Published in:
Open Access
01-06-2019 | Original Article
Estimation of tissue oxygen saturation from RGB images and sparse hyperspectral signals based on conditional generative adversarial network
Authors:
Qingbiao Li, Jianyu Lin, Neil T. Clancy, Daniel S. Elson
Published in:
International Journal of Computer Assisted Radiology and Surgery
|
Issue 6/2019
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Abstract
Purpose
Intra-operative measurement of tissue oxygen saturation (\({\hbox {StO}}_2\)) is important in detection of ischaemia, monitoring perfusion and identifying disease. Hyperspectral imaging (HSI) measures the optical reflectance spectrum of the tissue and uses this information to quantify its composition, including \({\hbox {StO}}_2\). However, real-time monitoring is difficult due to capture rate and data processing time.
Methods
An endoscopic system based on a multi-fibre probe was previously developed to sparsely capture HSI data (sHSI). These were combined with RGB images, via a deep neural network, to generate high-resolution hypercubes and calculate \({\hbox {StO}}_2\). To improve accuracy and processing speed, we propose a dual-input conditional generative adversarial network, Dual2StO2, to directly estimate \({\hbox {StO}}_2\) by fusing features from both RGB and sHSI.
Results
Validation experiments were carried out on in vivo porcine bowel data, where the ground truth \({\hbox {StO}}_2\) was generated from the HSI camera. Performance was also compared to our previous super-spectral-resolution network, SSRNet in terms of mean \({\hbox {StO}}_2\) prediction accuracy and structural similarity metrics. Dual2StO2 was also tested using simulated probe data with varying fibre number.
Conclusions
\({\hbox {StO}}_2\) estimation by Dual2StO2 is visually closer to ground truth in general structure and achieves higher prediction accuracy and faster processing speed than SSRNet. Simulations showed that results improved when a greater number of fibres are used in the probe. Future work will include refinement of the network architecture, hardware optimization based on simulation results, and evaluation of the technique in clinical applications beyond \({\hbox {StO}}_2\) estimation.