Abstract
Optical spectral images can be used to estimate the amount of bulk absorbers in tissues, specifically oxy- and deoxyhemoglobin, as well as scattering parameters. Most systems that capture spectral image data are large, heavy, and expensive. This paper presents a full end-to-end analysis of a low-cost reflectance-mode multispectral imaging system operating in the visible and near-infrared spectra. The system consists of 13 LEDs mounted on a printed circuit board, a monochrome machine vision camera, and a tablet computer to control the hardware. The bill of materials for the system is less than $1000. Hardware design and implementation are detailed. Calibration, image capture, and preprocessing are also discussed. In validation experiments, excellent agreement is observed in diffuse reflectance measurements between the spectral camera setup and a spectrometer. To demonstrate that such spectral image data can yield meaningful optical measurements in vivo, the forearms of eight volunteers are imaged in the system. Their data are then analyzed to estimate the tissue optical properties of different skin layers using a Monte Carlo lookup table. In three volunteers, spectral images are captured before and after inducing erythema using a warm wet towel. Across the three subjects, a clear increase in the blood content of the superficial plexus layer was observed as a result of the erythema. Collectively, these findings suggest that a low-cost system can capture accurate spectral data and that clinically meaningful information can be derived from it.
Highlights
Diffuse reflectance spectroscopy, where a broadband source illuminates a sample and the reflected spectrum is measured, is a well-trusted method for noninvasively characterizing biological tissues.[1,2] The diffuse reflectance signal is a function of the wavelength-dependent bulk optical properties of the tissue
The main disadvantage of spectroscopy is that it is based on point measurements that average over a large area
To validate the spectral camera system, spectral data were collected from the color calibration card using both the multispectral imaging system and the white-light spectrometer
Summary
Diffuse reflectance spectroscopy, where a broadband source illuminates a sample and the reflected spectrum is measured, is a well-trusted method for noninvasively characterizing biological tissues.[1,2] The diffuse reflectance signal is a function of the wavelength-dependent bulk optical properties of the tissue. The scattering properties, which affect the diffuse reflectance signal, can be estimated. Assessing the concentrations of these chromophores can be used to identify pathological changes in tissues. Such measurements have been shown to identify lesions in several tissues, including breast,[3,4] skin,[5] oral cavity,[6] bladder,[7] esophagus,[8] and the uterine cervix.[9,10] Reflectance mode spectroscopy has be used to characterize other chromophores in tissue, such as bilirubin when trying to assess jaundice in neonates.[11] The main disadvantage of spectroscopy is that it is based on point measurements that average over a large area. A visual follow-up is often needed, when clinical workflow requires selecting sites to biopsy
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