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Adhesive Cortical Device Enables Artifact-Free Neuromodulation for Closed-loop Epilepsy Treatment

- A shape-morphing cortex-adhesive sensor realizes personalized focused ultrasound neurostimulation through high-fidelity electrocorticography -

A team of researchers led by Professor SON Donghee and Professor SHIN Mikyung from the Center for Neuroscience Imaging Research (CNIR) within the Institute for Basic Science (IBS), along with Dr. KIM Hyungmin from the Bionics Research Center at the Korea Institute of Science and Technology (KIST), has developed a groundbreaking soft cortical device that could revolutionize the treatment of epilepsy and other neurological disorders.

Epilepsy, a neurological disorder affecting over 65 million people worldwide, is characterized by pathological electrical hyperactivity in the brain resulting in seizures. Notably, approximately 20-30% of all patients are diagnosed with intractable epilepsy, which does not respond to standard medications. Surgical resection of lesions remains a treatment option for these patients, but it presents challenges due to the complexity and risks involved in the procedure.

As a less invasive alternative treatment, the concept of neuromodulation has been proposed, which involves directly stimulating lesioned tissue with mechanical, electromagnetic, or optical energy to suppress brain hyperexcitability. One promising approach is transcranial focused ultrasound (tFUS) neurostimulation, a non-invasive method that stimulates the brain with high precision without causing permanent damage.

For tFUS to be effective in treating epilepsy, it must be paired with a system that can continuously monitor brain activity and adjust the treatment in real-time. However, existing cortex-interfacing devices face challenges due to their high stiffness and low shape adaptability, which makes it difficult for them to conform to the convoluted surface of the brain, resulting in poor tissue-device interfaces.

Their low adhesion to the brain surface also means they struggle to provide accurate brain signals during ultrasound stimulation, due to the interference caused by the mechanical pressure waves.

To address this challenge, the research team developed the Shape-Morphing Cortical-Adhesive (SMCA) sensor, a soft, flexible device that adheres closely to the brain’s surface, ensuring stable and accurate monitoring of brain activity even during tFUS stimulation. The SMCA sensor is composed of a unique combination of materials. It features a layer of catechol-conjugated alginate hydrogel that quickly bonds with brain tissue, providing strong adhesion and reducing the risk of movement or detachment. Additionally, the device’s substrate is made of a self-healing polymer that softens and conforms to the brain’s curved surface at body temperature, ensuring a snug fit and minimizing the risk of signal artifacts.

The team tested the SMCA sensor both ex vivo (outside the body) and in vivo (inside the body), comparing its performance to that of existing devices without adhesive or shape-morphing properties. In experiments with a rat model of epilepsy, the SMCA sensor successfully recorded brain activity during tFUS without interference, enabling the real-time monitoring necessary for effective treatment.

Using this innovative sensor, the researchers implemented a closed-loop seizure control system. This system uses the SMCA sensor to detect early signs of a seizure and automatically adjusts the tFUS treatment in response. The system successfully suppressed seizures in real-time, demonstrating the potential for personalized, adaptive epilepsy treatment.

Professor SON Donghee stated, “Through our study on the brain-adhesive soft bioelectronics platform, we have overcome a major challenge in the field of brain interfaces by achieving high-quality electrocorticography coupled with focused ultrasound stimulation without artifact interference.” He explained the significance of this research and outlined future plans by adding, “We expect our technology to become a cornerstone of a next-generation biomedical platform that enables precise diagnosis and personalized therapy for intractable neurological disorders. Following this study, we will advance the SMCA sensor platform by improving the shape-morphing and cortex-adhesive functionalities, developing highly integrated microelectrodes, and implementing a high-order closed-loop operational algorithm.”

Dr. Hyungmin KIM stated, “We achieved early detection of seizure activity via ECoG, enabling the prevention of seizures. Additionally, we implemented real-time feedback on the effects of ultrasound stimulation, which allowed for the application of personalized stimulation protocols. Looking ahead, we anticipate that the development of electrodes with more channels, as well as multi-channel ultrasound transducers, will facilitate precise mapping of seizure sources and targeted intervention, ultimately enhancing the efficacy and safety of this approach in clinical applications.”

This research was conducted in collaboration with colleagues from Sungkyunkwan University (SKKU) and the Korea Institute of Science and Technology (KIST). The findings were published in Nature Electronics on September 11, 2024.

Figure 1. Overview and operation principle of a shape-morphing cortex-adhesive (SMCA) sensor
      A. A schematic illustration for exploded view of a SMCA sensor. B. A schematic illustration for a SMCA sensor mounted conformally on a rodent’s brain tissue. (Inset) a photoimage illustrating robust tissue adhesion of a SMCA sensor on a rat’s cortex under shear strain. C. Schematic illustrations of sequential brain-interfacing steps of the SMCA sensor for explaining the tissue-adhesive shape-morphing mechanism.
Figure 1. Overview and operation principle of a shape-morphing cortex-adhesive (SMCA) sensor
A. A schematic illustration for exploded view of a SMCA sensor. B. A schematic illustration for a SMCA sensor mounted conformally on a rodent’s brain tissue. (Inset) a photoimage illustrating robust tissue adhesion of a SMCA sensor on a rat’s cortex under shear strain. C. Schematic illustrations of sequential brain-interfacing steps of the SMCA sensor for explaining the tissue-adhesive shape-morphing mechanism.

Schematic illustrations of sequential brain-interfacing steps of the SMCA sensor for explaining the tissue-adhesive shape-morphing mechanism.

Figure 2. Brain interfacing functionalities of SMCA soft patches
      A. Comparison of the tissue-adhesive strength between Alg and Alg–CA according to stretching direction. Both hydrogel materials were coupled with the SHP substrate. B. Plot of relative storage modulus of thermoset PDMS (red) and thermoplastic SHP (blue) films as a function of temperature. (Inset) showing the magnified view of the plot ranging from room temperature (25℃) to body temperature (37℃). C. Strain‒stress curves of PDMS (red) and SHP (blue) films. D. Comparative photoimages illustrating tissue-adhesion performances of Alg/SHP (top), Alg–CA/PDMS (middle), SMCA (bottom) films on bovine brain while shear strain was applied. E. Comparative sequential images of Alg–CA/PDMS (top) and SMCA (bottom) mounted on bovine brain tissue with curved surface morphology illustrating behaviour of soft films over time. The surface temperature of the brain tissue was set at 37 °C.
Figure 2. Brain interfacing functionalities of SMCA soft patches
A. Comparison of the tissue-adhesive strength between Alg and Alg–CA according to stretching direction. Both hydrogel materials were coupled with the SHP substrate. B. Plot of relative storage modulus of thermoset PDMS (red) and thermoplastic SHP (blue) films as a function of temperature. (Inset) showing the magnified view of the plot ranging from room temperature (25℃) to body temperature (37℃). C. Strain‒stress curves of PDMS (red) and SHP (blue) films. D. Comparative photoimages illustrating tissue-adhesion performances of Alg/SHP (top), Alg–CA/PDMS (middle), SMCA (bottom) films on bovine brain while shear strain was applied. E. Comparative sequential images of Alg–CA/PDMS (top) and SMCA (bottom) mounted on bovine brain tissue with curved surface morphology illustrating behaviour of soft films over time. The surface temperature of the brain tissue was set at 37 °C.

Figure 3. SMCA sensor allows for artefact-free neural recording
      A. Schematic image of the in vivo test for neural recording performance. M, motor; S, somatosensory; C, cingulate; R, retrosplenial; P, posterior parietal; V, visual; B, bregma; Ref, reference; Gnd, ground; B-E. Top-view images and corresponding timetrace plots of cortical activity from a representative trial of brain-mounted soft ECoG devices combined with 4 different materials, including PDMS B. SHP C. Alg (interface)/SHP (substrate) D. and SMCA (SMCA sensor) E. Magnified data plots of three consecutive channels, including a channel located on the visual cortex of the left hemisphere (Ch.15) directly stimulated by tFUS of each material platform.
Figure 3. SMCA sensor allows for artefact-free neural recording
A. Schematic image of the in vivo test for neural recording performance. M, motor; S, somatosensory; C, cingulate; R, retrosplenial; P, posterior parietal; V, visual; B, bregma; Ref, reference; Gnd, ground; B-E. Top-view images and corresponding timetrace plots of cortical activity from a representative trial of brain-mounted soft ECoG devices combined with 4 different materials, including PDMS B. SHP C. Alg (interface)/SHP (substrate) D. and SMCA (SMCA sensor) E. Magnified data plots of three consecutive channels, including a channel located on the visual cortex of the left hemisphere (Ch.15) directly stimulated by tFUS of each material platform.

Figure 4. Closed-loop seizure control system capable of apposite tFUS modulation utilizing neurosignal feedback
      A. An illustration of the customized headstage system incorating with the SMCA sensor and a tFUS transducer for closed-loop neural recording and feedback neurostimulation. (Inset) A corresponding image shows the portable closed-loop therapeutic system applied to an awake freely moving rat. B. Schematics and corresponding conceptual plots of neural signals from the soft ECoG devices (top, the conventional device without tissue adhesion and conformability; bottom, the SMCA sensor) as a function of time under tFUS stimulation. C. Schematic illustrations of conceptual ECoG plot recorded from the SMCA sensor during closed-loop tFUS seizure suppression in an awake rodent model. D. Timetrace plot of 16-channel ECoG signals recorded from the SMCA sensor for a case of closed-loop seizure control based on 3-level tFUS protocol modulation, applied to the awake epileptic rodent model. E. Detailed ECoG trace from single-channel in the SMCA sensor during closed-loop seizure control. Magnified plots show 5-sec cropped neural activities corresponding to major phase of seizure epoch during closed-loop tFUS neurostimulation.
Figure 4. Closed-loop seizure control system capable of apposite tFUS modulation utilizing neurosignal feedback
A. An illustration of the customized headstage system incorating with the SMCA sensor and a tFUS transducer for closed-loop neural recording and feedback neurostimulation. (Inset) A corresponding image shows the portable closed-loop therapeutic system applied to an awake freely moving rat. B. Schematics and corresponding conceptual plots of neural signals from the soft ECoG devices (top, the conventional device without tissue adhesion and conformability; bottom, the SMCA sensor) as a function of time under tFUS stimulation. C. Schematic illustrations of conceptual ECoG plot recorded from the SMCA sensor during closed-loop tFUS seizure suppression in an awake rodent model. D. Timetrace plot of 16-channel ECoG signals recorded from the SMCA sensor for a case of closed-loop seizure control based on 3-level tFUS protocol modulation, applied to the awake epileptic rodent model. E. Detailed ECoG trace from single-channel in the SMCA sensor during closed-loop seizure control. Magnified plots show 5-sec cropped neural activities corresponding to major phase of seizure epoch during closed-loop tFUS neurostimulation.

Notes for editors

- References
Sungjun Lee, Jeungeun Kum, Sumin Kim, Hyunjin Jung, Soojung An, Soon Jin Choi, Jae Hyuk Choi, Jinseok Kim, Ki Jun Yu, Wonhye Lee, Hyeok Kim, Hyung-Seop Han, Mikyung Shin, Hyungmin Kim and Donghee Son. A shape-morphing cortex-adhesive sensor for closed-loop transcranial ultrasound neurostimulation. Nature Electronics.
DOI: doi.org/10.1038/s41928-024-01240-x


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For further information or to request media assistance, please contact Donghee Son at the Center for Neuroscience Imaging Research (CNIR), Institute for Basic Science (IBS) (daniel3600@g.skku.edu) or William I. Suh at the IBS Public Relations Team (willisuh@ibs.re.kr).


- About the Institute for Basic Science (IBS)
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Last Update 2023-11-28 14:20