A Leaning-Based Method to Improve Cone Beam CT Image Quality for Adaptive Radiation Therapy

Yang, Xiaofeng; Lei, Yang; Higgins, Kristin; Dong, Xue; Liu, T.; Dhabaan, Anees; Elder, Eric; Tang, Xiangyang

doi:10.1016/j.ijrobp.2017.06.550

Cited by 8 publications

(7 citation statements)

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“…Alternating Regression Forest (ARF) is used in this study in training the regression model. Recent studies showed the efficacy of random forest in tackling medical image processing 25,29,32 . Classical random forest trains a bag of binary decision trees each of which is provided with a random subset of training data and trained independently from the others.…”

Section: Methodsmentioning

confidence: 99%

“…Recently, we developed a novel machine-learning based method to further improve CBCT image quality such that they are comparable to that of pCTs for potential application to CBCT-guided adaptive radiotherapy. 1,25,26 By building a set of paired training images of pCT and CBCT and using the pCT as the learning target, the image quality of CBCT was improved significantly through a learning process. Compared with existing methods, our method not only mitigates non-uniform and streaking artifacts, but also restores true HU values on CBCT images such that the CBCT images after correction share the same calibration as pCTs for dose calculation.…”

Section: Introductionmentioning

confidence: 99%

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Dosimetric study on learning-based cone-beam CT correction in adaptive radiation therapy

et al. 2019

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Introduction: Cone-beam CT (CBCT) image quality is important for its quantitative analysis in adaptive radiation therapy. However, due to severe artifacts, the CBCTs are primarily used for verifying patient setup only so far. We have developed a learning-based image quality improvement method which could provide CBCTs with image quality comparable to planning CTs (pCTs). The accuracy of dose calculations based on these CBCTs is unknown. In this study, we aim to investigate the dosimetric accuracy of our corrected CBCT (CCBCT) in brain stereotactic radiosurgery (SRS) and pelvic radiotherapy. Materials and Methods: We retrospectively investigated a total of 32 treatment plans from 22 patients, each of whom with both original treatment pCTs and CBCTs acquired during treatment setup. The CCBCT and original CBCT (OCBCT) were registered to the pCT for generating CCBCT-based and OCBCT-based treatment plans. The original pCT-based plans served as ground truth. Clinically-relevant dose volume histogram (DVH) metrics were extracted from the ground truth, OCBCT-based and CCBCT-based plans for comparison. Gamma analysis was also performed to compare the absorbed dose distributions between the pCT-based and OCBCT/ CCBCT-based plans of each patient. Results: CCBCTs demonstrated better image contrast and more accurate HU ranges when compared side-by-side with OCBCTs. For pelvic radiotherapy plans, the mean dose error in DVH metrics for PTV, bladder and rectum was significantly reduced, from 1% to 0.3%, after CBCT correction. The gamma analysis showed the average pass rate increased from 94.5% before correction to 99.0% after correction. For brain SRS treatment plans, both original and corrected CBCT images were accurate enough for dose calculation, though CCBCT featured higher image quality.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dosimetric study on learning-based cone-beam CT correction in adaptive radiation therapy

et al. 2019

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“…We test the parameter

μ

from 0.1 to 1.0 by 4‐fold cross‐validation, the performance is stable when

μ

= 0.5.

λ

is a balancing parameter in computing the information gain, and is designed based on its performance on balancing the information energy of CT target and MR features . In fact the MR features’ length is much bigger than CT target, which means the MR features have more information energy than CT target.…”

Section: Resultsmentioning

confidence: 99%

“…61 We test the parameter l from 0.1 to 1.0 by 4fold cross-validation, the performance is stable when l = 0.5. k is a balancing parameter in computing the information gain, and is designed based on its performance on balancing the information energy of CT target and MR features. 62 In fact the MR features' length is much bigger than CT target, which means the MR features have more information energy than CT target. Thus, k should be very small, and we set it to 0.05. c is also a balancing parameter to balance the information gain and global loss in optimization of splitting procedure of each decision tree.…”

Section: B Parameter Performancementioning

confidence: 99%

Learning‐based CBCT correction using alternating random forest based on auto‐context model

et al. 2018

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Purpose Quantitative Cone Beam CT (CBCT) imaging is increasing in demand for precise image‐guided radiotherapy because it provides a foundation for advanced image‐guided techniques, including accurate treatment setup, online tumor delineation, and patient dose calculation. However, CBCT is currently limited only to patient setup in the clinic because of the severe issues in its image quality. In this study, we develop a learning‐based approach to improve CBCT's image quality for extended clinical applications. Materials and methods An auto‐context model is integrated into a machine learning framework to iteratively generate corrected CBCT (CCBCT) with high‐image quality. The first step is data preprocessing for the built training dataset, in which uninformative image regions are removed, noise is reduced, and CT and CBCT images are aligned. After a CBCT image is divided into a set of patches, the most informative and salient anatomical features are extracted to train random forests. Within each patch, alternating RF is applied to create a CCBCT patch as the output. Moreover, an iterative refinement strategy is exercised to enhance the image quality of CCBCT. Then, all the CCBCT patches are integrated to reconstruct final CCBCT images. Results The learning‐based CBCT correction algorithm was evaluated using the leave‐one‐out cross‐validation method applied on a cohort of 12 patients’ brain data and 14 patients’ pelvis data. The mean absolute error (MAE), peak signal‐to‐noise ratio (PSNR), normalized cross‐correlation (NCC) indexes, and spatial nonuniformity (SNU) in the selected regions of interest (ROIs) were used to quantify the proposed algorithm's correction accuracy and generat the following results: mean MAE = 12.81 ± 2.04 and 19.94 ± 5.44 HU, mean PSNR = 40.22 ± 3.70 and 31.31 ± 2.85 dB, mean NCC = 0.98 ± 0.02 and 0.95 ± 0.01, and SNU = 2.07 ± 3.36% and 2.07 ± 3.36% for brain and pelvis data. Conclusion Preliminary results demonstrated that the novel learning‐based correction method can significantly improve CBCT image quality. Hence, the proposed algorithm is of great potential in improving CBCT's image quality to support its clinical utility in CBCT‐guided adaptive radiotherapy.

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“…Quantitative cone-beam CT (CBCT) imaging is on increasing demand for precise image guided radiation therapy since it provides a foundation for advanced image-guidance techniques, including accurate treatment setup, online tumor delineation and patient dose calculation (1, 2). With more precise treatment monitoring from accurate CBCT images, dose delivery errors can be significantly reduced in each fraction and further compensated for in subsequent fractions using adaptive radiation therapy (3-5). However, the current CBCT imaging has severe artifacts and its current clinical application is therefore limited to patient setup based on only bony structures.…”

Section: Introductionmentioning

confidence: 99%

Improving image quality of cone-beam CT using alternating regression forest

Lei

Tang

Higgins

et al. 2018

Medical Imaging 2018: Physics of Medical Imaging

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We propose a CBCT image quality improvement method based on anatomic signature and auto-context alternating regression forest. Patient-specific anatomical features are extracted from the aligned training images and served as signatures for each voxel. The most relevant and informative features are identified to train regression forest. The well-trained regression forest is used to correct the CBCT of a new patient. This proposed algorithm was evaluated using 10 patients’ data with CBCT and CT images. The mean absolute error (MAE), peak signal-to-noise ratio (PSNR) and normalized cross correlation (NCC) indexes were used to quantify the correction accuracy of the proposed algorithm. The mean MAE, PSNR and NCC between corrected CBCT and ground truth CT were 16.66HU, 37.28dB and 0.98, which demonstrated the CBCT correction accuracy of the proposed learning-based method. We have developed a learning-based method and demonstrated that this method could significantly improve CBCT image quality. The proposed method has great potential in improving CBCT image quality to a level close to planning CT, therefore, allowing its quantitative use in CBCT-guided adaptive radiotherapy.

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A Leaning-Based Method to Improve Cone Beam CT Image Quality for Adaptive Radiation Therapy

Cited by 8 publications

References 0 publications

Dosimetric study on learning-based cone-beam CT correction in adaptive radiation therapy

Dosimetric study on learning-based cone-beam CT correction in adaptive radiation therapy

Learning‐based CBCT correction using alternating random forest based on auto‐context model

Improving image quality of cone-beam CT using alternating regression forest

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