Abstract
Gamma oscillations (30–90 Hz) have been proposed as a signature of cortical visual information processing, particularly the balance between excitation and inhibition, and as a biomarker of neuropsychiatric diseases. Magnetoencephalography (MEG) provides highly reliable visual-induced gamma oscillation estimates, both at sensor and source level. Recent studies have reported a deficit of visual gamma activity in schizophrenia patients, in medication naive subjects, and high-risk clinical participants, but the genetic contribution to such a deficit has remained unresolved. Here, for the first time, we use a genetic risk score approach to assess the relationship between genetic risk for schizophrenia and visual gamma activity in a population-based sample drawn from a birth cohort. We compared visual gamma activity in a group (N = 104) with a high genetic risk profile score for schizophrenia (SCZ-PRS) to a group with low SCZ-PRS (N = 99). Source-reconstructed V1 activity was extracted using beamformer analysis applied to MEG recordings using individual MRI scans. No group differences were found in the induced gamma peak amplitude or peak frequency. However, a non-parametric statistical contrast of the response spectrum revealed more robust group differences in the amplitude of high-beta/gamma power across the frequency range, suggesting that overall spectral shape carries important biological information beyond the individual frequency peak. Our findings show that changes in gamma band activity correlate with liability to schizophrenia and suggest that the index changes to synaptic function and neuronal firing patterns that are of pathophysiological relevance rather than consequences of the disorder.
Highlights
Higher neuronal synchronization within the gamma frequency range (30–90 Hz) has been linked to several core cognitive processes, including memory performance [1], attention [2], object recognition [3], and motor control [4]
Group differences in gamma peak amplitude, latency, and frequency in the virtual sensor space We tested for group differences over the peak visual gamma response
For the first time, we investigated whether the visually induced gamma response differs between general population individuals at extreme ends of the distribution of a polygenic risk score for schizophrenia (SCZ-PRS)
Summary
Higher neuronal synchronization within the gamma frequency range (30–90 Hz) has been linked to several core cognitive processes, including memory performance [1], attention [2], object recognition [3], and motor control [4]. Highcontrast grating stimuli generate induced (i.e., not phase-locked to stimulus onset) gamma oscillations in local field potential (LFP) recordings from the primary visual cortex (V1) [5, 6], and high contrast image patterns increase the coherence between neuronal populations in V1 [7, 8]. There is well-established evidence that physiological and behavioral deficits in schizophrenia are associated with impaired perceptual processing; for example, abnormalities of the visual system have been demonstrated in patients with schizophrenia and their unaffected relatives using non-invasive physiological methods [20,21,22,23,24], post-mortem anatomy [25], and psychophysics [26, 27]. Dysfunction in high-order cortical areas that support more complex cognitive functions could be explained by perceptual deficits of bottom-up processing of incoming stimuli [30]
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