Event Abstract Back to Event Dissociating the role of dorsal and ventral visual streams in object lifting and weight perception Vonne Van Polanen1*, Guy Rens1 and Marco Davare1 1 KU Leuven, Belgium When sequentially lifting a series of differently weighted objects, our fingertip forces are typically scaled according to the weight of the previously lifted object, an effect often referred to as sensorimotor memory [2]. For instance, force rates are higher after the lift of a heavy compared to a light object. Recently, we showed that this effect on force parameters also changes perceptual estimates, where objects are judged lighter after the lift of a heavy compared to a light weight [3]. Here, we aimed to investigate the causal role of the dorsal vs. ventral visual streams in these processes, given they are classically involved in computing motor vs. perceptual parameters, respectively. We used transcranial magnetic stimulation (TMS) to investigate the contribution of the left anterior intraparietal sulcus (aIPS) and lateral occipital (LO) areas, which are important nodes for processing hand-object interactions in the dorsal and ventral streams. Subjects received TMS to either aIPS or LO. Neuronavigation (Brainsight) was used to localize our TMS targets on individual structural brain imaging scans. The left aIPS was defined anatomically as the intersection between the intraparietal and postcentral sulci and LO was located using previously published functional coordinates [1]. Subjects were asked to grip and lift equally sized but differently weighted (light, 2N, or heavy, 6N) objects in a pseudo-randomized order and provide a weight estimate on a self-chosen scale. During object lifting, TMS was applied in a burst of 3 pulses (10Hz) at 120% of the active motor threshold. Three stimulation conditions were compared for each brain area, with stimulation at object contact (dynamic phase), 500 ms after object lift-off (static phase) or no stimulation. We quantified the effect of TMS on perceptual weight estimates, peak grip and load force rates, loading phase duration and mean grip force during stable hold. For each parameter, a mixed ANOVA was performed with TMS target (aIPS or LO) as between-subject factor and TMS condition (dynamic, static, or no stimulation) and object order (light-light, heavy-light, light-heavy, or heavy-heavy) as within-subject factors. When previously lifting a heavy object, peak grip and load force rates were higher and loading phase durations were shorter compared to previously lifting a light object, in line with classical sensorimotor memory effects. It is noteworthy that TMS did not alter this order effect. We only found a general effect of TMS when applied during the dynamic phase, with increased force rate peaks compared to the other TMS conditions. Furthermore, stable grip forces were higher after lifting a heavy object compared to a light one. Interestingly, this effect was cancelled in the aIPS group. No general effect of TMS condition on stable grip force was found. Finally, weight estimations were lower when a light object was preceded by a heavy object compared to a light one, replicating our earlier findings [3]. TMS led to overall lighter weight ratings, independently of the targeted area or timing. Remarkably, the order effect on weight estimations was cancelled when TMS was applied during the static phase over either aIPS or LO. These findings suggest that both aIPS and LO are involved in late phases of object weight perception. Moreover, the role of dorsal and ventral stream areas in mediating sensorimotor memory effects seems limited to aIPS for controlling grip forces in later phases of lifting. Overall, this sheds new light on the interactions between brain networks mediating action and perception during object manipulation.