Forward-looking: Researchers have designed an EEG monitoring device that is simple and unobtrusive, resembling a strand of hair. This innovation could open the door to more comfortable and reliable long-term brain health monitoring for various medical and research purposes. Researchers at Penn State have developed a hairlike electrode that could reshape brain monitoring by offering a discreet, non-invasive alternative to traditional electroencephalography. The device attaches directly to the scalp and allows long-term, with no rigid metal electrodes or sticky gels for long-term EEGs. Electroencephalograms are vital for diagnosing and managing conditions like epilepsy, sleep disorders, and brain injuries. However, conventional systems use rigid metal electrodes and conductive gels that are messy, uncomfortable, and prone to inconsistent signals. The gels also require frequent reapplication, irritate the skin, and the electrodes often shift with movement, compromising data quality. The Penn State team addressed these issues with a 300-micrometer-wide electrode that adheres to the scalp using a specially formulated bioadhesive ink. This adhesive is nearly twice as strong as standard EEG gels, keeping the electrode secure during daily activities like showering and sweating, yet it peels off without damaging the skin. The thin, flexible design conforms closely to the scalp, reducing signal-degrading gaps. In initial testing, the electrode maintained stable performance for 24 hours of continuous wear. It maintained consistent impedance and captured high-quality brain signals, even during daily activities and overnight sleep. The device also reliably recorded alpha wave patterns at multiple intervals without compromising signal fidelity. Another notable feature of the electrode is its design. The 3D-printed electrode uses various colors to match the subject's hair color, making it nearly invisible when worn. This aesthetic advantage could increase acceptance and confidence among patients requiring extended EEG monitoring. // Related Stories Comparing the hairlike electrode, on left, and a human hair. The system requires a wired connection to recording equipment, but researchers are working on a wireless version. This advancement would offer users greater mobility during monitoring and unlock new possibilities for applications beyond clinical diagnostics, such as brain-computer interfaces, virtual reality, and assistive technologies for people with disabilities. A multidisciplinary team from Penn State and the National Taipei University of Technology that developed the innovative hairlike electrode recently detailed their research in Nature. The National Institutes of Health and various other institutions funded the project, underscoring the interest and importance of advancing such promising technology.