SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2944050657> ?p ?o ?g. }

Showing items 1 to 100 of ±140 with 100 items per page.

W2944050657 endingPage "3155" @default.
W2944050657 startingPage "3142" @default.
W2944050657 abstract "Scatter is a major factor degrading the image quality of cone beam computed tomography (CBCT). Conventional scatter correction strategies require handcrafted analytical models with ad hoc assumptions, which often leads to less accurate scatter removal. This study aims to develop an effective scatter correction method using a residual convolutional neural network (CNN).A U-net based 25-layer CNN was constructed for CBCT scatter correction. The establishment of the model consists of three steps: model training, validation, and testing. For model training, a total of 1800 pairs of x-ray projection and the corresponding scatter-only distribution in nonanthropomorphic phantoms taken in full-fan scan were generated using Monte Carlo simulation of a CBCT scanner installed with a proton therapy system. An end-to-end CNN training was implemented with two major loss functions for 100 epochs with a mini-batch size of 10. Image rotations and flips were randomly applied to augment the training datasets during training. For validation, 200 projections of a digital head phantom were collected. The proposed CNN-based method was compared to a conventional projection-domain scatter correction method named fast adaptive scatter kernel superposition (fASKS) method using 360 projections of an anthropomorphic head phantom. Two different loss functions were applied for the same CNN to evaluate the impact of loss functions on the final results. Furthermore, the CNN model trained with full-fan projections was fine-tuned for scatter correction in half-fan scan by using transfer learning with additional 360 half-fan projection pairs of nonanthropomorphic phantoms. The tuned-CNN model for half-fan scan was compared with the fASKS method as well as the CNN-based method without the fine-tuning using additional lung phantom projections.The CNN-based method provides projections with significantly reduced scatter and CBCT images with more accurate Hounsfield Units (HUs) than that of the fASKS-based method. Root mean squared error of the CNN-corrected projections was improved to 0.0862 compared to 0.278 for uncorrected projections or 0.117 for the fASKS-corrected projections. The CNN-corrected reconstruction provided better HU quantification, especially in regions near the air or bone interfaces. All four image quality measures, which include mean absolute error (MAE), mean squared error (MSE), peak signal-to-noise ratio (PSNR), and structural similarity (SSIM), indicated that the CNN-corrected images were significantly better than that of the fASKS-corrected images. Moreover, the proposed transfer learning technique made it possible for the CNN model trained with full-fan projections to be applicable to remove scatters in half-fan projections after fine-tuning with only a small number of additional half-fan training datasets. SSIM value of the tuned-CNN-corrected images was 0.9993 compared to 0.9984 for the non-tuned-CNN-corrected images or 0.9990 for the fASKS-corrected images. Finally, the CNN-based method is computationally efficient - the correction time for the 360 projections only took less than 5 s in the reported experiments on a PC (4.20 GHz Intel Core-i7 CPU) with a single NVIDIA GTX 1070 GPU.The proposed deep learning-based method provides an effective tool for CBCT scatter correction and holds significant value for quantitative imaging and image-guided radiation therapy." @default.
W2944050657 created "2019-05-16" @default.
W2944050657 creator A5020774876 @default.
W2944050657 creator A5025751238 @default.
W2944050657 creator A5036734976 @default.
W2944050657 creator A5072292164 @default.
W2944050657 creator A5081006499 @default.
W2944050657 date "2019-06-05" @default.
W2944050657 modified "2023-10-07" @default.
W2944050657 title "Projection‐domain scatter correction for cone beam computed tomography using a residual convolutional neural network" @default.
W2944050657 cites W1787224781 @default.
W2944050657 cites W1885185971 @default.
W2944050657 cites W1901129140 @default.
W2944050657 cites W1969915038 @default.
W2944050657 cites W1977836277 @default.
W2944050657 cites W1979317673 @default.
W2944050657 cites W1981305020 @default.
W2944050657 cites W1990869665 @default.
W2944050657 cites W2017401048 @default.
W2944050657 cites W2021157360 @default.
W2944050657 cites W2023437508 @default.
W2944050657 cites W2036494829 @default.
W2944050657 cites W2038493543 @default.
W2944050657 cites W2060434533 @default.
W2944050657 cites W2065723520 @default.
W2944050657 cites W2072021306 @default.
W2944050657 cites W2077699569 @default.
W2944050657 cites W2083927153 @default.
W2944050657 cites W2085254266 @default.
W2944050657 cites W2087991208 @default.
W2944050657 cites W2116085429 @default.
W2944050657 cites W2133665775 @default.
W2944050657 cites W2140836580 @default.
W2944050657 cites W2194775991 @default.
W2944050657 cites W2226061686 @default.
W2944050657 cites W2240067561 @default.
W2944050657 cites W2345106543 @default.
W2944050657 cites W2501312908 @default.
W2944050657 cites W2508457857 @default.
W2944050657 cites W2560725027 @default.
W2944050657 cites W2562637781 @default.
W2944050657 cites W2574952845 @default.
W2944050657 cites W2584483805 @default.
W2944050657 cites W2613041730 @default.
W2944050657 cites W2617128058 @default.
W2944050657 cites W2745006834 @default.
W2944050657 cites W2793258843 @default.
W2944050657 cites W2851782922 @default.
W2944050657 cites W2885143776 @default.
W2944050657 cites W2888538030 @default.
W2944050657 cites W2890756907 @default.
W2944050657 cites W2944050657 @default.
W2944050657 cites W2962793481 @default.
W2944050657 cites W2963444790 @default.
W2944050657 cites W2963470893 @default.
W2944050657 cites W3101123465 @default.
W2944050657 doi "https://doi.org/10.1002/mp.13583" @default.
W2944050657 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/6684491" @default.
W2944050657 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/31077390" @default.
W2944050657 hasPublicationYear "2019" @default.
W2944050657 type Work @default.
W2944050657 sameAs 2944050657 @default.
W2944050657 citedByCount "49" @default.
W2944050657 countsByYear W29440506572019 @default.
W2944050657 countsByYear W29440506572020 @default.
W2944050657 countsByYear W29440506572021 @default.
W2944050657 countsByYear W29440506572022 @default.
W2944050657 countsByYear W29440506572023 @default.
W2944050657 crossrefType "journal-article" @default.
W2944050657 hasAuthorship W2944050657A5020774876 @default.
W2944050657 hasAuthorship W2944050657A5025751238 @default.
W2944050657 hasAuthorship W2944050657A5036734976 @default.
W2944050657 hasAuthorship W2944050657A5072292164 @default.
W2944050657 hasAuthorship W2944050657A5081006499 @default.
W2944050657 hasBestOaLocation W29440506572 @default.
W2944050657 hasConcept C104293457 @default.
W2944050657 hasConcept C105795698 @default.
W2944050657 hasConcept C11413529 @default.
W2944050657 hasConcept C114614502 @default.
W2944050657 hasConcept C120665830 @default.
W2944050657 hasConcept C121332964 @default.
W2944050657 hasConcept C126838900 @default.
W2944050657 hasConcept C154945302 @default.
W2944050657 hasConcept C155512373 @default.
W2944050657 hasConcept C19499675 @default.
W2944050657 hasConcept C2779751349 @default.
W2944050657 hasConcept C2779813781 @default.
W2944050657 hasConcept C31972630 @default.
W2944050657 hasConcept C33923547 @default.
W2944050657 hasConcept C41008148 @default.
W2944050657 hasConcept C544519230 @default.
W2944050657 hasConcept C57493831 @default.
W2944050657 hasConcept C71924100 @default.
W2944050657 hasConcept C74193536 @default.
W2944050657 hasConcept C81363708 @default.
W2944050657 hasConceptScore W2944050657C104293457 @default.
W2944050657 hasConceptScore W2944050657C105795698 @default.
W2944050657 hasConceptScore W2944050657C11413529 @default.