Broadband Fourier-Transform Optical Photothermal Infrared Spectroscopy and Imaging

TL;DR

This paper introduces an ultra-broadband synchrotron infrared-based optical photothermal imaging and spectroscopy method that significantly extends spectral range and improves spatial resolution for biological tissue analysis.

Contribution

It presents the first use of synchrotron FT-OPTIR combining broadband infrared radiation with photothermal imaging, surpassing limitations of previous sources and enabling detailed tissue differentiation.

Findings

Extended spectral range covering entire mid-infrared spectrum.

Enhanced spatial resolution compared to synchrotron micro-spectroscopy.

Successful differentiation of cells in mouse brain tissue.

Abstract

Optical photothermal microscopy is a powerful, emerging method that overcomes the diffraction limit in infrared hyperspectral imaging by utilizing a visible probe laser beam to detect local temperature-induced modulation at the visible diffraction limit. However, the spectral range of this technique has been limited by the tuning range of infrared sources, which is generally restricted to the fingerprint window with commercially available quantum cascade lasers. In this work, ultra-broadband synchrotron infrared radiation was used for infrared photothermal imaging and spectroscopy, spanning the entire mid-infrared range. Both optical- and fluorescence-detected photothermal modalities were performed, demonstrating improved spectral range when compared to optical photothermal microscopy using commercial sources and improved spatial resolution when compared to synchrotron micro-spectroscopy measurements. Following these initial validation studies, synchrotron Fourier-transform optical photothermal infrared spectroscopy (FT-OPTIR) in combination with synchrotron micro-spectroscopy measurements were used to differentiate cells in mouse brain tissue sections.