Title :
Multilayer modeling of reflectance pulse oximetry
Author_Institution :
OB Sci. Inc., Germantown, WI, USA
Abstract :
A multilayer tissue description was employed in Monte Carlo simulations of reflectance pulse oximetry to study the impact of assumptions made in previous studies employing homogeneous tissue models. Simulation results with a discrete layer of arterial pulsatility were similar to previous studies employing homogenous tissue models. However, the relationship of normalized pulse amplitude to emitter-detector spacing reiterates that spacing has a significant impact on pulse oximetry function. The effect of melanin content as a thin, superficial absorber was also simulated, with results supporting the general clinical observation that skin shade need not substantially compromise pulse oximeter accuracy.
Keywords :
Monte Carlo methods; blood vessels; oximetry; physiological models; skin; Monte Carlo simulation; arterial pulsatility; emitter-detector spacing; homogeneous tissue models; melanin content; multilayer modeling; multilayer tissue description; normalized pulse amplitude; reflectance pulse oximetry; skin shade; Biomedical optical imaging; Blood; Light scattering; Nonhomogeneous media; Optical pulses; Optical scattering; Optical sensors; Particle scattering; Reflectivity; Skin; Fetal surveillance; Monte Carlo simulation; reflectance pulse oximetry; tissue optics; Algorithms; Computer Simulation; Fetal Monitoring; Humans; Melanins; Models, Cardiovascular; Models, Statistical; Oximetry; Oxygen; Reproducibility of Results; Sensitivity and Specificity; Skin Physiology; Tomography, Optical;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
DOI :
10.1109/TBME.2004.840188
