fibrin and Brain-Edema

We present a method to produce vascular disruptions within rat brain parenchyma that targets single microvessels. We used two-photon microscopy to image vascular architecture, to select a vessel for injury and to measure blood-flow dynamics. We irradiated the vessel with high-fluence, ultrashort laser pulses and achieved three forms of vascular insult. (i) Vessel rupture was induced at the highest optical energies; this provides a model for hemorrhage. (ii) Extravasation of blood components was induced near the lowest energies and was accompanied by maintained flow in the target vessel. (iii) An intravascular clot evolved when an extravasated vessel was further irradiated. Such clots dramatically impaired blood flow in downstream vessels, in which speeds dropped to as low as approximately 10% of baseline values. This demonstrates that a single blockage to a microvessel can lead to local cortical ischemia. Lastly, we show that hemodilution leads to a restoration of flow in secondary downstream vessels.

Topics: Animals; Blood Coagulation; Blood Flow Velocity; Brain Edema; Brain Ischemia; Capillary Permeability; Cerebral Cortex; Dextrans; Disease Models, Animal; Erythrocytes; Fibrin; Fluoresceins; Hemodilution; Hemorrhage; Heparin; Hypoxia, Brain; Lasers; Light; Male; Microcirculation; Microscopy, Confocal; Microtubule-Associated Proteins; Rats; Rats, Sprague-Dawley; Regional Blood Flow; Rupture; Sodium Chloride; Stroke; Tissue Plasminogen Activator; Vimentin

Hypoxia is a critical factor for cell death or survival in ischemic stroke, but the pathological consequences of combined ischemia-hypoxia are not fully understood. Here we examine this issue using a modified Levine/Vannucci procedure in adult mice that consists of unilateral common carotid artery occlusion and hypoxia with tightly regulated body temperature. At the cellular level, ischemia-hypoxia produced proinflammatory cytokines and simultaneously activated both prosurvival (eg, synthesis of heat shock 70 protein, phosphorylation of ERK and AKT) and proapoptosis signaling pathways (eg, release of cytochrome c and AIF from mitochondria, cleavage of caspase-9 and -8). However, caspase-3 was not activated, and very few cells completed the apoptosis process. Instead, many damaged neurons showed features of autophagic/lysosomal cell death. At the tissue level, ischemia-hypoxia caused persistent cerebral perfusion deficits even after release of the carotid artery occlusion. These changes were associated with both platelet deposition and fibrin accumulation within the cerebral circulation and would be expected to contribute to infarction. Complementary studies in fibrinogen-deficient mice revealed that the absence of fibrin and/or secondary fibrin-mediated inflammatory processes significantly attenuated brain damage. Together, these results suggest that ischemia-hypoxia is a powerful stimulus for spontaneous coagulation leading to reperfusion deficits and autophagic/lysosomal cell death in brain.

Topics: Animals; Apoptosis; Autophagy; Brain; Brain Edema; Brain Infarction; Cell Survival; Cytokines; Disseminated Intravascular Coagulation; Fibrin; Hypoxia-Ischemia, Brain; Lysosomes; Male; Mice; Mice, Inbred C57BL; Regional Blood Flow; Reperfusion; Signal Transduction

Activated protein C (APC) contributes to systemic anticoagulant and anti-inflammatory activities. APC may reduce organ damage by inhibiting thrombin generation and leukocyte activation. Neutrophils and cerebrovascular thrombosis contribute to ischemic neuronal injury, suggesting that APC may be a potential protective agent for stroke.. We examined the effects of APC in a murine model of focal ischemia. After middle cerebral artery occlusion/reperfusion, the average survival time in controls was 13.6 hours. Animals that received purified human plasma-derived APC 2 mg/kg IV either 15 minutes before or 10 minutes after stroke induction survived 24 hours and were killed for neuropathological analysis. APC 2 mg/kg given before or after onset of ischemia restored cerebral blood flow, reduced brain infarct volume (59% to 69%; P:<0.003) and brain edema (50% to 61%; P:<0.05), eliminated brain infiltration with neutrophils, and reduced the number of fibrin-positive cerebral vessels by 57% (P:<0.05) and 25% (nonsignificant), respectively. The neuroprotective effect of APC was dose-dependent and associated with significant inhibition of ICAM-1 expression on ischemic cerebral blood vessels (eg, 61% inhibition with 2 mg/kg APC). Intracerebral bleeding was not observed with APC.. APC exerts anti-inflammatory, antithrombotic, and neuroprotective effects in stroke. Central effects of APC are likely to be related to improved maintenance of the blood-brain barrier to neutrophils and to reduced microvascular obstructions and fibrin deposition.

Topics: Animals; Anti-Inflammatory Agents; Brain Edema; Brain Ischemia; Cerebrovascular Circulation; Chemotaxis, Leukocyte; Disease Models, Animal; Dose-Response Relationship, Drug; Enzyme Activation; Fibrin; Fibrinolytic Agents; Hemoglobins; Humans; Infarction, Middle Cerebral Artery; Intercellular Adhesion Molecule-1; Macrophage-1 Antigen; Mice; Mice, Inbred C57BL; Neuroprotective Agents; Neutrophils; Optic Chiasm; Protein C; Psychomotor Performance; Reperfusion Injury; Survival Rate

Although the serine protease, tissue plasminogen activator (tPA), is approved by the US Food and Drug Administration for therapy to combat focal cerebral infarction, the basic concept of thrombolytic tPA therapy for stroke was challenged by recent studies that used genetically manipulated tPA-deficient (tPA-/-) mice, which suggested that tPA mediates ischemic neuronal damage. However, those studies were potentially flawed because the genotypes of tPA-/- and wild-type control mice were not entirely clear, and ischemic neuronal injury was evaluated in isolation of tPA effects on brain thrombosis. Using mice with appropriate genetic backgrounds and a middle cerebral artery occlusion stroke model with nonsiliconized thread, which does lead to microvascular thrombus formation, in the present study we determined the risk for cerebrovascular thrombosis and neuronal injury in tPA-/- and genetically matched tPA+/+ mice subjected to transient focal ischemia. Cerebrovascular fibrin deposition and the infarction volume were increased by 8.2- and 6. 7-fold in tPA-/- versus tPA+/+ mice, respectively, and these variables were correlated with reduced cerebral blood flow up to 58% (P<0.05) and impaired motor neurological score by 70% (P<0.05). Our findings indicate that tPA deficiency exacerbates ischemia-induced cerebrovascular thrombosis and that endogenous tPA protects the brain from an ischemic insult, presumably through its thrombolytic action. In addition, our study emphasizes the importance of appropriate genetic controls in murine stroke research.

Topics: Animals; Blotting, Western; Brain Edema; Brain Ischemia; Capillaries; Cerebral Infarction; Cerebrovascular Circulation; Circle of Willis; Disease Models, Animal; Female; Fibrin; Intracranial Thrombosis; Male; Mice; Mice, Inbred C57BL; Mice, Knockout; Neuroprotective Agents; Stroke; Sutures; Tissue Plasminogen Activator

Cortical biopsies of eight patients with craniocerebral trauma complicated with subdural or epidural hematoma were examined with the transmission electron microscope. The patients showed post-traumatic neurobehavioural disorders and moderate or severe vasogenic brain edema. The capillary wall displayed increased vacuolar and vesicular endothelial transport, basement membrane thickening and vacuolization and swollen astrocytic end-feet. Pericapillary and parenchymatous hemorrhages were also observed. The extracellular space appeared considerably enlarged with presence of proteinaceous hematogenous edema fluid and fibrinous organization. Pyramidal and non-pyramidal neurons showed intracellular edema featured by irregular enlargement of rough endoplasmic reticulum, nuclear envelope and Golgi apparatus. The myelinated axons exhibited clear or black type axoplasmic degeneration, varicose fiber swelling, myelin sheath distortion, formation of myelin ovoids and increased amount of oligodendroglial ad-axonal layer. The dendrites also showed clear or dark and beaded shape degeneration. Synaptic degeneration was characterized by swollen and shrunken pre- and postsynaptic endings, clumping, enlargement and depletion of synaptic vesicles, synaptic membrane complex disassembly and detachment of glial ensheathment. Perivascular and perineuronal astrocytes appeared remarkably swollen. Phagocytic astrocytes were also found. Oligodendrocytes displayed hydropic and reactive changes. Reactive oligodendrocytes induced myelinolysis. The brain barrier dysfunction, the vasogenic and cytotoxic edema and the subsequent neuronal and neuroglial cell reactive and degeneration processes might represent the morphological substrate responsible for the post-traumatic neurobehavioural disorders.

Topics: Adolescent; Adult; Aged; Aged, 80 and over; Behavioral Symptoms; Blood-Brain Barrier; Brain Edema; Brain Injuries; Capillaries; Cerebral Cortex; Female; Fibrin; Humans; Male; Microscopy, Electron; Middle Aged; Nerve Degeneration; Neurocognitive Disorders

We report the first case of cleft palate in a newborn male gorilla (Gorilla gorilla gorilla).. The full-term infant was born to clinically healthy, wild-caught parents and survived 5 days. Autopsy disclosed a unilateral cleft palate, moderate scalp hemorrhage (birth versus postnatal trauma), cerebral edema, and a sterile fibrin vegetation in the heart. The palate was also shorter and narrower than expected, and the biorbital breadth was reduced; otherwise, growth and development appeared normal. Standard cranial and intraoral radiographs and three-dimensional reconstructions of computerized tomographic (CT) scans provided thorough and noninvasive methods of studying the craniofacial complex and extracranial skeleton. By this technique, major findings were: intact premaxilla, interpremaxillary, and premaxillary/maxillary sutures; intramaxillary cleft with ipsilateral choanal atresia; mildly asymmetric inferior turbinates; and normal nasal septum and vomer.. Except for choanal atresia, cleft palate was not associated with other major craniofacial or extracranial anomalies in this case. Choanal atresia has been observed at times with cleft palate, but to our knowledge, the association has not been reported in nonhuman primates. Cleft palate, with or without cleft lip, has been recognized in a variety of nonhuman primates, including the lemur, marmoset, tamarin, squirrel monkey, and macaque. Some occurrences are spontaneous, while others are syndromic and/or arise from genetic or teratogenic influences. Each mode of presentation is poorly understood in nonhuman primates, but in this case, the absence of relevant environmental or parental history suggests that the occurrence was spontaneous. Anatomic studies of nonhuman primates are particularly valuable when they involve endangered species and will hopefully increase our understanding of the pathogenesis and etiology of congenital disorders, as well as other relationships between nonhuman primates and humans.

Topics: Animals; Ape Diseases; Brain Edema; Cephalometry; Choanal Atresia; Cleft Palate; Cranial Sutures; Facial Bones; Fibrin; Gorilla gorilla; Heart Diseases; Image Processing, Computer-Assisted; Male; Maxilla; Nasal Septum; Orbit; Palate; Scalp; Tomography, X-Ray Computed; Turbinates

We developed a fibrin-rich thrombotic focal cerebral ischemic model with reproducible and predictable infarct volume in rats. In male Wistar rats (n = 77), a thrombus was induced at the origin of the middle cerebral artery (MCA) by injection of thrombin via an intraluminal catheter placed in the intracranial segment of the internal carotid artery (ICA). Thrombus induction and consequent ischemic cell damage were examined by histopathological analysis and neurological deficit scoring, and by measuring changes in cerebral blood flow (CBF) using laser-Doppler flowmetery (LDF), perfusion-weighted imaging (PWI), and by diffusion weighted imaging (DWI). Histopathology revealed that a fibrin-rich thrombus localized to the origin of the right MCA. Regional cerebral blood flow (rCBF) in the right parietal cortex was reduced by 34-58% of preinjection levels after injection of thrombin in rats administered 30 U of thrombin (n = 10). Magnetic resonance imaging (MRI) showed a reduction in CBF and a hyperintensity DWI encompassing the territory supplied by the right MCA. The infarct volume in rats administered 80 U of thrombin was 31.29 +/- 12.9% of the contralateral hemisphere at 24 h (n = 13), and 34.7 +/- 16.4% of the contralateral hemisphere at 168 h (n = 6). Rats administered 30 U of thrombin exhibited a hemispheric infarct volume of 34.0 +/- 14.5% (n = 9) at 24 h and 29.7 +/- 13.9% (n = 8) at 168 h. In addition, thrombotic rats (n = 3) treated with recombinant tissue plasminogen activator (rt-PA) (10 mg/kg) 2 h after thrombosis showed that CBF rapidly returned towards preischemic values as measured by PWI. This model of thrombotic ischemia is relevant to thromboembolic stroke in humans and may be useful in documenting the safety and efficacy of thrombolytic intervention as well as for investigating therapies complementary to antithrombotic therapy.

Topics: Animals; Brain Edema; Brain Ischemia; Carotid Artery, Internal; Cerebral Infarction; Disease Models, Animal; Fibrin; Fibrinolytic Agents; Injections, Intra-Arterial; Intracranial Embolism and Thrombosis; Laser-Doppler Flowmetry; Magnetic Resonance Imaging; Male; Microscopy, Confocal; Microscopy, Electron, Scanning; Parietal Lobe; Rats; Rats, Wistar; Recombinant Proteins; Reproducibility of Results; Thrombin; Thrombolytic Therapy; Tissue Plasminogen Activator

Human lys-plasminogen and the corresponding formulation buffer were tested in a rat model of global cerebral ischemia (clamping of both carotid arteries, withdrawal of 5 ml blood for 30 min). The two main parameters, tested in different experimental set-ups, were 1. brain edema (water content) 23.5 h after reperfusion and 2. assessment of neurological deficits 24, 48 and 72 h after reperfusion. In some groups of animals of the first set-up, brains were examined histologically for microvascular fibrin deposits. In a separate group of animals the fibrinolytic plasma activity of rats treated with 500 CU/kg lys-plasminogen was studied. Concerning brain water content lys-plasminogen completely antagonized the formation of brain edema when given with 500 caseolytic Units (CU)/kg i.v. with blood reperfusion and was still effective when given 30 min later. 200 CU/kg i.v. given with blood reperfusion as well as 500 CU/kg i.v. given 60 min after blood reperfusion proved ineffective. In none of the brains investigated microvascular fibrin deposits were found. In experiments with assessment of neurological deficits, animals treated with 500 CU/kg lys-plasminogen i.v. showed almost no disabilities (like sham operated animals) when compared to ischemic (positive) controls which were rather severely handicapped. The formulation buffer of lys-plasminogen, tested in an equivalent volume, was without any effect in both set-ups. No fibrinolytic activity was found in plasma samples of rats up to 240 min after treatment with 500 CU/kg lys-plasminogen i.v. It is concluded from these experiments that human lys-plasminogen has a protective effect in rats against the sequelae of global cerebral ischemia which is not related to the well-known fibrinolytic potential but might be a separate quality.

Topics: Animals; Body Water; Brain Chemistry; Brain Edema; Brain Ischemia; Carotid Arteries; Fibrin; Fibrinolytic Agents; Humans; Male; Peptide Fragments; Plasminogen; Rats; Rats, Sprague-Dawley; Reperfusion Injury

The coagulation cascade has a potential role in brain edema formation due to intracerebral hemorrhage. In this study blood and other solutions were injected stereotactically into the right basal ganglia in rats. Twenty-four hours following injection, brain water and ion contents were measured to determine the amount of brain edema. Intracerebral blood resulted in an increase in brain water content. The amount of brain edema surrounding the intracerebral hematoma was reduced by a thrombin inhibitor N alpha-(2-Naphthalenesulfonylglycyl)-4-amidino-DL-phenylalaninep iperidide, (alpha-NAPAP) infused into the hematoma after the clot had been allowed to solidify. The inhibitor did not alter the actual size of the clot mass. An artificial clot composed of fibrinogen, thrombin, and styrene microspheres also produced brain edema. A fibrin clot led to edema formation even in the absence of mass effect provided by the microspheres. The single component responsible for production of brain edema in all these models was thrombin. The edema was formed in response to a fibrinogen-independent pathway. These results indicate that the coagulation cascade is involved in brain edema that develops adjacent to an intracerebral hematoma.

Topics: Animals; Basal Ganglia; Blood Coagulation; Blood-Brain Barrier; Brain Edema; Cerebral Hemorrhage; Fibrin; Male; Rats; Rats, Sprague-Dawley; Thrombin

Topics: Animals; Basophils; Brain Edema; Cerebral Cortex; Cyclophosphamide; Disease Models, Animal; Encephalomyelitis, Autoimmune, Experimental; Endothelium; Extracellular Space; Fibrin; Freund's Adjuvant; Immunization, Passive; Inflammation; Intercellular Junctions; Lymphocytes; Macrophages; Microscopy, Electron; Myelin Basic Protein; Neutrophils; Pertussis Vaccine; Rats

Topics: Brain Diseases; Brain Edema; Fibrin; Kidney Cortex Necrosis; Kidney Diseases; Kidney Glomerulus; Myocardial Infarction; Necrosis; Pathology; Pulmonary Embolism; Shwartzman Phenomenon; Thrombosis