Acute Subdural Hematoma In Rats Research Articles

Influence of Blood Components on Neuroinflammation, Blood-Brain Barrier Breakdown, and Functional Damage After Acute Subdural Hematoma in Rats.

A central component of injury development after acute subdural hematoma (ASDH) is the increased intracranial pressure and consecutive mechanical reduction of cerebral blood flow (CBF). However, the role of different blood constituents in ASDH as additional lesioning factors remains unclear. This study examines the influence of blood components on neuroinflammation, blood-brain barrier (BBB) breakdown, and functional deficits in a rat model of ASDH. We infused corpuscular (whole blood, whole blood lysate, and red cell blood) and plasmatic (blood plasma, anticoagulated blood plasma, and aqueous isotonic solution) blood components into the subdural space while CBF was monitored. Rats then underwent behavioral testing. Lesion analysis and immunohistochemistry were performed 2 days after ASDH. Inflammatory reaction was assessed using staining for ionized calcium-binding adaptor molecule 1 and glial fibrillary acidic protein, interleukin-1ß, tumor necrosis factor-alpha, and membrane attack complex. Integrity of the BBB was evaluated with albumin and matrix metalloproteinase 9 (MMP9) staining. We observed a significant drop in CBF in the corpuscular group (75% ± 7.5% of baseline) with distinct post-operative deficits and larger lesion volume compared to the plasmatic group (13.6 ± 5.4 vs. 1.3 ± 0.4 mm3). Further, inflammation was significantly increased in the corpuscular group with stronger immunoreaction. After whole blood infusion, albumin and MMP9 immunoreaction were significantly increased, pointing toward a disrupted BBB. The interaction between corpuscular and plasmatic blood components seems to be a key factor in the detrimental impact of ASDH. This interaction results in neuroinflammation and BBB leakage. These findings underscore the importance of performing surgery as early as possible and also provide indications for potential pharmacological targets.

The construction of an improved model of acute subdural hematoma in rats

BackgroundTo construct a new and improved model of acute subdural hematoma in rats. New method30 male adult Sprague-Dawley rats(SD rats) were selected and randomly divided into two groups. The traditional model group was based on Miller's model construction method, and the improved model group was based on improved needle, injection site and operation method. The improved model was evaluated by comparing the physiological indicators, behavioral scores, magnetic resonance performance and HE staining results of the two groups of rats. ResultsThe physical signs of the rats in the two groups were similar. The survival rate of the improved group was higher than that of the traditional group. The hematoma in the improved model was thicker and concentrated in the ipsilateral side, as revealed by HE staining and MRI. The improved method has less intrusions on the cortex around the injection site and is more stable than the traditional model. Comparison with existing method(s)The operation difficulty of the improved model is reduced and easier. The survival rate of the improved group was higher than that of the traditional group. And the improved model will have more research possibilities. ConclusionThe improved model is based on the traditional model. Although it has some shortcomings, it can also be used in different research fields of the traditional model. The operation for the improved model is easier to perform. And the improved model has more applications in research.

Blood Aggravates Histological and Functional Damage after Acute Subdural Hematoma in Rats.

Acute subdural hematoma (ASDH) is associated with high morbidity and mortality. Whether the volume effect of the hematoma and increase of intracranial pressure (ICP) or the local effect of blood are responsible for this severe pathophysiology is unclear. Therefore, we compared subdural infusion of autologous blood and paraffin oil in a rat model of ASDH. In a histological study, we investigated the effects on acute ICP, cerebral perfusion pressure (CPP), cerebral blood flow (CBF), tissue oxygen changes, and brain damage at 2, 24, and 96 h post-infusion. Inflammatory reaction was analyzed by immuno-staining for microglia (ionized calcium binding adaptor molecule 1 [Iba1]) and activated astrocytes (glial fibrillary acidic protein [GFAP]). Besides acute ICP and CBF changes, we investigated the development of behavior (neuroscore and beamwalk test) for up to 4 days after injury in a behavioral study. Despite comparably increased ICP, there was a more pronounced lesion growth in the blood infusion group during the first 96 h. Further, there was an increased peri-lesional immunoreactive area of Iba1 and GFAP 96 h post-infusion, primarily in the blood infusion group, whereas hippocampal damage was comparable in both infusion groups. In the behavioral evaluation, paraffin-infused animals showed a better recovery, compared with the blood infusion group. In conclusion, comparable acute time-course of ICP, CPP, and CBF clearly indicates that the differences in lesion size, inflammatory reaction, and behavioral deficits after blood- and paraffin oil-induced ASDH are partially due to blood constituents. Therefore, current data suggest that subdural hematomas should be completely removed as quickly as possible; decompression alone may not be sufficient to prevent secondary brain damage.

Blood Constituents Trigger Brain Swelling, Tissue Death, and Reduction of Glucose Metabolism Early after Acute Subdural Hematoma in Rats

Outcome from acute subdural hematoma is often worse than would be expected from the pure increase of intracranial volume by bleeding. The aim was to test whether volume-independent pathomechanisms aggravate damage by comparing the effects of blood infusion with those of an inert fluid, paraffin oil, on intracranial pressure (ICP), cerebral perfusion pressure (CPP), local cerebral blood flow (CBF), edema formation, glucose metabolism ([18F]-deoxyglucose, MicroPET ), and histological outcome. Rats were injured by subdural infusion of 300 muL venous blood or paraffin. ICP, CPP, and CBF changes, assessed during the first 30 mins after injury, were not different between the injury groups at most time points (n=8 per group). Already at 2 h after injury, blood caused a significantly more pronounced decrease in glucose metabolism in the injured cortex when compared with paraffin (P<0.001, n=5 per group). Ipsilateral brain edema did not differ between groups at 2 h, but was significantly more pronounced in the blood-treated groups at 24 and 48 h after injury (n=8 per group). These changes caused a 56.2% larger lesion after blood when compared with paraffin (48.1+/-23.0 versus 21.1+/-11.8 mm(3); P<0.02). Blood constituent-triggered pathomechanisms aggravate the immediate effects due to ICP, CPP, and CBF during hemorrhage and lead to early reduction of glucose metabolism followed by more severe edema and histological damage.

Effects of hypertonic/hyperoncotic treatment and surgical evacuation after acute subdural hematoma in rats*

The treatment of acute subdural hematoma (ASDH) consists mainly of surgical evacuation of the hematoma. It is conceivable that early preoperative neuroprotection with hypertonic/hyperoncotic treatment (HHT) can improve survival rates. The present study investigated the benefit of treatment with hypertonic/hyperoncotic solution on functional and histologic outcome as supportive therapy accompanying surgical intervention. Laboratory experiment. University laboratory. Male Sprague-Dawley rats weighing 296-350 g (n = 56). ASDH was induced through subdural infusion of 400 microL of autologous venous blood. Thirty minutes after subdural blood infusion, the rats received either HyperHAES (7.2% saline/6% hydroxyethyl starch) or vehicle (NaCl 0.9%) intravenously, followed by surgical evacuation of the hematoma 1 hr after ASDH induction in those rats scheduled for surgical treatment. The experiment was divided into two parts: an acute study, which explored acute effects of HHT on blood variables, ASDH-induced changes of intracranial pressure (ICP), and cerebral perfusion pressure (CPP), and a chronic study, which investigated the chronic effects of HHT, surgical blood clot evacuation, and the combination of both on the functional and histologic outcome following ASDH (12 days). In the acute study, HHT expectedly raised the serum sodium concentration and lowered hematocrit. ASDH increased ICP and decreased CPP in all groups. HHT improved CPP by reducing ICP. In the chronic study, all treated groups showed a better recovery with respect to neurologic function and neuronal cell death compared with the vehicle-treated ASDH group. HHT with surgical evacuation or HHT alone improved functional and histologic outcome slightly more than surgical evacuation alone. In this rat model, HHT led to a decrease of ICP after ASDH. This significantly improved functional and histologic outcome, which was comparable to the effects after blood evacuation alone. The combination of evacuation of subdural blood and early HHT improved histologic outcome further but not significantly, which was due to the strong effects of single treatments and a ceiling effect of the combined treatment in this model.

Caspase-dependent cell death involved in brain damage after acute subdural hematoma in rats

Traumatic brain injury is associated with acute subdural hematoma (ASDH) that worsens outcome. Although early removal of blood can reduce mortality, patients still die or remain disabled after surgery and additional treatments are needed. The blood mass and extravasated blood induce pathomechanisms such as high intracranial pressure (ICP), ischemia, apoptosis and inflammation which lead to acute as well as delayed cell death. Only little is known about the basis of delayed cell death in this type of injury. Thus, the purpose of the study was to investigate to which extent caspase-dependent intracellular processes are involved in the lesion development after ASDH in rats. A volume of 300 μL blood was infused into the subdural space under monitoring of ICP and tissue oxygen concentration. To asses delayed cell death mechanisms, DNA fragmentation was measured 1, 2, 4 and 7 days after ASDH by TUNEL staining, and the effect of the pan-caspase inhibitor zVADfmk on lesion volume was assessed 7 days post-ASDH. A peak of TUNEL-positive cells was found in the injured cortex at day 2 after blood infusion (53.4 ± 11.6 cells/mm 2). zVADfmk (160 ng), applied by intracerebroventricular injection before ASDH, reduced lesion volume significantly by more than 50% (vehicle: 23.79 ± 7.62 mm 3; zVADfmk: 9.06 ± 4.08). The data show for the first time that apoptotic processes are evident following ASDH and that caspase-dependent mechanisms play a crucial role in the lesion development caused by the blood effect on brain tissue.

Effects of hypothermia on intracranial hemodynamics and ischemic brain damage-studies in the rat acute subdural hematoma model.

Brain ischemia is the leading pathophysiological mechanism in the development of secondary brain damage after subdural hematoma (SDH). Hypothermia has been used as the effective neuroprotective treatment in clinical and laboratory studies of ischemic brain injury. In this study, we have examined the rat acute SDH model to assess the effect of hypothermia upon intracranial hemodynamics and also upon ischemic brain injury 4 hours after the induction of hematoma. Moderate hypothermia (32 degrees C) did not affect the intracranial pressure nor cerebral perfusion pressure, and it significantly reduced cortical brain edema formation underneath the hematoma (80.88 +/- 0.17%; p < 0.01) compared with the normothermic control group (81.65 +/- 0.52%). This reduction in brain edema formation was comparable to the result of MK-801 (2 mg/kg) treatment (80.95 +/- 0.35%; p < 0.01). Ischemic brain damage detected by H-E staining was also significantly reduced in the hypothermia and MK-801 treated groups (59.1 +/- 12.3 mm3 and 66.4 +/- 13.8 mm3; p < 0.01 and p < 0.05) compared with the normothermic control group (86.6 +/- 20.7 mm3). In conclusion, the present study demonstrates that hypothermia is a potent neuroprotective method and an inhibition of the glutamate excitotoxic process may contribute the protective mechanisms of hypothermia in this rat acute SDH model.

Detection of ultra-early brain damage after acute subdural hematoma in the rat by magnetic resonance imaging.

We measured serial changes in diffusion-weighted magnetic resonance imaging (DW) and in apparent diffusion coefficient (ADC) 1 to 3 hours after induction of acute subdural hematoma (ASDH) in rats, to assess the rate of development of cytotoxic edema and ischemic brain damage observed in this model. Cortical ADC values underneath the hematoma in ASDH rats (n = 12) were significantly lower than those in sham-operated rats (n = 5) at 1 hour. By 3 hours, the area of ADC abnormality had further increased. The lesion areas, as percentage of hemispheric areas on 1- and 3-hour ADC maps, correlated significantly with those on the histologic sections stained with hematoxylin and eosin. The results indicate that DWI with ADC mapping may provide a valuable diagnostic tool for monitoring of early pathologic changes following subdural hematoma in head-injured patients.

Reducing hemoglobin oxygen affinity does not increase hydroxyl radicals after acute subdural hematoma in the rat.

Extensive evidence is available to show the importance of ischemia after severe human head injury. We have previously shown that pharmacologically increasing the release of oxygen in brain tissue where the local oxygen pressure is low reduces infarct size in animal models. To study the possible negative effects of this strategy, we tested the effect of an allosteric modifier of hemoglobin (RSR13) on free radical production in the rat acute subdural hematoma (ASDH) model, both under normoxic as well as under hyperoxic, normobaric conditions. When compared to baseline, induction of ASDH resulted in a significant increase (p < 0.05) in 2,3-DHBA (2,3 dihydroxybenzoic acid, produced from salicylate after attack by hydroxyl radicals) at 30 and 60 min postinduction, both for the control group (39% and 91%) as well as the RSR13-treated group (41% and 62%). The 2,5-DHBA also increased significantly (p < 0.05) in the drug-treated animals at the 30- and 60-min time points when compared to baseline (49% and 77%). At all time points, except the 30-min, the increase in 2,3-DHBA was less marked in the RSR13 animals than in the control group. Similarly, the 2,5-DHBA increase after ASDH was lower at all time points except for the 30-min time point in the RSR13-treated group. These results indicate that enhanced tissue oxygen release by the allosteric modifier of hemoglobin RSR13 does not increase hydroxyl radical production after ASDH. Clinical trials are needed to test this compound in humans after severe head injury.

Marked alterations in the cellular localisation and levels of apolipoprotein E following acute subdural haematoma in rat

Apolipoprotein E (apoE) plays a role in the response to acute brain injury, the mechanisms as yet remain unknown. In the present study, alterations in the immunohistochemical localisation of apoE in rat cortex were examined at 30 min. 2 h or 4 h following production of an acute subdural haematoma. Levels of apoE were determined in cortex by immunoblotting at 30 min and 4 h post-haematoma. Extensive areas of ischaemic cell damage were observed in the cortex underlying the haematoma with minimal damage observed in shams. In sham animals, apoE immunoreactivity was confined to astrocytes and their processes. Following the haematoma induction, apoE immunoreactivity was dramatically altered. At 30 min post-haematoma, intense apoE staining was observed in clusters of neuronal perikarya and the neuropil throughout the cortical layers underlying the haematoma and this persisted at 2 h and 4 h post-haematoma. Additionally, at 4 h post-haematoma marked apoE staining of discrete foci within the neuropil closely associated with capillaries was consistently observed in the ipsilateral cortex. Immunoblotting indicated there were no significant alterations in the cortical levels of apoE at 30 min post-haematoma but, at 4 h post-haematoma, there was a significant elevation (27%, P < 0.001) in the levels of apoE in cortex underlying the haematoma compared to control levels. The results indicate that following acute subdural haematoma, a rapid cellular redistribution of apoE occurs and precedes a significant elevation in the levels of apoE. These alterations in apoE may occur, at least initially, as part of the brain's protective response to injury.

Early changes in second messenger but not receptor binding sites after acute subdural hematoma: an in vitro autoradiographic study.

Neurotransmitter receptor-coupled mechanisms have been recently recognized as important determinants of cell damage after central nervous system (CNS) trauma and ischemia. Many of these receptors exert their intracellular effects via second messenger systems. This study used in vitro autoradiographic radioligand binding to measure beta-adrenergic and muscarinic cholinergic receptors and adenylate cyclase and protein kinase C (PKC) binding sites two h after acute subdural hematoma in rats. Both beta-adrenergic and cholinergic receptor binding sites were unchanged in comparison to controls, while adenylate cyclase binding significantly decreased in the ischemic cortex under the hematoma. These changes may constitute a major limiting factor on receptor-linked therapeutic strategies in trauma and ischemia. Protein kinase C activation significantly increased in the ischemic area under the hematoma in these studies. This appears to be a response to calcium flux, which may be in part glutamate mediated.