Connectivity-based segmentation of the brainstem by probabilistic tractography.

Diffusion magnetic resonance imaging is a non-invasive tool increasingly used for the investigation of brain connectivity in vivo. In this paper we propose a method that allows segmentation of the brainstem to four subregions (frontopontine, motor, sensory and reticular) based on connections to supratentorial structures, thereby eliminating the need for using anatomical landmarks within the brainstem for the identification of these subregions. The feasibility of connectivity-based brainstem segmentation was investigated in a group of healthy subjects (n = 20). Multifiber probabilistic tractography was performed using the FMRIB Software Library, and connections between a pontomesencephalic seed mask and four supratentorial target regions (anterior and posterior limbs of the internal capsule, sensory and medial thalamus) were used to determine connectivity maps of the brainstem. Results were compared with a neuroanatomy atlas and histological sections, confirming good anatomic correspondence. The four subregions detected by the connectivity-based segmentation showed good intersubject reproducibility. The presented method may be a potential tool to investigate brainstem connectivity in diseases that distort normal anatomy, and quantitative analyses of the diffusion-related parameters may provide additional information on the involvement of brainstem pathways in certain disease states (e.g., traumatic brain injury, demyelinating disorders, brainstem tumors). The potential clinical applicability of the method is demonstrated in two cases of severe traumatic brain injury.

[Increasing cerebral perfusion pressure in serious cranial injury--contradictory effects of dopamine]. / Az agyi perfúziós nyomás emelése dopaminnal--ellentmondásos hatások a súlyos koponyasérülés kezelésében.

BACKGROUND: Management of cerebral perfusion pressure is an important element of the treatment of traumatic brain injury. Vasopressors are accepted as a method of choice to increase mean arterial blood pressure and thus cerebral perfusion pressure in the face of rising intracranial pressure. There are, however, some unresolved issues and potential risks to this therapy. MATERIAL AND METHODS: This study therefore examines the effects of dopamine on physiological changes as well as on brain edema and water content that can be readily assessed by MRI/MRS in (1) a rodent model of rapidly rising intracranial pressure, caused by diffuse injury with secondary insult and (2) a model of cortical contusion. RESULTS: Dopamine was capable of restoring cerebral perfusion pressure in the model of rapidly rising intracranial pressure. However, this was associated with only a partial restoration of cerebral blood flow. In the brain tissue two profiles of change in the apparent diffusion coefficient of water (ADCw) were seen; one in which ADCw recovered to baseline, and one in which ADCw remained persistently low. Despite that dopamine did not alter these profiles, MRI-assessed tissue water content was increased four hours after injury and dopamine increased cerebral water content in both subgroups of injury, especially in the subgroup with a persistently low ADCw (p < 0.01). In the contusion group dopamine significantly worsened the edema both in the injured and in the contralateral area of hippocampus and temporal cortex even though the ADCw values did not change, except for the contralateral hippocampus, where both water content and ADC, values rose with treatment, suggesting extracellular accumulation of water. CONCLUSION: The results suggest that dopamine has a double effect--while it temporarily and partially restores cerebral blood perfusion, at the same time it induces an increase in brain swelling and thus an increase in intracranial pressure in some cases. It is possible that in a subgroup of patients vasopressor treatment leads to an opposite effect several hours later. Vasopressor therapy in the clinical setting therefore should be cautiously applied.

Dynamics and regional distribution of c-fos protein expression in rat brain after a closed head injury.

The objective of this study was to define the time- and brain-area-related distribution of c-fos expression in the brain during the first 24 h following a closed head injury in rats. In the control groups (n = 32), only a few c-fos positive nuclei were observed in the brain and the c-fos staining did not change during the next 24 h. In the closed head injury group c-fos-positive cells were rare in the brain regions during the first 30 min. During the next 2 h, the number of c-fos-positive cells increased rapidly in the basal ganglions, the ventricular ependyma cells the corticospinal tract, the area postrema, the cerebral neocortex, and the corpus callosum. The increase was highest in the corpus callosum (317 +/- 44.5 mm(-2)), in the thalamic reticular nucleus (474.8 +/- 49.2 mm(-2)), in the dentate hilus (1090 +/- 187 mm(-2)) and in the cerebral neocortex (992 +/- 93 mm(-2)). Thereafter, the elevated c-fos expression gradually decreased and at 6 h post-closed head injury no significant differences were observed between the controls and the trauma group. We conclude that a closed head injury induces a large, transient increase of c-fos expression in the brain. Since the observed time course and regional differences in c-fos expression are in good agreement with the cognitive and memory deficits observed after human TBI it can be utilized in further investigations, especially to test the effects of various forms of pharmacological or cellular therapy.

Beta-amyloid peptide-induced blood-brain barrier disruption facilitates T-cell entry into the rat brain.

Activated T-lymphocytes can migrate through the blood-brain barrier (BBB) and are able to invade the central nervous system (CNS). In the present study, we investigated whether disruption of the BBB leads to enhanced T-cell migration into the CNS. Amyloid-beta peptide 25-35 (A beta) or tumor necrosis factor-alpha (TNFalpha) were administered into the right common carotid artery of adult male Wistar rats. The agents were administered either alone, or were followed by a cell suspension of exogenously activated T-cells. Rats of other groups received activated or non-stimulated T-lymphocytes only. Sagittal brain sections were analyzed with immunohistochemistry of CD3 to reveal the presence of T-lymphocytes within the CNS parenchyma. Administration of activated T-cells alone led to T-cell migration into the brain. Infusion of either substances (A beta or TNFalpha) resulted in T-cell invasion of the CNS even when no exogenous T-cells were added. Infusion of either of the agents together with T-lymphocytes generated a more intense T-lymphocyte migration than in the other groups. Electron microscopic analysis and Evans-blue extravasation studies confirmed parallel disruption of the BBB. Our study demonstrates that A beta and TNFalpha induce enhanced T-lymphocyte migration towards the brain. This effect may be attributed at least partly to dysfunctioning of the BBB, but other mechanisms are also possible.

[Cerebral edema and changes of cerebral blood volume in patients with head injuries]. / Az agyödéma és az agyi vértérfogat változása koponyasérült betegekben.

AIM: The pathogenesis of traumatic brain swelling remains unclear. The generally held view is that brain swelling is caused primarily by vascular engorgement and that edema plays a relatively minor role in the swelling process. The goal of this study was to examine the roles of cerebral blood volume (CBV) and edema in traumatic brain swelling. PATIENTS AND METHODS: Both brain-tissue water and CBV were measured in 76 head-injured patients, and the relative contribution of edema and blood to total brain swelling was determined. Comparable measures of brain-tissue water were obtained in 30 healthy volunteers and CBV in seven volunteers. Brain edema was measured using magnetic resonance imaging, implementing a new technique for accurate measurement of total tissue water. Measurements of CBV in subgroup of 31 head-injured patients were based on consecutive measures of cerebral blood flow (CBF) obtained using stable xenon and calculation of mean transit time by dynamic computerized tomography scanning after a rapid bolus injection of iodinated contrast material. RESULTS: The mean (+/- standard deviation) percentage of swelling due to water was 9.37 +/- 8.7%, whereas that due to blood was -0.8 +/- 1.32%. CONCLUSION: The results of this study showed that brain edema is the major fluid component contributing to traumatic brain swelling. Moreover, CBV is reduced in proportion to CBF reduction following severe brain injury.