Advances in diffusion MRI acquisition and processing in the Human Connectome Project

The Human Connectome Project (HCP) is a collaborative 5-year effort to map human brain connections and their variability in healthy adults. A consortium of HCP investigators will study a population of 1200 healthy adults using multiple imaging modalities, along with extensive behavioral and genetic data. In this overview, we focus on diffusion MRI (dMRI) and the structural connectivity aspect of the project. We present recent advances in acquisition and processing that allow us to obtain very high-quality in-vivo MRI data, whilst enabling scanning of a very large number of subjects. These advances result from 2 years of intensive efforts in optimising many aspects of data acquisition and processing during the piloting phase of the project. The data quality and methods described here are representative of the datasets and processing pipelines that will be made freely available to the community at quarterly intervals, beginning in 2013

Increased metabolic activity in nucleus basalis of Meynert neurons in elderly individuals with mild cognitive impairment as indicated by the size of the Golgi apparatus.

In this study, we examined the metabolic activity of nucleus basalis of Meynert (NBM) neurons in individuals clinically diagnosed with no cognitive impairment (NCI, n = 8), mild cognitive impairment (MCI, n = 9), and subjects with moderate Alzheimer disease (AD, n = 7). We used Golgi apparatus (GA) size as a measure of neuronal metabolic activity. Subjects with MCI showed increased NBM metabolic activity; they had significantly more neurons with larger GA size as compared with NCI and AD subjects. In contrast, more NBM neurons with extremely small GA sizes, indicating reduced metabolic activity, were seen in AD. When these cases were classified according to their AD pathology (Braak I-II, III-IV, or V-VI), Braak III-IV subjects showed significantly increased GA sizes, comparable with the increase in clinically diagnosed MCI, whereas in Braak V-VI, GA sizes were dramatically reduced. Of all MCI and NCI subjects with similar Braak III-IV pathology, the MCI subjects again had significantly larger GA sizes. The larger NBM neuronal GA size seen in MCI suggests increased metabolic activity, associated with both the clinical progression from NCI to MCI, and with the early stages of AD pathology

Increased metabolic activity in nucleus basalis of Meynert neurons in elderly individuals with mild cognitive impairment as indicated by the size of the Golgi apparatus.

In this study, we examined the metabolic activity of nucleus basalis of Meynert (NBM) neurons in individuals clinically diagnosed with no cognitive impairment (NCI, n = 8), mild cognitive impairment (MCI, n = 9), and subjects with moderate Alzheimer disease (AD, n = 7). We used Golgi apparatus (GA) size as a measure of neuronal metabolic activity. Subjects with MCI showed increased NBM metabolic activity; they had significantly more neurons with larger GA size as compared with NCI and AD subjects. In contrast, more NBM neurons with extremely small GA sizes, indicating reduced metabolic activity, were seen in AD. When these cases were classified according to their AD pathology (Braak I-II, III-IV, or V-VI), Braak III-IV subjects showed significantly increased GA sizes, comparable with the increase in clinically diagnosed MCI, whereas in Braak V-VI, GA sizes were dramatically reduced. Of all MCI and NCI subjects with similar Braak III-IV pathology, the MCI subjects again had significantly larger GA sizes. The larger NBM neuronal GA size seen in MCI suggests increased metabolic activity, associated with both the clinical progression from NCI to MCI, and with the early stages of AD pathology.

Precuneus amyloid burden is associated with reduced cholinergic activity in Alzheimer disease

Objective: This study examined the relationship between postmortem precuneus cholinergic enzyme activity, Pittsburgh compound B (PiB) binding, and soluble amyloid-β concentration in mild cognitive impairment (MCI) and Alzheimer disease (AD). Methods: Choline acetyltransferase (ChAT) activity, [3H]PiB binding, and soluble amyloid-β1-42 (Aβ42) concentration were quantified in precuneus tissue samples harvested postmortem from subjects with no cognitive impairment (NCI), MCI, and mild AD and correlated with their last antemortem Mini-Mental State Examination (MMSE) score and postmortem pathologic evaluation according to the National Institute on Aging-Reagan criteria, recommendations of the Consortium to Establish a Registry for Alzheimer\u27s Disease, and Braak stage. Results: Precuneus ChAT activity was lower in AD than in NCI and was comparable between MCI and NCI. Precuneus [3H]PiB binding and soluble Aβ42 levels were elevated in MCI and significantly higher in AD than in NCI. Across all case subjects, reduced ChAT activity was associated with increased [3H]PiB binding, increased soluble Aβ42, lower MMSE score, presence of the APOE®4 allele, and more advanced AD pathology. Conclusions: Despite accumulating amyloid burden, cholinergic enzyme activity is stable in the precuneus during prodromal AD. A decline in precuneus ChAT activity occurs only in clinical AD, when PiB binding and soluble Aβ42 levels are substantially elevated compared with those in MCI. Anti-amyloid interventions in MCI case subjects with a positive PiB PET scan may aid in reducing cholinergic deficits and cognitive decline later in the disease process. Copyright © 2011 by AAN Enterprises, Inc

Supplementary Material for: Frontal Cortex and Hippocampal γ-Secretase Activating Protein Levels in Prodromal Alzheimer Disease

<p><b><i>Background:</i></b> β-Amyloid (Aβ) is the product of concerted cleavage of the amyloid precursor protein (APP) by β- and γ-secretases. However, the molecular mechanisms that regulate this process are not well understood. Recently, evidence was reported that γ-secretase activating protein (GSAP, 16 kDa), derived from a larger precursor protein (98 kDa), plays a role in Aβ metabolism through a mechanism involving its interaction with both γ-secretase and APP. However, a detailed evaluation of GSAP protein levels and their association with clinical and neuropathological variables are lacking during the clinical progression of Alzheimer disease (AD). <b><i>Methods:</i></b> We quantified levels of the GSAP precursor (98 kDa) and its active form (16 kDa) in the frontal cortex and hippocampus, areas displaying extensive Aβ and neurofibrillary tangle (NFT) pathology, in subjects who came to autopsy with a premortem clinical diagnosis of noncognitive impairment, mild cognitive impairment, mild to moderate AD, and severe AD using Western blotting. <b><i>Results:</i></b> Analysis found that 98-kDa GSAP levels were increased, while those of 16 kDa were reduced in the frontal cortex of severe-AD subjects. By contrast, GSAP levels remained stable in the hippocampus. Frontal cortex and hippocampal GSAP 98- and 16-kDa levels were not associated with Aβ, NFT, and neuropathological criteria across clinical groups. Interestingly, only neocortical 98-kDa GSAP values showed a significant correlation with the Mini-Mental State Examination and episodic memory scores. <b><i>Conclusions:</i></b> These data demonstrate that GSAP proteins are differentially dysregulated in severe AD, but only the full-length form was associated with cognitive test scores in AD.</p