Your search keyword '"Yao, Junjie"' showing total 8 results

1. Photoacoustic Microscopy

Author

Rong, Qiangzhou, Humayun, Lucas, Yao, Junjie, and Xia, Wenfeng, editor

Published

2024

2. Nanoparticles for Photoacoustic Imaging of Vasculature

Author

Zhou, Min, Li, Lei, Yao, Junjie, Bouchard, Richard R., Wang, Lihong. V., Li, Chun, Bulte, Jeff W.M., editor, and Modo, Michel M.J., editor

Published

2017

3. Three-Dimensional Deep-Tissue Functional and Molecular Imaging by Integrated Photoacoustic, Ultrasound, and Angiographic Tomography (PAUSAT).

Author

Li, Mucong, Beaumont, Nathan, Ma, Chenshuo, Rojas, Juan, Vu, Tri, Harlacher, Max, O'Connell, Graeme, Gessner, Ryan C., Kilian, Hailey, Kasatkina, Ludmila, Chen, Yong, Huang, Qiang, Shen, Xiling, Lovell, Jonathan F., Verkhusha, Vladislav V., Czernuszewicz, Tomek, and Yao, Junjie

Subjects

ACOUSTIC imaging, MICROBUBBLE diagnosis, ANGIOGRAPHY, MICROSCOPY, MAGNETIC resonance imaging, TOMOGRAPHY

Abstract

Non-invasive small-animal imaging technologies, such as optical imaging, magnetic resonance imaging and ${x}$ -ray computed tomography, have enabled researchers to study normal biological phenomena or disease progression in their native conditions. However, existing small-animal imaging technologies often lack either the penetration capability for interrogating deep tissues (e.g., optical microscopy), or the functional and molecular sensitivity for tracking specific activities (e.g., magnetic resonance imaging). To achieve functional and molecular imaging in deep tissues, we have developed an integrated photoacoustic, ultrasound and acoustic angiographic tomography (PAUSAT) system by seamlessly combining light and ultrasound. PAUSAT can perform three imaging modes simultaneously with complementary contrast: high-frequency B-mode ultrasound imaging of tissue morphology, microbubble-enabled acoustic angiography of tissue vasculature, and multi-spectral photoacoustic imaging of molecular probes. PAUSAT can provide three-dimensional (3D) multi-contrast images that are co-registered, with high spatial resolutions at large depths. Using PAUSAT, we performed proof-of-concept in vivo experiments on various small animal models: monitoring longitudinal development of placenta and embryo during mouse pregnancy, tracking biodistribution and metabolism of near-infrared organic dye on the whole-body scale, and detecting breast tumor expressing genetically-encoded photoswitchable phytochromes. These results have collectively demonstrated that PAUSAT has broad applicability in biomedical research, providing comprehensive structural, functional, and molecular imaging of small animal models. [ABSTRACT FROM AUTHOR]

Published

2022

4. Internal-Illumination Photoacoustic Tomography Enhanced by a Graded-Scattering Fiber Diffuser.

Author

Li, Mucong, Vu, Tri, Sankin, Georgy, Winship, Brenton, Boydston, Kohldon, Terry, Russell, Zhong, Pei, and Yao, Junjie

Subjects

DIFFUSERS (Fluid dynamics), PHOTOACOUSTIC effect, ACOUSTIC imaging, LIGHT scattering, PHOTOACOUSTIC spectroscopy, OPTICAL fibers, TOMOGRAPHY, MONTE Carlo method

Abstract

The penetration depth of photoacoustic imaging in biological tissues has been fundamentally limited by the strong optical attenuation when light is delivered externally through the tissue surface. To address this issue, we previously reported internal-illumination photoacoustic imaging using a customized radial-emission optical fiber diffuser, which, however, has complex fabrication, high cost, and non-uniform light emission. To overcome these shortcomings, we have developed a new type of low-cost fiber diffusers based on a graded-scattering method in which the optical scattering of the fiber diffuser is gradually increased as the light travels. The graded scattering can compensate for the optical attenuation and provide relatively uniform light emission along the diffuser. We performed Monte Carlo numerical simulations to optimize several key design parameters, including the number of scattering segments, scattering anisotropy factor, divergence angle of the optical fiber, and reflective index of the surrounding medium. These optimized parameters collectively result in uniform light emission along the fiber diffuser and can be flexibly adjusted to accommodate different applications. We fabricated and characterized the prototype fiber diffuser made of agarose gel and intralipid. Equipped with the new fiber diffuser, we performed thorough proof-of-concept studies on ex vivo tissue phantoms and an in vivo swine model to demonstrate the deep-imaging capability (~10 cm achieved ex vivo) of photoacoustic tomography. We believe that the internal light delivery via the optimized fiber diffuser is an effective strategy to image deep targets (e.g., kidney) in large animals or humans. [ABSTRACT FROM AUTHOR]

Published

2021

5. Correcting the limited view in optical‐resolution photoacoustic microscopy.

Author

Liu, Wei, Zhou, Yuan, Wang, Mengran, Li, Lei, Vienneau, Emelina, Chen, Ruimin, Luo, Jianwen, Xu, Chris, Zhou, Qifa, Wang, Lihong V., and Yao, Junjie

Abstract

Optical‐resolution photoacoustic microscopy (OR‐PAM) has proven useful for anatomical and functional imaging with high spatial resolutions. However, the coherent signal generation and the desired reflection‐mode detection in OR‐PAM can result in a limited detectability of features aligned with the acoustic axis (ie, vertical structures). Here, we investigated the limited‐view phenomenon in OR‐PAM by simulating the generation and propagation of the acoustic pressure waves and determined the key optical parameters affecting the visibility of vertical structures. Proof‐of‐concept numerical experiments were performed with different illumination angles, optical foci and numerical apertures (NA) of the objective lens. The results collectively show that an NA of 0.3 can readily improve the visibility of vertical structures in a typical reflection‐mode OR‐PAM system. This conclusion was confirmed by numerical simulations on the cortical blood vessels in a mouse brain and by experiments in a suture‐cross phantom and in a mouse brain in vivo. [ABSTRACT FROM AUTHOR]

Published

2018

6. Direct measurement of hypoxia in a xenograft multiple myeloma model by optical-resolution photoacoustic microscopy.

Author

Imai, Toru, Muz, Barbara, Yeh, Cheng-Hung, Yao, Junjie, Zhang, Ruiying, Azab, Abdel Kareem, and Wang, Lihong

Published

2017

7. Calibration-free absolute quantification of particle concentration by statistical analyses of photoacoustic signals in vivo.

Author

Zhou, Yong, Yao, Junjie, Maslov, Konstantin I., and Wang, Lihong V.

Subjects

*PHOTOACOUSTIC spectroscopy, *PHOTOACOUSTIC spectrometers, *PHOTOACOUSTIC effect, *PHOTOACOUSTIC detectors, *ACOUSTIC measurements, *PHOTOACOUSTIC spectra

Abstract

Currently, laser fluence calibration is typically required for quantitative measurement of particle concentration in photoacoustic imaging. Here, we present a calibration-free method to quantify the absolute particle concentration by statistically analyzing photoacoustic signals. The proposed method is based on the fact that Brownian motion induces particle count fluctuation in the detection volume. If the count of particles in the detection volume is assumed to follow the Poisson distribution, its expected value can be calculated by the photoacoustic signal mean and variance. We first derived a theoretical model for photoacoustic signals. Then, we applied our method to quantitative measurement of different concentrations of various particles, including red blood cells. Finally, we performed in vivo experiments to demonstrate the potential of our method in biological applications. The experimental results agreed well with the predictions from the theoretical model suggesting that our method can be used for noninvasive measurement of absolute particle concentrations in deep tissue without fluence calibration. [ABSTRACT FROM AUTHOR]

Published

2014

8. Non-Invasive and In Situ Characterization of the Degradation of Biomaterial Scaffolds by Volumetric Photoacoustic Microscopy.

Author

Zhang, Yu Shrike, Cai, Xin, Yao, Junjie, Xing, Wenxin, Wang, Lihong V., and Xia, Younan

Subjects

BIOMATERIALS, ACOUSTOOPTICAL devices, CHEMICAL decomposition, REGENERATIVE medicine, BLOOD vessels

Abstract

Degradation is among the most important properties of biomaterial scaffolds, which are indispensable for regenerative medicine. The currently used method relies on the measurement of mass loss across different samples and cannot track the degradation of an individual scaffold in situ. Here we report, for the first time, the use of multiscale photoacoustic microscopy to non-invasively monitor the degradation of an individual scaffold. We could observe alterations to the morphology and structure of a scaffold at high spatial resolution and deep penetration, and more significantly, quantify the degradation of an individual scaffold as a function of time, both in vitro and in vivo. In addition, the remodeling of vasculature inside a scaffold can be visualized simultaneously using a dual-wavelength scanning mode in a label-free manner. This optoacoustic method can be used to monitor the degradation of individual scaffolds, offering a new approach to non-invasively analyze and quantify biomaterial-tissue interactions in conjunction with the assessment of in vivo vascular parameters. [ABSTRACT FROM AUTHOR]

Published

2014