Noninvasive method for measuring local hemoglobin oxygen saturation in tissue using wide gap second derivative near-infrared spectroscopy

Abstract

A simple continuous wave near-infrared algorithm for estimating local hemoglobin oxygen saturation in tissue $(%StO2)$ is described using single depth attenuation measurements at 680, 720, 760, and 800 nm. Second derivative spectroscopy was used to reduce light scattering effects, chromophores with constant absorption, baseline/instrumentation drift, and movement artifacts. Unlike previous second derivative methods which focused primarily on measuring deoxyhemoglobin concentration; a wide 40 nm wavelength gap used for calculating second derivative attenuation significantly improved sensitivity to oxyhemoglobin absorption. Scaled second derivative attenuation at 720 nm was correlated to in vitro hemoglobin oxygen saturation to generate a $%StO2$ calibration curve. The calibration curve was insensitive to total hemoglobin, optical path length, and optical scattering. Measurement error due to normal levels of carboxyhemoglobin, methemoglobin, and water absorption were less than 10 $%StO2$ units. Severe methemoglobinemia or edema combined with low blood volume could cause $StO2$ errors to exceed 10 $StO2$ units. Both a broadband and commercial four-wavelength spectrometer (InSpectra™) measured $%StO2.$ The InSpectra tissue spectrometer readily detected limb ischemia on 26 human volunteers for hand, forearm, and leg muscles. A strong linear correlation, $r2>0.93,$ between $StO2$ and microvascular $%SO2$ was observed for isolated animal hind limb, kidney, and heart. © 2005 Society of Photo-Optical Instrumentation Engineers.