What question did this study set out to answer?

The aim is to develop a quadrupedal biohybrid robot capable of effective locomotion through innovative design features.

February 17, 2026Open Access

Light‐Driven Quadrupedal Walking Biohybrid Robot With Antagonistic Muscle‐Rings and Inclined Joints

Key Points

The aim is to develop a quadrupedal biohybrid robot capable of effective locomotion through innovative design features.
Designed a biohybrid robot with inclined joint axes and antagonistic muscle structures.
Implemented caffeine treatment to enhance muscle contractile force.
Used optical training methods to improve tissue fabrication reproducibility.
The robot achieved improved straight and turning locomotion.
Enhanced contractile force allowed for effective leg lift-off and touchdown.
Combined design features improved walking strides and adaptability to various terrains.

Abstract

This article describes a light‐driven quadrupedal walking biohybrid robot that achieves both straight and turning locomotion through alternating gait. Unlike conventional light‐driven biohybrid robots based on bending soft beams that result in undulatory crawling, our system generates leg lift‐off and touchdown via inclined joint axes and antagonistic muscle pair structures. In addition, caffeine treatment enhanced contractile force, while optical training improved tissue fabrication reproducibility. These combined features expand the possibilities for biohybrid walking robots with improved strides, terrain adaptability, and multijoint scalability.

Light‐Driven Quadrupedal Walking Biohybrid Robot With Antagonistic Muscle‐Rings and Inclined Joints

Key Points

Abstract

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