Standardization of Automated Cell-Based Protocols for Toxicity Testing of Biomaterials

Abstract

Advances in high-throughput screening (HTS) instrumentation have led to enormous reduction of costs (e.g., of pipetting stations) and to the development of smaller instruments for automation of day-to-day routines in small research laboratories. In the biomaterials community, there has been an increasing interest for standardized screening protocols to identify cell type–specific cytocompatible biomaterials suitable for tissue engineering (TE) applications. In this study, the authors established a multiplexed assay protocol for toxicity screening of biomaterials using a low- to medium-throughput robotic liquid handling station (LHS). The protocol contains analysis of viability, cytotoxicity, and apoptosis combined in one assay. This study includes performance results of a side-by-side comparison of the EpMotion 5070 LHS and conventional pipetting/dispensing systems. Critical parameters were optimized each for a given platform. Higher accuracy and reproducibility were achieved for LHS compared to manually treated samples. The practicability and accuracy of the method in a typical small laboratory setting were tested by running daily routine tasks by trained and untrained laboratory staff. In addition, advantages and disadvantages as well as the step-by-step application protocol are reported. The approach described provides a potential utility in screening biomaterials toxicity, allowing researchers to meet the needs of low- and medium-throughput laboratories.

Keywords

cytotoxicity automation biomaterials multiplexed assays HTS

References

Fox S.

Farr-Jones S.

Yund M.

.High Throughput Screening for Drug Discovery: Continually Transitioning into New Technology.J. Biomol. Screen. 1999;4 (4): 183-186

Smith A.

.Screening for Drug Discovery: The Leading Question.Nature. 2002;418 (6896): 453-459

Chapman T.

.Lab Automation and Robotics: Automation on the Move.Nature. 2003;421 (6923): 661-666

Pereira D. A.

Williams J. A.

.Origin and Evolution of High Throughput Screening.Br. J. Pharmacol. 2007;152 (1): 53-61

Worzella T.

Larson B.

.Perform Multiplexed Cell-Based Assays on Automated Platforms.Cell Notes. 2005;12:13-16

Michael S.

Auld D.

Klumpp C.

Jadhav A.

Zheng W.

Thorne N.

Austin C. P.

Inglese J.

Simeonov A.

.A Robotic Platform for Quantitative High-Throughput Screening.Assay Drug Dev. Technol. 2008;6 (5): 637-657

Albert K. J.

Bradshaw J. T.

Knaide T. R.

Rogers A. L.

.Verifying Liquid-Handler Performance for Complex or Nonaqueous Reagents: A New Approach.Clin. Lab. Med. 2007;27 (1): 123-138

Blow N.

.Lab Automation: Tales along the Road to Automation.Nat. Methods. 2008;5 (1): 109-112

Langer R.

Tirrell D. A.

.Designing Materials for Biology and Medicine.Nature. 2004;428 (6982): 487-492

10.

Simpson D. G.

Bowlin G. L.

.Tissue-Engineering Scaffolds: Can We Re-Engineer Mother Nature?.Expert Rev. Med. Devices. 2006;3 (1): 9-15

11.

Williams D. F.

.On the Mechanisms of Biocompatibility.Biomaterials. 2008;29 (20): 2941-2953

12.

Zaman G. J.

.Cell-Based Screening.Drug Discov. Today. 2004;9 (19): 828-830

13.

Power K. A.

Fitzgerald K. T.

Gallagher W. M.

.Examination of Cell-Host-Biomaterial Interactions via High-Throughput Technologies: A Re-appraisal.Biomaterials. 2010;31 (26): 6667-6674

14.

Kellard L.

Engelstein M.

.Automation of Cell-Based and Noncell-Based Permeability Assays.JALA. 2007;12:104-109

15.

Crouch S.

Slater K.

.High-Throughput Cytotoxicity Screening: Hit and Miss.Drug Discov. Today. 2001;6 (suppl 1): 48-53

16.

Hung P. J.

Lee P. J.

Sabounchi P.

Lin R.

Lee L. P.

.Continuous Perfusion Microfluidic Cell Culture Array for High-Throughput Cell-Based Assays.Biotechnol. Bioeng. 2005;89 (1): 1-8

17.

Kim M. S.

Yeon J. H.

Park J. K.

.A Microfluidic Platform for 3-Dimensional Cell Culture and Cell-Based Assays.Biomed. Microdevices. 2007;9 (1): 25-34

18.

Upadhyaya S.

Selvaganapathy P. R.

.Microfluidic Devices for Cell Based High Throughput Screening.Lab Chip. 2010;10 (3): 341-348

19.

Anderson D. G.

Levenberg S.

Langer R.

.Nanoliter-Scale Synthesis of Arrayed Biomaterials and Application to Human Embryonic Stem Cells.Nat. Biotechnol. 2004;22 (7): 863-866

20.

Anderson D. G.

Putnam D.

Lavik E. B.

Mahmood T. A.

Langer R.

.Biomaterial Microarrays: Rapid, Microscale Screening of Polymer-Cell Interaction.Biomaterials. 2005;26 (23): 4892-4897

21.

Mei Y.

Saha K.

Bogatyrev S. R.

Yang J.

Hook A. L.

Kalcioglu Z. I.

Cho S.-W.

Mitalipova M.

Pyzocha N.

Rojas F.

, et al.Combinatorial Development of Biomaterials for Clonal Growth of Human Pluripotent Stem Cells.Nat. Mater. 2010;9:768-778

22.

Neuss S.

Apel C.

Buttler P.

Denecke B.

Dhanasingh A.

Ding X.

Grafahrend D.

Groger A.

Hemmrich K.

Herr A.

, et al.Assessment of Stem Cell/Biomaterial Combinations for Stem Cell–Based Tissue Engineering.Biomaterials. 2008;29 (3): 302-313

23.

van den Dolder J.

Spauwen P. H.

Jansen J. A.

.Evaluation of Various Seeding Techniques for Culturing Osteogenic Cells on Titanium Fiber Mesh.Tissue Eng. 2003;9 (2): 315-325

24.

Williams D. F.

.On the Nature of Biomaterials.Biomaterials. 2009;30 (30): 5897-5909

25.

Grzeskowiak R.

Oltmanns R.

Accuracy and Precision of the EpMotion System. Hamburg, Germany: Eppendorf; 2004:

26.

Muller U.

.In Vitro Biocompatibility Testing of Biomaterials and Medical Devices.Med. Device Technol. 2008;19 (2): 30 32-34

27.

Dekker A.

Panfil C.

Valdor M.

Pennartz G.

Richter H.

Mittermayer C. H.

Kirkpatrick C. J.

.Quantitative Methods for In Vitro Cytotoxicity Testing of Biomaterials.Cells Mater. 1994;4 (2): 101-112

28.

Kevorkov D.

Makarenkov V.

.Statistical Analysis of Systematic Errors in High-Throughput Screening.J. Biomol. Screen. 2005;10 (6): 557-567

29.

Epstein D. M.

Tebbett I. R.

Boyd S. E.

.Eliminating Sources of Pipetting Error in the Forensic Laboratory.Forensic Sci. Commun. 2003;5 (4):