Scientists develop tiny brain implant that wirelessly transmits secret signals - Video

Imagine sending information straight into the brain without wires, surgery, or sound. That future just came a step closer thanks to scientists at Northwestern University, who have developed a tiny wireless device that uses light to “talk” directly to neurons. The breakthrough, published in Nature Neuroscience, could transform everything from prosthetic limb control to restoring lost senses.

The paper describes a soft, ultra-thin device that sits between the scalp and the skull. About the size of a postage stamp and thinner than a credit card, it emits precisely timed pulses of red light that penetrate bone to stimulate neuron networks in specific brain regions. Unlike older implants requiring fiber-optic cables or bulky interfaces, this system works wirelessly and remains completely under the skin-a leap forward in both safety and freedom of movement.

During testing, researchers led by Professor Yevgenia Kozorovitskiy and bioengineer John A. Rogers fitted the implant on mice genetically modified so that their neurons would respond to light. Using an array of **64 micro LEDs-each thinner than a human hair—**they projected complex patterns of illumination across the cortex. The animals quickly learned to recognize specific light patterns as signals and performed behavioral tasks in response, such as moving toward a target reward. In essence, the device allowed scientists to “train” the brain to interpret artificial light cues as meaningful messages, bypassing normal sensory routes like vision, hearing, or touch.

The system builds on the team’s earlier 2021 work, which used a single LED to control social behaviors in mice. This new multi LED platform goes much further, enabling multi site stimulation that mimics how natural brain activity spreads across large networks during real sensations. Future versions aim to expand the number of LEDs, refine timing control, and extend light penetration deeper into brain tissue.

The device’s potential applications are wide-ranging: restoring sensory feedback to prosthetic limbs, aiding stroke recovery, modulating chronic pain, and perhaps one day replacing damaged sensory inputs. As Rogers explains, the technology was designed “to integrate seamlessly with the brain—without the wires, without the burden.”

This innovation not only deepens our understanding of how brains process information but also points toward a new age of bioelectronic medicine, where light itself may become the language of healing.

REFERENCE: Mingzheng Wu, Yiyuan Yang, Jinglan Zhang, Andrew I. Efimov, Xiuyuan Li, Kaiqing Zhang, Yue Wang, Kevin L. Bodkin, Mohammad Riahi, Jianyu Gu, Glingna Wang, Minsung Kim, Liangsong Zeng, Jiaqi Liu, Lauren H. Yoon, Haohui Zhang, Sara N. Freda, Minkyu Lee, Jiheon Kang, Joanna L. Ciatti, Kaila Ting, Stephen Cheng, Xincheng Zhang, He Sun, Wenming Zhang, Yi Zhang, Anthony Banks, Cameron H. Good, Julia M. Cox, Lucas Pinto, Abraham Vázquez-Guardado, Yonggang Huang, Yevgenia Kozorovitskiy, John A. Rogers. Patterned wireless transcranial optogenetics generates artificial perception. Nature Neuroscience, 2025; DOI: 10.1038/s41593-025-02127-6