While it is generally accepted that neurons control complex behavior and brain computation, the role of non-neuronal cells in this context remains unclear. Astrocytes, glial cells of the central nervous system, exhibit complex forms of chemical excitation, most prominently calcium transients, evoked by local and projection neuron activity. In this talk, I will provide mechanistic links between astrocytes’ spatiotemporally complex activity patterns, neuronal molecular signaling, and behavior. Using a visual detection task, in vivo calcium imaging, robust statistical analyses, and machine learning approaches, my work shows that cortical astrocytes encode the animal's decision, reward, performance level, and sensory properties. Behavioral context and motor activity-related parameters strongly impact astrocyte responses. Error analysis confirms that astrocytes carry behaviorally relevant information, supporting astrocytes' complementary role to neuronal coding beyond their established homeostatic and metabolic roles.

Mammalian neonates are born immature. Thus mothers are equipped with innate motivation to nurture them. Moreover, in species that live in a family group, fathers and older siblings may also provide extensive care to the young. By studying those highly social species, including laboratory mice, common marmosets, and humans, we are trying to elucidate the neural mechanisms of parental care. Neuronal activity mapping and site-specific functional suppression in mice identified the central part of the medial preoptic area (cMPOA) as the hub of caregiving network for both mothers and fathers.Recent findings about the neural circuit and molecular signaling involved in caregiving motivation will be discussed.