Improving Hallucinations by Targeting the RSTS with TES

Improving Hallucinations by Targeting the RSTS with TES

Description
Description

Functional neuroimaging studies have identified neural correlates of hallucinations across multiple brain regions. Some studies suggest a common neuroanatomical substrate independent of the sensory modality, while others suggest different neural correlates for different types of hallucinations. However, whether these neuroimaging findings represented a cause, consequence or epiphenomenon of hallucinations was unclear until recently. Using lesion network mapping, researchers demonstrated that focal brain lesions play a causal role in the development of hallucinations and can occur in different brain locations, both inside and outside sensory pathway, and that greater than 90% of lesion locations causing hallucinations are negatively connected to the right superior temporal sulcus (rSTS). The rSTS is known to play a role in social cognition, biological motion, audiovisual integration, and speech. Hence, when spontaneous activity decreases at lesion locations causing hallucinations, spontaneous activity in the rSTS increases, the exact pattern thought to predispose to hallucinations. Additionally, functional connectivity within this region is abnormal in patients with visual and auditory hallucinations. Therefore, the association between rSTS connectivity and hallucinations would suggest this region may be optimal for modulation via non-invasive brain stimulation.

One method by which cortical excitability can be altered is with transcranial direct current stimulation (tDCS), a non-invasive brain stimulation technique. High definition tDCS (HD-tDCS) is a refined version of tDCS with improved spatial precision of cortical stimulation. This involves the application of a weak electrical current (1-2 mA) delivered to the brain via scalp electrodes. tDCS can modulate cortical excitability, where anodal stimulation tends to increase (i.e. the resting potential becomes less negative) and cathodal stimulation tends to decrease the underlying membrane potential (i.e. the resting potential becomes more negative). While tDCS is a promising adjunctive treatment of auditory hallucinations and negative symptoms in schizophrenia, less is known about its role in treating hallucinations overall. To date, no study has non-invasively stimulated the rSTS with tDCS in psychosis and examined its effects on hallucinations. However, there are studies in healthy volunteers showing that anodal stimulation to the STS resulted in increased auditory false perceptions, while cathodal stimulation decreased false perceptions and was lower than the sham condition. Taken together, the recent lesion network mapping identifying the rSTS as a major source of hallucinations combined with prior studies showing that the rSTS is associated with hallucinations suggest that it may be possible to alleviate hallucinations by designing a tDCS protocol that targets the rSTS with cathodal stimulation. Technological advances in noninvasive neuromodulation and electrical field modeling further allow us to create a tDCS protocol specifically guided by the results of lesion network mapping studies with high spatial resolution.