AI-Enabled Neural Stabilizer Devices: A Theoretical Novel Approach to Correcting Pathological Brain Waves in Neurological Disorders

Abstract

This article explores the development and potential applications of AI-enabled neural stabilizer devices in treating neurological and psychiatric conditions characterized by pathological brain waves, such as drug-resistant epilepsy. By integrating advanced artificial intelligence with neurostimulation technology, these devices continuously monitor brain activity through implanted electrodes, analyze neural signals in real-time to detect abnormal patterns, and deliver targeted electrical stimulation to disrupt pathological activity before or just after it manifests as clinical symptoms. The use of machine learning algorithms allows for personalized treatment tailored to the individual's unique neural patterns, enhancing the effectiveness of interventions. Clinical studies have demonstrated the efficacy of responsive neurostimulation systems in reducing seizure frequency among patients with refractory epilepsy. Beyond epilepsy, the potential applications extend to conditions like depression, obsessive-compulsive disorder, Tourette's syndrome, Parkinson's disease, and chronic pain. The article also addresses the ethical, technical, and regulatory challenges associated with implementing such advanced technology, emphasizing the need for interdisciplinary collaboration to realize the full potential of this innovative approach.