Minimizing near-infrared autofluorescence in preclinical imaging with diet and wavelength selection.

Abstract

Preclinical fluorescence imaging with NIR-I (700 to 900nm) illumination and short-wave infrared or NIR-II (1000 to 1700nm) emission increases tissue penetration depth and improves resolution through decreased scattering. Background autofluorescence decreases signal-to-background ratios (SBR) in fluorescence imaging; maximizing SBR will further improve the impact of deep tissue imaging. The impact of rodent diet, illumination wavelength, and emission range on the background fluorescence and contrast agent SBR were determined to assist with the experimental design of future imaging studies. Following illumination with 670, 760, or 808nm, autofluorescence in the NIR-I ( ), NIR-II ( ), and NIR-II LP ( ) regions was assessed in mice fed chow or a purified diet using an IR VIVO preclinical imager (Photon, Etc.). Comparison of the SBR of liver-localized indocyanine green in the various imaging conditions indicated when gut autofluorescence was a problematic confounder. Mice fed chow exhibit high levels of background autofluorescence in the gastrointestinal tract and, to a lesser extent, skin when illuminated with 670nm light for NIR-I imaging (700 to 975nm), interfering with the identification of fluorescently labeled tissue. Background autofluorescence was reduced by more than two orders of magnitude by any of the following changes: (1)purified diet; (2)excitation with 760 or 808nm illumination; or (3)emission in the NIR-II (1000 to 1600 or 1250 to 1600nm). Although the SBR was generally sufficient for feature identification except when imaging of chow-fed mice with 670nm excitation and NIR-I emission, switching to a purified diet, using longer excitation wavelengths, or using longer emission wavelengths improved SBR significantly. Systematic comparison of imaging conditions and diet highlights the reduction in autofluorescence and increase in SBR enabled by intentional choices in the experimental parameters including diet, excitation wavelength, and emission wavelength range.