Tatsuro Mori

Matrix metalloproteinase-9 is associated with blood-brain barrier opening and brain edema formation after cortical contusion in rats

Matrix metalloproteinases (MMPs) are associated with blood-brain opening and may be involved in the pathophysiology of acute brain injury. Previous research demonstrated that knockout mice deficient in MMP-9 subjected to transient focal cerebral ischemia had reduced blood-brain barrier (BBB) disruption and attenuated cerebral infarction. In this study, we examined MMP-9 up-regulation, BBB disruption, and brain edema formation after cortical impact injury in rats. Cortical contusion was induced by controlled cortical impact. Animals were sacrificed at intervals after injury. MMP up-regulation was assessed by gelatin zymography, and BBB integrity was evaluated using Evans blue dye with a spectrophotometric assay. Brain water content was measured by comparing wet and dry weights of each hemisphere as an indicator of brain edema. Zymograms showed elevated MMP-9 as early as at 3 hours after injury, reaching a maximum at 18 hours. Peak levels of BBB disruption occurred 6 hours after injury. Brain edema became progressively more severe, peaking 24 hours after injury. Compared to control group, treatment with MMP-inhibitor GM6001 significantly reduced BBB disruption 6 hours and brain water content (85.9 +/- 0.5% vs. 82.6 +/- 0.3%; p < 0.05) 24 hours after injury. These findings suggest that MMP-9 may contribute to BBB disturbance and subsequent brain edema after traumatic brain injury.

A Randomized Controlled Trial of Hydrocortisone Against Hyponatremia in Patients With Aneurysmal Subarachnoid Hemorrhage

Background and Purpose— Hyponatremia is common after aneurysmal subarachnoid hemorrhage (SAH). It is caused by natriuresis, which induces osmotic diuresis and decreases blood volume, contributing to symptomatic cerebral vasospasm (SCV). Hypervolemic therapy to prevent SCV will not be efficient under this condition. We conducted a randomized controlled trial to assess the efficacy of hydrocortisone, which promotes sodium retention in the kidneys. Methods— Seventy-one SAH patients were randomly assigned after surgery to treatment with either a placebo (n=36) or 1200 mg/d of hydrocortisone (n=35) for 10 days and tapered thereafter. Both groups underwent hypervolemic therapy. The primary end point was the prevention of hyponatremia. Results— Hydrocortisone prevented excess sodium excretion (P=0.04) and urine volume (P=0.04). Hydrocortisone maintained the targeted serum sodium level throughout the 14 days (P<0.001), and achieved the management protocol with lower sodium and fluid (P=0.007) supplementation. Hydrocortisone kept the normal plasma osmolarity (P<0.001). SCV occurred in 9 patients (25%) in the placebo group and in 5 (14%) in the hydrocortisone group. No significant difference in the overall outcome was observed between the 2 groups. Conclusions— Hydrocortisone overcame excess natriuresis and prevented hyponatremia. Although there was no difference in outcome, hydrocortisone supported efficient hypervolemic therapy.

Acute hemispheric swelling associated with thin subdural hematomas: pathophysiology of repetitive head injury in sports

INTRODUCTION The most common head injury in sports is concussion, and repeated concussions occurring within a short period occasionally can be fatal. Acute subdural hematoma is the most common severe head injury and can be associated with severe neurologic disability and death in sports. We investigated severe brain damage resulting from repetitive head injury in sports, and evaluated the pathophysiology of sports-related repetitive injury. METHODS We reviewed the literature containing detailed descriptions of repetitive severe sports-related head injury. In total, 18 cases were analyzed with regard to age, gender, type of sports, symptoms before second injury, and pathology of brain CT scans. RESULTS The majority of cases involved young males aged 16 to 23 years old, who sustained a second head injury before symptoms from the first head injury had resolved. Ten of 15 cases did not suffer loss of consciousness at insult. Eight cases were confirmed on brain CT scans after the second injury, and all 8 cases revealed brain swelling associated with a thin subdural hematoma. CONCLUSIONS Second impact syndrome is thought to occur because of loss of autoregulation of cerebral blood flow, leading to vascular engorgement, increased intracranial pressure, and eventual herniation. Our investigation suggests that the existence of subdural hematoma is a major cause of brain swelling following sports-related, repetitive head injury.

Prophylactic Management of Excessive Natriuresis With Hydrocortisone for Efficient Hypervolemic Therapy After Subarachnoid Hemorrhage

Background and Purpose— Hyponatremia caused by excessive natriuresis is common in patients with aneurysmal subarachnoid hemorrhage (SAH). Natriuresis decreases the total blood volume through osmotic diuresis and increases the risk of symptomatic cerebral vasospasm. In such patients, hypervolemic therapy is difficult to achieve without causing hyponatremia because sodium replacement provokes further natriuresis and osmotic diuresis. We examined the effects of hydrocortisone, which promotes sodium retention, in patients with SAH. Methods— Twenty-eight SAH patients were randomized into 2 groups after direct surgery: group 1 patients without hydrocortisone treatment (n=14) and group 2 patients with hydrocortisone treatment (1200 mg/d for 10 days; n=14). Both groups underwent hypervolemic therapy by aggressive sodium and water replacement. The goal of the hypervolemic therapy was to maintain the serum sodium level >140 mEq/L and the central venous pressure (CVP) within 8 to 12 cm H2O. Results— Group 2 demonstrated a lower sodium excretion (P <0.05) and higher serum sodium level (P <0.05) compared with group 1. Hyponatremia developed in 6 patients (43%) in group 1 and 0 patients in group 2 (P <0.05). Group 2 also demonstrated a lower urine volume, lower infusion volume (P <0.05) required for hypervolemic therapy, and higher CVP (P <0.05). Failure to maintain CVP was observed in 12 patients (86%) in group 1 and 3 patients (21%) in group 2 (P <0.05). Hydrocortisone caused no serious side effects. Conclusions— Hydrocortisone clearly attenuates excessive natriuresis. Prophylactic hydrocortisone administration appears to have a therapeutic value in inducing hypervolemia efficiently after SAH.

Hemodynamic Depression and Microthrombosis in the Peripheral Areas of Cortical Contusion in the Rat: Role of Platelet Activating Factor

Cerebrovascular damages leading to subsequent reductions in regional cerebral blood flow (rCBF) may play an important role in secondary cell damages following traumatic brain injury (TBI). Recent studies have demonstrated that rCBF markedly decrease in experimental model of TBI (e.g. fluid percussion injury, acute subdural hematoma, contusion). However, precise mechanisms underlying post-traumatic CBF reduction remain unclear. In the present study, the rCBF changes and microthrombosis formation were investigated in a cortical contusional model in rats, and the effects of etizolam (platelet activating factor antagonist) on microthrombosis were tested. The rCBF in the peripheral areas increased transiently, and decreased to ischemic level 3 hours post- injury. The histological examinations revealed microthrombosis formation in the contused area, extending from the center to the peripheral areas within 6 hours post-injury. The rCBF decrease and the contusion necrosis volume were significantly attenuated by etizolam administration. These results indicate that platelet activating factor is involved in microthrombosis formation and hemodynamic depression, and resultant ischemic damages within areas surrounding the contusion.

Heterogeneous Mechanisms of Early Edema Formation in Cerebral Contusion: Diffusion MRI and ADC Mapping Study

Severe cerebral contusion is sometimes associated with early edema formation within 24-48 hours post-trauma, and this frequently results in progressive ICP elevation and clinical deterioration. To investigate the underlying mechanisms of such severe contusion edema, diffusion imaging and ADC mapping were performed in 20 patients with cerebral contusion, employing 1.5 T echo planar MRI. Within 24 hours post-trauma, the diffusion images demonstrated a low intensity core in the central area and a high intensity rim in the peripheral area of contusion. The ADC value increased in the central area (ADC ratio (contusion/normal brain) = 1.13 +/- 0.13) and decreased in the peripheral area (ADC ratio = 0.83 +/- 0.13). This suggested that intra- and extracellular components underwent disintegration and homogenization within the central area, whereas cellular swelling was predominant in the peripheral area. A crescent-shaped zone of very high ADC value (ADC ratio = 1.38-1.61) was observed at the border between these two areas during the period of 24-48 hours post-trauma in some cases, apparently indicating that edema fluid was accumulated within a space formed by homogenization. The ADC values in the peripheral area shifted to an increase after 48-72 hours post-trauma. These findings imply that multiple mechanisms operate in early edema formation in cerebral contusion. It appears that the capacity for edema fluid accumulation increases in the central area and resistance for edema fluid propagation is elevated by cellular swelling in the peripheral area. We suggest that a combination of such events facilitates edema fluid accumulation in the central area and contributes, together with the cellular swelling in the peripheral area, to the mass effect of contusion edema. Diffusion MRI and ADC mapping represent powerful tools for investigating spatially as well as temporally heterogeneous mechanisms of contusion edema.

Pathogenesis of the Mass Effect of Cerebral Contusions: Rapid Increase in Osmolality within the Contusion Necrosis

The non-hemorrhagic mass effect of cerebral contusions is commonly attributed to vasogenic edema and/or cytotoxic edema (cellular swelling). We propose that a marked increase in osmolality within the contusion necrosis proper, in which the cellular elements uniformly undergo shrinkage, disintegration and homogenation, represents an important and unique mechanism underlying the contusion edema. The present study demonstrates in a rat model of cerebral contusion, that 1) the osmolality of the contused brain tissue increases rapidly, 2) the increase in osmolality is not caused by changes in inorganic ion contents, suggesting a metabolic production of osmoles or release of idiogenic osmoles, and 3) the contused brain tissue strongly attracts water, provided that blood supply is maintained. We suggest that the primary driving force of water accumulation into contused brain tissue is the elevated colloid osmotic potential of contusion necrosis.

Antioxidant, OPC-14117, attenuates edema formation and behavioral deficits following cortical contusion in rats.

Oxygen free radicals may contribute to tissue injury processes in the central nervous system following ischemia or trauma. Recent studies have suggested that inhibition of free radicals improves the outcome in experimental models involving such conditions, and antioxidant therapy appears promising. In the present study, behavioral changes and edema formation in rat cortical contusion model were investigated, and the effects of a superoxide radical scavenger, OPC-14117, were tested. Wistar rats were anesthetized with halothane inhalation. Cortical contusion was induced in the parietal cortex employing a controlled cortical impact device. Immediately following injury induction, OPC-14117 was administered (300 mg/kg, p.o.). Edema formation was assessed in the center and peripheral areas of the contusion by the specific gravity method. Behavioral changes were evaluated by the Morris water maze test and the habituation of exploratory activity. The results revealed that the vehicle-administered control showed progressive edema formation and behavioral deficits following the injury. These changes were significantly attenuated by the OPC-14117 treatment (p < 0.05). Further, OPC-14117 reduced the size of contusional necrosis (p < 0.05). These findings suggest that superoxide free radicals are involved in contusion-induced edema formation, necrosis formation, and behavioral deficits, and that OPC-14117 has a therapeutic potential to prevent secondary cell damage following traumatic brain injury.

Antioxidant, OPC-14117, Attenuates Edema Formation, and Subsequent Tissue Damage Following Cortical Contusion in Rats

Oxygen free radicals contribute to various kinds of tissue injury processes within the central nervous system. It has been suggested that inhibition of free radical formation has the potential to attenuate secondary neural tissue damage involving ischemia or trauma, and antioxidant therapy may offer a promising approach. In the present study, employing a cortical contusion model in the rat, contusion-induced neural damage, was evaluated by investigating edema formation, behavioral activities and histological changes. The effects of the superoxide radical scavenger, OPC-14117, were also tested to determine how free radicals may contribute to such neural damage. The results demonstrated that cerebral contusion induces a progressive decrease in tissue specific gravity representing edema formation, and behavioral deficits in the Morris water maze test and habituation of exploratory activity. Histological examinations revealed necrotic cavity formation in the cortex and selective neuronal death of the hippocampal CA3 region. These changes were significantly attenuated by OPC-14117, which was administered as a single dose immediately following trauma induction. The above results indicate that oxygen free radicals are involved in contusion-induced edema formation, subsequent tissue damage and cognitive deficits. The superoxide radical scavenger, OPC-14117, has a powerful therapeutic potential for preventing secondary cell damage following traumatic brain injury.

Effects of antioxidant, OPC-14117, on secondary cellular damage and behavioral deficits following cortical contusion in the rat.

In the present study, we examined the effects of OPC-14117, a superoxide radical scavenger, on the secondary cellular damage and cognitive dysfunction occurring in a rat model of cerebral contusion induced by a controlled cortical impact (CCI). Histological examinations revealed that the contusion necrosis volume reached 13.6+/-5.3 mm(3) in non-treated animals and declined to 1.9+/-0.6 mm(3) in OPC-14117-treated animals (P<0.01). The cell number of the CA3 region was 120.0+/-12.4 cells/mm in the normal controls, 73.6+/-9.9 cells/mm in the non-treated animals, and 111.2+/-10.2 cells/mm in the OPC-14117-treated animals, indicating that CCI-induced selective neuronal cell death in the CA3 region was attenuated by the OPC-14117 administration (P<0.01). The tissue osmolality, as determined with a vapor pressure osmometer, was 314.5+/-15.4 mmol/kg in the normal brain and increased to 426.0+/-20.1 mmol/kg at 12 h following CCI. The increase in tissue osmolality was significantly attenuated by OPC-14117 administration (P<0.01). The OPC-14117 administration also attenuated the CCI-induced cognitive deficits. The OPC-14117-treated animals showed a tendency to improve on the Morris water maze performance test. The impairment of the habituation of exploratory activity elicited by CCI was significantly attenuated by OPC-14117 administration (P<0.05). In conclusion, OPC-14117 may have a potential for decreasing secondary cellular damage due to traumatic brain injury since it is as efficacious as any other compound tested in this model.