Multiple sclerosis (MS) is one of the most common causes of chronic disability in young adults. In 85% of the cases, the disease starts with a relapsing-remitting course but, as age advances, the majority of patients enter a progressive phase of the disease characterized by neurological decline and brain atrophy. Treatments that delay, prevent or reverse this progression phase are an unmet need in MS research. The cause of progressive MS is not known, but remyelination failure may contribute. Hence, large efforts have been directed into identifying strategies to enhance endogenous remyelination, which can prevent neuronal death. Microglia are the immune cells of the central nervous system (CNS) and play a crucial role in orchestrating remyelination. With ageing, microglia do not respond adequately to myelin damage, leading to failed remyelination. Apart from ageing, clinical observations suggest that also obesity increases the risk of progression in MS. However, whether and how obesity might influence remyelination is not known.In this study, we use western diet (WD) to induce obesity in mice and investigate the impact of WD on microglia's response to demyelination. With this, we aim to understand how obesity might affect the pro-regenerative functions of microglia. Since the metabolism of myelin-derived lipids by microglia is an essential step for successful remyelination, we further examine how WD changes the lipid composition of the plasma and brain and whether these changes have consequences on microglia's response to demyelination. We find that WD consumption leads to impaired remyelination after toxin-induced demyelination due to deficient cholesterol efflux by microglia. Furthermore, we show that WD intake alters the lipid profile of the brain white and grey matter, is associated with modest microgliosis in the corpus callosum, and causes an increase in transforming growth factor-β (TGFβ) in the brain. Such excess TGFβ signalling leads to insufficient microglia response to damage and impaired cholesterol efflux, which ultimately prevents inflammation resolution and remyelination. By blocking TGFβ signalling or enhancing microglia activation through triggering-receptor expressed on myeloid cells 2 (TREM2), we could promote adequate microglia activation and successful resolution of damage in the CNS.Hence, we unravel a microglia immune checkpoint mechanism as a potential therapeutic target to promote a reparative inflammatory response after demyelinating injury.In conclusion, our study demonstrates that obesity leads to failed remyelination by disturbing the pro-regenerative functions of microglia. In addition, our findings expand the spectrum of potential therapeutic strategies to enhance endogenous remyelination. Microglia functionMicroglia are the only immune cells of the CNS and therefore the endogenous brain defence system.As such, they are responsible for CNS protection against diverse pathogenic factors (Kettenmann et al., 2011). Furthermore, microglia provide trophic support to neurons, remove apopto...
Ultra-high field MRI across the depth of the cortex has the potential to provide anatomically precise biomarkers and mechanistic insights into neurodegenerative disease like Huntington's disease that show layer-selective vulnerability. Here we compare multi-parametric mapping (MPM) measures across cortical depths for a 7T 500 μm whole brain acquisition to (a) layer-specific cell measures from the von Economo histology atlas, (b) layer-specific gene expression, using the Allen Human Brain atlas and (c) white matter connections using high-fidelity diffusion tractography, at a 1.3 mm isotropic voxel resolution, from a 300mT/m Connectom MRI system. We show that R2*, but not R1, across cortical depths is highly correlated with layer-specific cell number and layer-specific gene expression. R1-and R2*-weighted connectivity strength of cortico-striatal and intra-hemispheric cortical white matter connections was highly correlated with grey matter R1 and R2* across cortical depths. Limitations of the layer-specific relationships demonstrated are at least in part related to the high cross-correlations of von Economo atlas cell counts and layer-specific gene expression across cortical layers. These findings demonstrate the potential and limitations of combining 7T MPMs, gene expression and white matter connections to provide an anatomically precise framework for tracking neurodegenerative disease.
PURPOSEHigh-resolution quantitative multi-parameter mapping shows promise for non-invasively characterizing human brain microstructure but is limited by physiological artifacts. We implemented corrections for rigid head movement and respiration-related B0-fluctuations and evaluated them in healthy volunteers and dementia patients.METHODSCamera-based optical prospective motion correction (PMC) and free-induction decay (FID) navigator correction were implemented in a gradient and RF-spoiled multi-echo 3D gradient echo sequence for mapping proton density (PD), longitudinal relaxation rate (R1) and effective transverse relaxation rate (R2*). We studied their effectiveness separately and in concert in young volunteers and then evaluated the navigator correction (NAVcor) with PMC in a group of elderly volunteers and dementia patients. We used spatial homogeneity within white matter (WM) and gray matter (GM) and scan-rescan measures as quality metrics.RESULTSNAVcor and PMC reduced artifacts and improved the homogeneity and reproducibility of parameter maps. In elderly participants, NAVcor improved scan-rescan reproducibility of parameter maps (coefficient of variation decreased by 14.7% and 11.9% within WM and GM respectively). Spurious inhomogeneities within WM were reduced more in the elderly than in the young cohort (by 9% vs 2%). PMC increased regional GM/WM contrast and was especially important in the elderly cohort, which moved twice as much as the young cohort. We did not find a significant interaction between the two corrections.CONCLUSIONNavigator correction and PMC significantly improved the quality of PD, R1 and R2* maps, particularly in less compliant elderly volunteers and dementia patients.
High-resolution quantitative multi-parameter mapping shows promise for non-invasively characterizing human brain microstructure but is limited by physiological artifacts. We implemented corrections for rigid head movement and respiration-related B0-fluctuations and evaluated them in healthy volunteers and dementia patients. Methods: Camera-based optical prospective motion correction (PMC) and FID navigator correction were implemented in a gradient and RF-spoiled multi-echo 3D gradient echo sequence for mapping proton density (PD), longitudinal relaxation rate (R1) and effective transverse relaxation rate (R2*). We studied their effectiveness separately and in concert in young volunteers and then evaluated the navigator correction (NAVcor) with PMC in a group of elderly volunteers and dementia patients. We used spatial homogeneity within white matter (WM) and gray matter (GM) and scan-rescan measures as quality metrics. Results: NAVcor and PMC reduced artifacts and improved the homogeneity and reproducibility of parameter maps. In elderly participants, NAVcor improved scan-rescan reproducibility of parameter maps (coefficient of variation decreased by 14.7% and 11.9% within WM and GM respectively). Spurious inhomogeneities within WM were reduced more in the elderly than in the young cohort (by 9% vs. 2%). PMC increased regional GM/WM contrast and was especially important in the elderly cohort, which moved twice as much as the young cohort. We did not find a significant interaction between the two corrections.
Drop-coating deposition Raman (DCDR) spectroscopy is based on the measurement of a sample that has been preconcentrated by being dried on a special hydrophobic plate. In addition to its higher sensitivity, the advantage of DCDR over the conventional Raman spectroscopy is the small sample volume needed, the lack of interference from solvents, and the capability of segregating any impurities present and separating components in more complex samples. In this study, DCDR spectroscopy was employed to investigate the complex of the cationic copper(II) 5,10,15,20-tetrakis(1-methyl-4-pyridyl) porphyrin (CuTMPyP) and 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) liposomes. Drop-coating deposition Raman spectra were treated using factor analysis (FA), which led to the following conclusions: (i) the distribution of CuTMPyP in the complex is not homogenous, (ii) the DCDR technique segregates complexed and noncomplexed parts of the sample, (iii) the spectral changes caused by the drying process and by the interaction of CuTMPyP with the DPPC liposomes can be distinguished, and (iv) the porphyrin molecules interacting with DPPC affect both the order-disorder properties of the lipid chains and the lipid head.
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