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Deep tissue multiphoton microscopy using longer wavelength excitation.

Demirhan Kobat1, Michael E Durst, Nozomi Nishimura

  • 1School of Applied and Engineering Physics, Cornell University, Ithaca, NY 14853, USA. dk287@cornell.edu

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Two-photon fluorescence microscopy (TPM) using 1280-nm excitation achieves twice the imaging depth of 775-nm excitation in mouse brains. This enables high-contrast visualization of blood vessels up to 1 mm deep, facilitating blood flow studies.

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Area of Science:

  • Neuroscience
  • Biomedical Optics
  • Microscopy

Background:

  • Two-photon microscopy (TPM) is crucial for deep tissue imaging in neuroscience.
  • Wavelength selection significantly impacts imaging depth due to light scattering and absorption.
  • Optimizing excitation wavelength is key to enhancing TPM's penetration in biological tissues.

Purpose of the Study:

  • To compare the maximal imaging depth of 775-nm and 1280-nm excitation in two-photon fluorescence microscopy.
  • To evaluate the efficacy of longer wavelengths for in vivo and ex vivo imaging of mouse brain vasculature.
  • To assess the feasibility of deep-brain blood flow measurements using optimized TPM.

Main Methods:

  • In vivo and ex vivo two-photon fluorescence microscopy (TPM) of fluorescently-labeled mouse brain vasculature.
  • Comparative analysis of imaging depth achieved with 775-nm and 1280-nm excitation wavelengths.
  • Measurement of blood flow speed at depths up to 900 micrometers.

Main Results:

  • 1280-nm excitation achieved approximately twice the imaging depth compared to 775-nm excitation.
  • High-contrast imaging of blood vessels was obtained at depths up to 1 mm in adult mouse brains.
  • Achieved 1 mm imaging depth with approximately 1-nJ pulse energy at the sample surface using 1280-nm excitation.
  • Successful blood flow speed measurements were performed at a depth of 900 micrometers.

Conclusions:

  • Longer excitation wavelengths, such as 1280 nm, significantly enhance maximal imaging depth in two-photon microscopy.
  • 1280-nm TPM offers a viable method for deep-brain in vivo imaging and functional studies, including blood flow.
  • This advancement extends the capabilities of TPM for investigating neural circuits and vascular dynamics in intact brains.