RESUMO
Since the introduction of electronic cigarettes to the U.S. market in 2007, vaping prevalence has surged in both adult and adolescent populations. E-cigarettes are advertised as a safer alternative to traditional cigarettes and as a method of smoking cessation, but the U.S. government and health professionals are concerned that e-cigarettes attract young non-smokers. Here, we develop and analyze a dynamical systems model of competition between traditional and electronic cigarettes for users. With this model, we predict the change in smoking prevalence due to the introduction of vaping, and we determine the conditions under which e-cigarettes present a net public health benefit or harm to society.
Assuntos
Sistemas Eletrônicos de Liberação de Nicotina , Abandono do Hábito de Fumar , Vaping , Adolescente , Adulto , Humanos , Saúde Pública , FumarRESUMO
Lewy body dementias are characterized by deposition of alpha-synuclein (α-syn) protein aggregates known as Lewy bodies and Lewy neurites in cortical regions, in addition to brainstem. These aggregates are thought to cause the death of dopaminergic neurons in the substantia nigra and other vulnerable cell types in patients, leading to parkinsonism. There is evidence from mice that localized overexpression of wild-type α-syn leads to dopaminergic cell death in the substantia nigra. However, it is not known how cortical neurons are affected by α-syn. In this study, we used viral overexpression of α-syn to investigate whether localized overexpression within the cortex affects the density, length, and morphology of dendritic spines, which serve as a measure of synaptic connectivity. An AAV2/6 viral vector coding for wild-type human α-syn was used to target overexpression bilaterally to the medial prefrontal cortex within adult mice. After ten weeks the brain was stained using the Golgi-Cox method. Density of dendritic spines in the injected region was increased in layer V pyramidal neurons compared with animals injected with control virus. Immunohistochemistry in separate animals showed human α-syn expression throughout the region of interest, especially in presynaptic terminals. However, phosphorylated α-syn was seen in a discrete number of cells at the region of highest overexpression, localized mainly to the soma and nucleus. These findings demonstrate that at early timepoints, α-syn overexpression may alter connectivity in the cortex, which may be relevant to early stages of the disease. In addition, these findings contribute to the understanding of α-syn, which when overexpressed in the wildtype, non-aggregated state may promote spine formation. Loss of spines secondary to α-syn in cortex may require higher expression, longer incubation, cellular damage, concomitant dopaminergic dysfunction or other two-hit factors to lead to synaptic degeneration.
Assuntos
Córtex Cerebral/metabolismo , Córtex Cerebral/patologia , Espinhas Dendríticas/metabolismo , Espinhas Dendríticas/patologia , alfa-Sinucleína/metabolismo , Animais , Humanos , Masculino , CamundongosRESUMO
Striatal dopamine strongly regulates how individuals use time to guide behavior. Dopamine acts on D1- and D2- dopamine receptors in the striatum. However, the relative role of these receptors in the temporal control of behavior is unclear. To assess this, we trained rats on a task in which they decided to start and stop a series of responses based on the passage of time and evaluated how blocking D1 or D2-dopamine receptors in the dorsomedial or dorsolateral striatum impacted performance. D2 blockade delayed the decision to start and stop responding in both regions, and this effect was larger in the dorsomedial striatum. By contrast, dorsomedial D1 blockade delayed stop times, without significantly delaying start times, whereas dorsolateral D1 blockade produced no detectable effects. These findings suggest that striatal dopamine may tune decision thresholds during timing tasks. Furthermore, our data indicate that the dorsomedial striatum plays a key role in temporal control, which may be useful for localizing neural circuits that mediate the temporal control of action.