Polyimide-Based Flexible Multi-Electrode Arrays: Synthesis, Microfabrication, and in-vivo Validation

Neurological disorders such as epilepsy, Parkinsons disease, are rising globally, with conditions like drug-resistant epilepsy affecting millions of patients for whom traditional pharmacological treatments are ineffective. Implantable neural devices have shown great promise in managing these conditions, but their accessibility is limited due to high costs and the availability of suitable biocompatible materials.Thin film implantable neural interfaces hold immense promise over conventional clinical electrodes, offering higher resolution, flexibility, and improved integration with neural tissue. However, their widespread use, especially for flexible interfaces, is limited by the lack of customizable and medical grade materials. We report a novel synthesis method for ISO 10993-11 compliant polyamic acid that enables the fabrication of biocompatible polyimide films tailored for neural implants. Using this material, we developed 4 and 32 channel depth and surface electrodes, including custom whole brain ECoG arrays. These were implanted in the laforin knockout mice, a validated model of drug-resistant epilepsy, to monitor spontaneous seizures. Both acute and 12 day recordings demonstrated mechanical flexibility, long term stability, and excellent biocompatibility. This study presents a clinically safe material platform and a complete fabrication pathway for building thin film neural interfaces, paving the way for broader clinical use in applications such as epilepsy monitoring and stereo EEG.