GPU-based computational adaptive optics for volumetric optical coherence microscopy

Optical coherence tomography (OCT) is a non-invasive imaging technique that measures reflectance from within biological tissues. Current higher-NA optical coherence microscopy (OCM) technologies with near cellular resolution have limitations on volumetric imaging capabilities due to the trade-offs between resolution vs. depth-of-field and sensitivity to aberrations. Such trade-offs can be addressed using computational adaptive optics (CAO), which corrects aberration computationally for all depths based on the complex optical field measured by OCT. However, due to the large size of datasets plus the computational complexity of CAO and OCT algorithms, it is a challenge to achieve high-resolution 3D-OCM reconstructions at speeds suitable for clinical and research OCM imaging. In recent years, real-time OCT reconstruction incorporating both dispersion and defocus correction has been achieved through parallel computing on graphics processing units (GPUs). We add to these methods by implementing depth-dependent aberration correction for volumetric OCM using plane-by-plane phase deconvolution. Following both defocus and aberration correction, our reconstruction algorithm achieved depth-independent transverse resolution of 2.8 um, equal to the diffraction-limited focal plane resolution. We have translated the CAO algorithm to a CUDA code implementation and tested the speed of the software in real-time using two GPUs - NVIDIA Quadro K600 and Geforce TITAN Z. For a data volume containing 4096×256×256 voxels, our system’s processing speed can keep up with the 60 kHz acquisition rate of the line-scan camera, and takes 1.09 seconds to simultaneously update the CAO correction for 3 en face planes at user-selectable depths.

[1]  Etienne Cuche,et al.  Numerical parametric lens for shifting, magnification, and complete aberration compensation in digital holographic microscopy. , 2006, Journal of the Optical Society of America. A, Optics, image science, and vision.

[2]  Angelika Unterhuber,et al.  Anisotropic aberration correction using region of interest based digital adaptive optics in Fourier domain OCT. , 2015, Biomedical optics express.

[3]  S. Boppart,et al.  Cross-validation of interferometric synthetic aperture microscopy and optical coherence tomography. , 2010, Optics letters.

[4]  Nathan D. Shemonski,et al.  Computational high-resolution optical imaging of the living human retina , 2015, Nature Photonics.

[5]  Nathan D. Shemonski,et al.  Guide-star-based computational adaptive optics for broadband interferometric tomography. , 2012, Applied physics letters.

[6]  R. Richards-Kortum,et al.  Light scattering from cervical cells throughout neoplastic progression: influence of nuclear morphology, DNA content, and chromatin texture. , 2003, Journal of biomedical optics.

[7]  J. Duker,et al.  Ultrahigh-resolution, high-speed, Fourier domain optical coherence tomography and methods for dispersion compensation. , 2004, Optics express.

[8]  William J. Brown,et al.  Functional optical coherence tomography: principles and progress , 2015, Physics in medicine and biology.

[9]  Lingfeng Yu,et al.  Digital holographic tomography based on spectral interferometry. , 2007, Optics letters.

[10]  M. Roizen,et al.  Hallmarks of Cancer: The Next Generation , 2012 .

[11]  Stephen A. Boppart,et al.  Real-time in vivo computed optical interferometric tomography , 2013, Nature Photonics.

[12]  Stephen A. Boppart,et al.  Computed optical interferometric tomography for high-speed volumetric cellular imaging , 2014 .

[13]  Daniel L Marks,et al.  Nonparaxial vector-field modeling of optical coherence tomography and interferometric synthetic aperture microscopy. , 2007, Journal of the Optical Society of America. A, Optics, image science, and vision.

[14]  Wolfgang Drexler,et al.  Subaperture correlation based digital adaptive optics for full field optical coherence tomography. , 2013, Optics express.

[15]  Daniel L Marks,et al.  Interferometric Synthetic Aperture Microscopy , 2007, OFC/NFOEC 2008 - 2008 Conference on Optical Fiber Communication/National Fiber Optic Engineers Conference.

[16]  Michael S. Feld,et al.  Imaging human epithelial properties with polarized light-scattering spectroscopy , 2001, Nature Medicine.

[17]  Lingfeng Yu,et al.  Improved lateral resolution in optical coherence tomography by digital focusing using two-dimensional numerical diffraction method. , 2007, Optics express.

[18]  Adeel Ahmad,et al.  Computational adaptive optics for broadband optical interferometric tomography of biological tissue , 2012, Proceedings of the National Academy of Sciences.

[19]  Zhihua Ding,et al.  Phase-resolved functional optical coherence tomography: simultaneous imaging of in situ tissue structure, blood flow velocity, standard deviation, birefringence, and Stokes vectors in human skin. , 2002, Optics letters.

[20]  P. Artal,et al.  Adaptive-optics ultrahigh-resolution optical coherence tomography. , 2004, Optics letters.