TY - JOUR
T1 - Fast generation of digitally reconstructed radiographs using attenuation fields with application to 2D-3D image registration
AU - Russakoff, Daniel B.
AU - Rohlfing, Torsten
AU - Mori, Kensaku
AU - Rueckert, Daniel
AU - Ho, Anthony
AU - Adler, John R.
AU - Maurer, Calvin R.
N1 - Funding Information:
Manuscript received April 8, 2005; revised July 27, 2005. The work of D. B. Russakoff and C. Maurer was supported in part by the Bio-X Program at Stanford University through the Interdisciplinary Initiatives Program under the Grant “Image-Guided Radiosurgery for the Spine and Lungs.” The work of T. Rohlfing was supported in part by the National Science Foundation (NSF) under Grant EIA-0104114 “Integrating Soft Segmentation with Intensity-Based Matching for 2D/3D Image Data Registration.” The work of K. Mori was supported in part by a Grant-in-Aid for Scientific Research from the Ministry of Education, Culture, Sports, Science, and Technology. Some of the material in this paper was presented at the Medical Imaging 2003 conference and the Second International Workshop on Biomedical Image Registration (WBIR 2003). The Associate Editor responsible for coordinating the review of this paper and recommending its publication was S. Aylward. Asterisk indicates corresponding author.
PY - 2005/11
Y1 - 2005/11
N2 - Generation of digitally reconstructed radiographs (DRRs) is computationally expensive and is typically the rate-limiting step in the execution time of intensity-based two-dimensional to three-dimensional (2D-3D) registration algorithms. We address this computational issue by extending the technique of light field rendering from the computer graphics community. The extension of light fields, which we call attenuation fields (AFs), allows most of the DRR computation to be performed in a preprocessing step; after this precomputation step, DRRs can be generated substantially faster than with conventional ray casting. We derive expressions for the physical sizes of the two planes of an AF necessary to generate DRRs for a given X-ray camera geometry and all possible object motion within a specified range. Because an AF is a ray-based data structure, it is substantially more memory efficient than a huge table of precomputed DRRs because it eliminates the redundancy of replicated rays. Nonetheless, an AF can require substantial memory, which we address by compressing it using vector quantization. We compare DRRs generated using AFs (AF-DRRs) to those generated using ray casting (RC-DRRs) for a typical C-arm geometry and computed tomography images of several anatomic regions. They are quantitatively very similar: the median peak signal-to-noise ratio of AF-DRRs versus RC-DRRs is greater than 43 dB in all cases. We perform intensity-based 2D-3D registration using AF-DRRs and RC-DRRs and evaluate registration accuracy using gold-standard clinical spine image data from four patients. The registration accuracy and robustness of the two methods is virtually identical whereas the execution speed using AF-DRRs is an order of magnitude faster.
AB - Generation of digitally reconstructed radiographs (DRRs) is computationally expensive and is typically the rate-limiting step in the execution time of intensity-based two-dimensional to three-dimensional (2D-3D) registration algorithms. We address this computational issue by extending the technique of light field rendering from the computer graphics community. The extension of light fields, which we call attenuation fields (AFs), allows most of the DRR computation to be performed in a preprocessing step; after this precomputation step, DRRs can be generated substantially faster than with conventional ray casting. We derive expressions for the physical sizes of the two planes of an AF necessary to generate DRRs for a given X-ray camera geometry and all possible object motion within a specified range. Because an AF is a ray-based data structure, it is substantially more memory efficient than a huge table of precomputed DRRs because it eliminates the redundancy of replicated rays. Nonetheless, an AF can require substantial memory, which we address by compressing it using vector quantization. We compare DRRs generated using AFs (AF-DRRs) to those generated using ray casting (RC-DRRs) for a typical C-arm geometry and computed tomography images of several anatomic regions. They are quantitatively very similar: the median peak signal-to-noise ratio of AF-DRRs versus RC-DRRs is greater than 43 dB in all cases. We perform intensity-based 2D-3D registration using AF-DRRs and RC-DRRs and evaluate registration accuracy using gold-standard clinical spine image data from four patients. The registration accuracy and robustness of the two methods is virtually identical whereas the execution speed using AF-DRRs is an order of magnitude faster.
KW - Digitally reconstructed radiographs
KW - Image-guided therapy
KW - Intensity-based 2D-3D image registration
KW - Light fields
UR - http://www.scopus.com/inward/record.url?scp=27744471166&partnerID=8YFLogxK
U2 - 10.1109/TMI.2005.856749
DO - 10.1109/TMI.2005.856749
M3 - Article
C2 - 16279081
AN - SCOPUS:27744471166
SN - 0278-0062
VL - 24
SP - 1441
EP - 1454
JO - IEEE Transactions on Medical Imaging
JF - IEEE Transactions on Medical Imaging
IS - 11
ER -