Diffusion tensor imaging detects axonal injury in a mouse model of repetitive closed-skull traumatic brain injury

Mild traumatic brain injuries (TBI) are common in athletes, military personnel, and the elderly, and increasing evidence indicates that these injuries have long-term health effects. However, the difficulty in detecting these mild injuries in vivo is a significant impediment to understanding the underlying pathology and treating mild TBI. In the following experiments, we present the results of diffusion tensor imaging (DTI) and histological analysis of a model of mild repetitive closed-skull brain injury in mouse. Histological markers used included silver staining and amyloid precursor protein (APP) immunohistochemistry to detect axonal injury, and Iba-1 immunohistochemistry to assess microglial activation. At 24h post-injury, before silver staining or microglial abnormalities were apparent by histology, no significant changes in any of the DTI parameters were observed within white matter. At 7 days post-injury we observed a reduction in axial and mean diffusivity. Relative anisotropy at 7 days correlated strongly with the degree of silver staining. Interestingly, APP was not observed at any timepoint examined. In addition to the white matter alterations, mean diffusivity was elevated in ipsilateral cortex at 24h but returned to sham levels by 7 days. Altogether, this demonstrates that DTI is a sensitive method for detecting axonal injury despite a lack of conventional APP pathology. Further, this reflects a need to better understand the histological basis for DTI signal changes in mild TBI.     

Chronic upregulation of activated microglia immunoreactive for galectin-3/Mac-2 and nerve growth factor following diffuse axonal injury

Background  

Diffuse axonal injury in patients with traumatic brain injury (TBI) can be associated with morbidity ranging from cognitive difficulties to coma. Magnetic resonance imaging scans now allow early detection of axonal injury following TBI, and have linked cognitive disability in these patients to white matter signal changes. However, little is known about the pathophysiology of this white matter injury, and the role of microglial activation in this process. It is increasingly recognized that microglia constitute a heterogeneous population with diverse roles following injury. In the present studies, we tested the hypothesis that following diffuse axonal injury involving the corpus callosum, there is upregulation of a subpopulation of microglia that express the lectin galectin-3/Mac-2 and are involved in myelin phagocytosis.     

Diabetes insipidus contributes to traumatic brain injury pathology via CD36 neuroinflammation

Each year, over one million people in the United States are affected by traumatic brain injury (TBI). Symptoms of both acute and chronic neuroinflammation follow TBI, coinciding with a robust immune response and activation of the brain’s endogenous repair mechanisms. TBI can lead to endocrine failure as a result of damage to the thalamic region of the brain, evidenced by excessive thirst and polyuria often accompanying TBI. These symptoms indicate the presence of diabetes insipidus (DI), a disruption of water homeostasis due to antidiuretic hormone deficiency. This deficiency accompanies a mechanical or neuroinflammatory damage to the thalamic region during TBI, evidenced by increased expression of inflammatory microglial marker MHCII in this brain region. Excessive thirst and urinations, which are typical DI symptoms, in our chronic TBI rats also suggest a close connection between TBI and DI. We seek to bridge this gap between TBI and DI through investigation of the Cluster of Differentiation 36 (CD36) receptor. This receptor is associated with Low-Density Lipoprotein (LDL) deregulation, pro-inflammatory events, and innate immunity regulation. We posit that CD36 exacerbates TBI through immune activation and subsequent neuroinflammation. Indeed, scientific evidence already supports pathological interaction of CD36 in other neurological disorders including stroke and Alzheimer’s disease. We propose that DI contributes to TBI pathology via CD36 neuroinflammation. Use of CD36 as a biomarker may provide insights into treatment and disease pathology of TBI and DI. This unexplored avenue of research holds potential for a better understanding and treatment of TBI and DI.     

Microglia‐Derived Macrophage Colony Stimulating Factor Promotes Generation of Proinflammatory Cytokines by Astrocytes in the Periventricular White Matter in the Hypoxic Neonatal Brain

Inflammation in the periventricular white matter (PWM) of hypoxic neonatal brain causes myelination disturbances. In this connection, macrophage colony‐stimulating factor (M‐CSF) has been reported to regulate release of proinflammatory cytokines that may be linked to PWM damage. We sought to determine if M‐CSF derived from amoeboid microglial cells (AMC) would promote proinflammatory cytokine production by astrocytes in the PWM following hypoxic exposure, and, if so, whether it is associated with axon degeneration and myelination disturbances. In 1‐day hypoxic rats, expression of M‐CSF was upregulated in AMC. This was coupled with increased expression of CSF‐1 receptor, tumor necrosis factor‐α (TNF‐α) and interleukin‐1β (IL‐1β) in astrocytes, and TNF‐receptor 1 and IL‐receptor 1 on the axons. Neurofilament‐200 immunopositive axons and myelin basic protein immunopositive processes appeared to undergo disruption in 14‐days hypoxic rats. By electron microscopy, some axons showed degenerative changes affecting the microtubules and myelin sheath. Primary cultured microglial cells subjected to hypoxia showed enhanced release of M‐CSF. Remarkably, primary cultured astrocytes treated with conditioned‐medium derived from hypoxic microglia or M‐CSF exhibited increased production of TNF‐α and IL‐1β. Our results suggest that AMC‐derived M‐CSF promotes astrocytes to generate proinflammatory cytokines, which may be involved in axonal damage following a hypoxic insult.     

Widespread τ and amyloid-β pathology many years after a single traumatic brain injury in humans

While a history of a single traumatic brain injury (TBI) is associated with the later development of syndromes of cognitive impairment such as Alzheimer's disease, the long-term pathology evolving after single TBI is poorly understood. However, a progressive tauopathy, chronic traumatic encephalopathy, is described in selected cohorts with a history of repetitive concussive/mild head injury. Here, post-mortem brains from long-term survivors of just a single TBI (1-47 years survival; n=39) vs. uninjured, age-matched controls (n=47) were examined for neurofibrillary tangles (NFTs) and amyloid-β (Aβ) plaques using immunohistochemistry and thioflavine-S staining. Detailed maps of findings permitted classification of pathology using semiquantitative scoring systems. NFTs were exceptionally rare in young, uninjured controls, yet were abundant and widely distributed in approximately one-third of TBI cases. In addition, Aβ-plaques were found in a greater density following TBI vs. controls. Moreover, thioflavine-S staining revealed that while all plaque-positive control cases displayed predominantly diffuse plaques, 64% of plaque-positive TBI cases displayed predominantly thioflavine-S-positive plaques or a mixed thioflavine-S-positive/diffuse pattern. These data demonstrate that widespread NFT and Aβ plaque pathologies are present in up to a third of patients following survival of a year or more from a single TBI. This suggests that a single TBI induces long-term neuropathological changes akin to those found in neurodegenerative disease.     

Illuminating protein interactions in tissue using confocal and two-photon excitation fluorescent resonance energy transfer microscopy

Traumatic brain injury (TBI) remains the most common cause of death in persons under age 45 in the Western world. One of the principal determinants of morbidity and mortality following TBI is traumatic axonal injury (TAI). Current hypotheses on the pathogenesis of TAI involve activation of apoptotic cascades secondary to TBI. While a number of studies have demonstrated direct evidence for the activation of apoptotic cascades in TAI, the precise pathway by which these cascades are initiated remains a subject of intense investigation. As axolemmal disruption with the subsequent intra-axonal influx of large molecular weight species has been demonstrated to occur in relation to local axonal breakdown, attention has focused on cascades that may occur as a result of loss of ionic homeostasis. One proposed pathway by which this has been hypothesized to occur is the Ca(2+)-mediated activation of calmodulin and subsequent activation of the phosphatase calcineurin with dephosphorylation of a protein known as BAD, leading to a proapoptotic interaction between BAD and the mitochondrial protein Bcl-xL. While this pathway is an intriguing route for traumatic axonal pathogenesis, neither conventional immunocytochemical/histochemical nor ultrastructural approaches have had the capacity to shed insight on whether BAD and Bcl-xL interact in TAI in vivo. We describe the implementation of confocal and two-photon excitation fluorescence resonance energy transfer (FRET) microscopy techniques through which we demonstrate interaction between the proapoptotic protein BAD and the prosurvival protein Bcl-xL within TAI following TBI. Further, we report on a method to reliably detect protein interactions within aldehyde fixed tissue sections through conventional immunohistochemical approaches.     

Axonal injury following mild traumatic brain injury is exacerbated by repetitive insult and is linked to the delayed attenuation of NeuN expression without concomitant neuronal death in the mouse

Mild traumatic brain injury (mTBI) affects brain structure and function and can lead to persistent abnormalities. Repetitive mTBI exacerbates the acute phase response to injury. Nonetheless, its long‐term implications remain poorly understood, particularly in the context of traumatic axonal injury (TAI), a player in TBI morbidity via axonal disconnection, synaptic loss and retrograde neuronal perturbation. In contrast to the examination of these processes in the acute phase of injury, the chronic‐phase burden of TAI and/or its implications for retrograde neuronal perturbation or death have received little consideration. To critically assess this issue, murine neocortical tissue was investigated at acute (24‐h postinjury, 24hpi) and chronic time points (28‐days postinjury, 28dpi) after singular or repetitive mTBI induced by central fluid percussion injury (cFPI). Neurons were immunofluorescently labeled for NeuroTrace and NeuN (all neurons), p‐c‐Jun (axotomized neurons) and DRAQ5 (cell nuclei), imaged in 3D and quantified in automated manner. Single mTBI produced axotomy in 10% of neurons at 24hpi and the percentage increased after repetitive injury. The fraction of p‐c‐Jun+ neurons decreased at 28dpi but without neuronal loss (NeuroTrace), suggesting their reorganization and/or repair following TAI. In contrast, NeuN+ neurons decreased with repetitive injury at 24hpi while the corresponding fraction of NeuroTrace+ neurons decreased over 28dpi. Attenuated NeuN expression was linked exclusively to non‐axotomized neurons at 24hpi which extended to the axotomized at 28dpi, revealing a delayed response of the axotomized neurons. Collectively, we demonstrate an increased burden of TAI after repetitive mTBI, which is most striking in the acute phase response to the injury. Our finding of widespread axotomy in large fields of intact neurons contradicts the notion that repetitive mTBI elicits progressive neuronal death, rather, emphasizing the importance of axotomy‐mediated change.     

骨髓间充质干细胞立体定向移植联合亚低温治疗大鼠脑损伤

背景：临床研究证明,亚低温(33~35 ℃)能有效减轻继发性脑和脊髓损伤,对中枢神经损伤有确切的保护作用。 目的：检测是否可以通亚低温治疗的方法提高骨髓间充质干细胞立体定向移植对重型颅脑损伤大鼠的治疗效果。 方法：采用液压颅脑损伤仪,给予Wistar大鼠2.53.31~303.98 kPa液压冲击力,制成重型液压颅脑损伤大鼠模型,将其随机分为脑损伤组,骨髓间充质干细胞移植组,亚低温+骨髓间充质干细胞组。后2组伤后6 h将体外培养的SD大鼠骨髓间充质干细胞立体定向移植到脑损伤灶内,亚低温+骨髓间充质干细胞组同时给予低温治疗。伤后第3天用Western Blot检测脑组织中AQP4蛋白合成的变化,采用干湿比重法测脑组织含水量。伤后24 h,3 d及伤后1,2 周行动物神经学缺损评分,2周后处死行免疫组织化学和苏木精-伊红染色。 结果与结论：亚低温治疗后,与脑损伤组和骨髓间充质干细胞移植组相比,亚低温+骨髓间充质干细胞组AQP4蛋白表达量及脑水肿程度也明显降低(P < 0.05),移植后1和2周,亚低温+骨髓间充质干细胞组的大鼠神经学缺损评分明显低于其他两组;且其脑组织切片中的神经元数量较其他两组明显增多(P < 0.01)。提示骨髓间充质干细胞立体定向移植联合亚低温治疗大鼠脑损伤可明显改善重型颅脑损伤后大鼠的神经学功能。     

Isoform‐specific upregulation of FynT kinase expression is associated with tauopathy and glial activation in Alzheimer's disease and Lewy body dementias

Cumulative data suggest the involvement of Fyn tyrosine kinase in Alzheimer''s disease (AD). Previously, our group has shown increased immunoreactivities of the FynT isoform in AD neocortex (with no change in the alternatively spliced FynB isoform) which associated with neurofibrillary degeneration and reactive astrogliosis. Since both the aforementioned neuropathological features are also variably found in Lewy Body dementias (LBD), we investigated potential perturbations of Fyn expression in the post‐mortem neocortex of patients with AD, as well as those diagnosed as having one of the two main subgroups of LBD: Parkinson''s disease dementia (PDD) and dementia with Lewy bodies (DLB). We found selective upregulation of FynT expression in AD, PDD, and DLB which also correlated with cognitive impairment. Furthermore, increased FynT expression correlated with hallmark neuropathological lesions, soluble β‐amyloid, and phosphorylated tau, as well as markers of microglia and astrocyte activation. In line with the human post‐mortem studies, cortical FynT expression in aged mice transgenic for human P301S tau was upregulated and further correlated with accumulation of aggregated phosphorylated tau as well as with microglial and astrocytic markers. Our findings provide further evidence for the involvement of FynT in neurodegenerative dementias, likely via effects on tauopathy and neuroinflammation.     

Wallerian Degeneration: A Major Component of Early Axonal Pathology in Multiple Sclerosis

Axonal loss is a major component of the pathology of multiple sclerosis (MS) and the morphological basis of permanent clinical disability. It occurs in demyelinating plaques but also in the so‐called normal‐appearing white matter (NAWM). However, the contribution of Wallerian degeneration to axonal pathology is not known. Here, we analyzed the extent of Wallerian degeneration and axonal pathology in periplaque white matter (PPWM) and lesions in early multiple sclerosis biopsy tissue from 63 MS patients. Wallerian degeneration was visualized using an antibody against the neuropeptide Y receptor Y1 (NPY‐Y1R). The number of SMI‐32‐positive axons with non‐phosphorylated neurofilaments was significantly higher in both PPWM and plaques compared to control white matter. APP‐positive, acutely damaged axons were found in significantly higher numbers in plaques compared to PPWM. Strikingly, the number of NPY‐Y1R‐positive axons undergoing Wallerian degeneration was significantly higher in PPWM and plaques than in control WM. NPY‐Y1R‐positive axons in PPWM were strongly correlated to those in the lesions. Our results show that Wallerian degeneration is a major component of axonal pathology in the periplaque white matter in early MS. It may contribute to radiological changes observed in early MS and most likely plays a major role in the development of disability.     

Distinct changes in all major components of the neurovascular unit across different neuropathological stages of Alzheimer's disease

In the brain capillaries, endothelial cells, pericytes, astrocytes and microglia form a structural and functional complex called neurovascular unit (NVU) which is critically involved in maintaining neuronal homeostasis. In the present study, we applied a comprehensive immunohistochemical approach to investigate the structural alterations in the NVU across different Alzheimer''s disease (AD) neuropathological stages. Post‐mortem human cortical and hippocampal samples derived from AD patients and non‐demented elderly control individuals were immunostained using a panel of markers representing specific components of the NVU including Collagen IV (basement membrane), PDGFR‐β (pericytes), GFAP (astrocytes), Iba1 (microglia), MRC1 (perivascular macrophages) and lectin as an endothelial cell label. Astrocytes (GFAP) and microglia (Iba1) were quantified both in the whole visual‐field and specifically within the NVU, and the sample set was additionally analyzed using anti‐tau (AT8) and three different anti‐Aβ (clones G2‐10, G2‐11, 4G8) antibodies. Analyses of lectin labeled sections showed an altered vascular distribution in AD patients as revealed by a reduced nearest distance between capillaries. Within the NVU, a Braak‐stage dependent reduction in pericyte coverage was identified as the earliest structural alteration during AD progression. In comparison to non‐demented elderly controls, AD patients showed a significantly higher astrocyte coverage within the NVU, which was paralleled by a reduced microglial coverage around capillaries. Assessment of perivascular macrophages moreover demonstrated a relocation of these cells from leptomeningeal arteries to penetrating parenchymal vessels in AD patients. Collectively, the results of our study represent a comprehensive first in‐depth analysis of AD‐related structural changes in the NVU and suggest distinct alterations in all components of the NVU during AD progression.     

COVID‐19‐related neuropathology and microglial activation in elderly with and without dementia

The actual role of SARS‐CoV‐2 in brain damage remains controversial due to lack of matched controls. We aim to highlight to what extent is neuropathology determined by SARS‐CoV‐2 or by pre‐existing conditions. Findings of 9 Coronavirus disease 2019 (COVID‐19) cases and 6 matched non‐COVID controls (mean age 79 y/o) were compared. Brains were analyzed through immunohistochemistry to detect SARS‐CoV‐2, lymphocytes, astrocytes, endothelium, and microglia. A semi‐quantitative scoring was applied to grade microglial activation. Thal‐Braak stages and the presence of small vessel disease were determined in all cases. COVID‐19 cases had a relatively short clinical course (0–32 days; mean: 10 days), and did not undergo mechanical ventilation. Five patients with neurocognitive disorder had delirium. All COVID‐19 cases showed non‐SARS‐CoV‐2‐specific changes including hypoxic‐agonal alterations, and a variable degree of neurodegeneration and/or pre‐existent SVD. The neuroinflammatory picture was dominated by ameboid CD68 positive microglia, while only scant lymphocytic presence and very few traces of SARS‐CoV‐2 were detected. Microglial activation in the brainstem was significantly greater in COVID‐19 cases (p = 0.046). Instead, microglial hyperactivation in the frontal cortex and hippocampus was clearly associated to AD pathology (p = 0.001), regardless of the SARS‐CoV‐2 infection. In COVID‐19 cases complicated by delirium (all with neurocognitive disorders), there was a significant enhancement of microglia in the hippocampus (p = 0.048). Although higher in cases with both Alzheimer''s pathology and COVID‐19, cortical neuroinflammation is not related to COVID‐19 per se but mostly to pre‐existing neurodegeneration. COVID‐19 brains seem to manifest a boosting of innate immunity with microglial reinforcement, and adaptive immunity suppression with low number of brain lymphocytes probably related to systemic lymphopenia. Thus, no neuropathological evidence of SARS‐CoV‐2‐specific encephalitis is detectable. The microglial hyperactivation in the brainstem, and in the hippocampus of COVID‐19 patients with delirium, appears as a specific topographical phenomenon, and probably represents the neuropathological basis of the “COVID‐19 encephalopathic syndrome” in the elderly.     

Impact of α‐synuclein spreading on the nigrostriatal dopaminergic pathway depends on the onset of the pathology

Misfolded α‐synuclein spreads along anatomically connected areas through the brain, prompting progressive neurodegeneration of the nigrostriatal pathway in Parkinson''s disease. To investigate the impact of early stage seeding and spreading of misfolded α‐synuclein along with the nigrostriatal pathway, we studied the pathophysiologic effect induced by a single acute α‐synuclein preformed fibrils (PFFs) inoculation into the midbrain. Further, to model the progressive vulnerability that characterizes the dopamine (DA) neuron life span, we used two cohorts of mice with different ages: 2‐month‐old (young) and 5‐month‐old (adult) mice. Two months after α‐synuclein PFFs injection, we found that striatal DA release decreased exclusively in adult mice. Adult DA neurons showed an increased level of pathology spreading along with the nigrostriatal pathway accompanied with a lower volume of α‐synuclein deposition in the midbrain, impaired neurotransmission, rigid DA terminal composition, and less microglial reactivity compared with young neurons. Notably, preserved DA release and increased microglial coverage in the PFFs‐seeded hemisphere coexist with decreased large‐sized terminal density in young DA neurons. This suggests the presence of a targeted pruning mechanism that limits the detrimental effect of α‐synuclein early spreading. This study suggests that the impact of the pathophysiology caused by misfolded α‐synuclein spreading along the nigrostriatal pathway depends on the age of the DA network, reducing striatal DA release specifically in adult mice.     

A lack of amyloid beta plaques despite persistent accumulation of amyloid beta in axons of long-term survivors of traumatic brain injury

Traumatic brain injury (TBI) is a risk factor for developing Alzheimer's disease (AD). Additionally, TBI induces AD-like amyloid β (Aβ) plaque pathology within days of injury potentially resulting from massive accumulation of amyloid precursor protein (APP) in damaged axons. Here, progression of Aβ accumulation was examined using brain tissue from 23 cases with post-TBI survival of up to 3 years. Even years after injury, widespread axonal pathology was consistently observed and was accompanied by intra-axonal co-accumulations of APP with its cleavage enzymes, beta-site APP cleaving enzyme and presenilin-1 and their product, Aβ. However, in marked contrast to the plaque pathology noted in short-term cases post TBI, virtually no Aβ plaques were found in long-term survivors. A potential mechanism for Aβ plaque regression was suggested by the post-injury accumulation of an Aβ degrading enzyme, neprilysin. These findings fail to support the premise that progressive plaque pathology after TBI ultimately results in AD.     

Diffuse axonal injury induced by simultaneous moderate linear and angular head accelerations in rats

Diffuse axonal injury (DAI) is one of the most common and important pathologic features of human traumatic brain injury (TBI), accounting for high mortality and development of persistent post-traumatic neurologic sequelae. Although a relatively high number of therapies have been shown to be effective in experimental models, there are currently few treatments that are effective for improving the prognosis of clinical DAI. A major reason is the failure of current models to validly reproduce the pathophysiological characteristics observed after clinical DAI. In the present study, we employed a specially designed, highly controllable model to induce a sudden rotation in the coronal plane (75 degrees rotation at 1.6×10⁴ degrees/s) combined with lateral translation (1.57 cm displacement at 3.4×10² cm/s) to the rat's head. We were interested in discovering whether the combined accelerations could reproduce the pathophysiological changes analogous to those seen in human DAI. The axonal injury as assessed with amyloid protein precursor (APP) as a marker was consistently present in all injured rats. The commonly injured brain regions included the subcortical regions, deep white matter, corpus callosum and brain stem. The evolution of APP accumulations in brain sections depicted the detailed progression of axonal pathology. Ultrastructural studies gave further insights into the presence and progression of axonal injury. All injured rats exhibited transient physiological dysfunction, as well as immediate and dramatic neurological impairment that still persisted at 14 days after injury. These results suggest that this model reproduced the major pathophysiological changes analogous to those observed after severe clinical TBI and provides an attractive vehicle for experimental brain injury research.     

Higher levels of kallikrein‐8 in female brain may increase the risk for Alzheimer's disease

Women seem to have a higher vulnerability to Alzheimer''s disease (AD), but the underlying mechanisms of this sex dichotomy are not well understood. Here, we first determined the influence of sex on various aspects of Alzheimer''s pathology in transgenic CRND8 mice. We demonstrate that beta‐amyloid (Aβ) plaque burden starts to be more severe around P180 (moderate disease stage) in female transgenics when compared to males and that aging aggravates this sex‐specific difference. Furthermore, we show that female transgenics suffer from higher levels of neurovascular dysfunction around P180, resulting in impaired Aβ peptide clearance across the blood‐brain‐barrier at P360. Female transgenics show also higher levels of diffuse microgliosis and inflammation, but the density of microglial cells surrounding Aβ plaques is less in females. In line with this finding, testosterone compared to estradiol was able to improve microglial viability and Aβ clearance in vitro. The spatial memory of transgenics was in general poorer than in wildtypes and at P360 worse in females irrespective of their genotype. This difference was accompanied by a slightly diminished dendritic complexity in females. While all the above‐named sex‐differences emerged after the onset of Aβ pathology, kallikrein‐8 (KLK8) protease levels were, as an exception, higher in female than in male brains very early when virtually no plaques were detectable. In a second step, we quantified cerebral KLK8 levels in AD patients and healthy controls, and could ascertain, similar to mice, higher KLK8 levels not only in AD‐affected but also in healthy brains of women. Accordingly, we could demonstrate that estradiol but not testosterone induces KLK8 synthesis in neuronal and microglial cells. In conclusion, multiple features of AD are more pronounced in females. Here, we show for the first time that this sex‐specific difference may be meditated by estrogen‐induced KLK8 overproduction long before AD pathology emerges.     

Heterogeneity of cellular inflammatory responses in ageing white matter and relationship to Alzheimer’s and small vessel disease pathologies

White matter lesions (WML) are common in the ageing brain, often arising in a field effect of diffuse white matter abnormality. Although WML are associated with cerebral small vessel disease (SVD) and Alzheimer’s disease (AD), their cause and pathogenesis remain unclear. The current study tested the hypothesis that different patterns of neuroinflammation are associated with SVD compared to AD neuropathology by assessing the immunoreactive profile of the microglial (CD68, IBA1 and MHC‐II) and astrocyte (GFAP) markers in ageing parietal white matter (PARWM) obtained from the Cognitive Function and Ageing Study (CFAS), an ageing population‐representative neuropathology cohort. Glial responses varied extensively across the PARWM with microglial markers significantly higher in the subventricular region compared to either the middle‐zone (CD68 p = 0.028, IBA1 p < 0.001, MHC‐II p < 0.001) or subcortical region (CD68 p = 0.002, IBA1 p < 0.001, MHC‐II p < 0.001). Clasmatodendritic (CD) GFAP⁺ astrocytes significantly increased from the subcortical to the subventricular region (p < 0.001), whilst GFAP⁺ stellate astrocytes significantly decreased (p < 0.001). Cellular reactions could be grouped into two distinct patterns: an immune response associated with MHC‐II/IBA1 expression and CD astrocytes; and a more innate response characterised by CD68 expression associated with WML. White matter neuroinflammation showed weak relationships to the measures of SVD, but not to the measures of AD neuropathology. In conclusion, glial responses vary extensively across the PARWM with diverse patterns of white matter neuroinflammation. Although these findings support a role for vascular factors in the pathogenesis of age‐related white matter neuroinflammation, additional factors other than SVD and AD pathology may drive this. Understanding the heterogeneity in white matter neuroinflammation will be important for the therapeutic targeting of age‐associated white matter damage.     

Magnetic resonance identified ventricular dilation in traumatic brain injury: comparison of pre- and postin jury scan and postin jury results.

A case study is presented in which a patient received magnetic resonance (MR) imaging of the brain 3 months prior to a severe traumatic brain injury (TBI). The post-TBI MR findings are compared and contrasted with the pre-TBI MR images. The posttraumatic changes demonstrate a significant dilation of the ventricular system which reflects diffuse axonal injury and loss of brain substance. Correspondingly, the neuropsychological studies in this individual reflect global deficits which match the nonspecific, traumatically induced degenerative changes found in the postinjury MR scan. This case study is unique in that specific preinjury MR findings are available for direct comparison and quantitative analysis of TBI-associated changes in brain structure with neuropsychological outcome.     

White Matter Integrity Following Traumatic Brain Injury: The Association with Severity of Injury and Cognitive Functioning

Traumatic brain injury (TBI) frequently results in impairments of memory, speed of information processing, and executive functions that may persist over many years. Diffuse axonal injury is one of the key pathologies following TBI, causing cognitive impairments due to the disruption of cortical white matter pathways. The current study examined the association between injury severity, cognition, and fractional anisotropy (FA) following TBI. Two diffusion tensor imaging techniques—region-of-interest tractography and tract-based spatial statistics—were used to assess the FA of white matter tracts. This study examined the comparability of these two approaches as they relate to injury severity and cognitive performance. Sixty-eight participants with mild-to-severe TBI, and 25 healthy controls, underwent diffusion tensor imaging analysis. A subsample of 36 individuals with TBI also completed cognitive assessment. Results showed reduction in FA values for those with moderate and severe TBI, compared to controls and individuals with mild TBI. Although FA tended to be lower for individuals with mild TBI no significant differences were found compared to controls. Information processing speed and executive abilities were most strongly associated with the FA of white matter tracts. The results highlight similarities and differences between region-of-interest tractography and tract-based spatial statistics approaches, and suggest that they may be used together to explore pathology following TBI.