Elevated amygdala response to faces following early deprivation.

A functional neuroimaging study examined the long-term neural correlates of early adverse rearing conditions in humans as they relate to socio-emotional development. Previously institutionalized (PI) children and a same-aged comparison group were scanned using functional magnetic resonance imaging (fMRI) while performing an Emotional Face Go/Nogo task. PI children showed heightened activity of the amygdala, a region that supports emotional learning and reactivity to emotional stimuli, and corresponding decreases in cortical regions that support perceptual and cognitive functions. Amygdala activity was associated with decreased eye-contact as measured by eye-tracking methods and during a live dyadic interaction. The association between early rearing environment and subsequent eye-contact was mediated by amygdala activity. These data support the hypothesis that early adversity alters human brain development in a way that can persist into childhood, and they offer insight into the socio-emotional disturbances in human behavior following early adversity.

What happens when doctors stop prescribing temazepam? Use of alternative therapies.

We investigated the withdrawal of temazepam in a single general practice using two alternative prescribing policies: an alternative benzodiazepine; or an alternative group of drugs recommended for short-term management of insomnia, including sedative antihistamines and chloral hydrate. The study showed that temazepam prescribing in general practice can be reduced or stopped by using a simple intervention. An alternative benzodiazepine is useful in helping patients to stop their use of hypnotic agents. The use of antihistamines as substitute hypnotics is not advocated on the basis of our findings.

Contribution of quinidine metabolites to electrophysiologic responses in human subjects.

The quinidine metabolites 3-hydroxyquinidine, 2'-oxoquinidione, and quinidine-N-oxide and the contaminant dihydroquinidine have been shown to have electrophysiologic activity. This study investigated the time-dependent contributions of quinidine, dihydroquinidine, and the quinidine metabolites to the electrophysiologic effects of a prolonged quinidine infusion in 14 patients referred for management of symptomatic ventricular tachyarrhythmias. Electrophysiologic testing and blood sampling were done at baseline and every 5 minutes throughout a 110-minute quinidine infusion. Changes in ventricular effective refractory periods correlated significantly with serum concentrations of quinidine-N-oxide (r = 0.54; p less than 0.001), 3-hydroxyquinidine (r = 0.50; p less than 0.001), and time (r = 0.52; p less than 0.001) but did not correlate with the quinidine concentrations (r = 0.19). Multiple linear regression revealed that only 3-hydroxyquinidine and time contributed independently to changes in the ventricular effective refractory period. Quinidine concentration was the only variable that contributed independently to changes in ventricular tachycardiac cycle lengths. Time was the only variable that correlated independently with changes in QRS and QTc durations. These data indicate that active metabolites accumulate during an intravenous infusion that attains therapeutic quinidine levels and that quinidine and its metabolites may have different electrophysiologic effects.