Quantification of blood flow index in diffuse correlation spectroscopy using a robust deep learning method
Wang, Quan and Pan, Mingliang and Zang, Zhenya and Li, David Day-Uei (2024) Quantification of blood flow index in diffuse correlation spectroscopy using a robust deep learning method. Journal of Biomedical Optics, 29 (1). 015004. ISSN 1083-3668 (https://doi.org/10.1117/1.JBO.29.1.015004)
Preview |
Text.
Filename: Wang-etal-JBO-2024-Quantification-of-blood-flow-index-in-diffuse-correlation-spectroscopy.pdf
Final Published Version License: Download (9MB)| Preview |
Abstract
Significance: Diffuse correlation spectroscopy (DCS) is a powerful, noninvasive optical technique for measuring blood flow. Traditionally the blood flow index (BFi) is derived through nonlinear least-square fitting the measured intensity autocorrelation function (ACF). However, the fitting process is computationally intensive, susceptible to measurement noise, and easily influenced by optical properties (absorption coefficient μ a and reduced scattering coefficient μ' s) and scalp and skull thicknesses. Aim: We aim to develop a data-driven method that enables rapid and robust analysis of multiple-scattered light's temporal ACFs. Moreover, the proposed method can be applied to a range of source-detector distances instead of being limited to a specific source-detector distance. Approach: We present a deep learning architecture with one-dimensional convolution neural networks, called DCS neural network (DCS-NET), for BFi and coherent factor (β) estimation. This DCS-NET was performed using simulated DCS data based on a three-layer brain model. We quantified the impact from physiologically relevant optical property variations, layer thicknesses, realistic noise levels, and multiple source-detector distances (5, 10, 15, 20, 25, and 30 mm) on BFi and β estimations among DCS-NET, semi-infinite, and three-layer fitting models. Results: DCS-NET shows a much faster analysis speed, around 17,000-fold and 32-fold faster than the traditional three-layer and semi-infinite models, respectively. It offers higher intrinsic sensitivity to deep tissues compared with fitting methods. DCS-NET shows excellent anti-noise features and is less sensitive to variations of μ a and μ' s at a source-detector separation of 30 mm. Also, we have demonstrated that relative BFi (rBFi) can be extracted by DCS-NET with a much lower error of 8.35%. By contrast, the semi-infinite and three-layer fitting models result in significant errors in rBFi of 43.76% and 19.66%, respectively. Conclusions: DCS-NET can robustly quantify blood flow measurements at considerable source-detector distances, corresponding to much deeper biological tissues. It has excellent potential for hardware implementation, promising continuous real-time blood flow measurements.
ORCID iDs
Wang, Quan, Pan, Mingliang, Zang, Zhenya and Li, David Day-Uei ORCID: https://orcid.org/0000-0002-6401-4263;-
-
Item type: Article ID code: 87850 Dates: DateEvent27 January 2024Published3 January 2024AcceptedSubjects: Science > Physics > Optics. Light
Medicine > Biomedical engineering. Electronics. InstrumentationDepartment: Faculty of Engineering > Biomedical Engineering
Faculty of Science > Strathclyde Institute of Pharmacy and Biomedical Sciences
Strategic Research Themes > Health and WellbeingDepositing user: Pure Administrator Date deposited: 22 Jan 2024 12:10 Last modified: 17 Dec 2024 01:30 URI: https://strathprints.strath.ac.uk/id/eprint/87850