Robotic Patterning a Superhydrophobic Surface for Collective Cell Migration Screening

Collective cell migration, in which cells migrate as a group, is fundamental in many biological and pathological processes. There is increasing interest in studying the collective cell migration in high throughput. Cell scratching, insertion blocker, and gel-dissolving techniques are some methodolog...

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Veröffentlicht in:	Tissue engineering. Part C, Methods Methods, 2018-04, Vol.24 (4), p.25-213
Hauptverfasser:	Pang, Yonggang, Yang, Jing, Hui, Zhixin, Grottkau, Brian E.
Format:	Artikel
Sprache:	eng
Schlagworte:	3-D printers Biomedical materials Bone Neoplasms - pathology Cancer Cell adhesion & migration Cell culture Cell migration Cell Movement Cell Survival Cell Tracking - methods Cells, Cultured Contact angle Endothelial cells Gene expression Human Umbilical Vein Endothelial Cells - cytology Human Umbilical Vein Endothelial Cells - physiology Humans Hydrophobic and Hydrophilic Interactions Hydrophobic surfaces Laboratories Medical schools Methods Articles Nanoparticles Nanotechnology - instrumentation Osteosarcoma - pathology Pattern formation Polyvinyl alcohol Printing, Three-Dimensional Robotics Robotics - instrumentation Robotics - methods Silica Silicon - chemistry Silicones Solvents Surgery Umbilical vein Wound healing
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container_title	Tissue engineering. Part C, Methods
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creator	Pang, Yonggang Yang, Jing Hui, Zhixin Grottkau, Brian E.
description	Collective cell migration, in which cells migrate as a group, is fundamental in many biological and pathological processes. There is increasing interest in studying the collective cell migration in high throughput. Cell scratching, insertion blocker, and gel-dissolving techniques are some methodologies used previously. However, these methods have the drawbacks of cell damage, substrate surface alteration, limitation in medium exchange, and solvent interference. The superhydrophobic surface, on which the water contact angle is greater than 150 degrees, has been recently utilized to generate patterned arrays. Independent cell culture areas can be generated on a substrate that functions the same as a conventional multiple well plate. However, so far there has been no report on superhydrophobic patterning for the study of cell migration. In this study, we report on the successful development of a robotically patterned superhydrophobic array for studying collective cell migration in high throughput. The array was developed on a rectangular single-well cell culture plate consisting of hydrophilic flat microwells separated by the superhydrophobic surface. The manufacturing process is robotic and includes patterning discrete protective masks to the substrate using 3D printing, robotic spray coating of silica nanoparticles, robotic mask removal, robotic mini silicone blocker patterning, automatic cell seeding, and liquid handling. Compared with a standard 96-well plate, our system increases the throughput by 2.25-fold and generates a cell-free area in each well non-destructively. Our system also demonstrates higher efficiency than conventional way of liquid handling using microwell plates, and shorter processing time than manual operating in migration assays. The superhydrophobic surface had no negative impact on cell viability. Using our system, we studied the collective migration of human umbilical vein endothelial cells and cancer cells using assays of endpoint quantification, dynamic cell tracking, and migration quantification following varied drug treatments. This system provides a versatile platform to study collective cell migration in high throughput for a broad range of applications.
doi_str_mv	10.1089/ten.tec.2017.0499
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Part C, Methods</title><addtitle>Tissue Eng Part C Methods</addtitle><description>Collective cell migration, in which cells migrate as a group, is fundamental in many biological and pathological processes. There is increasing interest in studying the collective cell migration in high throughput. Cell scratching, insertion blocker, and gel-dissolving techniques are some methodologies used previously. However, these methods have the drawbacks of cell damage, substrate surface alteration, limitation in medium exchange, and solvent interference. The superhydrophobic surface, on which the water contact angle is greater than 150 degrees, has been recently utilized to generate patterned arrays. Independent cell culture areas can be generated on a substrate that functions the same as a conventional multiple well plate. However, so far there has been no report on superhydrophobic patterning for the study of cell migration. 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The superhydrophobic surface had no negative impact on cell viability. Using our system, we studied the collective migration of human umbilical vein endothelial cells and cancer cells using assays of endpoint quantification, dynamic cell tracking, and migration quantification following varied drug treatments. 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subjects	3-D printers Biomedical materials Bone Neoplasms - pathology Cancer Cell adhesion & migration Cell culture Cell migration Cell Movement Cell Survival Cell Tracking - methods Cells, Cultured Contact angle Endothelial cells Gene expression Human Umbilical Vein Endothelial Cells - cytology Human Umbilical Vein Endothelial Cells - physiology Humans Hydrophobic and Hydrophilic Interactions Hydrophobic surfaces Laboratories Medical schools Methods Articles Nanoparticles Nanotechnology - instrumentation Osteosarcoma - pathology Pattern formation Polyvinyl alcohol Printing, Three-Dimensional Robotics Robotics - instrumentation Robotics - methods Silica Silicon - chemistry Silicones Solvents Surgery Umbilical vein Wound healing
title	Robotic Patterning a Superhydrophobic Surface for Collective Cell Migration Screening
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