Development and characterization of enhanced green fluorescent protein and luciferase expressing cell line for non-destructive evaluation of tissue engineering constructs

This study investigates the utility of genetically modified cells developed for the qualitative and quantitative non-destructive evaluation of cells on biomaterials. The Fisher rat fibroblastic cell line has been genetically modified to stably express the reporter genes enhanced green fluorescence p...

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Bibliographic Details
Published in:Biomaterials 2004-12, Vol.25 (27), p.5809-5819
Main Authors: Blum, Jeremy S., Temenoff, Johnna S., Park, Hansoo, Jansen, John A., Mikos, Antonios G., Barry, Michael A.
Format: Article
Language:English
Subjects:
Animals
Biocompatible Materials - chemistry
Biotechnology - methods
Cell Line
Fibroblasts - metabolism
Genes, Reporter
Genetic Vectors
Genetically modified cells
Green Fluorescent Proteins - chemistry
Green Fluorescent Proteins - metabolism
Hydrogel, Polyethylene Glycol Dimethacrylate - chemistry
Imaging
Luciferases - metabolism
Luminescent Proteins - chemistry
Membrane Glycoproteins - metabolism
Mice
Microscopy, Fluorescence - methods
Models, Biological
Plasmids - metabolism
Rats
Rats, Inbred F344
Reporter genes
Retroviridae - genetics
Time Factors
Tissue engineering
Tissue Engineering - methods
Titanium - chemistry
Viral Envelope Proteins - metabolism
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Summary:This study investigates the utility of genetically modified cells developed for the qualitative and quantitative non-destructive evaluation of cells on biomaterials. The Fisher rat fibroblastic cell line has been genetically modified to stably express the reporter genes enhanced green fluorescence protein (EGFP) and luciferase. These reporter genes provide two unique opportunities to evaluate cell growth on materials without destruction of the sample. Utilizing the fluorescence of EGFP expressed in the cells, we were able to demonstrate distribution of cells in a oligo(poly(ethylene glycol) fumarate) hydrogel material and on a titanium fiber mesh scaffold using an inverted fluorescent light microscope. In addition, we were able to utilize a molecular light imaging system to macroscopically image the cells on these materials both with fluorescence and luminescence, as well as quantify the signal from the samples. Quantification of cell growth on the titanium mesh material for a period of 28 days was accomplished using the molecular light imaging system. Imaging was extended in vivo to cells on the titanium mesh scaffolds subcutaneously implanted in Fisher rats for a period of 28 days. This study outlines a non-destructive method to evaluate cells growing on biomaterials in vitro and in vivo.
ISSN:0142-9612
1878-5905
DOI:10.1016/j.biomaterials.2004.01.035