3 research outputs found
Resting State Functional Connectivity Correlates of Inhibitory Control in Children with Attention-Deficit/Hyperactivity Disorder
Motor inhibition is among the most commonly studied executive functions in
attention-deficit/hyperactivity disorder (ADHD). Imaging studies using probes of
motor inhibition such as the stop signal task (SST) consistently demonstrate
ADHD-related dysfunction within a right-hemisphere fronto-striatal network that
includes inferior frontal gyrus and pre-supplementary motor area. Beyond
findings of focal hypo- or hyper-function, emerging models of ADHD
psychopathology highlight disease-related changes in functional interactions
between network components. Resting state fMRI (R-fMRI) approaches have emerged
as powerful tools for mapping such interactions (i.e., resting state functional
connectivity, RSFC), and for relating behavioral and diagnostic variables to
network properties. We used R-fMRI data collected from 17 typically developing
controls (TDC) and 17 age-matched children with ADHD (aged
8ā13āyears) to identify neural correlates of SST performance
measured outside the scanner. We examined two related inhibition indices: stop
signal reaction time (SSRT), indexing inhibitory speed, and stop signal delay
(SSD), indexing inhibitory success. Using 11 fronto-striatal seed
regions-of-interest, we queried the brain for relationships between RSFC and
each performance index, as well as for interactions with diagnostic status. Both
SSRT and SSD exhibited connectivityābehavior relationships independent
of diagnosis. At the same time, we found differential
connectivityābehavior relationships in children with ADHD relative to
TDC. Our results demonstrate the utility of RSFC approaches for assessing
brain/behavior relationships, and for identifying pathology-related differences
in the contributions of neural circuits to cognition and behavior
Distinct neural signatures detected for ADHD subtypes after controlling for micro-movements in resting state functional connectivity MRI data
Contains fulltext :
126873.pdf (publisher's version ) (Open Access)In recent years, there has been growing enthusiasm that functional magnetic resonance imaging (MRI) could achieve clinical utility for a broad range of neuropsychiatric disorders. However, several barriers remain. For example, the acquisition of large-scale datasets capable of clarifying the marked heterogeneity that exists in psychiatric illnesses will need to be realized. In addition, there continues to be a need for the development of image processing and analysis methods capable of separating signal from artifact. As a prototypical hyperkinetic disorder, and movement-related artifact being a significant confound in functional imaging studies, ADHD offers a unique challenge. As part of the ADHD-200 Global Competition and this special edition of Frontiers, the ADHD-200 Consortium demonstrates the utility of an aggregate dataset pooled across five institutions in addressing these challenges. The work aimed to (1) examine the impact of emerging techniques for controlling for "micro-movements," and (2) provide novel insights into the neural correlates of ADHD subtypes. Using support vector machine (SVM)-based multivariate pattern analysis (MVPA) we show that functional connectivity patterns in individuals are capable of differentiating the two most prominent ADHD subtypes. The application of graph-theory revealed that the Combined (ADHD-C) and Inattentive (ADHD-I) subtypes demonstrated some overlapping (particularly sensorimotor systems), but unique patterns of atypical connectivity. For ADHD-C, atypical connectivity was prominent in midline default network components, as well as insular cortex; in contrast, the ADHD-I group exhibited atypical patterns within the dlPFC regions and cerebellum. Systematic motion-related artifact was noted, and highlighted the need for stringent motion correction. Findings reported were robust to the specific motion correction strategy employed. These data suggest that resting-state functional connectivity MRI (rs-fcMRI) data can be used to characterize individual patients with ADHD and to identify neural distinctions underlying the clinical heterogeneity of ADHD
The NKI-Rockland Sample: A Model for Accelerating the Pace of Discovery Science in Psychiatry
The National Institute of Mental Health strategic plan for advancing psychiatric neuroscience calls for an acceleration of discovery and the delineation of developmental trajectories for risk and resilience across the lifespan. To attain these objectives, sufficiently powered datasets with broad and deep phenotypic characterization, state-of-the-art neuroimaging, and genetic samples must be generated and made openly available to the scientific community. The enhanced Nathan Kline Institute Rockland Sample (NKI-RS) is a response to this need. NKI-RS is an ongoing, institutionally-centered endeavor aimed at creating a large-scale (N>1000), deeply phenotyped, community-ascertained, lifespan sample (ages 6-85 years old) with advanced neuroimaging and genetics. These data will be publically shared, openly and prospectively (i.e., on a weekly basis). Herein, we describe the conceptual basis of the NKI-RS, including study design, sampling considerations, and steps to synchronize phenotypic and neuroimaging assessment. Additionally, we describe our process for sharing the data with the scientific community while protecting participant confidentiality, maintaining an adequate database, and certifying data integrity. The pilot phase of the NKI-RS, including challenges in recruiting, characterizing, imaging, and sharing data, is discussed while also explaining how this experience informed the final design of the enhanced NKI-RS. It is our hope that familiarity with the conceptual underpinnings of the enhanced NKI-RS will facilitate harmonization with future data collection efforts aimed at advancing psychiatric neuroscience and nosology