Revealing the differences between normal and pathological ageing using functional magnetic resonance imaging (fMRI)

The aim of the present study was to use fMRI to examine the brain activation patterns found in normal and pathological ageing on specific cognitive tasks. The cognitive paradigms that were chosen, consisted of an n-back working memory task and a semantic memory and processing task. Manipulation of the n-back task enabled vigilance and working memory load to be investigated. Patients with Alzheimer's Disease (AD) and individuals with amnestic Mild Cognitive Impairment (MCI) were compared to normal elderly and young controls. The experiments showed that the patterns of brain activation found in normal and pathological ageing do not appear to fall along the same continuum. When comparing the elderly group to the young group, areas of under-activation could be seen, in addition to other regions of activation which were thought to be due to compensation. The comparison of the normal to the pathological groups revealed distinct differences in the levels and locations of the significant activations. On the vigilance and working memory tasks, the behavioural scores and reaction times of the pathological groups were not significantly different from the normal elderly, yet substantial differences could be identified in the brain activation patterns. The semantic memory task, contrary to expectation, revealed a significant difference in behavioural performance between the young group and the elderly group. Both the reaction times and the performance scores of the AD group were significantly different compared to the elderly, however. Significant differences also occurred in the brain activation patterns of both pathological groups (AD and MCI) compared to the elderly. The differences that were present between the normal and pathological groups on each of the tasks, suggest that sensitive cognitive fMRI paradigms might be very useful in resolving diagnostic ambiguity in people at increased risk of developing AD

Brain Activation Patterns Characterizing Different Phases of Motor Action: Execution, Choice and Ideation.

Motor behaviour is controlled by a large set of interacting neural structures, subserving the different components involved in hierarchical motor processes. Few studies have investigated the neural substrate of higher-order motor ideation, i.e. the mental operation of conceiving a movement. The aim of this functional magnetic resonance imaging study was to segregate the neural structures involved in motor ideation from those involved in movement choice and execution. An index finger movement paradigm was adopted, including three different conditions: performing a pre-specified movement, choosing and executing a movement and ideating a movement of choice. The tasks involved either the right or left hand, in separate runs. Neuroimaging results were obtained by comparing the different experimental conditions and computing conjunction maps of the right and left hands for each contrast. Pre-specified movement execution was supported by bilateral fronto-parietal motor regions, the cerebellum and putamen. Choosing and executing finger movement involved mainly left fronto-temporal areas and the anterior cingulate. Motor ideation activated almost exclusively left hemisphere regions, including the inferior, middle and superior frontal regions, middle temporal and middle occipital gyri. These findings show that motor ideation is controlled by a cortical network mainly involved in abstract thinking, cognitive and motor control, semantic and visual imagery processes

Revealing the differences between normal and pathological ageing using functional magnetic resonance imaging (MRI)

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Structural and functional correlates of hypnotic depth and suggestibility

This study explores whether self-reported depth of hypnosis and hypnotic suggestibility are associated with individual differences in neuroanatomy and/or levels of functional connectivity. Twenty-nine people varying in suggestibility were recruited and underwent structural, and after a hypnotic induction, functional magnetic resonance imaging at rest. We used voxel-based morphometry to assess the correlation of grey matter (GM) and white matter (WM) against the independent variables: depth of hypnosis, level of relaxation and hypnotic suggestibility. Functional networks identified with independent components analysis were regressed with the independent variables. Hypnotic depth ratings were positively correlated with GM volume in the frontal cortex and the anterior cingulate cortex (ACC). Hypnotic suggestibility was positively correlated with GM volume in the left temporal-occipital cortex. Relaxation ratings did not correlate significantly with GM volume and none of the independent variables correlated with regional WM volume measures. Self-reported deeper levels of hypnosis were associated with less connectivity within the anterior default mode network. Taken together, the results suggest that the greater GM volume in the medial frontal cortex and ACC, and lower connectivity in the DMN during hypnosis facilitate experiences of greater hypnotic depth. The patterns of results suggest that hypnotic depth and hypnotic suggestibility should not be considered synonyms

Patterns of brain activity during a semantic task differentiate normal aging from early Alzheimer's disease

In a study of the effects of normal and pathological aging on semantic-related brain activity, 29 patients with Alzheimer's disease (AD) and 19 controls subjects (10 young and 9 older controls) performed a version of the Pyramids and Palm Trees Test that had been adapted for use during functional magnetic resonance imaging (fMRI). Young and older controls activated the left inferior and middle frontal gyri, precuneus; and superior parietal lobule. Right frontal and left temporal cortices were activated only in the young. The AD group activated only the left prefrontal and cingulate cortex. Separate analyses of high- and low-performing AD subgroups showed a similar pattern of activation in the left frontal lobe, although activiation was more widespread in low performers. High performers significantly deactivated anterior midline frontal structures, however, while low performers did not. When the older adult and AD groups were combined, there was a significant positive correlation between left frontal and parietal activation and Mini-Mental State Examination (MMSE) score (covarying for age), suggesting a disease effect. A significant negative correlation between activation in the left temporal cortex and age (covarying for MMSE score) reflected a possible age effect. These differential effects suggest that semantic activation paradigms might aid diagnosis in those cases for whom conventional assessments lack the necessary sensitivity to detect subtle changes