerebral lesions and those observed in the developing human brain, such as ulegyria and porencephaly, are discussed.