Robots for Biointerfaces

Bio-integrated Robotics Lab

Robots for Biointerfaces

기존의 생체전자 인터페이스는 스스로 움직이지 못하며, 외부의 개입 없이는 환경에 적응할 수 없는 수동적인 기계 장치입니다. 이러한 한계로 인해, 수동적 조작에 따른 정밀도의 저하와 자율적 이동성 부재로 인한 침습적 접근의 불가피성이 오랫동안 당연시되어 왔습니다.

BiRL은 이러한 한계를 넘어, 소프트 로보틱스의 감지(sensing)와 구동(actuation) 기술을 생체전자 인터페이스에 융합함으로써, 능동적으로 움직이고 적응하는 '로봇형 바이오인터페이스'라는 새로운 패러다임을 제시하고자 합니다. 이를 통해 섬세하고 복잡한 생체 구조를 따라 자율적으로 이동하며, 자동화와 인공지능(AI)을 기반으로 전례 없는 수준의 정밀도와 기능성을 구현합니다.

이러한 연구를 통해 BiRL은 '관찰자'로 머물던 바이오인터페이스를, 생체 시스템과 함께 '상호작용하는 지능형 주체'로 진화시키는 연구를 이끌고 있습니다.

Conventional biointerfaces are mechanically passive — they do not move or adapt on their own. This often-overlooked limitation leads to challenges such as reduced precision from manual operation and invasive procedures due to the lack of autonomous mobility.

At BiRL, we are redefining this paradigm. By integrating soft robotic sensing and actuation into biointerfaces, we transform them from static devices into active robotic systems. These soft robotic biointerfaces can autonomously navigate, adapt, and interact with delicate, geometrically complex biological tissues.

Empowered by automation and AI, this new class of biointerfaces achieves unprecedented levels of precision, adaptability, and intelligence — marking a shift from passive observation to active, intelligent participation in biological systems.

Related work 1

Related work1 img

S. Song, F. Fallegger, A. Trouillet, K. Kim, S. P. Lacour, Deployment of an electrocorticography
system with a soft robotic actuator. Science Robotics 8, eadd1002 (2023).

Electrocorticography (ECoG) is a minimally invasive approach frequently used clinically to map epileptogenic regions of the brain and facilitate lesion resection surgery and increasingly explored in brain-machine interface applications. Current devices display limitations that require trade-offs among cortical surface coverage, spatial electrode resolution, aesthetic, and risk consequences and often limit the use of the mapping technology to the operating room. In this work, we report on a scalable technique for the fabrication of large-area soft robotic electrode arrays and their deployment on the cortex through a square-centimeter burr hole using a pressure-driven actuation mechanism called eversion. The deployable system consists of up to six prefolded soft legs, and it is placed subdurally on the cortex using an aqueous pressurized solution and secured to the pedestal on the rim of the small craniotomy. Each leg contains soft, microfabricated electrodes and strain sensors for real-time deployment monitoring. In a proof-of-concept acute surgery, a soft robotic electrode array was successfully deployed on the cortex of a minipig to record sensory cortical activity. This soft robotic neurotechnology opens promising avenues for minimally invasive cortical surgery and applications related to neurological disorders such as motor and sensory deficits.

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