TY - JOUR T1 - Using Network Analysis to Localize the Epileptogenic Zone from Invasive EEG Recordings in Intractable Focal Epilepsy JF - bioRxiv DO - 10.1101/247387 SP - 247387 AU - Adam Li AU - Bhaskar Chennuri AU - Sandya Subramanian AU - Robert Yaffe AU - Steve Gliske AU - William Stacey AU - Robert Norton AU - Austin Jordan AU - Kareem A. Zaghloul AU - Sara K. Inati AU - Shubhi Agrawal AU - Jennifer J. Haagensen AU - Jennifer Hopp AU - Chalita Atallah AU - Emily Johnson AU - Nathan Crone AU - William S. Anderson AU - Zach Fitzgerald AU - Juan Bulacio AU - John T. Gale AU - Sridevi V. Sarma AU - Jorge Gonzalez-Martinez Y1 - 2018/01/01 UR - http://biorxiv.org/content/early/2018/01/16/247387.abstract N2 - Treatment of medically intractable focal epilepsy (MIFE) by surgical resection of the epileptogenic zone (EZ) is often effective provided the EZ can be reliably identified. Even with the use of invasive recordings, the clinical differentiation between the EZ and normal brain areas can be quite challenging, mainly in patients without MRI detectable lesions. Consequently, despite relatively large brain regions being removed, surgical success rates barely reach 60-65%. Such variable and unfavorable outcomes associated with high morbidity rates are often caused by imprecise and/or inaccurate EZ localization. We developed a localization algorithm that uses network-based data analytics to process invasive EEG recordings. This network algorithm analyzes the centrality signatures of every contact electrode within the recording network and characterizes contacts into susceptible EZ based on the centrality trends over time. The algorithm was tested in a retrospective study that included 42 patients from four epilepsy centers. Our algorithm had higher agreement with EZ regions identified by clinicians for patients with successful surgical outcomes and less agreement for patients with failed outcomes. These findings suggest that network analytics and a network systems perspective of epilepsy may be useful in assisting clinicians in more accurately localizing the EZ.AUTHOR SUMMARY Epilepsy is a disease that results in abnormal firing patterns in parts of the brain that comprise the epileptogenic network, known as the epileptogenic zone (EZ). Current methods to localize the EZ for surgical treatment often requires observations of hundreds of thousands of EEG data points measured from many electrodes implanted in a patient’s brain. In this paper, we used network science to show that EZ regions may exhibit specific network signatures before, during and after seizure events. Our algorithm computes the likelihood of each electrode being in the EZ and tends to agree more with clinicians during successful resections and less during failed surgeries. These results suggest that a networked analysis approach to EZ localization may be valuable in a clinical setting. ER -