Your search keyword '"Sally Claire Chappell"' showing total 2 results

1. Time‐Lapse Microscopy Approaches to Track Cell Cycle and Lineage Progression at the Single‐Cell Level

Author

Marie Wiltshire, Rachel J. Errington, Paul J. Smith, Imtiaz A. Khan, Victoria D. Griesdoorn, Nuria Marquez, and Sally Claire Chappell

Subjects

Histology, Lineage (genetic), Population, Video microscopy, Biology, Bioinformatics, Time-Lapse Imaging, Biochemistry, Time-lapse microscopy, S Phase, Cell Adhesion, Animals, Data Mining, Humans, Cell Lineage, education, Mitosis, Event (probability theory), Microscopy, education.field_of_study, Cell Death, Cell Cycle, General Medicine, Cell cycle, G2 Phase Cell Cycle Checkpoints, Medical Laboratory Technology, Temporal resolution, Single-Cell Analysis, Biological system

Abstract

Time-lapse microscopy can be described as the repeated collection of an image (in n-dimensions; x, y, z, λ) or field of view from a microscope at discrete time intervals. The duration of the time interval defines the temporal resolution, which in turn characterizes the type of event detected. This unit describes the implementation of time-lapse microscopy to link initial cell cycle position during acute exposures to anti-cancer agents with anti-proliferative consequences for individual cells. The approach incorporates fundamental concepts arising from the ability to capture simple video sequences of cells from which it is possible to extract kinetic descriptors that reflect the interplay of mitosis and cell death in the growth of an unsynchronized tumor population. Utilizing a multi-well format enables the user to screen different drug derivatives, multiple dose ranges, or cell cultures with unique genetic backgrounds. The objective of this unit is to present the basic methodology for capturing time-lapse sequences and touch upon subsequent mining of the data for deriving event curves and possible cell lineage maps.

Published

2013

2. Time‐Lapse Microscopy Approaches to Track Cell Cycle Progression at the Single‐Cell Level

Author

Paul J. Smith, Marie Wiltshire, Sally Claire Chappell, Rachel J. Errington, and Nuria Marquez

Subjects

education.field_of_study, Microscopy, Video, Time Factors, Histology, Cell Death, Cell Cycle, Population, Video microscopy, Nanotechnology, General Medicine, Cell cycle, Biology, Biochemistry, Time-lapse microscopy, Medical Laboratory Technology, Discrete time and continuous time, Temporal resolution, Microscopy, Animals, Biological system, education, Mitosis, Cell Division

Abstract

Time-lapse microscopy can be described as the repeated collection of a field of view from a microscope at discrete time intervals. The duration of the time interval defines the temporal resolution, which in turn characterizes the type of event detected. This unit describes the implementation of time-lapse microscopy to link initial cell cycle position during acute exposures to anti-cancer agents with anti-proliferative consequences for individual cells. The approach incorporates fundamental concepts arising from the ability to capture simple video sequences of cells from which it is possible to extract kinetic descriptors that reflect the interplay of mitosis and cell death in the growth of an unsynchronized tumor population. Utilizing a multi-well format enables the user to test different drug derivatives, multiple dose ranges, or cell cultures with unique genetic backgrounds. The objective of this unit is to present a generic methodology for capturing time-lapse sequences and subsequently mining the data for comprehensive event analysis. Keywords: video microscopy; time-lapse; data mining; cell cycle dynamics

Published

2005