Hyperspectral absorption microscopy using photoacoustic remote sensing

An improved method of remote optical absorption spectroscopy and hyperspectral optical absorption imaging is described which takes advantage of the photoacoustic remote sensing detection architecture. A wide collection of photoacoustic excitation wavelengths ranging from 210 nm to 1550 nm was provided by a nanosecond tunable source allowing access to various salient endogenous chromophores such as DNA, hemeproteins, and lipids. Sensitivity of the device was demonstrated by characterizing the infrared absorption spectrum of water. Meanwhile, the efficacy of the technique was explored by recovering cell nuclei and oxygen saturation from a live chicken embryo model and by recovering adipocytes from freshly resected murine adipose tissue. This represents a continued investigation into the characteristics of the hyperspectral photoacoustic remote sensing technique which may represent an effective means of non-destructive endogenous contrast characterization and visualization. (C) 2021 Optical Society of America under the terms of the OSA Open Access Publishing Agreement

Automated summary

The improved method utilizes photoacoustic remote sensing architecture to provide a wide range of photoacoustic excitation wavelengths, enabling effective access to endogenous chromophores. Experimental data demonstrated the device's sensitivity and efficacy in recovering cellular components in animal models.