Grüneisen Parameter-Based Photoacoustic System for Quantitative Blood Flow Velocity Measurement

Yuelin Han; Dongjian Wu; Gang Li; Yiming Ma; Mingjian Sun

doi:10.1117/12.3075255

Grüneisen Parameter-Based Photoacoustic System for Quantitative Blood Flow Velocity Measurement

Yuelin Han
, Dongjian Wu
, Gang Li
, Yiming Ma^*
, Mingjian Sun^*

^*Corresponding author for this work

School of Information Science and Engineering

Harbin Institute of Technology Weihai
Shandong Laboratory of Advanced Biomaterials and Medical Devices in Weihai

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Blood flow dynamics are a vital functional parameter within biological tissues. Accurate measurement of blood flow plays a crucial role in the early diagnosis and treatment of numerous diseases, including burns, strokes, atherosclerosis, diabetes, and cancer. In addition, blood flow conditions significantly affect the distribution and efficacy of drugs within the human body, making precise quantification of blood flow highly valuable in clinical medicine. In this study, we propose a method for measuring blood flow velocity based on photoacoustic thermal sensing. This approach overcomes several limitations of traditional photoacoustic velocity measurement techniques, which often rely heavily on medium heterogeneity and are limited in measurement range. By introducing a “thermal tagging” mechanism, we establish a correlation model between flow velocity, temperature, and photoacoustic pressure. This enables high-precision velocity quantification using only a single pulsed laser source, and it is applicable to both homogeneous and heterogeneous media. Based on this principle, we developed a photoacoustic velocity measurement and imaging system. Experiments were carried out to conduct single-point flow velocity detection and two-dimensional mapping of both morphology and velocity. By adjusting the system parameters, the flow velocity measurement range can be adjusted individually, and the average flow velocity measurement error over the range is kept to within 3%. This work provides a novel, non-invasive, rapid, and high-resolution approach for quantitative blood flow measurement. The method expands the functional boundaries of photoacoustic technology and lays a foundation for its broader application in multimodal biomedical diagnostics.

Original language	English
Title of host publication	Second Conference of Young Scientists of the Chinese Society of Optical Engineering
Editors	Liangcai Cao, Qiming Zhang, Pengcheng Hu, Liwei Liu
Publisher	SPIE
ISBN (Electronic)	9781510694781
DOIs	https://doi.org/10.1117/12.3075255
State	Published - 15 Sep 2025
Event	2nd Conference of Young Scientists of the Chinese Society of Optical Engineering - Ningbo, China Duration: 25 Apr 2025 → 27 Apr 2025

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	13799
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	2nd Conference of Young Scientists of the Chinese Society of Optical Engineering
Country/Territory	China
City	Ningbo
Period	25/04/25 → 27/04/25

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

Flow velocity measurement
Grüneisen Parameter
Photoacoustic imaging

Access to Document

10.1117/12.3075255

Cite this

Han, Y., Wu, D., Li, G., Ma, Y., & Sun, M. (2025). Grüneisen Parameter-Based Photoacoustic System for Quantitative Blood Flow Velocity Measurement. In L. Cao, Q. Zhang, P. Hu, & L. Liu (Eds.), Second Conference of Young Scientists of the Chinese Society of Optical Engineering Article 137993B (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13799). SPIE. https://doi.org/10.1117/12.3075255

Han, Yuelin ; Wu, Dongjian ; Li, Gang et al. / Grüneisen Parameter-Based Photoacoustic System for Quantitative Blood Flow Velocity Measurement. Second Conference of Young Scientists of the Chinese Society of Optical Engineering. editor / Liangcai Cao ; Qiming Zhang ; Pengcheng Hu ; Liwei Liu. SPIE, 2025. (Proceedings of SPIE - The International Society for Optical Engineering).

@inproceedings{de5ec6fbd0a74059a404154ae31e4009,

title = "Gr{\"u}neisen Parameter-Based Photoacoustic System for Quantitative Blood Flow Velocity Measurement",

abstract = "Blood flow dynamics are a vital functional parameter within biological tissues. Accurate measurement of blood flow plays a crucial role in the early diagnosis and treatment of numerous diseases, including burns, strokes, atherosclerosis, diabetes, and cancer. In addition, blood flow conditions significantly affect the distribution and efficacy of drugs within the human body, making precise quantification of blood flow highly valuable in clinical medicine. In this study, we propose a method for measuring blood flow velocity based on photoacoustic thermal sensing. This approach overcomes several limitations of traditional photoacoustic velocity measurement techniques, which often rely heavily on medium heterogeneity and are limited in measurement range. By introducing a “thermal tagging” mechanism, we establish a correlation model between flow velocity, temperature, and photoacoustic pressure. This enables high-precision velocity quantification using only a single pulsed laser source, and it is applicable to both homogeneous and heterogeneous media. Based on this principle, we developed a photoacoustic velocity measurement and imaging system. Experiments were carried out to conduct single-point flow velocity detection and two-dimensional mapping of both morphology and velocity. By adjusting the system parameters, the flow velocity measurement range can be adjusted individually, and the average flow velocity measurement error over the range is kept to within 3\%. This work provides a novel, non-invasive, rapid, and high-resolution approach for quantitative blood flow measurement. The method expands the functional boundaries of photoacoustic technology and lays a foundation for its broader application in multimodal biomedical diagnostics.",

keywords = "Flow velocity measurement, Gr{\"u}neisen Parameter, Photoacoustic imaging",

author = "Yuelin Han and Dongjian Wu and Gang Li and Yiming Ma and Mingjian Sun",

note = "Publisher Copyright: {\textcopyright} 2025 SPIE.; 2nd Conference of Young Scientists of the Chinese Society of Optical Engineering ; Conference date: 25-04-2025 Through 27-04-2025",

year = "2025",

month = sep,

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doi = "10.1117/12.3075255",

language = "英语",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

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address = "美国",

}

Han, Y, Wu, D, Li, G, Ma, Y & Sun, M 2025, Grüneisen Parameter-Based Photoacoustic System for Quantitative Blood Flow Velocity Measurement. in L Cao, Q Zhang, P Hu & L Liu (eds), Second Conference of Young Scientists of the Chinese Society of Optical Engineering., 137993B, Proceedings of SPIE - The International Society for Optical Engineering, vol. 13799, SPIE, 2nd Conference of Young Scientists of the Chinese Society of Optical Engineering, Ningbo, China, 25/04/25. https://doi.org/10.1117/12.3075255

Grüneisen Parameter-Based Photoacoustic System for Quantitative Blood Flow Velocity Measurement. / Han, Yuelin; Wu, Dongjian; Li, Gang et al.
Second Conference of Young Scientists of the Chinese Society of Optical Engineering. ed. / Liangcai Cao; Qiming Zhang; Pengcheng Hu; Liwei Liu. SPIE, 2025. 137993B (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 13799).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Grüneisen Parameter-Based Photoacoustic System for Quantitative Blood Flow Velocity Measurement

AU - Han, Yuelin

AU - Wu, Dongjian

AU - Li, Gang

AU - Ma, Yiming

AU - Sun, Mingjian

PY - 2025/9/15

Y1 - 2025/9/15

N2 - Blood flow dynamics are a vital functional parameter within biological tissues. Accurate measurement of blood flow plays a crucial role in the early diagnosis and treatment of numerous diseases, including burns, strokes, atherosclerosis, diabetes, and cancer. In addition, blood flow conditions significantly affect the distribution and efficacy of drugs within the human body, making precise quantification of blood flow highly valuable in clinical medicine. In this study, we propose a method for measuring blood flow velocity based on photoacoustic thermal sensing. This approach overcomes several limitations of traditional photoacoustic velocity measurement techniques, which often rely heavily on medium heterogeneity and are limited in measurement range. By introducing a “thermal tagging” mechanism, we establish a correlation model between flow velocity, temperature, and photoacoustic pressure. This enables high-precision velocity quantification using only a single pulsed laser source, and it is applicable to both homogeneous and heterogeneous media. Based on this principle, we developed a photoacoustic velocity measurement and imaging system. Experiments were carried out to conduct single-point flow velocity detection and two-dimensional mapping of both morphology and velocity. By adjusting the system parameters, the flow velocity measurement range can be adjusted individually, and the average flow velocity measurement error over the range is kept to within 3%. This work provides a novel, non-invasive, rapid, and high-resolution approach for quantitative blood flow measurement. The method expands the functional boundaries of photoacoustic technology and lays a foundation for its broader application in multimodal biomedical diagnostics.

AB - Blood flow dynamics are a vital functional parameter within biological tissues. Accurate measurement of blood flow plays a crucial role in the early diagnosis and treatment of numerous diseases, including burns, strokes, atherosclerosis, diabetes, and cancer. In addition, blood flow conditions significantly affect the distribution and efficacy of drugs within the human body, making precise quantification of blood flow highly valuable in clinical medicine. In this study, we propose a method for measuring blood flow velocity based on photoacoustic thermal sensing. This approach overcomes several limitations of traditional photoacoustic velocity measurement techniques, which often rely heavily on medium heterogeneity and are limited in measurement range. By introducing a “thermal tagging” mechanism, we establish a correlation model between flow velocity, temperature, and photoacoustic pressure. This enables high-precision velocity quantification using only a single pulsed laser source, and it is applicable to both homogeneous and heterogeneous media. Based on this principle, we developed a photoacoustic velocity measurement and imaging system. Experiments were carried out to conduct single-point flow velocity detection and two-dimensional mapping of both morphology and velocity. By adjusting the system parameters, the flow velocity measurement range can be adjusted individually, and the average flow velocity measurement error over the range is kept to within 3%. This work provides a novel, non-invasive, rapid, and high-resolution approach for quantitative blood flow measurement. The method expands the functional boundaries of photoacoustic technology and lays a foundation for its broader application in multimodal biomedical diagnostics.

KW - Flow velocity measurement

KW - Grüneisen Parameter

KW - Photoacoustic imaging

UR - https://www.scopus.com/pages/publications/105022842969

U2 - 10.1117/12.3075255

DO - 10.1117/12.3075255

M3 - 会议稿件

AN - SCOPUS:105022842969

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Second Conference of Young Scientists of the Chinese Society of Optical Engineering

A2 - Cao, Liangcai

A2 - Zhang, Qiming

A2 - Hu, Pengcheng

A2 - Liu, Liwei

PB - SPIE

T2 - 2nd Conference of Young Scientists of the Chinese Society of Optical Engineering

Y2 - 25 April 2025 through 27 April 2025

ER -

Han Y, Wu D, Li G, Ma Y , Sun M. Grüneisen Parameter-Based Photoacoustic System for Quantitative Blood Flow Velocity Measurement. In Cao L, Zhang Q, Hu P, Liu L, editors, Second Conference of Young Scientists of the Chinese Society of Optical Engineering. SPIE. 2025. 137993B. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.3075255

Grüneisen Parameter-Based Photoacoustic System for Quantitative Blood Flow Velocity Measurement

Abstract

Publication series

Conference

UN SDGs

Keywords

Access to Document

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