Pattern Classification of Working Memory Networks Reveals Differential Effects of Methylphenidate, Atomoxetine, and Placebo in Healthy Volunteers

Stimulant and non-stimulant drugs can reduce symptoms of attention deficit/hyperactivity disorder (ADHD). The stimulant drug methylphenidate (MPH) and the non-stimulant drug atomoxetine (ATX) are both widely used for ADHD treatment, but their differential effects on human brain function remain unclear. We combined event-related fMRI with multivariate pattern recognition to characterize the effects of MPH and ATX in healthy volunteers performing a rewarded working memory (WM) task. The effects of MPH and ATX on WM were strongly dependent on their behavioral context. During non-rewarded trials, only MPH could be discriminated from placebo (PLC), with MPH producing a similar activation pattern to reward. During rewarded trials both drugs produced the opposite effect to reward, that is, attenuating WM networks and enhancing task-related deactivations (TRDs) in regions consistent with the default mode network (DMN). The drugs could be directly discriminated during the delay component of rewarded trials: MPH produced greater activity in WM networks and ATX produced greater activity in the DMN. Our data provide evidence that: (1) MPH and ATX have prominent effects during rewarded WM in task-activated and -deactivated networks; (2) during the delay component of rewarded trials, MPH and ATX have opposing effects on activated and deactivated networks: MPH enhances TRDs more than ATX, whereas ATX attenuates WM networks more than MPH; and (3) MPH mimics reward during encoding. Thus, interactions between drug effects and motivational state are crucial in defining the effects of MPH and ATX

The genetic identity of the only Italian population of the genus Macroprotodon Guichenot, 1850 on the island of Lampedusa, Sicily

The only Italian population of false smooth snakes is found on Lampedusa, a small island located in the Sicilian Channel and part of the African continental shelf. The taxonomic identity of this population is currently uncertain, although it is most often attributed to Macroprotodon cucullatus textilis on a morphological basis. We present here the first genetic data on this population. The analysis carried out on the mitochondrial cytochrome b gene shows that the Lampedusan false smooth snake belongs to a Glade shared with a single sample from central Tunisia. The genetic distance between this lineage and its sister group (M. abubakeri) is comparable to or higher than that found among many reptile species. To define the identity of this distinctive lineage, as well as the Macroprotodon taxonomic structure, further sampling efforts within the undersampled distribution area of this genus and more extensive analyses will be necessary