Michael G. Nichols, Creighton University, Department of Biomedical and Biomedical Sciences, Omaha, NE 68178, USA. Tel: +1 402.280.2159; fax: +1 402.280.2140; e-mail: [email protected]

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Summary

Lipophilic fluorescent dyes have been used to trace neuronal connections because of their ability to diffuse laterally within nerve cell membranes. Given the hundreds to thousands of connections that a typical neuron makes with its neighbours, a diffusion-matched set of spectrally distinct dyes is desirable. To extend a set of these dyes to obtain six independent labels, we have characterized the properties of novel violet and near-infrared candidates. By combining two-photon and confocal microscopy all of these candidates can be imaged using a single Titanium Sapphire laser. Here we present measurements of the two-photon action cross-sections and diffusion properties of the dyes, using either the relative diffusion distance or fluorescence recovery after photobleaching techniques, and demonstrate six-colour neuronal tracing within the spinal cord and brain tissue.

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Volume239, Issue2

August 2010

Pages 117-134

Photo- and bio-physical characterization of novel violet and near-infrared lipophilic fluorophores for neuronal tracing

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Photo- and bio-physical characterization of novel violet and near-infrared lipophilic fluorophores for neuronal tracing

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