Abstract
.Significance: Spatial frequency-domain imaging (SFDI) is a powerful technique for mapping tissue oxygen saturation over a wide field of view. However, current SFDI methods either require a sequence of several images with different illumination patterns or, in the case of single-snapshot optical properties (SSOP), introduce artifacts and sacrifice accuracy.Aim: We introduce OxyGAN, a data-driven, content-aware method to estimate tissue oxygenation directly from single structured-light images.Approach: OxyGAN is an end-to-end approach that uses supervised generative adversarial networks. Conventional SFDI is used to obtain ground truth tissue oxygenation maps for ex vivo human esophagi, in vivo hands and feet, and an in vivo pig colon sample under 659- and 851-nm sinusoidal illumination. We benchmark OxyGAN by comparing it with SSOP and a two-step hybrid technique that uses a previously developed deep learning model to predict optical properties followed by a physical model to calculate tissue oxygenation.Results: When tested on human feet, cross-validated OxyGAN maps tissue oxygenation with an accuracy of 96.5%. When applied to sample types not included in the training set, such as human hands and pig colon, OxyGAN achieves a 93% accuracy, demonstrating robustness to various tissue types. On average, OxyGAN outperforms SSOP and a hybrid model in estimating tissue oxygenation by 24.9% and 24.7%, respectively. Finally, we optimize OxyGAN inference so that oxygenation maps are computed times faster than previous work, enabling video-rate, 25-Hz imaging.Conclusions: Due to its rapid acquisition and processing speed, OxyGAN has the potential to enable real-time, high-fidelity tissue oxygenation mapping that may be useful for many clinical applications.
Highlights
Tissue oxygenation (StO2) is a measure of the amount of oxygen in biological tissue and is often estimated by computing the fraction of oxygenated hemoglobin over total hemoglobin
When applied to sample types not included in the training set, such as human hands and pig colon, OxyGAN achieves a 93% accuracy, demonstrating robustness to various tissue types
Due to its rapid acquisition and processing speed, OxyGAN has the potential to enable real-time, high-fidelity tissue oxygenation mapping that may be useful for many clinical applications
Summary
Tissue oxygenation (StO2) is a measure of the amount of oxygen in biological tissue and is often estimated by computing the fraction of oxygenated hemoglobin over total hemoglobin. StO2 is a useful clinical biomarker for tissue viability, the continuous monitoring of which is valuable for surgical guidance and patient management.[1,2] Abnormal levels of StO2 are indicative of many pathological conditions, such as sepsis, diabetes, and chronic obstructive pulmonary disease.[3,4,5]. One of the most widely used techniques for measuring physiological oxygen levels is pulse oximetry. Robustness, and low cost, pulse oximetry requires a pulsatile arterial signal and only provides a systemic measure of oxygenation.[6,7] The majority of existing devices for local assessment of StO2 are based on near-infrared (NIR) spectroscopy.
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