High-aspect-ratio gold nanorods: their synthesis and application to image cell-induced strain fields in collagen films

Gold nanoparticles are receiving considerable attention due to their novel properties and the potential variety of their uses. Long gold nanorods with dimensions of approximately 20 × 400 nm exhibit strong light scattering and can be easily observed under dark-field microscopy. Here we describe the...

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Published inMethods in molecular biology (Clifton, N.J.) Vol. 1026; p. 1
Main Authors Chernak, Davin J, Sisco, Patrick N, Goldsmith, Edie C, Baxter, Sarah C, Murphy, Catherine J
Format Journal Article
LanguageEnglish
Published United States 2013
Subjects
Animals
Biomechanical Phenomena
Cell Culture Techniques
Cell Proliferation
Cetrimonium Compounds - chemistry
Collagen - metabolism
Cryopreservation
Fibroblasts - cytology
Fibroblasts - metabolism
Gold - chemistry
Image Processing, Computer-Assisted
Light
Molecular Imaging - methods
Nanotechnology - methods
Nanotubes - chemistry
Nitrogen - chemistry
Rats
Scattering, Radiation
Software
Stress, Mechanical
Time Factors
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Summary:Gold nanoparticles are receiving considerable attention due to their novel properties and the potential variety of their uses. Long gold nanorods with dimensions of approximately 20 × 400 nm exhibit strong light scattering and can be easily observed under dark-field microscopy. Here we describe the use of this light-scattering property to track micrometer scale strains in collagen gels and thick films, which result from cell traction forces applied by neonatal heart fibroblasts. The use of such collagen constructs to model cell behavior in the extracellular matrix is common, and describing local mechanical environments on such a small scale is necessary to understand the complex factors associated with the remodeling of the collagen network. Unlike other particles used for tracking purposes, gold nanorods do not photobleach, allowing their optical signal to be tracked for longer periods of time, and they can be easily synthesized and coated with various charged or neutral shells, potentially reducing the effect of their presence on the cell system or allowing selective placement. Techniques described here are ultimately applicable for investigations with a wide variety of cells and cell environments.
ISSN:1940-6029
DOI:10.1007/978-1-62703-468-5_1