BACKGROUND: Numerous studies have shown abnormalities in both cortico-basal ganglia dynamics and gut function in Parkinson's disease (PD). Research investigating the effects of oral levodopa medication in PD has primarily focused on gut function in terms of physiological regulation and microbiota, highlighting the medication's dose-dependent effects. Although gut-brain coupling has been suggested as a significant factor, it is not yet a standard clinical practice for managing motor complications in PD. OBJECTIVES: To assess the use of non-invasive electrophysiology to extract differentiating gut-brain coupling features in Parkinson's patients. We hypothesized that gut-brain coupling, especially in the beta cortical frequency, can inform about the precise severity of motor complications, namely dyskinesia. METHODS: Electroencephalography (EEG) and electrogastrography (EGG) were recorded from adults during physiological and cognitive control tasks at baseline and following food intake (and levodopa administration in PD). After exclusion of incomplete datasets, 60 participants were analyzed (36 PD, 24 healthy controls). Gut-brain coupling metrics, autonomic measures, and motor symptom severity were assessed using correlation and regression analyses. RESULTS: We found that the dyskinesia symptoms were highly correlated to tremor and rigidity symptoms in our patient cohort (rank correlation coefficient>0.5). Linear regression analysis showed that changes in normogastric gut-frontal brain coupling post intervention during focused deep breathing task can inform about the severity of motor complication in patients. The model suggested a characteristic curve relating heart rate variability and gut-brain coupling for reduced symptom severity, opening doors for suitable autonomic interventions. CONCLUSIONS: Our study provides preliminary evidence that gut-brain electrophysiological coupling is sensitive to motor complication severity in Parkinson's disease, particularly under dopaminergic modulation and autonomic engagement. While larger and mechanistically controlled studies are required, these findings support further investigation of gut-brain dynamics as a systems-level biomarker in PD.new LIMITATION: Interpretation is limited by subgroup imbalance, age differences between PD and controls, and overlap among motor symptom domains. Additionally, levodopa may independently influence cortical, motor, and gastrointestinal activity, limiting attribution of observed effects solely to gut-brain mechanisms. Larger, balanced, medication-controlled studies are required to confirm specificity.