Experimental brain tumors and edema in rats

The extracellular space in the edematous human cerebral cortex: an electron microscopic study using cortical biopsies

In a vascular anomaly showing moderate edema, the extracellular space appeared apparently normal, exhibiting a membrane to membrane space of about 20 nm in width. In congenital hydrocephalus, this space appeared notably enlarged and occupied by an electron transparent, nonproteinaceous interstitial edema fluid, due to abnormal accumulation of cerebrospinal fluid. In brain trauma, the distended extracellular space contained either electron-lucid nonproteinaceous or electron-dense proteinaceous edema fluid. Hemorrhagic foci, fibrinoid material, and non-nervous invading cells, such as macrophages and monocytes, were also found. In brain tumors, the widened extracellular space showed electron-dense proteinaceous edema fluid and bundles of fibrinoid material. The enlarged extracellular space found in congenital hydrocephalus, vascular anomalies, brain trauma, and tumors is closely related to the clinical symptoms exhibited by the patients under study.

Pathophysiology of brain edema formation

A number of mechanisms seem to be involved in edema formation after an ICH. At least three phases of edema are involved in ICH. These include a very early phase (first several hours) involving hydrostatic pressure and clot retraction, a second phase (first 2 days) involving the activation of the coagulation cascade and thrombin production, and a third phase (after 3 days) involving RBC lysis and hemoglobin-induced neuronal toxicity. Activation of the complement system in brain parenchyma also plays an important role in the second and third phases. There are potential therapeutic strategies to address each of these mechanisms. Because the adverse effect of an ICH seems to result from a toxic effect of blood components on brain tissue, early clot removal may be the best strategy, because it results in the removal of all the toxic components [93]. Hematoma aspiration after tissue plasminogen activator (tPA) infusion has also been shown to be relatively safe and effective in animal models. Kaufman et al [94] reported that tPA lysed the hematoma in minutes and did not cause inflammation or bleeding in rabbits. Because clots lysed with tPA can be aspirated through a needle or catheter, mechanical brain injury by this method is minimized. In a rat model, aspiration of clot with tPA reduced clot volume and brain injury [95,96]. Recently, Wagner et al [97] infused tPA into hematomas in a porcine model at 3 hours after induction and aspirated the liquified clots 1 hour later. Clot removal after tPA treatment resulted in a 72% reduction in hematoma volume compared with untreated controls. Clot removal also reduced brain edema volume and BBB disruption and improved cerebral tissue pressure [93]. Six randomized trials have been accomplished, but surgical evacuation of the clot remains controversial [98-103]. Recently, thrombolysis and aspiration under CT guidance reduced the hematoma volume effectively [104]. Infusion of tPA directly into the hematoma before clot aspiration has also been used in human beings. Up to 90% of the original hematoma volume can be removed [105, 106]. Schaller et al [107] injected tPA directly into a hematoma 72 hours after the ictus in patients. The hematomas were lysed, and the liquified clots were drained in 14 patients. Two patients died, but none had recurrent hemorrhage. In conclusion, much has been learned about the basic mechanisms involved in edema formation after ICH. Animal models indicate that a number of components of blood are capable of inducing brain injury and brain edema. Now, it is time to translate that basic information into clinical trials.

Role of the CNS microvascular pericyte in the blood-brain barrier

Pericytes are a very important cellular constituent of the blood-brain barrier. They play a regulatory role in brain angiogenesis, endothelial cell tight junction formation, blood-brain barrier differentiation, as well as contribute to the microvascular vasodynamic capacity and structural stability. Central nervous system pericytes express macrophage functions and are actively involved in the neuroimmune network operating at the blood-brain barrier. They exhibit unique functional characteristics critical for the pathogenesis of a number of cerebrovascular, neurodegenerative, and neuroimmune diseases.

Ultrastructural and morphometric investigation of human brain capillaries in normal and peritumoral tissues

Capillaries of peritumoral and normal brain tissues were ultrastructurally and morphometrically investigated to evaluate the changes in peritumoral capillaries connected with the tumor-associated vasogenic edema. The endothelial cells of peritumoral capillaries showed varying thickness, electron-lucent cytoplasm, and structurally normal tight junctions. The basal lamina was thickened, rarefied, and vacuolated. The pericytes were provided with pinocytotic vesicles and phagocytic bodies. The astrocytic glia appeared empty or swollen, with few glycogen granules and a disarranged cytoskeleton; well-preserved glia was occasionally observed. The brain tissue was slightly edematous. No statistically significant differences were observed between normal and peritumoral capillaries as regards diameter, wall thickness, endothelial thickness, and endothelial vesicle density. Instead, the peritumoral capillaries displayed three times as many endothelial surface-connected vesicles, a markedly thicker basal lamina, and significantly reduced extension of pericytic and glial investments. The kind and severity of the vascular modifications, compared with the slight edematous appearance of the nervous tissue, strengthen the hypothesis that peritumoral capillaries could be involved in the edema resolution process.

Quantitative study of microvessel ultrastructure in human peritumoral brain tissue. Evidence for a blood-brain barrier defect

The form and function of blood vessels are determined by the cells that constitute their microenvironment. Brain tissue around tumors contains varying numbers of tumor cells that could influence local capillaries to lose their blood-brain barrier (BBB), as they do in the tumor itself. Microvascular permeability cannot be measured directly in humans but can be inferred from a knowledge of vessel ultrastructure. The authors have examined the vascular ultrastructure associated with the BBB in human peritumoral brain tissue for evidence of BBB compromise and to correlate BBB features with the cellular components of the vessel microenvironment. Light microscopic examination of brain tissue samples in patients with primary brain tumors showed that the tissue lying beyond the visible edge of the tumor ranged from essentially normal to grossly infiltrated with tumor cells. Although some of the vessels were structurally normal, the microvessels as a group had elongated junctional clefts (unfused regions) and an increase in the density of endothelial vesicles. Furthermore, the cleft index (the percentage of the junctional profile that is unfused) varied directly with the local cell density. A subpopulation of vessels enveloped by a layer of tumor cells was grossly abnormal. However, vessels that were not immediately invested by tumor cells also showed some abnormalities. It is concluded that tumor cells infiltrating peritumoral brain tissue cause blood vessels to take on some of the structural characteristics of leaky vessels. Since direct contact is not required, and since the degree of abnormality correlates with the number of tumor cells in the environment, the authors suggest that this inductive influence is exerted over a distance and is dependent on the concentration of the inducing factors.