PEER-REVIEWED PUBLICATION

2024

Automated fabrication of a scalable heart-on-a-chip device by 3D printing of thermoplastic elastomer nanocomposite and hot embossing

Wu Q, Xue R, et al.

Bioactive Materials

University of Toronto, University Health Network, University of Manchester, Université de Montréal, National Research Council Canada, Massachusetts Institute of Technology, Montreal TransMedTech Institute, Centre Hospitalier Universitaire Sainte-Justine

Canada, United Kingdom, United States

RESEARCH SUMMARY

This study presents an automated, scalable workflow for fabricating next-generation multiwell heart-on-a-chip devices by combining hot embossing of polystyrene substrates with precision 3D printing of quantum-dot-doped thermoplastic elastomer (TPE/QD) microwires. Built-in carbon electrodes enable long-term electrical stimulation, while fluorescent microwires serve as integrated force sensors for engineered human iPSC-derived cardiac tissues. Compared to manual Biowire II fabrication, the automated method reduced per-well production time by more than four orders of magnitude and enabled seamless expansion to 24- and 96-well formats. Cardiac tissues matured under electrical pacing exhibited improved excitation thresholds, enhanced capture rates, positive force–frequency behavior, robust sarcomeric alignment, and physiologically relevant drug responses to nifedipine and lidocaine. This automated platform significantly advances high-throughput cardiac tissue engineering and preclinical pharmacological screening. :contentReference[oaicite:1]{index=1}

A customized MicroSquisher system developed collaboratively with the research team was used to obtain high-resolution force–displacement curves of TPE/QD nanocomposite microwires used as integrated force sensors in the heart-on-a-chip device. Custom SU-8-based probe geometries were fabricated to match the curvature and diameter of cardiac microtissues formed around the microwires, ensuring accurate bending measurements under micronewton-scale loads. The MicroSquisher enabled quantification of microwire stiffness, calibration of fluorescent wire-deflection-based force sensing, and validation that quantum dot incorporation did not alter mechanical behavior. These calibrated wire mechanics were essential for accurate contractile force extraction during tissue maturation and drug-response assays. :contentReference[oaicite:2]{index=2}

AUTHORS

Qinghua Wu; Ruikang Xue; Yimu Zhao; Kaitlyn Ramsay; Erika Yan Wang; Houman Savoji; Teodor Veres; Sarah H. Cartmell; Milica Radisic.

PUBLICATION DETAILS

JOURNAL

Bioactive Materials

YEAR

2024

INSTITUTIONS

COUNTRIES

Canada, United Kingdom, United States

INSTRUMENT USED

Custom

TESTING METHODS

Compression TestingMicro-Mechanical TestingUltra Low Force Testing

RESEARCH APPLICATIONS

3D Bioprinting & Bioink Materials TestingCardiac Tissue Engineering & MechanicsMechanotransductionOrgan-On-A-Chip SystemsPolymers and Elastomers Testing

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