TMS Reveals Dynamic Interaction between Inferior Frontal Gyrus and Posterior Middle Temporal Gyrus in Gesture-Speech Semantic Integration.

Abstract

Semantic processing is an amodal process with modality-specific information integrated in supramodal "convergence zones" or "semantic hub" with executive mechanisms that tailor semantic representation in a task-appropriate way. One unsolved question is how frontal control region dynamically interacts with temporal representation region in semantic integration. The present study addressed this issue by using inhibitory double-pulse transcranial magnetic stimulation over the left inferior frontal gyrus (IFG) or left posterior middle temporal gyrus (pMTG) in one of eight 40 ms time windows (TWs) (3 TWs before and 5 TWs after the identification point of speech), when human participants (12 females, 14 males) were presented with semantically congruent or incongruent gesture-speech pairs but merely identified the gender of speech. We found a TW-selective disruption of gesture-speech integration, indexed by the semantic congruency effect (i.e., a cost of reaction time because of semantic conflict), when stimulating the left pMTG in TW1, TW2, and TW7 but when stimulating the left IFG in TW3 and TW6. Based on the timing relationship, we hypothesize a two-stage gesture-speech integration circuit with a pMTG-to-IFG sequential involvement in the prelexical stage for activating gesture semantics and top-down constraining the phonological processing of speech. In the postlexical stage, an IFG-to-pMTG feedback signal might be implicated for the control of goal-directed representations and multimodal semantic unification. Our findings provide new insights into the dynamic brain network of multimodal semantic processing by causally revealing the temporal dynamics of frontal control and temporal representation regions.SIGNIFICANCE STATEMENT Previous research has identified differential functions of left inferior frontal gyrus (IFG) and posterior middle temporal gyrus (pMTG) in semantic control and semantic representation, respectively, and a causal contribution of both regions in gesture-speech integration. However, it remains largely unclear how the two regions dynamically interact in semantic processing. By using double-pulse transcranial magnetic stimulation to disrupt regional activity at specific time, this study for the first time revealed critical time windows when the two areas were causally involved in integrating gesture and speech semantics. Findings suggest a pMTG-IFG-pMTG neurocircuit loop in gesture-speech integration, which deepens current knowledge and inspires future investigation of the temporal dynamics and cognitive processes of the amodal semantic network.