Parallelized multi–graphics processing unit framework for high-speed Gabor-domain optical coherence microscopy

Abstract. Gabor-domain optical coherence microscopy (GD-OCM) is a volumetric high-resolution technique capable of acquiring three-dimensional (3-D) skin images with histological resolution. Real-time image processing is needed to enable GD-OCM imaging in a clinical setting. We present a parallelized and scalable multi-graphics processing unit (GPU) computing framework for real-time GD-OCM image processing. A parallelized control mechanism was developed to individually assign computation tasks to each of the GPUs. For each GPU, the optimal number of amplitude-scans (A-scans) to be processed in parallel was selected to maximize GPU memory usage and core throughput. We investigated five computing architectures for computational speed-up in processing 1000×1000 A-scans. The proposed parallelized multi-GPU computing framework enables processing at a computational speed faster than the GD-OCM image acquisition, thereby facilitating high-speed GD-OCM imaging in a clinical setting. Using two parallelized GPUs, the image processing of a 1×1×0.6  mm3 skin sample was performed in about 13 s, and the performance was benchmarked at 6.5 s with four GPUs. This work thus demonstrates that 3-D GD-OCM data may be displayed in real-time to the examiner using parallelized GPU processing.

[1]  Yugang Min,et al.  A multi-GPU real-time dose simulation software framework for lung radiotherapy , 2012, International Journal of Computer Assisted Radiology and Surgery.

[2]  P Altmeyer,et al.  Histomorphologic correlation with routine histology and optical coherence tomography , 2004, Skin research and technology : official journal of International Society for Bioengineering and the Skin (ISBS) [and] International Society for Digital Imaging of Skin (ISDIS) [and] International Society for Skin Imaging.

[3]  Jeehyun Kim,et al.  Simple Spectral Calibration Method and Its Application Using an Index Array for Swept Source Optical Coherence Tomography , 2011 .

[4]  J G Fujimoto,et al.  High-resolution optical coherence microscopy for high-speed, in vivo cellular imaging. , 2003, Optics letters.

[5]  S Meeks,et al.  SU-E-J-73: Effect of 4D-CT Image Artifacts On the 3D Lung Registration Accuracy: A Parametric Study Using a GPU-Accelerated Multi-Resolution Multi-Level Optical Flow. , 2013, Medical physics.

[6]  Adrian Mariampillai,et al.  Real-time speckle variance swept-source optical coherence tomography using a graphics processing unit , 2012, Biomedical optics express.

[7]  Sheila MacNeil,et al.  Evaluating the use of optical coherence tomography for the detection of epithelial cancers in vitro. , 2011, Journal of biomedical optics.

[8]  Kang Zhang,et al.  Real-time numerical dispersion compensation using graphics processing unit for Fourier-domain optical coherence tomography , 2011 .

[9]  Eric Clarkson,et al.  Dispersion control with a Fourier-domain optical delay line in a fiber-optic imaging interferometer. , 2005, Applied optics.

[10]  Panomsak Meemon,et al.  Assessment of a liquid lens enabled in vivo optical coherence microscope. , 2010, Applied optics.

[11]  Thilo Gambichler,et al.  In vivo optical coherence tomography of basal cell carcinoma. , 2007, Journal of dermatological science.

[12]  Vrushali R. Korde,et al.  Using optical coherence tomography to evaluate skin sun damage and precancer , 2007, Lasers in surgery and medicine.

[13]  Kevin P Thompson,et al.  Broadband astigmatism-corrected Czerny-Turner spectrometer. , 2010, Optics express.

[14]  Adrian Bradu,et al.  Gabor fusion technique in a Talbot bands optical coherence tomography system. , 2012, Optics express.

[15]  Zhihua Ding,et al.  High-resolution optical coherence tomography over a large depth range with an axicon lens. , 2002, Optics letters.

[16]  Jin U. Kang,et al.  Real-time three-dimensional Fourier-domain optical coherence tomography video image guided microsurgeries. , 2012, Journal of biomedical optics.

[17]  R. Jain,et al.  Cancer imaging by optical coherence tomography: preclinical progress and clinical potential , 2012, Nature Reviews Cancer.

[18]  Jin U. Kang,et al.  Motion-compensated hand-held common-path Fourier-domain optical coherence tomography probe for image-guided intervention , 2012, Biomedical optics express.

[19]  Jin U. Kang,et al.  Real-time 3D and 4D Fourier domain Doppler optical coherence tomography based on dual graphics processing units , 2012, Biomedical optics express.

[20]  B. Wong,et al.  Optical Coherence Tomography of Laryngeal Cancer , 2006, The Laryngoscope.

[21]  Eitan Grinspun,et al.  Sparse matrix solvers on the GPU: conjugate gradients and multigrid , 2003, SIGGRAPH Courses.

[22]  J. Schmitt,et al.  Correlation of Thickness of Basal Cell Carcinoma by Optical Coherence Tomography In Vivo and Routine Histologic Findings: A Pilot Study , 2007, Dermatologic surgery : official publication for American Society for Dermatologic Surgery [et al.].

[23]  Zhongping Chen,et al.  Noninvasive imaging of oral premalignancy and malignancy. , 2005, Journal of biomedical optics.

[24]  Kang Zhang,et al.  Graphics processing unit accelerated non-uniform fast Fourier transform for ultrahigh-speed, real-time Fourier-domain OCT , 2010, Optics express.

[25]  Rüdiger Westermann,et al.  Linear algebra operators for GPU implementation of numerical algorithms , 2003, SIGGRAPH Courses.

[26]  G. Mckenzie,et al.  Optical Coherence Tomography Used as a Modality to Delineate Basal Cell Carcinoma prior to Mohs Micrographic Surgery , 2011, Case Reports in Dermatology.

[27]  R. Leitgeb,et al.  Extended focus high-speed swept source OCT with self-reconstructive illumination. , 2011, Optics express.

[28]  Barry Cense,et al.  Advances in optical coherence tomography imaging for dermatology. , 2004, The Journal of investigative dermatology.

[29]  Takashi Tanaka,et al.  Computer generated holography using a graphics processing unit. , 2006, Optics express.

[30]  Jing Xu,et al.  Performance and scalability of Fourier domain optical coherence tomography acceleration using graphics processing units. , 2011, Applied optics.

[31]  Kate Sugden,et al.  Processing and rendering of Fourier domain optical coherence tomography images at a line rate over 524 kHz using a graphics processing unit. , 2011, Journal of biomedical optics.

[32]  Zeev Zalevsky,et al.  Improved extended depth of focus full field spectral domain Optical Coherence Tomography , 2010 .

[33]  D. D. de Bruin,et al.  Optical biopsy of epithelial cancers by optical coherence tomography (OCT) , 2013, Lasers in Medical Science.

[34]  Alan W. Greynolds Multi-core and GPU accelerated simulation of a radial star target imaged with equivalent t-number circular and Gaussian pupils , 2013, Optics & Photonics - Optical Engineering + Applications.

[35]  Kevin Wong,et al.  Graphics processing unit accelerated optical coherence tomography processing at megahertz axial scan rate and high resolution video rate volumetric rendering , 2013, Journal of biomedical optics.

[36]  Yugang Min,et al.  A GPU-based framework for modeling real-time 3D lung tumor conformal dosimetry with subject-specific lung tumor motion. , 2010, Physics in medicine and biology.

[37]  Christian M. Oh,et al.  GPU accelerated real-time multi-functional spectral-domain optical coherence tomography system at 1300nm , 2012, Optics express.

[38]  Boris Povazay,et al.  Multispectral in vivo three-dimensional optical coherence tomography of human skin. , 2010, Journal of biomedical optics.

[39]  Randima Fernando,et al.  GPU Gems: Programming Techniques, Tips and Tricks for Real-Time Graphics , 2004 .

[40]  Jeehyun Kim,et al.  Ultra-Fast Displaying Spectral Domain Optical Doppler Tomography System Using a Graphics Processing Unit , 2012, Sensors.

[41]  Peter Koch,et al.  Holoscopy--holographic optical coherence tomography. , 2011, Optics letters.

[42]  T. Höller,et al.  Preoperative characterization of basal cell carcinoma comparing tumour thickness measurement by optical coherence tomography, 20-MHz ultrasound and histopathology. , 2012, Acta dermato-venereologica.

[43]  P. Andersen,et al.  OCT imaging of skin cancer and other dermatological diseases , 2009, Journal of biophotonics.

[44]  Suhwan Kim,et al.  High Speed SD-OCT System Using GPU Accelerated Mode for in vivo Human Eye Imaging , 2013 .

[45]  Jannick P Rolland,et al.  Bessel beam spectral-domain high-resolution optical coherence tomography with micro-optic axicon providing extended focusing range. , 2008, Optics letters.

[46]  Edmund Koch,et al.  An advanced algorithm for dispersion encoded full range frequency domain optical coherence tomography. , 2012, Optics express.

[47]  Kazuhiro Sasaki,et al.  Extended depth of focus adaptive optics spectral domain optical coherence tomography , 2012, Biomedical optics express.

[48]  Mark Oskin,et al.  Using modern graphics architectures for general-purpose computing: a framework and analysis , 2002, MICRO 35.

[49]  Eva Lankenau,et al.  OCT in Dermatology , 2008 .

[50]  Panomsak Meemon,et al.  Gabor-based fusion technique for Optical Coherence Microscopy. , 2010, Optics express.

[51]  Yuuki Watanabe,et al.  Real-time processing for full-range Fourier-domain optical-coherence tomography with zero-filling interpolation using multiple graphic processing units. , 2010, Applied optics.

[52]  Kang Zhang,et al.  Real-time intraoperative 4D full-range FD-OCT based on the dual graphics processing units architecture for microsurgery guidance , 2011, Biomedical optics express.

[53]  Panomsak Meemon,et al.  Cellular resolution optical coherence microscopy with high acquisition speed for in-vivo human skin volumetric imaging. , 2011, Optics letters.

[54]  Supraja Murali,et al.  Three-dimensional adaptive microscopy using embedded liquid lens. , 2009, Optics letters.

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

[56]  J. Fujimoto,et al.  In vivo ultrahigh-resolution optical coherence tomography. , 1999, Optics letters.

[57]  Jeehyun Kim,et al.  Full-range k-domain linearization in spectral-domain optical coherence tomography. , 2011, Applied optics.

[58]  Adrian Bradu,et al.  Real-time resampling in Fourier domain optical coherence tomography using a graphics processing unit. , 2010, Journal of biomedical optics.

[59]  Iwona Gorczynska,et al.  Four-dimensional structural and Doppler optical coherence tomography imaging on graphics processing units , 2012, Journal of biomedical optics.

[60]  P. Meemon,et al.  Gabor domain optical coherence microscopy , 2008, BiOS.

[61]  Jin U. Kang,et al.  Real-time reference A-line subtraction and saturation artifact removal using graphics processing unit for high-frame-rate Fourier-domain optical coherence tomography video imaging , 2012 .

[62]  Zhilin Hu,et al.  Fourier domain optical coherence tomography with a linear-in-wavenumber spectrometer. , 2007, Optics letters.

[63]  Adrian Gh. Podoleanu,et al.  Direct electronic linearization for camera based spectral domain optical coherence tomography , 2013, Photonics West - Biomedical Optics.

[64]  V. Michael Bove,et al.  Real-time holographic video images with commodity PC hardware , 2005, IS&T/SPIE Electronic Imaging.

[65]  R. Steiner,et al.  Optical Coherence Tomography: Clinical Applications in Dermatology , 2003 .