Photoacoustic Spatial Coherence Theory and Applications to Coherence-Based Image Contrast and Resolution

The photoacoustic effect relies on optical transmission, which causes thermal expansion and generates acoustic signals. Coherence-based photoacoustic signal processing is often preferred over more traditional signal processing methods due to improved signal-to-noise ratios, imaging depth, and resolution in applications such as cell tracking, blood flow estimation, and imaging. However, these applications lack a theoretical spatial coherence model to support their implementation. In this article, the photoacoustic spatial coherence theory is derived to generate theoretical spatial coherence functions. These theoretical spatial coherence functions are compared with k-Wave simulated data and experimental data from point and circular targets (0.1–12 mm in diameter) with generally good agreement, particularly in the shorter spatial lag region. The derived theory was used to hypothesize and test previously unexplored principles for optimizing photoacoustic short-lag spatial coherence (SLSC) images, including the influence of the incident light profile on photoacoustic spatial coherence functions and associated SLSC image contrast and resolution. Results also confirm previous trends from experimental observations, including changes in SLSC image resolution and contrast as a function of the first ${M}$ lags summed to create SLSC images. For example, small targets (e.g., <1–4 mm in diameter) can be imaged with larger ${M}$ values to boost target contrast and resolution, and contrast can be further improved by reducing the illuminating beam to a size that is smaller than the target size. Overall, the presented theory provides a promising foundation to support a variety of coherence-based photoacoustic signal processing methods, and the associated theory-based simulation methods are more straightforward than the existing k-Wave simulation methods for SLSC images.

[1]  Wiendelt Steenbergen,et al.  Photoacoustic needle: minimally invasive guidance to biopsy , 2013, Journal of biomedical optics.

[2]  Steven L. Jacques,et al.  Coupling 3D Monte Carlo light transport in optically heterogeneous tissues to photoacoustic signal generation , 2014, Photoacoustics.

[3]  Eduardo Gonzalez,et al.  In Vivo Demonstration of Photoacoustic Image Guidance and Robotic Visual Servoing for Cardiac Catheter-Based Interventions , 2020, IEEE Transactions on Medical Imaging.

[4]  Da-Kang Yao,et al.  Photoacoustic measurement of the Grüneisen parameter of tissue , 2014, Journal of biomedical optics.

[5]  Lihong V Wang,et al.  Universal back-projection algorithm for photoacoustic computed tomography , 2005, SPIE BiOS.

[6]  Muyinatu A Lediju Bell,et al.  Design of a multifiber light delivery system for photoacoustic-guided surgery , 2017, Journal of biomedical optics.

[7]  J. Mari,et al.  Interventional multispectral photoacoustic imaging with a clinical ultrasound probe for discriminating nerves and tendons: an ex vivo pilot study. , 2015, Journal of biomedical optics.

[8]  Kelley M Kempski,et al.  In vivo photoacoustic imaging of major blood vessels in the pancreas and liver during surgery , 2019, Journal of biomedical optics.

[9]  Emad M Boctor,et al.  Short-lag spatial coherence beamforming of photoacoustic images for enhanced visualization of prostate brachytherapy seeds. , 2013, Biomedical optics express.

[10]  M. O'Donnell,et al.  Coherence factor of speckle from a multi-row probe , 1999, 1999 IEEE Ultrasonics Symposium. Proceedings. International Symposium (Cat. No.99CH37027).

[11]  Li Li,et al.  On the speckle-free nature of photoacoustic tomography. , 2009, Medical physics.

[12]  Allen Nussbaum,et al.  Optical System Design , 1997 .

[13]  J. Cardoso,et al.  Diffraction Effects in Pulse-Echo Measurement , 1984, IEEE Transactions on Sonics and Ultrasonics.

[14]  Muyinatu A. Lediju Bell,et al.  Development and validation of a short-lag spatial coherence theory for photoacoustic imaging , 2018, BiOS.

[15]  Joshua Shubert,et al.  Feasibility of photoacoustic-guided teleoperated hysterectomies , 2018, Journal of medical imaging.

[16]  Xiaoyu Guo,et al.  Transurethral light delivery for prostate photoacoustic imaging , 2015, Journal of biomedical optics.

[17]  René Skov Hansen Using high-power light emitting diodes for photoacoustic imaging , 2011 .

[18]  Bo Wang,et al.  Photoacoustic imaging of coronary artery stents. , 2009, Optics express.

[19]  Michelle Graham,et al.  Theoretical application of short-lag spatial coherence to photoacoustic imaging , 2017, 2017 IEEE International Ultrasonics Symposium (IUS).

[20]  Paul C. Beard,et al.  High power visible light emitting diodes as pulsed excitation sources for biomedical photoacoustics , 2016, Biomedical optics express.

[21]  Muyinatu A. Lediju Bell,et al.  Photoacoustic-based approach to surgical guidance performed with and without a da Vinci robot , 2017, Journal of Biomedical Optics.

[22]  Erwin J. Alles,et al.  Photoacoustic clutter reduction using short-lag spatial coherence weighted imaging , 2014, 2014 IEEE International Ultrasonics Symposium.

[23]  Anastasia K. Ostrowski,et al.  Localization of Transcranial Targets for Photoacoustic-Guided Endonasal Surgeries , 2015, Photoacoustics.

[24]  Muyinatu A. Lediju Bell,et al.  A novel drill design for photoacoustic guided surgeries , 2018, BiOS.

[25]  J. Walkup,et al.  Statistical optics , 1986, IEEE Journal of Quantum Electronics.

[26]  M. L. Li,et al.  Optoacoustic imaging with synthetic aperture focusing and coherence weighting. , 2004, Optics letters.

[27]  Da Xing,et al.  Noninvasive photoacoustic imaging of the developing vasculature during early tumor growth , 2008, Physics in medicine and biology.

[28]  Pai-Chi Li,et al.  SNR-dependent coherence-based adaptive imaging for high-frame-rate ultrasonic and photoacoustic imaging , 2014, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control.

[29]  J. Laufer,et al.  In vivo high-resolution 3D photoacoustic imaging of superficial vascular anatomy , 2009, Physics in medicine and biology.

[30]  Suhyun Park,et al.  Adaptive beamforming for photoacoustic imaging. , 2008, Optics letters.

[31]  Roy G. M. Kolkman,et al.  In vivo photoacoustic imaging of blood vessels with a pulsed laser diode , 2006, Lasers in Medical Science.

[32]  Xosé Luís Deán-Ben,et al.  On the link between the speckle free nature of optoacoustics and visibility of structures in limited-view tomography , 2016, Photoacoustics.

[33]  T. Hirasawa,et al.  Influence of laser pulse width to the photoacoustic temporal waveform and the image resolution with a solid-state excitation laser , 2012, Photonics West - Biomedical Optics.

[34]  R. Waag,et al.  About the application of the van Cittert-Zernike theorem in ultrasonic imaging , 1995, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[35]  Nick Bottenus,et al.  Acoustic reciprocity of spatial coherence in ultrasound imaging , 2015, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control.

[36]  P. Beard Biomedical photoacoustic imaging , 2011, Interface Focus.

[37]  Jin U. Kang,et al.  In vivo visualization of prostate brachytherapy seeds with photoacoustic imaging , 2014, Journal of biomedical optics.

[38]  Jesse V. Jokerst,et al.  The characterization of an economic and portable LED-based photoacoustic imaging system to facilitate molecular imaging , 2017, Photoacoustics.

[39]  B T Cox,et al.  k-Wave: MATLAB toolbox for the simulation and reconstruction of photoacoustic wave fields. , 2010, Journal of biomedical optics.

[40]  Muyinatu A. Lediju Bell,et al.  Coherence-based photoacoustic imaging of brachytherapy seeds implanted in a canine prostate , 2014, Medical Imaging.

[41]  Raoul Mallart,et al.  The van Cittert–Zernike theorem in pulse echo measurements , 1991 .

[42]  W. Marsden I and J , 2012 .

[43]  Vladimir P Zharov,et al.  Photoacoustic flow cytometry. , 2012, Methods.

[44]  Sheng-Wen Huang,et al.  Photoacoustic correlation spectroscopy and its application to low-speed flow measurement. , 2010, Optics letters.

[45]  Michael C. Kolios,et al.  Improving the quality of photoacoustic images using the short-lag spatial coherence imaging technique , 2013, Photonics West - Biomedical Optics.

[46]  Yang Zhou,et al.  Coherent-weighted three-dimensional image reconstruction in linear-array-based photoacoustic tomography , 2016, Biomedical optics express.

[47]  G. E. Trahey,et al.  Short-lag spatial coherence of backscattered echoes: imaging characteristics , 2011, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[48]  Ou,et al.  Additive noise models for photoacoustic spatial coherence theory , 2018 .

[49]  Muyinatu A. Lediju Bell,et al.  Improved contrast in laser-diode-based photoacoustic images with short-lag spatial coherence beamforming , 2014, 2014 IEEE International Ultrasonics Symposium.

[50]  M. Fink,et al.  The notion of coherence in optics and its application to acoustics , 1994 .