Research Portfolio

Projects

Major research and engineering projects organized around BioMEMS platforms, engineered cardiac tissue monitoring, and biosignal analysis systems.

Hypoxia model electromechanical platform diagram
2026.03-Present | MNTL

BioMEMS-Based Multimodal Platform for Engineered Cardiac Tissue Monitoring

Background: Three-dimensional cardiac tissue models require synchronized mechanical and electrical readouts for functional evaluation.

Technical route: Integrating MEMS strain sensing, microelectrode recording, low-noise acquisition, microscopy, and multimodal signal analysis.

My contribution: Platform design, sensing workflow integration, experimental measurement, and cardiac electromechanical feature analysis.

Representative results: Current public records describe the project as an ongoing PhD-stage platform for disease modeling and cardiotoxicity evaluation.

High-throughput drug cardiotoxicity screening platform diagram
2024.03-2026.03 | MNTL

High-Throughput Drug Cardiotoxicity Screening Platform Based on 3D Cardiac Tissues

Background: Drug response evaluation benefits from parallelized in vitro cardiac tissue models with multiparametric functional readouts.

Technical route: Combining 3D cardiac tissue construction with strain-based mechanical sensing and electrophysiological monitoring.

My contribution: System integration, platform optimization, data acquisition workflow design, and analysis of drug-induced functional responses.

Representative results: Related outputs are reflected in selected publications and international conference presentations.

Graphene conductive microenvironment for cardiomyocyte maturation diagram
2022.09-2024.03 | MNTL

Graphene/SU-8 Conductive Microenvironment for Cardiomyocyte Maturation

Background: Conductive microenvironments can regulate cardiomyocyte maturation and intercellular electrophysiological communication.

Technical route: Developing graphene/SU-8 platforms and evaluating cardiomyocyte functional maturation, contraction, and field-potential behavior.

My contribution: Platform development, experimental implementation, data interpretation, and manuscript/conference output preparation.

Representative results: The project supported the ACS Nano publication on enhanced cardiomyocyte maturation and intercellular communication.