OBJECTIVES: High-throughput chemical and biochemical technologies are now exploited by modern pharmacology and toxicology to synthesize a multitude of new molecules with bioactive potential, or to isolate them from living matter. Testing molecules in cell systems on a large scale, however, is a rate-limiting step in drug discovery or in toxicity assessment. In this study, we developed a low-cost high-throughput method for first-level screening of cytotoxic molecules. MATERIALS AND METHODS: We used microplate spectrophotometry to measure growth kinetics of human tumour cells that grow in suspension (Molt3) or adherent to the plastic surface of culture wells (HeLa) in standard RPMI medium. Cells were treated with colchicin, idarubicin or paclitaxel under various treatment schedules. The effects were quantified and compared with those measured by optical microscopy using the trypan blue dye exclusion method to reveal dead cells. RESULTS: Proliferation kinetics of tumour cells can be quantified by measuring variations in optical densities of cell samples at 410 and 560 nm wavelengths. For cells that grow in suspension, one single reading at 730 nm may be sufficient to reconstruct growth curves that parallel those obtained by direct cell counting. Effects of the cytotoxic treatments could also be quantified and results compared very favourably with those obtained using standard techniques. CONCLUSIONS: Microplate spectrophotometry is a robust and sensitive method to monitor growth of animal cell populations both in the absence and in the presence of cytotoxic drugs. This method implements existing technologies and can be fully automated.
OBJECTIVES: High-throughput chemical and biochemical technologies are now exploited by modern pharmacology and toxicology to synthesize a multitude of new molecules with bioactive potential, or to isolate them from living matter. Testing molecules in cell systems on a large scale, however, is a rate-limiting step in drug discovery or in toxicity assessment. In this study, we developed a low-cost high-throughput method for first-level screening of cytotoxic molecules. MATERIALS AND METHODS: We used microplate spectrophotometry to measure growth kinetics of humantumour cells that grow in suspension (Molt3) or adherent to the plastic surface of culture wells (HeLa) in standard RPMI medium. Cells were treated with colchicin, idarubicin or paclitaxel under various treatment schedules. The effects were quantified and compared with those measured by optical microscopy using the trypan blue dye exclusion method to reveal dead cells. RESULTS: Proliferation kinetics of tumour cells can be quantified by measuring variations in optical densities of cell samples at 410 and 560 nm wavelengths. For cells that grow in suspension, one single reading at 730 nm may be sufficient to reconstruct growth curves that parallel those obtained by direct cell counting. Effects of the cytotoxic treatments could also be quantified and results compared very favourably with those obtained using standard techniques. CONCLUSIONS: Microplate spectrophotometry is a robust and sensitive method to monitor growth of animal cell populations both in the absence and in the presence of cytotoxic drugs. This method implements existing technologies and can be fully automated.
Authors: James Inglese; Douglas S Auld; Ajit Jadhav; Ronald L Johnson; Anton Simeonov; Adam Yasgar; Wei Zheng; Christopher P Austin Journal: Proc Natl Acad Sci U S A Date: 2006-07-24 Impact factor: 11.205
Authors: C Tomelleri; E Milotti; C Dalla Pellegrina; O Perbellini; A Del Fabbro; M T Scupoli; R Chignola Journal: Cell Prolif Date: 2008-02 Impact factor: 6.831
Authors: R Chignola; M Pasti; C Candiani; A Franceschi; C Anselmi; G Tridente; M Colombatti Journal: Int J Cancer Date: 1995-05-16 Impact factor: 7.396
Authors: Menghang Xia; Ruili Huang; Kristine L Witt; Noel Southall; Jennifer Fostel; Ming-Hsuang Cho; Ajit Jadhav; Cynthia S Smith; James Inglese; Christopher J Portier; Raymond R Tice; Christopher P Austin Journal: Environ Health Perspect Date: 2008-03 Impact factor: 9.031