Researchers from the GIST Propose Ultrasound Stimulation as an Effective Therapy for Alzheimers Disease in New Study


Synchronizing ones brainwaves to ultrasound pulses could reduce the accumulation of abnormal proteins characteristic of the onset of Alzheimers disease.

Effects of transcranial ultrasound stimulation pulsed at 40 Hz on Aβ plaques and brain rhythms in 5×FAD mice

Alzheimers disease affects over 50 million people worldwide and is presently incurable. A viable treatment strategy involves reducing abnormal protein accumulation in the brain with gamma waves. However, studies validating its therapeutic effects using non-focused ultrasound with gamma entrainment are lacking. Now, scientists from the Gwangju Institute of Science and Technology demonstrate reduced protein accumulation in the brain by synchronizing brain waves to external ultrasound pulses at gamma frequency, opening doors to a non-invasive therapy.

With the increase in average life expectancy in many parts of the world, certain age-related diseases have become more common. Alzheimer’s disease (AD), unfortunately, is one of them, being extremely prevalent within aging societies in Japan, Korea, and various European countries. Currently there is no cure or an effective strategy to slow down the progression of AD. As a result, it causes much suffering to patients, families, and caregivers as well as a massive economic burden.

Fortunately, a recent study by a team of scientists at the Gwangju Institute of Science and Technology (GIST) in Korea has just demonstrated that there might be a way to combat AD by using “ultrasound-based gamma entrainment,” a technique that involves syncing up a person’s (or an animal’s) brain waves above 30 Hz (called “gamma waves”) with an external oscillation of a given frequency. The process happens naturally by exposing a subject to a repetitive stimulus, such as sound, light, or mechanical vibrations.

Previous studies on mice have shown that gamma entrainment could fight off the formation of β-amyloid plaques and tau protein accumulations — a standard hallmark of the onset of AD. In this recent paper, which was published in Translational Neurodegeneration, the GIST team demonstrated that it is possible to realize gamma entrainment by applying ultrasound pulses at 40 Hz, i.e., in the gamma frequency band, into the brain of an AD-model mice.

One of the main benefits of this approach lies in the way it is administered. Associate Professor Jae Gwan Kim, who led the study alongside Assistant Professor Tae Kim, explains: “Compared with other gamma entrainment methods that rely on sounds or flickering lights, ultrasound can reach the brain non-invasively without disturbing our sensory system. This makes ultrasound-based approaches more comfortable for the patients.

As their experiments showed, mice exposed to ultrasound pulses for two hours daily for two weeks had reduced β-amyloid plaque concentration and tau protein levels in their brain. Furthermore, electroencephalographic analyses of these mice also revealed functional improvements, suggesting that brain connectivity also benefits from this treatment. Moreover, the procedure did not cause any type of microbleeding (brain hemorrhages), indicating that it was not mechanically harmful to brain tissue.

Overall, the promising results of this study could pave the way to innovative, non-invasive therapeutic strategies for AD without side effects, as well as help treat other conditions besides AD. Dr. Tae Kim remarked: “While our approach can significantly improve the quality of life of patients by slowing the progression of AD, it could also offer a new solution to other neurodegenerative diseases, such as Parkinson’s disease.

Let us hope future studies will cement ultrasound-based gamma entrainment as an effective treatment option, and provide a much-needed relief to AD patients and their families.


Authors: Mincheol Park1, Gia Minh Hoang1, Thien Nguyen1, Eunkyung Lee1, Hyun Jin Jung2, Youngshik Choe2, Moon Hwan Lee3, Jae Youn Hwang3, Jae Gwan Kim1* and Tae Kim1*

Title of original paper: Effects of transcranial ultrasound stimulation pulsed at 40 Hz on Aβ plaques and brain rhythms in 5×FAD mice

Journal: Translational Neurodegeneration



  1. Department of Biomedical Science and Engineering, Gwangju Institute of Science and Technology
  2. Korea Brain Research Institute
  3. Department of Information and Communication Engineering, Daegu Gyeongbuk Institute of Science and Technology

About the Gwangju Institute of Science and Technology (GIST)
The Gwangju Institute of Science and Technology (GIST) was founded in 1993 by the Korean government as a research-oriented graduate school to help ensure Korea’s continued economic growth and prosperity by developing advanced science and technology with an emphasis on collaboration with the international community. Since that time, GIST has pioneered a highly regarded undergraduate science curriculum in 2010 that has become a model for other science universities in Korea. To learn more about GIST and its exciting opportunities for researchers and students alike, please visit:

About the authors
Jae Gwan Kim is an Associate Professor of the Department of Biomedical Science and Engineering at GIST in Korea. His group develops methods to diagnose and treat Alzheimer’s disease using functional near-infrared spectroscopy and transcranial ultrasound stimulation.

Tae Kim is an Assistant Professor of the Department of Biomedical Science and Engineering at GIST in Korea. He is a psychiatrist and neuroscientist who focuses on bridging clinical psychiatry and basic neuroscience in regards to sleep physiology and its disorders, mental disorders, and dementia. One of his main research topics covers the neurobiological mechanisms of gamma oscillations and their clinical implications.



Gwangju Institute of Science and Technology (GIST)

GIST is a research-oriented university & a prestigious school in science and technology, located at Gwangju, South Korea. Visit: