留言板

尊敬的读者、作者、审稿人, 关于本刊的投稿、审稿、编辑和出版的任何问题, 您可以本页添加留言。我们将尽快给您答复。谢谢您的支持!

姓名
邮箱
手机号码
标题
留言内容
验证码

从实验室到市场:光声成像的产业化进程

Yasha Saxena Chulhong Kim Yao Junjie

downloadPDF
文章导航 > 红外与激光工程  > 2017 >  46(11): 1103001-1103001(14)
Yasha Saxena, Chulhong Kim, Yao Junjie. 从实验室到市场:光声成像的产业化进程[J]. 红外与激光工程, 2017, 46(11): 1103001-1103001(14). doi: 10.3788/IRLA201746.1103001
引用本文: Yasha Saxena, Chulhong Kim, Yao Junjie. 从实验室到市场:光声成像的产业化进程[J]. 红外与激光工程, 2017, 46(11): 1103001-1103001(14). doi: 10.3788/IRLA201746.1103001
shu
Yasha Saxena, Chulhong Kim, Yao Junjie. From bench to market:commercialization of photoacoustic imaging[J]. Infrared and Laser Engineering, 2017, 46(11): 1103001-1103001(14). doi: 10.3788/IRLA201746.1103001
Citation: Yasha Saxena, Chulhong Kim, Yao Junjie. From bench to market:commercialization of photoacoustic imaging[J]. Infrared and Laser Engineering, 2017, 46(11): 1103001-1103001(14). doi: 10.3788/IRLA201746.1103001
shu

从实验室到市场:光声成像的产业化进程

doi: 10.3788/IRLA201746.1103001
  • 1.

    Department of Biomedical Engineering,Duke University,Durham,USA;

  • 2.

    Departments of Creative IT Engineering and Electrical Engineering,Pohang University of Science and Technology(POSTECH),Pohang,Republic of Korea

基金项目: 

美国杜克大学MEDx基金

详细信息
    作者简介:

    Yasha Saxena (1990-),女,硕士生,主要从事光声成像技术方面的研究。Email:yasha.saxena@duke.edu

  • 中图分类号: O439

From bench to market:commercialization of photoacoustic imaging

  • 1.

    Department of Biomedical Engineering,Duke University,Durham,USA;

  • 2.

    Departments of Creative IT Engineering and Electrical Engineering,Pohang University of Science and Technology(POSTECH),Pohang,Republic of Korea

More Information
    Author Bio:

    Yasha Saxena (1990-),女,硕士生,主要从事光声成像技术方面的研究。Email:yasha.saxena@duke.edu

  • 摘要: Photoacoustic imaging (PAI) or optoacoustic imaging, the modern application of an ancient physical discovery to biomedical imaging, is without doubt one of the most exciting imaging technologies that has drawn increasing attention from biomedical specialists. In PAI, the rich contrast of optical excitation is seamlessly combined with the high spatial resolution and large penetration depth of ultrasonic detection to produce clear images of optically scattering biological tissues. As a complementary imaging modality that surpasses the territory of traditional microscopic optical imaging, PAI has been explored for numerous biomedical studies, and hence enthusiastically embraced by researchers around the globe who have attested to its unique imaging capabilities, namely the deep penetration and functional sensitivity. Not surprisingly, as the market clearly sees the promise, the commercial production of PAI systems has grown apace with the technological advancements and clinical applications. The adoption of commercial PAI in research and clinical settings has however seen difficulties, majorly due to costs, regulatory blocks, and competition with mainstream technologies. Here, from a practical standpoint, a wide range of commercial PAI systems currently available in the market were introduced, their advantages and disadvantages were analyzed, and the design considerations for targeted applications were emphasized. The key technological, logistical, and clinical issues were also discussed that need to be solved to accelerate the technology translations. By doing so, it is hoped that a clearer picture of the future commercialization of PAI for clinicians, researchers, and industrial entrepreneurs will be presented.
    Abstract: Photoacoustic imaging (PAI) or optoacoustic imaging, the modern application of an ancient physical discovery to biomedical imaging, is without doubt one of the most exciting imaging technologies that has drawn increasing attention from biomedical specialists. In PAI, the rich contrast of optical excitation is seamlessly combined with the high spatial resolution and large penetration depth of ultrasonic detection to produce clear images of optically scattering biological tissues. As a complementary imaging modality that surpasses the territory of traditional microscopic optical imaging, PAI has been explored for numerous biomedical studies, and hence enthusiastically embraced by researchers around the globe who have attested to its unique imaging capabilities, namely the deep penetration and functional sensitivity. Not surprisingly, as the market clearly sees the promise, the commercial production of PAI systems has grown apace with the technological advancements and clinical applications. The adoption of commercial PAI in research and clinical settings has however seen difficulties, majorly due to costs, regulatory blocks, and competition with mainstream technologies. Here, from a practical standpoint, a wide range of commercial PAI systems currently available in the market were introduced, their advantages and disadvantages were analyzed, and the design considerations for targeted applications were emphasized. The key technological, logistical, and clinical issues were also discussed that need to be solved to accelerate the technology translations. By doing so, it is hoped that a clearer picture of the future commercialization of PAI for clinicians, researchers, and industrial entrepreneurs will be presented.
  • [1] Bell A G. Upon the production and reproduction of sound by light[J]. American Journal of Science, 1880, 20(118):305-324.
    [2] Brody H. Medical imaging[J]. Nature, 2013. 502(7473):S81.
    [3] Cox B, Laufer J G, Arridge S R, et al. Quantitative spectroscopic photoacoustic imaging:a review[J]. Journal of Biomedical Optics, 2012, 17(6):061202.
    [4] Greneur C L, Sagot B. Biomedical photoacoustic imaging patent landscape[R]. New York:Knowmade Company, 2015.
    [5] Taruttis A, Ntziachristos V. Advances in real-time multispectral optoacoustic imaging and its applications[J]. Nature Photonics, 2015, 9(4):219-227.
    [6] Wang L H V, Hu S. Photoacoustic tomography:in vivo imaging from organelles to organs[J]. Science, 2012, 335(6075):1458-1462.
    [7] Yao J J, Wang L H V. Photoacoustic microscopy[J]. Laser Photonics Reviews, 2013, 7(5):758-778.
    [8] Zackrisson S, van de Ven S M W Y, Gambhir S S. Light in and sound out:emerging translational strategies for photoacoustic imaging[J]. Cancer Research, 2014, 74(4):979-1004.
    [9] Wang L H, Yao J J. A practical guide to photoacoustic tomography in the life sciences[J]. Nature Methods, 2016, 13(8):627-638.
    [10] Vengerov M. An optical-acoustic method of gas analysis[J]. Nature, 1946, 158(4001):28-29.
    [11] Michaels J E. Thermal impact-the mechanical response of solids to extreme electromagnetic radiation[J]. Planetary and Space Science, 1961, 7:427-433.
    [12] White R M. Generation of elastic waves by transient surface heating[J]. Journal of Applied Physics, 1963, 34(12):3559-3567.
    [13] Amar L, Bruna M, Velghe M, et al. On Detection of laser induced ultrasonic waves in human eye and elaboration of a theory on fundamental mechanism of vision[J]. Zeitschrift Fur Angewandte Mathematik Und Physik, 1965, 16(1):182-183.
    [14] Kreuzer L B. Ultralow gas concentration infrared absorption spectroscopy[J]. Journal of Applied Physics, 1971, 42(7):2934-2943.
    [15] Bowen T. Radiation-induced thermoacoustic soft-tissue imaging[J]. IEEE Transactions on Sonics and Ultrasonics, 1982, 29(3):197737.
    [16] Rosencwaig A, Gersho A. Theory of the photoacoustic effect with solids[J]. Journal of Applied Physics, 1976, 47(1):64-69.
    [17] Rosencwaig A. Photoacoustics and photoacoustic spectroscopy[M]. New York:Wiley, 1980.
    [18] Kruger R A, Liu P, Fang Y R, et al. Photoacoustic ultrasound(Paus)-reconstruction tomography[J]. Medical Physics, 1995, 22(10):1605-1609.
    [19] Kruger R A, Liu P Y. Photoacoustic ultrasound-pulse production and detection in 0.5-percent Liposyn[J]. Medical Physics, 1994, 21(7):1179-1184.
    [20] Kruger R A. Photoacoustic ultrasound[J]. Medical Physics, 1994, 21(1):127-131.
    [21] Oraevsky A A, Esenaliev R O, Jacques S L, et al. Lateral and z-axial resolution in laser optoacoustic imaging with ultrasonic transducers[C]//SPIE, 1995, 2389:198-208.
    [22] Esenaliev R O, Oraevsky A A, Jacques S L, et al. Laser optoacoustic tomography for medical diagnostics:experiments with biological tissues[C]//SPIE, 1996, 2676:10.1117/12, 238817.
    [23] Oraevsky A A, Jacques S L, Tittel F K. Determination of tissue optical properties by piezoelectric detection of laser-induced stress waves[C]//SPIE, 1993, 1882:86-101.
    [24] Waldner M J, Knieling F, Egger C, et al. Multispectral optoacoustic tomography in Crohn's disease:noninvasive imaging of disease activity[J]. Gastroenterology, 2016, 151(2):238-240.
    [25] Vionnet L, Tateau J, Schwarz M, et al. 24-MHz scanner for optoacoustic imaging of skin and burn. medical imaging[J]. IEEE Transactions on Medical Imaging, 2014, 33(2):535-545.
    [26] Tzoumas S, Antonio N, Nikolaos C, et al. Effects of multispectral excitation on the sensitivity of molecular optoacoustic imaging[J]. Journal of Biophotonics, 2015, 8(8):629-637.
    [27] Taruttis A, Morscher S, Burton N C, et al. Fast multispectral optoacoustic tomography (MSOT) for dynamic imaging of pharmacokinetics and biodistribution in multiple organs[J]. PLoS One, 2012, 7(1):e30491.
    [28] Stoffels I, Morscher S, Helfrich I, et al. Metastatic status of sentinel lymph nodes in melanoma determined noninvasively with multispectral optoacoustic imaging[J]. Science Translational Medicine, 2015, 7(317):317ra199.
    [29] Sela G, Lauri A, Deanben X L, et al. Functional optoacoustic neuro-tomography (FONT) for whole-brain monitoring of calcium indicators[J]. Quantitative Biology, 2015, arXiv:1501.02450.
    [30] Razansky D, Baeten J, Ntziachristos V. Sensitivity of molecular target detection by multispectral optoacoustic tomography (MSOT)[J]. Medical Physics, 2009, 36(3):939-945.
    [31] Petrova E V, Oraevsky A A, Ermilov S A. Red blood cell as a universal optoacoustic sensor for non-invasive temperature monitoring[J]. Applied Physics Letters, 2014, 105(9):094103.
    [32] Oraevsky A A, Jacques S L, Tittel F K, et al. Lateral and z-axial resolution in laser optoacoustic imaging with ultrasonic transducers in optical tomography, photon migration, and spectroscopy of tissue and model media:theory, human studies, and instrumentation[C]//SPIE, 1995.
    [33] Nikitin S M, Khokhlova T D, Pelivanov I M. Temperature dependence of the optoacoustic transformation efficiency in ex vivo tissues for application in monitoring thermal therapies[J]. Journal of Biomedical Optics, 2012, 17(6):061214.
    [34] Herzog E, Taruttis A, Beziere N, et al. Optical imaging of cancer heterogeneity with multispectral optoacoustic tomography[J]. Radiology, 2012, 263(2):461-468.
    [35] Esenaliev R O, Oraevsky A A, Jacques S L, et al. Laser optoacoustic tomography for medical diagnostics:experiments with biological tissues. in biomedical sensing, imaging, and tracking technologies I[C]//SPIE, 1996, 2676:238817.
    [36] Deliolanis N C, Ale A, Morscher S, et al. Deep-tissue reporter-gene imaging with fluorescence and optoacoustic tomography:A performance overview[J]. Mol Imaging Biol, 2014, 16(5):652-660.
    [37] Dean-Ben X L, Razansky D. Adding fifth dimension to optoacoustic imaging:volumetric time-resolved spectrally enriched tomography[J]. Light-Science Applications, 2014, 3:e137.
    [38] Brecht H P, Su R, Fronheiser M, et al. Whole-body three-dimensional optoacoustic tomography system for small animals[J]. Journal of Biomedical Optics, 2009, 14(6):064007.
    [39] Bost W, Stracke F, Wei B E C, et al. High frequency optoacoustic microscopy[C]//IEEE Eng Med Biol Soc, 2009, 2009:5883-5886.
    [40] Wang X D, Pang Y, Ku G, et al. Noninvasive laser-induced photoacoustic tomography for structural and functional in vivo imaging of the brain[J]. Nature Biotechnology, 2003, 21(7):803-806.
    [41] Zhang H F, Maslov K, Stoica G, et al. Functional photoacoustic microscopy for high-resolution and noninvasive in vivo imaging[J]. Nature Biotechnology, 2006, 24(7):848-851.
    [42] de la Zerda A, Lius Z, Bodapati S, et al. Carbon nanotubes as photoacoustic molecular imaging agents in living mice[J]. Nature Nanotechnology, 2008, 3(9):557-562.
    [43] Kim J W, Galanzha E I, Shashkov E V, et al. Golden carbon nanotubes as multimodal photoacoustic and photothermal high-contrast molecular agents[J]. Nature Nanotechnology, 2009, 4(10):688-694.
    [44] Razansky D, Distel M, Vinegoni C, et al. Multispectral opto-acoustic tomography of deep-seated fluorescent proteins in vivo[J]. Nature Photonics, 2009, 3(7):412-417.
    [45] Yang J M, Favazza C, Chen R, et al. Simultaneous functional photoacoustic and ultrasonic endoscopy of internal organs in vivo[J]. Nature Medicine, 2012, 18(8):1297-1302.
    [46] Pu K Y, Shuhendler A J, Jokerst J V, et al. Semiconducting polymer nanoparticles as photoacoustic molecular imaging probes in living mice[J]. Nature Nanotechnology, 2014, 9(3):233-239.
    [47] Jathoul A P, Laufer J, Ogulade O, et al. Deep in vivo photoacoustic imaging of mammalian tissues using a tyrosinase-based genetic reporter[J]. Nature Photonics, 2015, 9(4):239-246.
    [48] Yao J, Wang L, Yang J M, et al. High-speed label-free functional photoacoustic microscopy of mouse brain in action[J]. Nature methods, 2015, 12(5):407-410.
    [49] Yao J, Kaberniuk A A, Li L, et al. Multiscale photoacoustic tomography using reversibly switchable bacterial phytochrome as a near-infrared photochromic probe[J]. Nature Methods, 2016, 13(1):67-73.
    [50] Manohar S, Razansky D. Photoacoustics:a historical review[J]. Advances in Optics and Photonics, 2016, 8(4):586-617.
    [51] Jansen K, Van A F, Beusekm van H M, et al. Intravascular photoacoustic imaging of human coronary atherosclerosis[J]. Optics Letters, 2011, 36(5):597-599.
    [52] Xia J, Chatni M R, Maslov K, et al. Whole-body ring-shaped confocal photoacoustic computed tomography of small animals in vivo[J]. Journal of Biomedical Optics, 2012, 17(5):050506.
    [53] Xia J, Yao J, Wang L V. Photoacoustic tomography:principles and advances[J]. Electromagn Waves(Camb), 2014, 147:1-22.
    [54] Mallidi S, Watanabe K, Timerman D, et al. Prediction of tumor recurrence and therapy monitoring using ultrasound-guided photoacoustic imaging[J]. Theranostics, 2015, 5(3):289-301.
    [55] Fakhrejahani E, Torri M, Kitai T, et al. Clinical report on the first prototype of a photoacoustic tomography system with dual illumination for breast cancer imaging[J]. PLoS One, 2015, 10(10):e0139113.
    [56] Kruger R A, Lam R B, Reineche D R, et al. Photoacoustic angiography of the breast[J]. Medical Physics, 2010. 37(11):6096-6100.
    [57] Heijblom M, Lam R B, Reinecke D R, et al. Visualizing breast cancer using the Twente photoacoustic mammoscope:What do we learn from twelve new patient measurements[J]. Optics Express, 2012, 20(11):11582-11597.
    [58] Xing W X, Wang L D, Maslov K, et al. Integrated optical-and acoustic-resolution photoacoustic microscopy based on an optical fiber bundle[J]. Optics Letters, 2013, 38(1):52-54.
    [59] Yoon T J, Cho Y S. Recent advances in photoacoustic endoscopy[J]. World J Gastrointest Endosc, 2013, 5(11):534-539.
    [60] Wang P, Ma T, Slipohenko M N, et al. High-speed intravascular photoacoustic imaging of lipid-laden atherosclerotic plaque enabled by a 2-kHz barium nitrite raman laser[J]. Sci Rep, 2014, 4:6889.
    [61] Bohndiek S E, Bodapati S, Dominique van De Sompel, et al. Development and application of stable phantoms for the evaluation of photoacoustic imaging instruments[J]. PLoS One, 2013, 8(9):e75533.
    [62] Mehrmohammadi M, Yoom S J, Yeager D, et al. Photoacoustic imaging for cancer detection and staging[J]. Curr Mol Imaging, 2013, 2(1):89-105.
    [63] American national standard for the safe use of lasers[S]. New York:American National Standard Institute, 2007.
    [64] Shigeta Y, Agano T, Sato N, et al. Detection of ICG at low concentrations by photoacoustic imaging system using LED light source[C]//SPIE, 2017:100644x:doi 10.1117/12.2251678.
    [65] Agano T, Sato N. Photoacoustic imaging system using LED light source[C]//2016 Conference on Lasers and Electro-Optics (Cleo), 2016:ATh3N.5.
    [66] Zhang Y, Jeon M, Rich L J, et al. Non-invasive multimodal functional imaging of the intestine with frozen micellar naphthalocyanines[J]. Nature Nanotechnology, 2014. 9(8):631-638.
    [67] Talukdar Y, Avti P, Sun J, et al. Multimodal ultrasound-photoacoustic imaging of tissue engineering scaffolds and blood oxygen saturation in and around the scaffolds[J]. Tissue Engineering Part C, Methods, 2014, 20(5):440-449.
    [68] Song W, Wei Q, Liu T, et al. Integrating photoacoustic ophthalmoscopy with scanning laser ophthalmoscopy, optical coherence tomography, and fluorescein angiography for a multimodal retinal imaging platform[J]. Journal of Biomedical Optics, 2012, 17(6):061206.
    [69] Kim J, Lee D, Jung U, et al. Photoacoustic imaging platforms for multimodal imaging[J]. Ultrasonography, 2015, 34(2):88-97.
    [70] Akers W J, Edwards W B, Kim C, et al. Multimodal sentinel lymph node mapping with single-photon emission computed tomography(SPECT)/computed tomography(CT) and photoacoustic tomography[J]. Translational Research, 2012, 159(3):175-181.
    [71] Kim J, Park S, Jung Y, et al. Programmable real-time clinical photoacoustic and ultrasound imaging system[J]. Scientific Reports, 2016, 6:35137.
    [72] Yao J, Xia J, Wang L V. Multiscale functional and molecular photoacoustic tomography[J]. Ultrasonic Imaging, 2016, 38(1):44-62.
    [73] Wilson K E, Wang T Y, Willmann J K. Acoustic and photoacoustic molecular imaging of cancer[J]. Journal of Nuclear Medicine, 2013, 54(11):1851-1854.
    [74] Li M, Oh Jung-Tack, Xie Xueyi, et al. Simultaneous molecular and hypoxia imaging of brain tumors in vivo using spectroscopic photoacoustic tomography[J]. Proceedings of the IEEE, 2008, 96(3):481-489.
    [75] Levi J, Kothapalli S R, Bohndiek S, et al. Molecular photoacoustic imaging of follicular thyroid carcinoma[J]. Clinical Cancer Research, 2013, 19(6):1494-1502.
    [76] Kircher M F, Adam de la Zerda, Jess V Jokerst, et al. A brain tumor molecular imaging strategy using a new triple-modality MRI-photoacoustic-Raman nanoparticle[J]. Nature Medicine, 2012, 18(5):829-U235.
    [77] Kim C, Favazza C, Wang L V. In vivo photoacoustic tomography of chemicals:high-resolution functional and molecular optical imaging at new depths[J]. Chem Rev, 2010, 110(5):2756-2782.
    [78] de la Zerda A, Kim J-W, Galanzha E, et al. Advanced contrast nanoagents for photoacoustic molecular imaging, cytometry, blood test and photothermal theranostics[J]. Contrast Media Molecular Imaging, 2011, 6(5):346-369.
    [79] Ray A, Wang X D, Lee Y, et al. Targeted blue nanoparticles as photoacoustic contrast agent for brain tumor delineation[J]. Nano Research, 2011, 4(11):1163-1173.
    [80] Galanzha E I, Nedosekin D A, Sarimollaoglu M, et al. Photoacoustic and photothermal cytometry using photoswitchable proteins and nanoparticles with ultrasharp resonances[J]. Journal of Biophotonics, 2013, 8(1):81-93.
    [81] Brannon-Peppas L, Blanchette J O. Nanoparticle and targeted systems for cancer therapy[J]. Adv Drug Deliv Rev, 2004, 56(11):1649-1659.
    [82] Zhang Y S, Wang Y, Wan L D, et al. Labeling human mesenchymal stem cells with gold nanocages for in vitro and in vivo tracking by two-photon microscopy and photoacoustic microscopy[J]. Theranostics, 2013, 3(8):532-543.
    [83] Danielli A, Maslov K, Garcia-Uribe A, et al. Label-free photoacoustic nanoscopy[J]. Journal of Biomedical Optics, 2014, 19(8):086006.
  • [1] 张振辉, 王尔褀, 石玉娇.  光声技术在脑组织成像中的应用(特邀) . 红外与激光工程, 2022, 51(11): 20220541-1-20220541-7. doi: 10.3788/IRLA20220541
    [2] Li Ning, Wei Daozhi, Zhang Dongyang, Yao Liangfu.  Information fusion method of ranging-imaging guidance integrated fuze . 红外与激光工程, 2021, 50(11): 20210039-1-20210039-8. doi: 10.3788/IRLA20210039
    [3] Yang Xu, Jiang Pengfei, Wu Long, Xu Lu, Zhang Jianlong, Hu Haili, Liu Yuehao, Zhang Yong.  Underwater Fourier single pixel imaging based on water degradation function compensation method . 红外与激光工程, 2020, 49(11): 20200281-1-20200281-12. doi: 10.3788/IRLA20200281
    [4] Wang Xing, Gao Lei, Wang Yan, Wang Haitao.  Design of a hybid ultrasound and digital holography imaging system for detection of internal micro-defects . 红外与激光工程, 2020, 49(7): 20190518-1-20190518-11. doi: 10.3788/IRLA20190518
    [5] Ji Yi.  Visible light optical coherence tomography in biomedical imaging . 红外与激光工程, 2019, 48(9): 902001-0902001(9). doi: 10.3788/IRLA201948.0902001
    [6] 杨虹, 黄远辉, 苗少峰, 宫睿, 邵晓鹏, 毕祥丽.  频率域光声成像系统的研究 . 红外与激光工程, 2016, 45(4): 424001-0424001(7). doi: 10.3788/IRLA201645.0424001
    [7] Xuezhi Wang, Yajing Huang, Weiping Yang, Bill Moran.  Target rotation parameter estimation for ISAR imaging via frame processing . 红外与激光工程, 2016, 45(3): 302001-0302001(11). doi: 10.3788/IRLA201645.0302001
  • 加载中
WeChat 点击查看大图
计量
  • 文章访问数:  523
  • HTML全文浏览量:  92
  • PDF下载量:  381
  • 被引次数: 0
出版历程
  • 收稿日期:  2017-10-25
  • 修回日期:  2017-12-11
  • 刊出日期:  2017-11-25

从实验室到市场:光声成像的产业化进程

doi: 10.3788/IRLA201746.1103001
  • 1. Department of Biomedical Engineering,Duke University,Durham,USA;
  • 2. Departments of Creative IT Engineering and Electrical Engineering,Pohang University of Science and Technology(POSTECH),Pohang,Republic of Korea
    • 作者简介:

    Yasha Saxena (1990-),女,硕士生,主要从事光声成像技术方面的研究。Email:yasha.saxena@duke.edu

  • 收稿日期: 2017-10-25
  • 修回日期: 2017-12-11
  • 刊出日期: 2017-11-25
基金项目:

美国杜克大学MEDx基金

  • 中图分类号: O439

摘要: Photoacoustic imaging (PAI) or optoacoustic imaging, the modern application of an ancient physical discovery to biomedical imaging, is without doubt one of the most exciting imaging technologies that has drawn increasing attention from biomedical specialists. In PAI, the rich contrast of optical excitation is seamlessly combined with the high spatial resolution and large penetration depth of ultrasonic detection to produce clear images of optically scattering biological tissues. As a complementary imaging modality that surpasses the territory of traditional microscopic optical imaging, PAI has been explored for numerous biomedical studies, and hence enthusiastically embraced by researchers around the globe who have attested to its unique imaging capabilities, namely the deep penetration and functional sensitivity. Not surprisingly, as the market clearly sees the promise, the commercial production of PAI systems has grown apace with the technological advancements and clinical applications. The adoption of commercial PAI in research and clinical settings has however seen difficulties, majorly due to costs, regulatory blocks, and competition with mainstream technologies. Here, from a practical standpoint, a wide range of commercial PAI systems currently available in the market were introduced, their advantages and disadvantages were analyzed, and the design considerations for targeted applications were emphasized. The key technological, logistical, and clinical issues were also discussed that need to be solved to accelerate the technology translations. By doing so, it is hoped that a clearer picture of the future commercialization of PAI for clinicians, researchers, and industrial entrepreneurs will be presented.

English Abstract

    全文HTML

参考文献 (83)

目录

    /

    返回文章
    返回

    版权所有 © 2019 《红外与激光工程》编辑部地址: 天津市空港经济区中环西路58号邮政编码: 300308

    津ICP备19007885号-1

    本系统由 北京仁和汇智信息技术有限公司 开发    百度统计