Brain-Computer Interface Technology Transforms Neurosurgical Practice and Brain-Related Care

Brain-computer interface technology is establishing direct communication between the brain and external devices, moving from science fiction concept to clinical application according to a comprehensive review published in March 2025 in the Medical Journal of Peking Union Medical College Hospital. The study, led by Professor Zhao Jizong of Beijing Tiantan Hospital, Capital Medical University, synthesizes the latest advancements in invasive and non-invasive BCIs, clinical applications, and integration with artificial intelligence. BCIs function by detecting neural signals and translating them into commands that control external devices, essentially bypassing damaged pathways to restore function.

These systems range from non-invasive headsets to fully implantable microelectrode arrays, each with varying precision and risks. Clinically, BCI devices have enabled paralyzed individuals to regain movement and aphasia patients to communicate through decoded speech intentions. Cutting-edge hardware, including graphene-based chips and flexible cortical films, enhance signal resolution while minimizing immune response. In neurosurgery, BCIs have transformed intraoperative brain mapping, allowing real-time navigation that preserves critical cognitive and motor regions during tumor resections.

Closed-loop systems show exceptional promise in managing Parkinson's disease and epilepsy, adjusting neural stimulation based on live brain activity. Emerging avenues include using BCIs to detect consciousness in non-responsive patients, assist in psychiatric treatment, and even boost memory in those with Alzheimer's disease. As AI integration improves decoding speed and accuracy, BCIs are rapidly evolving from assistive devices into precision tools for intelligent brain modulation. The horizon for BCI applications is rapidly expanding with the study available through its DOI at https://dx.doi.org/10.12290/xhyxzz.2025-0152.

In clinical practice, they promise more personalized and effective treatments for stroke recovery, spinal cord injury, and neurodegeneration. Beyond hospitals, BCIs could redefine human-computer interaction—enabling cognition-based communication, virtual control, and even mental augmentation. However, widespread deployment depends on overcoming technical hurdles such as long-term device stability and regulatory approval, as well as societal concerns over mental privacy and equity. Despite remarkable strides, key obstacles remain including signal stability, long-term biocompatibility, and affordability that continue to challenge clinical translation.

Ethical concerns around autonomy, identity, and mental privacy also loom large. Professor Zhao Jizong noted that BCI technology represents one of the most exciting frontiers in neuroscience and clinical medicine, with its ability to restore lost functions and interface directly with the brain inviting us to rethink the boundaries of medicine, ethics, and human identity. With continued innovation and cross-sector coordination, BCIs could soon move from experimental trials to transformative tools in intelligent healthcare and neuro-enhancement. The technology's impact extends well beyond the clinic—BCIs are poised to influence cognition, ethical governance, and national security as this disruptive technology matures, promising to transform how we interact with the world while illuminating the brain's inner workings and advancing the frontier of precision medicine.