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Chapter 6 - High-content imaging

Published online by Cambridge University Press:  05 April 2013

By
Frits Hulshof ,
Er Liu ,
Andrea Negro ,
Samy Gobaa ,
Matthias Lutolf ,
Prabhas V. Moghe  and
Hugo Fernandes
Edited by
Jan de Boer  and
Clemens A. van Blitterswijk
Jan de Boer
Affiliation:
University of Twente, Enschede, The Netherlands
Clemens A. van Blitterswijk
Affiliation:
University of Twente, Enschede, The Netherlands
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Summary

Scope

High-content imaging (HCI) plays a pivotal role in high-throughput screening (HTS) of biological responses to biomaterials. This chapter will give a brief introduction to its basic principles by explaining the most commonly used imaging techniques, describing the general structure of an image analysis pipeline and providing a summary of available HCI software. Special emphasis will be devoted to the initial steps of image analysis such as image correction, segmentation and feature extraction. Additionally we include a brief overview of relevant literature and description of promising new tools for HCI. Finally, two classic experiments will be described, which use state-of-the-art HCI in biomaterial science by experts in the field.

Origins of high-content imaging

The first person to observe micro-organisms with a microscopic device was the Dutchman Antoni van Leeuwenhoek (1), who was able to make and polish tiny lenses of high curvature which were the forerunners of the modern microscope. Robert Hooke, the English father of microscopy, later improved on the design and confirmed van Leeuwenhoek’s findings. Since then, light microscopy has evolved into its modern incarnation. The first use of fluorescence microscopy in biology was in 1881 when the bacteriologist Paul Ehrlich used fluorescin to observe the aqueous humour in the eye. The first immuno-staining was performed in 1950 by Melvin Kaplan (2). Green fluorescent protein (GFP) was the first fluorescent protein used in biology. It was isolated from jellyfish in 1961 by Shimomura and co-workers, and it was cloned by Prisher in 1992. The ability either to use antibody conjugated fluorophores or to clone GFP into chimaeric proteins led to the implementation of the fluorescence microscope in modern biology. High-content imaging (HCI) is the automation of fluorescence microscopy whereby the manual interpretation of images is replaced by computer algorithms.

Type
Chapter
Information
Materiomics
High-Throughput Screening of Biomaterial Properties
 , pp. 85 - 100
Publisher: Cambridge University Press
Print publication year: 2013

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References

Bickle, M. The beautiful cell: high-content screening in drug discovery. Analyt Bioanal Chem. 2010;398(1):219–26.CrossRefGoogle Scholar
Treiser, MD, Liu, E, Dubin, RA et al. Profiling cell–biomaterial interactions via cell-based fluororeporter imaging. Biotechniques. 2007;43(3):361–6, 8.Google Scholar
Kriston-Vizi, J, Lim, CA, Condron, P et al. An automated high-content screening image analysis pipeline for the identification of selective autophagic inducers in human cancer cell lines. J Biomol Screen. 2010;15(7):869–81.CrossRefGoogle Scholar
Carpenter, AE, Jones, TR, Lamprecht, MR et al. CellProfiler: image analysis software for identifying and quantifying cell phenotypes. Genome Biol. 2006;7(10):R100.Google Scholar
Pernagallo, S, Unciti-Broceta, A, Diaz-Mochon, JJ, Bradley, M.Deciphering cellular morphology and biocompatibility using polymer microarrays. Biomed Mater. 2008;3(3):034112.CrossRefGoogle Scholar
Gobaa, S, Hoehnel, S, Roccio, M et al. Artificial niche microarrays for probing single stem cell fate in high-throughput. Nat Methods. 2011;8(11):949–55.CrossRefGoogle Scholar
Mei, Y, Saha, K, Bogatyrev, SR et al. Combinatorial development of biomaterials for clonal growth of human pluripotent stem cells. Nat Mater. 2010;9(9):768–78.CrossRefGoogle Scholar
Inglese, J, Johnson, RL, Simeonov, A et al. High-throughput screening assays for the identification of chemical probes. Nat Chem Biol. 2007;3(8):466–79.CrossRefGoogle Scholar
Pal, NR, Pal, SK. A review on image segmentation techniques. Pattern Recogn. 1993;26(9):1277–94.CrossRefGoogle Scholar
Kobel, S, Lutolf, M.High-throughput methods to define complex stem cell niches. Biotechniques. 2010;48(4):ix–xxii.Google Scholar
Masters, BR. History of the optical microscope in cell biology and medicine. Encyclopedia of Life Sciences. Wiley; 2008.
Masters, BR. The development of fluorescence microscopy. Encyclopedia of Life Sciences. Wiley; 2010.
Kobel, S, Lutolf, M. High-throughput methods to define complex stem cell niches. Biotechniques. 2010;48(4):ix–xxii. Epub 2010/06/24.Google Scholar
Bickle, M. The beautiful cell: high-content screening in drug discovery. Analyt Bioanalyt Chem. 2010;398(1):219–26. Epub 2010/06/26.Google Scholar
Conrad, C, Erfle, H, Warnat, P et al. Automatic identification of subcellular phenotypes on human cell arrays. Genome Res. 2004;14(6):1130–6. Epub 2004/06/03.Google Scholar
Bhadriraju, K, Elliott, JT, Nguyen, M, Plant, AL. Quantifying myosin light chain phosphorylation in single adherent cells with automated fluorescence microscopy. BMC Cell Biol. 2007; 8:43. Epub 2007/10/19.Google Scholar
Pal, NR, Pal, SK. A review on image segmentation techniques. Pattern Recogn. 1993; 26(9):1277–94.CrossRefGoogle Scholar
Treiser, MD, Liu, E, Dubin, RA et al. Profiling cell–biomaterial interactions via cell-based fluororeporter imaging. Biotechniques. 2007;43(3):361–6, 8. Epub 2007/10/03.Google Scholar
Yang, J, Mei, Y, Hook, AL, Taylor, M et al. Polymer surface functionalities that control human embryoid body cell adhesion revealed by high-throughput surface characterization of combinatorial material microarrays. Biomaterials. 2010;31(34):8827–38. Epub 2010/09/14.Google Scholar
Mei, Y, Hollister-Lock, J, Bogatyrev, SR et al. A high-throughput micro-array system of polymer surfaces for the manipulation of primary pancreatic islet cells. Biomaterials. 2010;31(34):8989–95. Epub 2010/09/11.Google Scholar
Pernagallo, S, Diaz-Mochon, JJ, Bradley, M. Acooperative polymer-DNA microarray approach to biomaterial investigation. Lab Chip. 2009;9(3):397–403. Epub 2009/01/22.Google Scholar
Fuchs, F, Pau, G, Kranz, D et al. Clustering phenotype populations by genome-wide RNAi and multiparametric imaging. Mol Syst Biol. 2010;6:370. Epub 2010/06/10.Google Scholar
Bakal, C, Aach, J, Church, G, Perrimon, N. Quantitative morphological signatures define local signaling networks regulating cell morphology. Science. 2007;316(5832):1753–6. Epub 2007/06/26.Google Scholar
Treiser, MD, Yang, EH, Gordonov, S et al. Cytoskeleton-based forecasting of stem cell lineage fates. Proc Natl Acad Sci USA. 2010;107(2):610–5. Epub 2010/01/19.Google Scholar
Kriston-Vizi, J, Lim, CA, Condron, P et al. An automated high-content screening image analysis pipeline for the identification of selective autophagic inducers in human cancer cell lines. J Biomol Screen. 2010;15(7):869–81. Epub 2010/06/16.Google Scholar
Inglese, J, Johnson, RL, Simeonov, A et al. High-throughput screening assays for the identification of chemical probes. Nat Chem Biol. 2007;3(8):466–79. Epub 2007/07/20.Google Scholar
Kozak, K, Bakos, G, Hoff, A et al. Workflow-based software environment for large-scale biological experiments. J Biomol Screen. 2010;15(7):892–9. Epub 2010/07/14.Google Scholar
Conrad, C, Wunsche, A, Tan, TH et al. Micropilot: automation of fluorescence microscopy-based imaging for systems biology. Nature Methods. 2011;8(3):246-U89.Google Scholar
Pau, G, Fuchs, F, Sklyar, O, Boutros, M, Huber, W. EBImage – an R package for image processing with applications to cellular phenotypes. Bioinformatics. 2010;26(7):979–81. Epub 2010/03/27.Google Scholar
Abramoff, MD, Magelhaes, PJ, Ram, SJ. Image processing with ImageJ. Biophotonics International. 2004;11(7):36–42.Google Scholar
Carpenter, AE, Jones, TR, Lamprecht, MR et al. CellProfiler: image analysis software for identifying and quantifying cell phenotypes. Genome Biol. 2006;7(10):R100. Epub 2006/11/02.Google Scholar
Mayr, LM, Bojanic, D. Novel trends in high-throughput screening. Curr Opin Pharmacol. 2009;9(5):580–8. Epub 2009/09/25.Google Scholar
Joseph, J, Seervi, M, Sobhan, PK, Retnabai, ST. High-throughput ratio imaging to profile caspase activity: potential application in multiparameter high content apoptosis analysis and drug screening. PLoS One. 2011;6(5):e20114. Epub 2011/06/04.Google Scholar
Mei, Y, Saha, K, Bogatyrev, SR et al. Combinatorial development of biomaterials for clonal growth of human pluripotent stem cells. Nat Mater. 2010;9(9):768–78.CrossRefGoogle Scholar
Pozarowski, P, Holden, E, Darzynkiewicz, Z. Laser scanning cytometry: principles and applications. Methods Mol Biol. 2006;319:165–92. Epub 2006/05/25.Google Scholar
Pernagallo, S, Unciti-Broceta, A, Diaz-Mochon, JJ, Bradley, M. Deciphering cellular morphology and biocompatibility using polymer microarrays. Biomed Mater. 2008;3(3):034112. Epub 2008/08/19.Google Scholar
Khan, F, Tare, RS, Kanczler, JM, Oreffo, RO, Bradley, M. Strategies for cell manipulation and skeletal tissue engineering using high-throughput polymer blend formulation and microarray techniques. Biomaterials. 2010;31(8):2216–28. Epub 2010/01/09.Google Scholar
Unadkat, HV, Hulsman, M, Cornelissen, K et al. An algorithm-based topographical biomaterials library to instruct cell fate. Proc Natl Acad Sci USA. 2011;108(40):16565–70. Epub 2011/09/29.Google Scholar
Dalby, MJ, Gadegaard, N, Tare, R et al. The control of human mesenchymal cell differentiation using nanoscale symmetry and disorder. Nat Mater. 2007;6(12):997–1003. Epub 2007/09/25.Google Scholar
Lovmand, J, Justesen, J, Foss, M et al. The use of combinatorial topographical libraries for the screening of enhanced osteogenic expression and mineralization. Biomaterials. 2009;30(11):2015–22. Epub 2009/01/31.Google Scholar
Kumar, S, Alibhai, D, Margineanu, A et al. FLIM FRET technology for drug discovery: automated multiwell-plate high-content analysis, multiplexed readouts and application in situ. Chemphyschem. 2011;12(3):609–26. Epub 2011/02/22.Google Scholar
Mank, M, Reiff, DF, Heim, N et al. FRET-based calcium biosensor with fast signal kinetics and high fluorescence change. Biophys J. 2006;90(5):1790–6.CrossRefGoogle Scholar
Zhang, Y, Hong, H, Cai, W. Imaging with Raman spectroscopy. Curr Pharm Biotechnol. 2010;11(6):654–61. Epub 2010/05/26.Google Scholar
Schulze, HG, Konorov, SO, Caron, NJ et al. Assessing differentiation status of human embryonic stem cells noninvasively using Raman microspectroscopy. Analyt Chem. 2010;82(12):5020–7. Epub 2010/05/21.Google Scholar
Evans, CL, Xie, XS. Coherent anti-Stokes Raman scattering microscopy: chemical imaging for biology and medicine. Annu Rev Analyt Chem (Palo Alto Calif). 2008;1:883–909. Epub 2008/07/19.Google Scholar
Schlucker, S. SERS microscopy: nanoparticle probes and biomedical applications. ChemPhysChem. 2009;10(9–10):1344–54. Epub 2009/07/01.Google Scholar
Hong, H, Gao, T, Cai, W. Molecular imaging with single-walled carbon nanotubes. Nano Today. 2009;4(3):252–61. Epub 2009/06/01.Google Scholar
Nolan, JP, Sebba, DS. Surface-enhanced Raman scattering (SERS) cytometry. Methods Cell Biol. 2011;102:515–32. Epub 2011/06/28.Google Scholar
Liu, E, Treiser, MD, Patel, H et al. High-content profiling of cell responsiveness to graded substrates based on combinatorially variant polymers. Comb Chem High Throughput Screen. 2009;12(7):646–55. Epub 2009/06/18.Google Scholar
Kiel, MJ, Morrison, SJ. Uncertainty in the niches that maintain haematopoietic stem cells. Nat Rev Immunol. 2008;8(4):290–301.CrossRefGoogle Scholar
Gobaa, S, Hoehnel, S, Roccio, M et al. Artificial niche microarrays for probing single stem cell fate in high throughput. Nat Methods. 2011;8(11):949–55. Epub 2011/10/11.Google Scholar

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