PT - JOURNAL ARTICLE AU - Son Ta Dinh AU - Moritz M. Nickel AU - Laura Tiemann AU - Elisabeth S. May AU - Henrik Heitmann AU - Vanessa D. Hohn AU - Günther Edenharter AU - Daniel Utpadel-Fischler AU - Thomas R. Tölle AU - Paul Sauseng AU - Joachim Gross AU - Markus Ploner TI - Brain dysfunction in chronic pain patients assessed by resting-state electroencephalography AID - 10.1101/595470 DP - 2019 Jan 01 TA - bioRxiv PG - 595470 4099 - http://biorxiv.org/content/early/2019/04/01/595470.short 4100 - http://biorxiv.org/content/early/2019/04/01/595470.full AB - Chronic pain is a common and severely disabling disease whose treatment is often unsatisfactory. Insights into the brain mechanisms of chronic pain promise to advance the understanding of the underlying pathophysiology and might help to develop disease markers and novel treatments. Here, we systematically and comprehensively exploited the potential of electroencephalography (EEG) to determine abnormalities of brain function during the resting state in chronic pain. To this end, we performed state-of-the-art analyses of oscillatory brain activity, brain connectivity and brain networks in 101 patients of either sex suffering from chronic pain. The results show that global and local measures of brain activity did not differ between chronic pain patients and a healthy control group. However, we observed significantly increased connectivity at theta (4 – 8 Hz) and gamma (> 60 Hz) frequencies in frontal brain areas as well as global network reorganization at gamma frequencies in chronic pain patients. Furthermore, a machine learning algorithm could differentiate between patients and healthy controls with an above-chance accuracy of 57%, mostly based on frontal connectivity. These results implicate increased theta and gamma synchrony in frontal brain areas in the pathophysiology of chronic pain. While substantial challenges concerning accuracy, specificity and validity of potential EEG-based disease markers remain to be overcome, our study identifies abnormal frontal synchrony at theta and gamma frequencies as promising targets for non-invasive brain stimulation and/or neurofeedback approaches.