Next-generation Fiber-based Biomedical, Neural, and Robotic Interfaces (Talk)

To investigate and control the biological/neural system, it is essential to develop the techniques and devices capable of recording and modulating cellular signals as well as freely moving inside the body. However, current interfaces are limited in many factors such as mechanical invasiveness, non-adaptability (flexibility/stretchability), less-functionality, and limited form factors. Naturally, there is a huge need for new systems allowing for precise manipulation and monitoring of cellular and neural activities with high adaptability and minimal invasiveness. Application of fiber-based interfaces fabricated by novel manufacturing skill, thermal drawing process (TDP) can be a solution to address these issues. This preform-to-fiber thermal drawing enables the broad range of functions achievable in multimaterial fibers that include sensors of optical, thermal, chemical, acoustic, and mechanical signals to 3D-from micro actuator and robot. Notably, the multifunctional fibers can be produced from polymers with moduli lower than that of metals and glasses, and with tunable cross-sectional geometry and dimensions on the micrometer scale, which suggests their use as minimally invasive interfaces to biological systems. In this talk, I will introduce various examples of fiber-based interfaces for biomedical and neural applications: (1) Flexible and stretchable fiber-based neural probes; (2) Fiber-type scaffold to help the tissue regeneration; (3) Fiber-based artificial muscle; (4) Multifunctional fiber-based robotic system. These technologies enabling a natural interfacing between biological/neural circuits and external Machines/computers contributes not only human health and welfare but also develop the future with hyper-connectivity.