Abstract
Using stereolithography, 20 different structural variations comprised of millimeter diameter holes surrounded by trenches, plateaus, or micro-ring structures were prepared and tested for their ability to stably hold arrays of microliter sized droplets within the structures over an extended period of time. The micro-ring structures were the most effective in stabilizing droplets against mechanical and chemical perturbations. After confirming the importance of micro-ring structures using rapid prototyping, we developed an injection molding tool for mass production of polystyrene 3D cell culture plates with an array of 384 such micro-ring surrounded through-hole structures. These newly designed and injection molded polystyrene 384 hanging drop array plates with micro-rings were stable and robust against mechanical perturbations as well as surface fouling-facilitated droplet spreading making them capable of long term cell spheroid culture of up to 22 days within the droplet array. This is a significant improvement over previously reported 384 hanging drop array plates which are susceptible to small mechanical shocks and could not reliably maintain hanging drops for longer than a few days. With enhanced droplet stability, the hanging drop array plates with micro-ring structures provide better platforms and open up new opportunities for high-throughput preparation of microscale 3D cell constructs for drug screening and cell analysis.
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Acknowledgement
This material is based upon work supported by the Coulter Foundation, and the College of Engineering Translational Research Fund. We also thank Toby Donajkowski and Michael Deininger of the Design and Prototype Lab at the University of Michigan Medical Innovation Center for helpful discussion regarding the stereolithography equipment, providing the stereolithography machine, and fabricating the rapid prototype 384 hanging drop plates for us. A.Y. Hsiao acknowledges a Horace H. Rackham Predoctoral Fellowship from the University of Michigan.
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Hsiao, A.Y., Tung, YC., Kuo, CH. et al. Micro-ring structures stabilize microdroplets to enable long term spheroid culture in 384 hanging drop array plates. Biomed Microdevices 14, 313–323 (2012). https://doi.org/10.1007/s10544-011-9608-5
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DOI: https://doi.org/10.1007/s10544-011-9608-5