Flytrap-Inspired Mesh-Trap Bioelectronics for Full Spherical Electrophysiological Interrogation of 3D Tissues

Three-dimensional (3D) in vitro tissue models are emerging as powerful platforms for studying development, disease, and therapeutic responses, where close monitoring of electrophysiological activity is essential. However, existing probing methods remain limited in accessibility or spatiotemporal resolution for comprehensive electrophysiological mapping of suspended 3D tissues that closely mimic the native environments. Here we introduce a Venus flytrap-inspired bioelectronic mesh system that enables the full spherical enclosure of 3D tissues in a suspended configuration. The system consists of two hemispherical meshes that envelop the tissue, constructed from highly flexible, stretchable, cell-scale ribbons interconnected into a tissue-compliant network with integrated recording electrode arrays. This architecture enables intimate, conformal tissue integration and supports stable electrophysiological recordings over 300 days. The high-resolution recordings allow precise tracking of local dynamics and correlated global signaling, enabling comprehensive assessment of tissue development as well as detailed evaluation of drug responses for disease modeling. Beyond single tissues, the mesh architecture is extended to fully enclose assembloids composed of multiple tissues, enabling characterization of cross-tissue signaling relevant to advanced heterogenous tissue modeling. Furthermore, the system is translated into array-based platforms, demonstrated by a 4x4 array integrating 1024 electrodes, for high-throughput tissue sampling and cross-study analysis. The developed bioelectronic system and integration method provide a broadly applicable platform to advance electrophysiological studies across diverse tissues and organoids.