Impulsive individuals excessively discount the value of delayed rewards, and this is thought to reflect deficits in brain regions critical for impulse control such as the anterior cingulate cortex (ACC). Delay discounting (DD) is an established measure of cognitive impulsivity, referring to the devaluation of rewards delayed in time. This study used male Wistar rats performing a DD task to test the hypothesis that neural activity states in ACC ensembles encode strategies that guide decision-making. Optogenetic silencing of ACC neurons exclusively increased impulsive choices at the 8 s delay by increasing the number of consecutive low-value, immediate choices. In contrast to shorter delays where animals preferred the delay option, no immediate or delay preference was detected at 8 s. These data suggest that ACC was critical for decisions requiring more deliberation between choice options. To address the role of ACC in this process, large-scale multiple single-unit recordings were performed and revealed that...

Principal neurons (PNs) of the lateral superior olive (LSO) are a critical component of brain circuits that compare information between the two ears to extract sound source-location-related cues. LSO PNs are not a homogenous group but differ in their transmitter type, intrinsic membrane properties, and projection pattern to higher processing centers in the inferior colliculus. Glycinergic inhibitory LSO PNs have higher input resistance than glutamatergic excitatory LSO PNs (∼double). This suggests that the inhibitory cell type has a lower minimum input or signal intensity required to produce an output (activation threshold) which may impact how they integrate binaural inputs. However, cell-type-specific differences in the strength of synaptic drive could offset or accentuate such differences in intrinsic excitability and have not been assessed. To evaluate this possibility, we used a knock-in mouse model to examine spontaneous and electrically stimulated (evoked) synaptic events in LSO PN types using volta...

Understanding the roles of astrocytic calcium signaling in multiple brain regulatory mechanisms including metabolism, blood flow, neuromodulation and neuroinflammation has remained one of the enduring challenges in glial biology. To delineate astrocytic contribution from concurrent neuronal activity, it is vital to establish robust control and manipulate astrocytes using a technique like optogenetics due to its high cellular specificity and temporal resolution. The lack of an experimental paradigm to induce controlled calcium signaling in astrocytes has hindered progress in the field. To address this, in this study, we systematically characterize and identify light stimulation paradigms for inducing regulated, on-demand increases in astrocytic calcium in acute brain slice cortical astrocytes from MlC1-ChR2(C128S)-EYFP mice (of either sex). We identified paradigms 20%, 40% and 60% (of T=100s) to elicit robust calcium responses upon periodic stimulations, while the 95% paradigm exhibited a response only duri...

Speaking at meetings and conferences is one important venue. The following guidelines have been adopted by the SfN to achieve diverse representation of the neuroscience community at meetings and conferences.

Speaking at meetings and conferences is one important venue. The following guidelines have been adopted by the SfN to achieve diverse representation of the neuroscience community at meetings and conferences.

Our awards span a wide range of achievements, from recognizing the merits of young and promising neuroscientists, to honoring those who’ve dedicated their careers to furthering the field.

Our awards span a wide range of achievements, from recognizing the merits of young and promising neuroscientists, to honoring those who’ve dedicated their careers to furthering the field.

Our awards span a wide range of achievements, from recognizing the merits of young and promising neuroscientists, to honoring those who’ve dedicated their careers to furthering the field.

Motor reaction times in humans are highly variable from one trial to the next, even for simple and automatic tasks, such as shifting your gaze to a suddenly appearing target. Although classic models of reaction time generation consider this variability to reflect intrinsic noise, some portion of it could also be attributed to ongoing neuronal processes. For example, variations of alpha rhythm frequency (8–12 Hz) across individuals, or alpha amplitude across trials, have been related previously to manual reaction time variability. Here we investigate the trial-by-trial influence of oscillatory phase, a dynamic marker of ongoing activity, on saccadic reaction time in three paradigms of increasing cognitive demand (simple reaction time, choice reaction time, and visual discrimination tasks). The phase of ongoing prestimulus activity in the high alpha/low beta range (11–17 Hz) at frontocentral locations was strongly associated with saccadic response latencies. This relation, present in all three paradigms, pea...

The Society for Neuroscience (SfN) strongly advocates for the responsible and ethical use of animals in biomedical research, including the use of non-human primates (NHPs). NHPs continue to serve a critical role in advancing scientific understanding of the brain.