Researching

Journals
  • Advanced Photonics
  • Photonics Insights
  • Advanced Photonics Nexus
  • Photonics Research
  • Advanced Imaging
  • View All Journals
  • Chinese Optics Letters
  • High Power Laser Science and Engineering
    • Articles
  • Optics
  • Physics
  • Geography
  • View All Subjects
    • Conferences
  • CIOP
  • HPLSE
  • AP
  • View All Events
    • News
    About CLP
    Search by keywords or author
    Journals >Advanced Imaging >Volume 2 >Issue 2 >Page 021001 > Article
    • Advanced Imaging
    • Vol. 2, Issue 2, 021001 (2025)
    Self-supervised PSF-informed deep learning enables real-time deconvolution for optical coherence tomography | On the Cover
    Weiyi Zhang, Haoran Zhang, Qi Lan, Chang Liu..., Zheng Li, Chengfu Gu and Jianlong Yang*|Show fewer author(s)
    Author Affiliations
  • School of Biomedical Engineering, Shanghai Jiao Tong University, Shanghai, China
    • show less
    DOI: 10.3788/AI.2025.10026 Cite this Article Set citation alerts
    Weiyi Zhang, Haoran Zhang, Qi Lan, Chang Liu, Zheng Li, Chengfu Gu, Jianlong Yang, "Self-supervised PSF-informed deep learning enables real-time deconvolution for optical coherence tomography," Adv. Imaging 2, 021001 (2025) Copy Citation Text show less
    References

    [1] B. E. Bouma et al. Optical coherence tomography. Nat. Rev. Methods Primers, 2, 79(2022).

    [2] M. J. Gora et al. Endoscopic optical coherence tomography: technologies and clinical applications. Biomed. Opt. Express, 8, 2405(2017).

    [3] M.-Y. Fu et al. The progress of optical coherence tomography in industry applications. Adv. Dev. Instrum., 5, 0053(2024).

    [4] V. B. Silva et al. Signal-carrying speckle in optical coherence tomography: a methodological review on biomedical applications. J. Biomed. Opt., 27, 030901(2022).

    [5] A. Agrawal et al. Three-dimensional characterization of optical coherence tomography point spread functions with a nanoparticle-embedded phantom. Opt. Lett., 35, 2269(2010).

    [6] J. Wang, B. Wohlberg, R. Adamson. Convolutional dictionary learning for blind deconvolution of optical coherence tomography images. Biomed. Opt. Express, 13, 1834(2022).

    [7] B. Baumann et al. Signal averaging improves signal-to-noise in oct images: but which approach works best, and when?. Biomed. Opt. Express, 10, 5755(2019).

    [8] M. Szkulmowski, M. Wojtkowski. Averaging techniques for OCT imaging. Opt Express, 21, 9757(2013).

    [9] J. J. Rico-Jimenez et al. Real-time oct image denoising using a self-fusion neural network. Biomed. Opt. Express, 13, 1398(2022).

    [10] J. Nienhaus et al. Live 4D-OCT denoising with self-supervised deep learning. Sci. Rep., 13, 5760(2023).

    [11] B. Qiu et al. N2NSR-OCT: simultaneous denoising and super-resolution in optical coherence tomography images using semisupervised deep learning. J. Biophotonics, 14, e202000282(2021).

    [12] A. Guo et al. Unsupervised denoising of optical coherence tomography images with nonlocal-generative adversarial network. IEEE Trans. Instrum. Meas., 70, 1(2020).

    [13] Y. Li, Y. Fan, H. Liao. Self-supervised speckle noise reduction of optical coherence tomography without clean data. Biomed. Opt. Express, 13, 6357(2022).

    [14] J. Liu et al. Future-proof imaging: computational imaging. Adv. Imaging, 1, 012001(2024).

    [15] J. M. Schmitt, Z. Liang. Deconvolution and enhancement of optical coherence tomograms, 2981, 46(1997).

    [16] J. M. Schmitt. Restoration of optical coherence images of living tissue using the clean algorithm. J. Biomed. Opt., 3, 66(1998).

    [17] J. Högbom. Aperture synthesis with a non-regular distribution of interferometer baselines. Astron. Astrophys. Suppl. Ser., 15, 417(1974).

    [18] T. S. Ralston et al. Deconvolution methods for mitigation of transverse blurring in optical coherence tomography. IEEE Trans. Image Process., 14, 1254(2005).

    [19] Y. Liu et al. Deconvolution methods for image deblurring in optical coherence tomography. JOSA A, 26, 72(2009).

    [20] S. Hojjatoleslami, M. Avanaki, A. G. Podoleanu. Image quality improvement in optical coherence tomography using lucy–richardson deconvolution algorithm. Appl. Opt., 52, 5663(2013).

    [21] E. Bousi, C. Pitris. Axial resolution improvement by modulated deconvolution in fourier domain optical coherence tomography. J. Biomed. Opt., 17, 071307(2012).

    [22] G. Liu et al. Automatic estimation of point-spread-function for deconvoluting out-of-focus optical coherence tomographic images using information entropy-based approach. Opt. Express, 19, 18135(2011).

    [23] D. Yin, Y. Gu, P. Xue. Speckle-constrained variational methods for image restoration in optical coherence tomography. JOSA A, 30, 878(2013).

    [24] X. Ge et al. Deblurring, artifact-free optical coherence tomography with deconvolution-random phase modulation. Opto-Electron. Sci., 3, 230020(2024).

    [25] J. M. Schmitt, S. Xiang, K. M. Yung. Speckle in optical coherence tomography. J. Biomed. Opt., 4, 95(1999).

    [26] W. Zhao et al. Sparse deconvolution improves the resolution of live-cell super-resolution fluorescence microscopy. Nat. Biotechnol., 40, 606(2022).

    [27] A. Krull, T.-O. Buchholz, F. Jug. Noise2void-learning denoising from single noisy images, 2129(2019).

    [28] J. Lequyer et al. A fast blind zero-shot denoiser. Nat. Mach. Intell., 4, 953(2022).

    [29] H. Zhang et al. Cross-attention learning enables real-time nonuniform rotational distortion correction in oct. Biomed. Opt. Express, 15, 319(2023).

    [30] C. Gu et al. Computer-generated holography enables high-uniformity, high-efficiency depth-of-focus extension in endoscopic oct. Opt. Lett., 49, 6896(2024).

    [31] Q. Lan et al. OCT as both a shape sensor and a tomographic imager for large-scale freeform robotic scanning. Opt. Lett., 50, 45(2024).

    [32] T. Wang et al. Heartbeat OCT: in vivo intravascular megahertz-optical coherence tomography. Biomed Opt Express, 6, 5021(2015).

    [33] M. Li et al. OCTA-500: a retinal dataset for optical coherence tomography angiography study. Med. Image Anal., 93, 103092(2024).

    [34] J.-L. Starck, E. Pantin, F. Murtagh. Deconvolution in astronomy: a review. Publ. Astron. Soc. Pac., 114, 1051(2002).

    [35] O. Ronneberger, P. Fischer, T. Brox. U-net: convolutional networks for biomedical image segmentation, 234(2015).

    [36] T. Wang et al. Intravascular optical coherence tomography imaging at 3200 frames per second. Opt. Lett., 38, 1715(2013).

    [37] J. Lehtinen et al. Noise2Noise: Learning image restoration without clean data(2018).

    Full Text
    Get PDF
    Figures&Tables (12)
    Equations (24)
    References (37)
    Get Citation
    Copy Citation Text
    Weiyi Zhang, Haoran Zhang, Qi Lan, Chang Liu, Zheng Li, Chengfu Gu, Jianlong Yang, "Self-supervised PSF-informed deep learning enables real-time deconvolution for optical coherence tomography," Adv. Imaging 2, 021001 (2025)
    Download Citation
    EndNote(RIS)
    BibTex
    Plain Text
    Set citation alerts for the article
    Tools
    Share
    Set citation alerts for the article
    Save the article for my favorites
    Paper Information
    Recommended Topics
    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology