In-situ electromechanical testing and loading system for dynamic cell-biomaterial interaction study.

The mechanical and electrical properties of biomaterials are essential in cell function regulation during cell-biomaterial interaction. However, previous studies focused on probing cell regulation mechanisms under one type of stimulus, and a platform that enables the study of electromechanical coupling effects of a biomaterial on cells is still lacking. Here, we present an in-situ electromechanical testing and loading system to image live cells when co-cultured with electroactive biomaterials. The system can provide accurate and repeatable stretch on biomaterials and cells to mimic in vivo tension microenvironment. Besides, the integrated displacement transducer, force sensor, and electrical signal detector enable the real time detection of electromechanical signals on electroactive biomaterials under various stretch loading. Combined with a microscope, live cell imaging can be realized to probe cell behavior. The feasibility of the system is validated by culturing mesenchymal stem cells on piezoelectric nanofiber and conductive hydrogel. Experiment results show the device as a reliable and accurate tool to investigate electromechanical properties of biomaterials and probe essential features of live cells. Our system provides a way to correlate cell behavior with electromechanical cues directly and is useful for exploration of cell function during cell-biomaterial interaction.