Atypical

Atypical SRT1720 chemical structure connectivity within the DMN, and between DMN regions and “task-positive” nodes (e.g., DLPFC and cingulate cortex), is apparent in psychosis, personality disorders, mood disorders, and ADHD (Castellanos et al., 2008, Whitfield-Gabrieli et al., 2009, Sheline et al., 2010, Chai et al., 2011, Cole et al., 2011, Garrett et al., 2011, Holt et al., 2011 and Motzkin et al., 2011). If the DMN is important for self-representation and social cognition, as has been suggested, alterations in DMN connectivity may contribute to impaired social functioning in diverse disorders. As we mentioned above, comorbidity between mental disorders is the rule rather than the exception, invading

nearly all canonical diagnostic boundaries. In fact, covariation among psychiatric diagnoses is so prevalent, and so extensive, that it alone belies the artificial nature of phenomenologically based categorical classification. Findings in both community and clinical samples suggest that while DSM-based models of Selleck CP868596 discrete taxa provide a poor fit to the data, dimensional models characterized by continuous liability to psychopathology

fit the data well (Krueger and Markon, 2011 and Markon et al., 2011). Latent variable approaches have proven especially useful in moving toward an empirical classification of mental illness (“quantitative nosology”). This class of multivariate techniques approximates the latent structure of psychiatric illness by assessing common and unique symptom variance across disorders. These analyses have identified to three core syndrome spectra: internalizing (high negative affect; including anxiety, depressive,

phobic, and obsessive-compulsive symptoms), externalizing (behavioral disinhibition; including impulsivity, substance abuse, and antisocial behaviors) and thought disorder (atypical/bizarre cognitions; comprising psychotic, paranoiac, and schizoptypal symptoms) (Kotov et al., 2011 and Krueger and Markon, 2006). Twin studies demonstrate that common genetic factors largely account for the observed syndromic clustering, suggesting a biological basis for coherent patterns of comorbidity derived from factor analysis (Kendler et al., 2003 and Kendler et al., 2011). Put another way, high covariation at the phenotypic level appears to be shaped by high covariation at the genetic level (Lahey et al., 2011). According to this proposed genetic architecture, common sources of genetic variability drive comorbidity between symptomatically related disorders within syndrome spectra. However, the precise biological mechanisms though which genes predispose risk for broad syndrome spectra remain unresolved. Here, we propose that connectivity circuits may be systems-level units that underlie the observed clustering of symptoms.

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