Litcius/Paper detail

3D Spatiotemporal Electrophysiology of Cardiac Organoids Using Shell Microelectrode Arrays

Soo Jin Choi, Z. Liu, Feiyu Yang, Hanwen Wang, Derosh George, David H. Gracias, Deok‐Ho Kim

2025Advanced Materials7 citationsDOI

Abstract

Cardiac organoids have emerged as powerful platforms for modeling human heart development and disease. However, traditional 2D microelectrode arrays (MEAs) are limited to planar recordings and fail to capture the 3D propagation of electrical signals. Here, programmable, shape-adaptive, organoid-encapsulating shell MEAs are presented as a technology that enables comprehensive 3D electrophysiological mapping. These on-chip-fabricated devices feature customizable geometries and electrode layouts tailored to an organoid's unique morphology. Shell MEAs generate high-resolution 3D isochrone and conduction velocity maps, unveiling long-term spatiotemporal field potential dynamics in spontaneously beating organoids. Furthermore, they integrate multiple modalities, such as calcium imaging to corroborate electrophysiological findings and pharmacological screening to assess organoid responses to isoproterenol, E-4031, and serotonin. This platform represents a significant advance in bioelectronic interfaces, enabling high-content 3D spatiotemporal functional analysis for cardiac disease modeling and pharmacological testing.

Topics & Concepts

MicroelectrodeElectrophysiologyOrganoidMultielectrode arrayCardiac electrophysiologyMaterials scienceNanotechnologyShell (structure)PlanarElectrodeBiomedical engineeringLocal field potentialConduction abnormalities3d printedComputer scienceNeuroscience3d modelElectrical conductionElectrode arrayNeuroscience and Neural EngineeringMicrofluidic and Capillary Electrophoresis Applications3D Printing in Biomedical Research
3D Spatiotemporal Electrophysiology of Cardiac Organoids Using Shell Microelectrode Arrays | Litcius