Home Brain-Computer Interfaces Accelerate Integration into Healthcare: Clinical Applications and Product Innovations Surge

Brain-Computer Interfaces Accelerate Integration into Healthcare: Clinical Applications and Product Innovations Surge

Feb 13, 2026 14:09 CST Updated 14:09
CEC CLOUD BRAIN

Healthcare Industry Data Service Provider

Source: People's Daily

Equipped with a smart bionic hand, amputees can easily pick up a water cup to drink;高位截瘫 patients use their thoughts to move the computer cursor, control a wheelchair, and command a robot dog to fetch takeout ……

In recent years, with consecutive breakthroughs in technologies such as neural signal processing, biocompatible materials, and artificial intelligence, brain-computer interfaces have begun to transition from science fiction scenarios to clinical applications, bringing new possibilities for the treatment and rehabilitation of many patients.New Hope

On January 1 this year, as China's first brain-computer interface medical device standard was officially implemented, brain-computer interfaces once again became a hot topic in the market. What is the prospect of brain-computer interfaces, and what can they bring to health? How to break through bottlenecks and accelerate clinical applications? Reporters conducted interviews on this.

Non-invasive: Restoration of Partial Human Functions

"As if I had turned intoRobot"The moment I thought about it, my foot really did step out." This was Mr. Pei's feeling from Tianjin when he first wore the "Shengong—Shenxing" exoskeleton device.

Mr. Pei suffered a sudden cerebral hemorrhage, resulting in right-sided hemiplegia. Due to the inability of his right leg to support standing and walking, his daily activities are now reliant on a wheelchair.

The team from Tianjin University's Brain-Computer Interaction and Human-Machine Symbiosis Haihe Laboratory (hereinafter referred to as "Haihe Laboratory") conducted more than two weeks of brain-controlled exoskeleton gait rehabilitation training for Mr. Pei. Afterwards, his gait significantly improved, with notable enhancements in walking stability and endurance. He is now able to walk independently for short distances.

"Shengong-Shenxing" Exoskeleton Device is a non-invasive brain-computer interface product independently developed by the Haihe Laboratory team. The team has also developed equipment such as "Shengong-Shenji" and "Shengong-Shenjia," which can effectively help stroke patients achieve motor function rehabilitation in their hands and arms, having served more than 3,000 patients cumulatively; Among consumer-oriented products, CEC CLOUD BRAIN's Guoxin Brain-Computer Intelligent Headband has entered the mass production stage. With its "cloud-edge-terminal" intelligent architecture and precise multi-dimensional state recognition capabilities, the product has been successfully applied in scenarios such as fatigue driving warnings and concentration training.

Brain-computer interface technology is also benefiting people with disabilities.

In front of a piano, Mr. Gu skillfully played a melodious piano piece. Amidst the "click-clack" mechanical sounds, he used his mind to control the independent movement of all five fingers of the intelligent bionic hand, which, together with his healthy right hand, performed this piece at two beats per second. Afterwards, he gently picked up an orange with the bionic hand and even lifted a 10-kilogram dumbbell.

"This hand does not require surgical implantation and can be controlled through intuitive thoughts, as if my left hand has returned," Mr. Gu said. Eight years ago, he lost his left hand in an accident, causing great inconvenience in his life. After wearing the intelligent bionic hand, he can easily perform activities such as typing, cooking, and drinking water.

This intelligent bionic hand is a non-invasive brain-computer interface device developed and produced by Zhejiang Qiangnao Technology Co., Ltd. The wearer can control the prosthetic limb with their brain to complete daily tasks. Han Bicheng, founder and CEO of Qiangnao Technology, introduced that the company's technology has helped tens of thousands of physically disabled people in China and abroad to live and work normally.

"Brain-computer interfaces can be divided into non-invasive and invasive (including semi-invasive) according to the implantation method. The advantages of non-invasive brain-computer interface technology are that it is non-invasive, safe, and has higher compatibility." Cao Yong, director of the Clinical and Translational Ward for Brain-Computer Interfaces at Beijing Tiantan Hospital, Capital Medical University, and executive deputy director of the Neurosurgery Center, analyzed that this technology is relatively easier to achieve and has already been used by many patients, such as rehabilitation training for stroke and spinal cord injury patients, and limb function restoration for amputees through wearing smart prosthetics. Currently, China's non-invasive brain-computer interface technology is at an internationally advanced level.

Invasive: Helping Paralyzed Patients Rehabilitate

Little Rui, who is paralyzed in all four limbs, "thinks it over," and the mechanical arm fixed on the table slowly brings a glass of water to his mouth. As Little Rui drinks the water, tears of excitement glisten in his eyes, and a long-absent joy spreads across his face.

In February 2025, the neurosurgery team at Peking University First Hospital successfully implanted the "BeiNao No.1" brain-computer interface into Xiao Rui, a 30-year-old patient. On the fifth day after the surgery, Xiao Rui recovered well. The research team tested the "BeiNao No.1" and guided Xiao Rui through training sessions. Soon, Xiao Rui was able to control a robotic arm to drink water using only his thoughts.

"The 'Beijing Brain One' intelligent brain-computer system has 128 channels, with signal acquisition accuracy, signal transmission, and processing performance all at world-leading levels," introduced Luo Minmin, the director of the Beijing Institute of Brain Science and Intelligence Technology. This system, through a miniature internal device, portable external device, and software algorithms, can bring hope of rehabilitation to patients with spinal cord injuries, stroke, ALS, and other motor or speech function disorders. Currently, the 'Beijing Brain One' intelligent brain-computer system has completed six human implants, assisting patients in achieving limb movement, speech function replacement, and rehabilitation.

Moreover, the "BeiNao No.1" intelligent brain-computer system stimulates the patient's hand muscles by releasing electrical signals to perform actions such as clenching fists, flexing wrists, and extending wrists. Through long-term training and reinforcement, it can prevent muscle atrophy and significantly improve the possibility of patient rehabilitation. After six months of training, Xiaorui’s originally paralyzed hand was able to grasp wooden blocks and pinch marbles between fingers. Eleven months post-surgery, Xiaorui’s overall rehabilitation progress was good, with continuous improvement in upper limb motor function.

Cao Yong said that invasive brain-computer interfaces involve placing functional devices inside the human body, whether under the scalp or beneath the skull, requiring incisions to monitor brain signals. Compared to non-invasive methods, the advantage lies in obtaining higher-quality signals, but it demands more advanced technology and presents greater surgical difficulty.

Clinical Application: Collaborative Innovation Breaks Through Bottlenecks

From leading the first Phase III multicenter clinical trial in China for brain-computer interface treatment of drug-resistant epilepsy, to completing epidural brain-computer interface surgery, and then to wireless implantable speech decoding brain-computer interface surgery... Xuanwu Hospital of Capital Medical University is actively exploring innovative brain-computer interface therapies in several major disease areas, including epilepsy, Parkinson's disease, spinal cord injury, and ALS.

Since 2025, the热度 of brain-computer interfaces has continued to rise. Some believe that with brain-computer interfaces, paralyzed individuals can live like normal people. However, Zhao Guoguang, Director of the National Center for Neurological Disorders and President of Xuanwu Hospital, Capital Medical University, remains cautious. He believes that brain-computer interface technology is still mainly in the clinical trial stage and cannot solve all patient problems. For instance, in the case of ALS (amyotrophic lateral sclerosis), current brain-computer interface technology cannot halt the degenerative disease progression but can only help patients regain partial speech function, not a cure.

"Whether invasive or non-invasive, brain-computer interfaces have demonstrated clear application value in the rehabilitation of motor dysfunction, diagnosis and treatment of neurological and psychiatric diseases, hearing rehabilitation, and other health fields, showing broad prospects," said Ming Dong, Vice President of Tianjin University and Director of Haihe Laboratory. The brain has 80 to 100 billion neurons, each connected to tens of thousands of other neurons. Human understanding of the brain is still far from sufficient, and large-scale recording and accurate decoding and encoding remain challenging. In recent years, brain-computer interface technology has developed rapidly, but there are still bottlenecks in the application of this technology.

In fact, brain-computer interface technology, especially invasive types, still has a long way to go from clinical trials to true clinical application. For instance, how to reliably, stably, and durably obtain EEG signals after implantation; how the implantation targets should be selected; how to achieve long-term compatibility between the implant and brain tissue to ensure greater safety for patients… These issues continue to challenge experts.

Guoguang Zhao believes that the key to promoting brain-computer interface technology "from 0 to 1" breakthrough and "from 1 to N" wide application is to build a collaborative innovation ecosystem involving medical, industrial, academic, research, and application sectors. Medical institutions should actively propose clinical needs and open clinical resources for scientific research units and enterprises to validate new technologies; research institutes and universities need to proactively collaborate with clinical entities to quickly integrate the latest achievements into applications; enterprises must closely cooperate with medical teams from the early stage of R&D, develop products according to clinical needs, and provide engineering and industrialization support.

In May 2025, Beijing Tiantan Hospital, in collaboration with multiple research institutions across China, jointly established a clinical and translational ward for brain-computer interface (BCI), focusing on scientific research, clinical trials, and promoting the transformation of related technological achievements; In April 2025, the comprehensive clinical experimental ward for brain-computer interface, a collaboration between Haihe Laboratory of Tianjin University and Tianjin Huanhu Hospital, began construction, systematically deploying comprehensive BCI clinical solutions for various types of severe neurological conditions… The ecosystem for collaborative innovation in brain-computer interface is rapidly taking shape.

Policy Support: Better Serve People's Health

The interviewed experts believe that the application of brain-computer interface in the health field is still in its infancy, facing issues such as the review and approval of medical devices, the lack of service charge standards, and medical insurance access. There is an urgent need to introduce and implement relevant policies to address these problems specifically.

"The 15th Five-Year Plan proposal suggests 'promoting quantum technology, biomanufacturing, hydrogen energy and nuclear fusion, brain-computer interfaces, embodied intelligence, and sixth-generation mobile communications to become new economic growth points.' Since 2025, China has introduced a series of policy measures to advance the clinical application of brain-computer interfaces."

In March 2025, under the guidance of the National Healthcare Security Administration, the Hubei Provincial Healthcare Security Bureau introduced the first nationwide medical service price program for brain-computer interface technology. Subsequently, in the project guidelines for the nervous system issued by the National Healthcare Security Administration, brain-computer interface was independently established as a separate project to address issues regarding product pricing. Currently, provinces such as Hubei, Zhejiang, and Sichuan have implemented this program.

In July 2025, the Ministry of Industry and Information Technology and six other departments jointly issued the "Implementation Opinions on Promoting the Innovative Development of the Brain-Computer Interface Industry," proposing multiple measures such as strengthening fundamental software and hardware research, creating high-performance products, and empowering innovative entities. This policy marks the first instance of cross-departmental collaboration, covering the entire chain from brain-computer interface technology R&D, standard setting to clinical application.

In September 2025, the National Medical Products Administration (NMPA) released the "Terminology for Medical Devices Using Brain-Computer Interface Technology." Yuan Peng, Deputy Director of the NMPA's Department of Medical Device Registration, introduced that brain-computer interface medical devices integrate multiple disciplines such as neuroscience, clinical medicine, and computer science. The same concept may have different expressions in different fields, and the lack of standardized terminology and inconsistent concepts have become fundamental challenges hindering industry development. The release of this standard establishes a unified "language" system for this emerging field, supporting its standardized and orderly development.

To accelerate the research, development, and market entry of brain-computer interface medical devices, in December 2025, the National Medical Products Administration (NMPA) included implantable brain-computer interface medical devices in the priority review list for high-end medical devices. Yuan Peng stated that brain-computer interface medical devices are a typical representation of high-end medical devices and new quality productive forces, which will bring significant changes to human health in the future. The NMPA will strengthen its support for brain-computer interface technology through expedited review and approval processes and scientific regulation, enabling it to better serve public health.