Ming-Kai Ho

In vivo histology of the myelin g-ratio with magnetic resonance imaging

The myelin g-ratio, defined as the ratio between the inner and the outer diameter of the myelin sheath, is a fundamental property of white matter that can be computed from a simple formula relating the myelin volume fraction to the fiber volume fraction or the axon volume fraction. In this paper, a unique combination of magnetization transfer, diffusion imaging and histology is presented, providing a novel method for in vivo magnetic resonance imaging of the axon volume fraction and the myelin g-ratio. Our method was demonstrated in the corpus callosum of one cynomolgus macaque, and applied to obtain full-brain g-ratio maps in one healthy human subject and one multiple sclerosis patient. In the macaque, the g-ratio was relatively constant across the corpus callosum, as measured by both MRI and electron microscopy. In the human subjects, the g-ratio in multiple sclerosis lesions was higher than in normal appearing white matter, which was in turn higher than in healthy white matter. Measuring the g-ratio brings us one step closer to fully characterizing white matter non-invasively, making it possible to perform in vivo histology of the human brain during development, aging, disease and treatment.

Cortical atrophy and hypoperfusion in a transgenic mouse model of Alzheimer's disease

Magnetic resonance imaging studies have revealed distinct patterns of cortical atrophy and hypoperfusion in patients with Alzheimers disease. The relationship between these in vivo imaging measures and the corresponding underlying pathophysiological changes, however, remains elusive. Recently, attention has turned to neuroimaging of mouse models of Alzheimers disease in which imaging-pathological correlations can be readily performed. In this study, anatomical and arterial spin labeling perfusion magnetic resonance imaging scans of amyloid precursor protein transgenic and age-matched wild-type mice were acquired at 3, 12, and 18 months of age. Fully-automated image processing methods were used to derive quantitative measures of cortical thickness and perfusion. These studies revealed increased regional cortical thickness in young transgenic mice relative to age-matched wild-type mice. However, the transgenic mice generally demonstrated a greater rate of cortical thinning over 15 months. Cortical perfusion was significantly reduced in young transgenic mice in comparison with wild-type mice across most brain regions. Previously unreported regional genotype differences and age-related changes in cortical thickness and cerebral perfusion were identified in amyloid precursor protein transgenic and wild-type mice.

Early cortical thickness changes predict β-amyloid deposition in a mouse model of Alzheimer's disease.

Magnetic resonance imaging (MRI) studies have identified aberrant cortical structure in Alzheimers disease (AD). The association between MRI-derived cortical morphometry measures and β-amyloid, however, remains poorly understood. In this study, we explored the potential relationship between early alterations in cortical thickness and later stage β-amyloid deposition, using a novel approach, in a transgenic AD mouse model. We acquired longitudinal anatomical MRI scans from mutant amyloid precursor protein (APP) transgenic mice and age-matched wild-type mice at 1 and 3.5months-of-age, and employed fully-automated image processing methods to derive objective, quantitative measures of cortical thickness on a region-of-interest basis. We also generated 3D quantitative immunohistochemistry (qIHC) volumes of deposited β-amyloid burden from 18month-old transgenic mice using an automated, production-level process. These studies revealed thinner cortex in most regions in the 1month-old transgenic mice relative to age-matched wild-types, with the exception of the frontal, perirhinal/entorhinal, posterior cingulate, and retrosplenial cortical regions. Between 1 and 3.5months-of-age, the transgenic mice demonstrated stable or increasing cortical thickness, while the wild-type mice showed cortical thinning. Based on data from co-registered 3D MRI and qIHC volumes, we identified an association between abnormal, early, regional cortical thickness change over 2.5months and later β-amyloid deposition. These observations suggest that the spatio-temporal pattern of early (pre-plaque) alterations in cerebral cortical structure is indicative of regional predisposition to later β-amyloid pathology in a transgenic AD mouse model.

Quantitative analysis of the myelin g-ratio from electron microscopy images of the macaque corpus callosum

We provide a detailed morphometric analysis of eight transmission electron micrographs (TEMs) obtained from the corpus callosum of one cynomolgus macaque. The raw TEM images are included in the article, along with the distributions of the axon caliber and the myelin g-ratio in each image. The distributions are analyzed to determine the relationship between axon caliber and g-ratio, and compared against the aggregate metrics (myelin volume fraction, fiber volume fraction, and the aggregate g-ratio), as defined in the accompanying research article entitled ‘In vivo histology of the myelin g-ratio with magnetic resonance imaging’ (Stikov et al., NeuroImage, 2015).

MicroRNA Expression Patterns in Human Astrocytes in Relation to Anatomical Location and Age.

Anatomic distribution and age are variables linked to functions of astrocytes under physiologic and pathologic conditions. We measured the relative expression of a panel of microRNAs (miRNAs) in astrocytes captured by laser micro-dissection from normal human adult white and grey matter, human fetal white matter and germinal matrix samples. Although expression of most miRNAs was comparable between adult and fetal samples, regional differences were observed. In the adult cerebral cortex, expression of miRNAs in morphologically distinct inter-laminar astrocytes underlying the glial limitans differed from those in deeper cortical layers, suggesting functional specialization possibly related to structural stability and defense from potentially harmful factors in the cerebrospinal fluid. Differences between adult white and grey matter miRNA expression included higher expression of pro-inflammatory miRNAs in the former, potentially contributing to differences in inflammation between grey and white matter plaques in multiple sclerosis. Lower expression of miRNAs in fetal versus adult white matter astrocytes likely reflects the immaturity of these migrating cells. Highly expressed miRNAs in the fetal germinal matrix are probably relevant in development and also recapitulate some responses to injury. Future studies can address regional alterations of miRNA expression in pathological conditions.

Cerebral hypoperfusion in young transgenic APP mice predicts spatial distribution of amyloid deposition

Institutional Animal Care and Use Committee. Results: Some extent of ARIA-E was observed in 20/28 APP+PS1, and 0/10 of the WT littermates. The most common pattern was observed in the ventral regions of the piriform cortical lobe and the medial nucleus of the amygdala. Histological results showed albumin in the parenchyma in the anatomical region that had an MR-visible ARIA-E lesion. ARIA-H was observed in 21/28 APP+PS1 mice, and in 0/10 of the WT littermates. These were primarily in the dorsal half of the cortex, but several appeared in the cerebellum. Perls’ iron positive foci histologically colocalized with these MR-visible ARIA-H lesions. Conclusions: In summary, we have demonstrated MR imaging can detect spontaneously-occurring intensity alterations consistent with ARIA-E and AREA-H in aged Ab-bearing transgenic mice, with the APP+PS1 strain appearing to be most sensitive. The pathogenesis of these findings and their relevance toMR clinical observations are being evaluated in ongoing studies with therapies targeting Ab reduction.

In situ microRNA profiles of astrocytes in the context of ischemic brain injury and multiple sclerosis

expression of Ly6C and Ly6G, very important in infectious, autoimmune and tumor models. The present work will further characterize the potential role of miR-223 in the EAE model and MS. First we found an upregulation of miR-233 in the Peripheral Blood Mononuclear Cell (PBMC) of 20 MS samples vs. 20 controls (fold change over controls 1.64 ± 1.25 vs. 1.20 ± 0.95, P = 0.018). This result was confirmed in a different cohort of subjects, including 15 untreated MS subjects (population from Italy: 11 RRMS, 4 PPMS) and 12 healthy controls. In this cohort, miR-233 was upregulated in MS vs. control subjects (fold change over controls 0.81 ± 0.65 vs. 0.40 ± 0.26, P = 0.010). We also performed several active EAE experiments in miR-223 knockout (miR-223 KO) mice and littermate control mice. MiR-223 KO mice developed a significantly less severe disease (P b 0.0001 by two-way ANOVA) with a significantly higher percentage of PMN-MDSC (CD11b/Ly6G positive cells) and MO-MDSC (CD11b/Ly6C positive cells) in the spleens and spinal cords compared to control mice. We found also that MO-MDSC from miR-223 KO mice had greater immune-suppressive effects on CD4 T cell proliferation than controls in antigen T cell stimulatory conditions. It is established that MO-MDSCs inhibit CD4 and CD8 T cell proliferation mostly via ARG1 action. ARG1 was promptly upregulated in MO-MDSC from miR-223 KO cells corresponding to their high immunosuppressive function. These results demonstrate altered levels of miR 223 in the PBMC of MS patients and suggest that miR-223 plays a role in EAE. This may lead to the identification of new disease biomarkers of therapeutic targets.

MRI-derived cortical thickness measurements from APP transgenic mice

phyof theMTLwas 26.7%-35.6%.TheVBMOF24 pureADpatients showed that parietal lobe atrophy was the most severe part of the cortical atrophy. The FDG-PET follow up of a few cases showed us that the hypometabolism in the parietal lobe occurred earlier than in the post cingulate. The hypometabolism of theMTLwas extendedmore later.Conclusions: The hypometabolism and cortex atrophy of the parietal lobe could be valuable for AD diagnosis.