|
|||||
|
|
Simultaneously Capturing Real-time Images in Two Emission Channels Using a Dual Camera Emission Splitting System: Applications to Cell Adhesion |
|
| Authors: | Grady E. Carlson Eric W. Martin Monica M. Burdick |
| Affiliation: | 1.Department of Chemical and Biomolecular Engineering, Russ College of Engineering and Technology, Ohio University;2.Biomedical Engineering Program, Ohio University |
| Abstract: | Multi-color immunofluorescence microscopy to detect specific molecules in the cell membrane can be coupled with parallel plate flow chamber assays to investigate mechanisms governing cell adhesion under dynamic flow conditions. For instance, cancer cells labeled with multiple fluorophores can be perfused over a potentially reactive substrate to model mechanisms of cancer metastasis. However, multi-channel single camera systems and color cameras exhibit shortcomings in image acquisition for real-time live cell analysis. To overcome these limitations, we used a dual camera emission splitting system to simultaneously capture real-time image sequences of fluorescently labeled cells in the flow chamber. Dual camera emission splitting systems filter defined wavelength ranges into two monochrome CCD cameras, thereby simultaneously capturing two spatially identical but fluorophore-specific images. Subsequently, psuedocolored one-channel images are combined into a single real-time merged sequence that can reveal multiple target molecules on cells moving rapidly across a region of interest. |
| Keywords: | Bioengineering Issue 79 Cellular Biology Biomedical Engineering Molecular Biology Biophysics Biochemistry Chemical Engineering Chemistry Cell Adhesion Molecules Biological Markers Antigens Cell Adhesion Molecules Microscopy Fluorescence Cell Physiological Processes Cell Adhesion Cell Physiological Phenomena Colocalization cell rolling two-color fluorescence cell imaging |