Neil G. Harris

Time course of cellular pathology after controlled cortical impact injury

Several different models of brain trauma are currently used and each simulates different aspects of the clinical condition and to varying degrees of accuracy. While numerous studies have characterized the cellular pathology after weight-drop or fluid percussion injury, detailed information on the histopathology that evolves after the controlled cortical impact model is incomplete. We have determined the spatiotemporal pathologies of neuronal, axonal, vascular, and macro- and microglial elements at 1, 4, 7, and 28 days after moderate controlled cortical impact injury. Neuronal injury identified by pyknotic perikarya and disrupted neurofilament-stained axonal profiles were evident by 1 day in ipsilateral cortex and hippocampus and at later times in the thalamus. glial fibrillary acidic protein-reactive astrocytes were more widespread, reaching a maximum immunointensity at 4 days across the ipsilateral hemisphere but declining to control levels thereafter. Microglia/macrophage-OX42 staining was initially restricted to the contusion site and then later to the thalamus, consistent with the pattern of neuronal injury. Increases in nestin immunoreactivity-a postulated marker of neural progenitor cells, and in NG2 proteoglycan-a marker of oligodendrocyte precursor cells, were detected by 1 day, reaching maximal immunointensity at 4-7 days after injury. Mean density and diameter of cortical microvessels was significantly reduced and increased respectively but only at the initial time points, suggesting that some degree of vascular remodeling takes place after injury. We discuss these results in light of recent evidence that suggests there may be some degree of endogenous repair after central nervous system injury.

Normal pressure hydrocephalus and cerebral blood flow: a PET study of baseline values

Regional cerebral blood flow (CBF) was studied with O15-water positron emission tomography and anatomic region-of-interest analysis on coregistered magnetic resonance in patients with idiopathic (n = 12) and secondary (n = 5) normal pressure hydrocephalus (NPH). Mean CBF was compared with values obtained from healthy volunteers (n = 12) and with clinical parameters. Mean CBF was significantly decreased in the cerebrum and cerebellum of patients with NPH. The regional analysis demonstrated that CBF was reduced in the basal ganglia and the thalamus but not in white matter regions. The results suggest that the role of the basal ganglia and thalamus in NPH may be more prominent than currently appreciated. The implications for theories regarding the pathogenesis of NPH are discussed.

Positron emission tomography using 18F-labelled endothelin-1 reveals prevention of binding to cardiac receptors owing to tissue-specific clearance by ETB receptors in vivo

1 Our aim was to synthesise an 18F analogue of endothelin‐1 (ET‐1), to dynamically image ET receptors in vivo by positron emission tomography (PET) and to elucidate the function of the ETB subtype as a clearing receptor in organs expressing high densities including kidney and lung. 2 [18F]‐ET‐1 was characterised in vitro and bound with a single subnanomolar affinity (KD=0.43±0.05u2003nM, Bmax=27.8±2.1u2003fmolu2003mg−1 protein) to human left ventricle (n=4). 3 The in vivo distribution of [18F]‐ET‐1 in anaesthetised rats was measured using a dedicated small animal PET scanner (microPET) and ex vivo analysis. 4 Dynamic PET data demonstrated that high levels of radioligand accumulated rapidly in the lung, kidney and liver, consistent with receptor binding. The in vivo distribution correlated with the anatomical localisation of receptors detected in vitro using [125I]‐ET‐1. However, the receptor density visualised in the heart was unexpectedly low compared with that predicted from the in vitro measurements. 5 [18F]‐ET‐1 binding in lungs could not be displaced by the ETB selective antagonist BQ788, in agreement with the proposed internalisation of ET‐1 by ETB receptors. In contrast, infusion of BQ788 prior to injecting [18F]‐ET‐1 significantly reduce the amount of radioligand visualised in the ETB rich lung and kidney by 85% (P<0.05, n=3) and 55% (P<0.05, n=3), respectively. 6 Under conditions of ETB receptor blockade, the heart could be visualised by microPET imaging. 7 These results suggest that clearance by ETB receptors in the lung and kidney prevents binding of ET‐1 to receptors in the heart.

Changes in Cerebral Blood Flow during Cerebrospinal Fluid Pressure Manipulation in Patients with Normal Pressure Hydrocephalus: A Methodological Study:

The combination of cerebral blood flow measurement using 15O-water positron emission tomography with magnetic resonance coregistration and CSF infusion studies was used to study the global and regional changes in CBF with changes in CSF pressure in 15 patients with normal pressure hydrocephalus. With increases in CSF pressure, there was a variable increase in arterial blood pressure between individuals and global CBF was reduced, including in the cerebellum. Regionally, mean CBF decreased in the thalamus and basal ganglia, as well as in white matter regions. These reductions in CBF were significantly correlated with changes in the CSF pressure and with proximity to the ventricles. A three-dimensional finite-element analysis was used to analyze the effects on ventricular size and the distribution of stress during infusion. To study regional cerebral autoregulation in patients with possible normal pressure hydrocephalus, a sensitive CBF technique is required that provides absolute, not relative normalized, values for regional CBF and an adequate change in cerebral perfusion pressure must be provoked.

The Relationship between the Apparent Diffusion Coefficient Measured by Magnetic Resonance Imaging, Anoxic Depolarization, and Glutamate Efflux during Experimental Cerebral Ischemia

A reduction in the apparent diffusion coefficient (ADC) of water measured by magnetic resonance imaging (MRI) has been shown to occur early after cerebrovascular occlusion. This change may be a useful indicator of brain tissue adversely affected by inadequate blood supply. The objective of this study was to test the hypothesis that loss of membrane ion homeostasis and depolarization can occur simultaneously with the drop in ADC. Also investigated was whether elevation of extracellular glutamate ([GLU]e) would occur before ADC changes. High-speed MRI of the trace of the diffusion tensor (15-second time resolution) was combined with simultaneous recording of the extracellular direct current (DC) potential and on-line [GLU]e from the striatum of the anesthetized rat. After a control period, data were acquired during remote middle cerebral artery occlusion for 60 minutes, followed by 30 minutes of reperfusion, and cardiac arrest-induced global ischemia. After either focal or global ischemia, the ADC was reduced by 10 to 25% before anoxic depolarization occurred. After either insult, the time for half the maximum change in ADC was significantly shorter than the corresponding DC potential parameter (P < 0.05). The [GLU]e remained at low levels during the entire period of varying ADC and DC potential and did not peak until much later after either ischemic insult. This study demonstrates that ADC changes can occur before membrane depolarization and that high [GLU]e has no involvement in the early rapid ADC decrease.

18 F-Endothelin-1, a positron emission tomography (PET) radioligand for the endothelin receptor system: radiosynthesis and in vivo imaging using microPET

Positron emission tomography (PET) is a powerful technique with the sensitivity to image and quantify receptor-bound radioligands in vivo. Recent progress in PET scanner technology has resulted in the development of dedicated tomographs designed for small animals, with resolution that allows the delineation of discrete organs and their larger substructures in rats and mice. Our aim was to determine whether endothelin-1 (ET-1) could be labelled with (18)F, and whether the resulting (18)F-ET-1 would have the required pharmacokinetic properties to permit binding and imaging of ET receptors in vivo. (18)F-ET-1 could be produced in a total radiochemical yield of 5.9+/-0.7% in 207+/-3 min (n=20). Specific radioactivities were in the range 220-370 GBq/micromol, and the radiochemical purity of the isolated (18)F-ET-1 was >95%. In vivo distribution in the rat was studied using microPET. High levels of (18)F-ET-1 uptake were found in lung and kidney, whereas liver showed moderate levels of uptake. The resolution of the microPET scanner was sufficient to differentiate heterogeneous uptake in subrenal structures in the rat.

Relationship Between Flow-Metabolism Uncoupling and Evolving Axonal Injury After Experimental Traumatic Brain Injury

Blood flow-metabolism uncoupling is a well-documented phenomenon after traumatic brain injury, but little is known about the direct consequences for white matter. The aim of this study was to quantitatively assess the topographic interrelationship between local cerebral blood flow (LCBF) and glucose metabolism (LCMRglc) after controlled cortical impact injury and to determine the degree of correspondence with the evolving axonal injury. LCMRglc and LCBF measurements were obtained at 3 hours in the same rat from 18F-fluorodeoxyglucose and 14C-iodoantipyrine coregistered autoradiographic images, and compared to the density of damaged axonal profiles in adjacent sections and in an additional group at 24 hours using beta-amyloid precursor protein (ß-APP) immunohistochemistry. LCBF was significantly reduced over the ipsilateral hemisphere by 48 ± 15% compared with sham-controls, whereas LCMRglc was unaffected, apart from foci of elevated LCMRglc in the contusion margin. Flow-metabolism was uncoupled, indicated by a significant 2-fold elevation in the LCMRglc/LCBF ratio within most ipsilateral structures. There was a significant increase in ß-APP-stained axons from 3 to 24 hours, which was negatively correlated with LCBF and positively correlated with the LCMRglc/LCBF ratio at 3 hours in the cingulum and corpus callosum. Our study indicates a possible dependence of axonal outcome on flow-metabolism in the acute injury stage.

Communicating Hydrocephalus: The Biomechanics of Progressive Ventricular Enlargement Revisited

BACKGROUNDnThis article investigates the physical mechanisms involved in the chronic ventricular enlargement that accompanies communicating hydrocephalus (CH)--including its normal and low-pressure forms. In particular, it proposes that this phenomenon can be explained by the combined effect of: (a) a reversal of interstitial fluid flow in the parenchyma, and (b) a reduction in the elastic modulus of the cerebral mantle.nnnMETHODnTo investigate this hypothesis, these changes have been incorporated into a finite element computer simulation of CH, in which brain tissue is idealized as a sponge-like material. The fluid pressure in the lateral ventricles and the subarachnoid space has been set to 10 mmHg, while the fluid pressure inside the parenchyma has been set to 7.5 mmHg. The elastic moduli of white and gray matter have been set to the reduced values of 1 and 5 kPa, respectively.nnnFINDINGSnThe simulation revealed a substantial ventricular distension (6.5 mm mean outward displacement), which was accompanied by the appearance of stress concentrations in the cerebral mantle.nnnINTERPRETATIONnThese results support the notion that a relative reduction in intraparenchymal fluid pressure coupled with low tissue elasticity can produce both a significant ventricular enlargement and periventricular solid stress concentrations.

MRI measurement of blood-brain barrier permeability following spontaneous reperfusion in the starch microsphere model of ischemia

Quantification of the acute increases in blood-brain barrier (BBB) permeability that occur subsequent to experimental ischemic injury has been limited to single time-point, invasive methodologies. Although permeability can be qualitatively assessed to visualise regional changes during sequential studies on the same animal using contrast-enhanced magnetic resonance imaging (MRI), quantitative information on the magnitude of change is required to compare barrier function during sequential studies on the same animal or between different animals. Recently, improvements in MRI tracer kinetic models and in MR hardware design mean that an estimate of permeability in vivo can now be obtained with acceptable accuracy and precision. We report here the use of such methods to study acute changes following spontaneous reperfusion in an animal model of ischemia. We have obtained estimates of BBB permeability following spontaneous reperfusion, subsequent to forebrain ischemia by unilateral carotid injection of starch microspheres in the rat. T2*-weighted and diffusion-trace imaging were used to monitor the initial reduction in CBF and the time-course of ischemia, respectively. Following reperfusion, an intraveneous bolus of dimeglumine gadopentetate (Gd-DTPA) and horseradish peroxidase (HRP) was given during a continuous acquisition of T1 maps with a 48 s temporal resolution. Permeability maps were constructed using a 4-compartment model; K(trans), the permeability-surface area product of the capillary walls was estimated to be 9.2 +/- 0.6 x 10(-4) min(-1) in the cortex. Visualisation of the regional extent of HRP extravasation on histological sections following termination of the experiment demonstrated very little correspondence to the region of Gd-DTPA leakage. Quantitative MRI assessment of BBB permeability following ischemia-reperfusion is consistent with published values obtained by invasive methods. Differences between Gd-DTPA-enhancement and HRP may reflect differences in the molecular size of the tracers.

A Model of the Cerebral and Cerebrospinal Fluid Circulations to Examine Asymmetry in Cerebrovascular Reactivity

The authors examined the steal phenomenon using a new mathematical model of cerebral blood flow and the cerebrospinal fluid circulation. In this model, the two hemispheres are connected through the circle of Willis by an anterior communicating artery (ACoA) of varying size. The right hemisphere has no cerebrovascular reactivity and the left is normally reactive. The authors studied the asymmetry of hemispheric blood flow in response to simulated changes in arterial blood pressure and carbon dioxide concentration. The hemispheric blood flow was dependent on the local regulatory capacity but not on the size of the ACoA. Flow through the ACoA and carotid artery was strongly dependent on the size of the communicating artery. A global interhemispheric “steal effect” was demonstrated to be unlikely to occur in subjects with nonstenosed carotid arteries. Vasoreactive effects on intracranial pressure had a major influence on the circulation in both hemispheres, provoking additional changes in blood flow on the nonregulating side. A method for the quantification of the crosscirculatory capacity has been proposed.