What this Trial Is About

Effort-based decisions are essential in daily life but strongly impaired in apathy across various brain disorders. Now, significant research to unveil the neural causes of apathy is needed. A crucial corollary to this is the need to identify the brain network and neural mechanisms underlying effort-based decisions. A fronto-striatal network and the noradrenergic system are involved in effort-based decision-making and apathy. Further, motor cortical structures may play a role in effort-based decision-making. However, the role of circuits connecting the fronto-striatal network and the noradrenergic system to the motor structures has been disregarded so far. Non-invasive brain stimulation methods provide a unique and safe means to test the causal role of connectivity changes between fronto-subcortical and motor structures in effort-based decision-making. It's now necessary to have an integrative, connectionnist framework to uncover the causal role of connectivity changes between fronto-subcortical and motor structures in effort-based decision-making. The overarching goal of the present research protocol is to establish an integrative framework testing the causal role of connectivity within recurrent, bidirectional circuits between fronto-subcortical circuits and motor structures in effort-based decision-making. To achieve this overarching goal, investigators will quantifiy the causal role of effective connectivity and oscillatory synchrony in these circuits on effort-related behavior using a non-invasive brain stimulation strategy. Further, a secondary aim is to identify potential non-invasive brain stimulation methods that could increase engagement in effortful behavior, paving the way for translational clinical applications in the context of apathy. The investigators hypothesize that effort-based decision-making in healthy subjects is governed by bidirectional interactions between fronto-subcortical circuits and motor structures such as the primary motor cortex, mediated by oscillatory synchrony in specific frequency bands (e.g., theta and gamma bands). Accordingly, they hypothesize that transient, non-invasive modulation of connectivity and oscillatory synchrony between these structures in healthy human subjects will directly modulate their decision to engage in effort. Specifically, five experiments will use complementary approaches to test the hypothesis.

Neural Bases of Motivation