The selfie project: A successful approach to lifestyle monitoring and health promotion in adolescents.

Adolescence is a critical period for the physical and cognitive development. To promote adolescents' health and well-being, prevention and health education interventions are to be implemented at all levels of society, with schools and families playing a fundamental role. In 2015, the "Semi di Melo" Center for Education and Research on Childhood and Adolescence was established in Milan, northern Italy to help parents and teachers to better explicate their supportive role toward their children/students during adolescence. Through a survey called 'Selfie', conducted via an internet-based, self-administered, and fully anonymous questionnaire, Semi di Melo collects qualitative and quantitative information on the demographic characteristics, lifestyle, leisure time, risk behavior, social relationships and mental wellbeing of middle and high school students in Italy. Data are then analyzed, interpreted, and shared with teachers, parents, and students during guided workshops and focus groups aimed at raising awareness of risky behaviours during adolescence and facilitating intergenerational exchange. To date, the Selfie questionnaire has been distributed to more than 400 Italian public schools, reaching more than 90,000 students. In late 2022, Semi di Melo and the University of Pavia started a collaboration to expand research on data acquired from the Selfie questionnaire through an analytical approach, allowing a more comprehensive understanding of Italian adolescents' lifestyle, social, and psychological well-being. The gathered evidence will be made available to help educators, health and social care professionals, as well as local authorities and decision-makers to develop effective support systems and evidence-based interventions that help adolescents realise their full potentia.

Alpha5GABAA receptors mediate the amnestic but not sedative-hypnotic effects of the general anesthetic etomidate.

A fundamental objective of anesthesia research is to identify the receptors and brain regions that mediate the various behavioral components of the anesthetic state, including amnesia, immobility, and unconsciousness. Using complementary in vivo and in vitro approaches, we found that GABAA receptors that contain the alpha5 subunit (alpha5GABAARs) play a critical role in amnesia caused by the prototypic intravenous anesthetic etomidate. Whole-cell recordings from hippocampal pyramidal neurons showed that etomidate markedly increased a tonic inhibitory conductance generated by alpha5GABAARs, whereas synaptic transmission was only slightly enhanced. Long-term potentiation (LTP) of field EPSPs recorded in CA1 stratum radiatum was reduced by etomidate in wild-type (WT) but not alpha5 null mutant (alpha5-/-) mice. In addition, etomidate impaired memory performance of WT but not alpha5-/- mice for spatial and nonspatial hippocampal-dependent learning tasks. The brain concentration of etomidate associated with memory impairment in vivo was comparable with that which increased the tonic inhibitory conductance and blocked LTP in vitro. The alpha5-/- mice did not exhibit a generalized resistance to etomidate, in that the sedative-hypnotic effects measured with the rotarod, loss of righting reflex, and spontaneous motor activity were similar in WT and alpha5-/- mice. Deletion of the alpha5 subunit of the GABAARs reduced the amnestic but not the sedative-hypnotic properties of etomidate. Thus, the amnestic and sedative-hypnotic properties of etomidate can be dissociated on the basis of GABAAR subtype pharmacology.

Defective place cell activity in nociceptin receptor knockout mice with elevated NMDA receptor-dependent long-term potentiation.

There is growing evidence that NMDA receptor-dependent long-term potentiation (LTP) in the hippocampus mediates the synaptic plasticity that underlies spatial learning and memory. LTP deficiencies correlate well with spatial memory deficits and LTP enhancements may improve spatial memory. In addition, LTP deficiencies are associated with abnormal place cells as expected from the spatial mapping hypothesis of hippocampal function. In contrast, nothing is known on how enhanced NMDA receptor-dependent LTP affects place cells. To address this question we recorded place cells from mice lacking the nociceptin receptor (NOP1/ORL1/OP4) that have enhanced hippocampal LTP. We found that the enhanced LTP was mediated by NMDA receptors, did not require L-type calcium channels, and occurred only when high frequency tetanizing stimulus trains were used. Place cells in nociceptin receptor knockout mice were abnormal in several ways: they were less stable, had noisier positional firing patterns, larger firing fields and higher discharge rates inside and outside the firing fields. Our results suggest that excessive LTP can cause subnormal hippocampal place cell function. The effects of LTP enhancement on place cell function may therefore also depend on molecular details of synaptic plasticity, including the relationship between stimulus frequency and synaptic strength, and not merely on the magnitude of synaptic strength increases. The data have important clinical implications on development of strategies to improve cognitive function.

Impairment in long-term retention but not short-term performance on a water maze reversal task following hippocampal or mediodorsal striatal N-methyl-D-aspartate receptor blockade.

Male Long-Evans rats were injected with 32 ng/mul of the N-methyl-D-aspartate (NMDA) receptor antagonist 3-(2-carboxypiperazin-4-yl) propyl-1-phosphonic acid (CPP) or vehicle and trained to locate a hidden platform in a different location (reversal training) than used on the initial 4 days of training. Rats treated with vehicle or CPP into the dorsal hippocampus, basolateral amygdala, or mediodorsal striatum had similar latencies to locate the platform on the reversal day. Rats infused with CPP into the dorsal hippocampus or mediodorsal striatum failed to search preferentially in the novel location during a 24-hr, drug-free retention test, whereas all other groups searched preferentially in this location. Therefore, blocking dorsal hippocampal or mediodorsal striatal NMDA receptors selectively blocked long-term spatial retention without producing short-term performance deficits.

Place-cell impairment in glutamate receptor 2 mutant mice.

There is a strong correlation between Hebbian, NMDA receptor-dependent long-term potentiation (LTP), place-cell firing, and learning and memory. We made glutamate receptor 2 (GluR2) null mutant mice that show enhanced non-Hebbian LTP in hippocampal CA1 neurons and impaired performance in a spatial learning task. We concluded that in vivo hippocampal place cells of GluR2 mutant mice were functionally impaired because (1) only 22.6% of CA1 neurons showed place fields in GluR2 mutant mice, which was significantly lower than that (43.8%) in wild-type mice; (2) GluR2 mutant place fields were much less precise; and (3) GluR2 mutant place fields were extremely unstable. Our data suggest that place cells of GluR2 knock-out mice did not form robust place fields, and that enhanced non-Hebbian LTP might play a negative role in their formation.