Contrast enhancement for portal images by combination of subtraction and reprojection processes for Compton scattering

Hariu, Masatsugu; Suda, Yoshihiko; Chang, Weishan; Myojoyama, Atsushi; Saitoh, Hidetoshi

doi:10.1002/acm2.12181

Cited by 5 publications

(3 citation statements)

References 14 publications

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“…Human visual perception is known to be affected the most by contrast changes 16, 17, 24. In this study, CLAHE algorithm was used for contrast enhancement 16, 21, 23.…”

Section: Methodsmentioning

confidence: 99%

Enhancement of megavoltage electronic portal images for markerless tumor tracking

Cheong

Yoon

Park

et al. 2018

J Applied Clin Med Phys

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PurposeThe poor quality of megavoltage (MV) images from electronic portal imaging device (EPID) hinders visual verification of tumor targeting accuracy particularly during markerless tumor tracking. The aim of this study was to investigate the effect of a few representative image processing treatments on visual verification and detection capability of tumors under auto tracking.MethodsImages of QC‐3 quality phantom, a single patient's setup image, and cine images of two‐lung cancer patients were acquired. Three image processing methods were individually employed to the same original images. For each deblurring, contrast enhancement, and denoising, a total variation deconvolution, contrast‐limited adaptive histogram equalization (CLAHE), and median filter were adopted, respectively. To study the effect of image enhancement on tumor auto‐detection, a tumor tracking algorithm was adopted in which the tumor position was determined as the minimum point of the mean of the sum of squared pixel differences (MSSD) between two images. The detectability and accuracy were compared.ResultsDeblurring of a quality phantom image yielded sharper edges, while the contrast‐enhanced image was more readable with improved structural differentiation. Meanwhile, the denoising operation resulted in noise reduction, however, at the cost of sharpness. Based on comparison of pixel value profiles, contrast enhancement outperformed others in image perception. During the tracking experiment, only contrast enhancement resulted in tumor detection in all images using our tracking algorithm. Deblurring failed to determine the target position in two frames out of a total of 75 images. For original and denoised set, target location was not determined for the same five images. Meanwhile, deblurred image showed increased detection accuracy compared with the original set. The denoised image resulted in decreased accuracy. In the case of contrast‐improved set, the tracking accuracy was nearly maintained as that of the original image.ConclusionsConsidering the effect of each processing on tumor tracking and the visual perception in a limited time, contrast enhancement would be the first consideration to visually verify the tracking accuracy of tumors on MV EPID without sacrificing tumor detectability and detection accuracy.

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“…Human visual perception is known to be affected the most by contrast changes 16, 17, 24. In this study, CLAHE algorithm was used for contrast enhancement 16, 21, 23.…”

Section: Methodsmentioning

confidence: 99%

Enhancement of megavoltage electronic portal images for markerless tumor tracking

Cheong

Yoon

Park

et al. 2018

J Applied Clin Med Phys

View full text Add to dashboard Cite

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“…Yip et al 2 attempted to improve the quality of EPID images with a combination of four conventional EPID layers, which made a significant enhancement of tracking accuracy of poorly visible objects. Masatsugu Hariu et al 14 improved the EPID image quality by reducing the Compton scattered photons estimated at each point through the Monte Carlo simulation. Joerg Rottmann 13 uses a design with four detection layers, which improves image quality compared to traditional single-layer EPID.…”

mentioning

confidence: 99%

A new registration algorithm of electronic portal imaging devices images based on the automatic detection of bone edges during radiotherapy

Chen

et al. 2020

Sci Rep

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The precision and efficiency of the registration of megavolt-level electronic portal imaging devices (EPID) images with the naked eye in the orthogonal window are reduced. This study aims to develop a new registration algorithm with enhanced accuracy and efficiency. Ten setup errors with different translation and rotation were simulated with the phantom. For each error, one set of simulated computer tomography images and EPID images were acquired and registered with the traditional and the new method. The traditional method was performed by two senior physicists with the Varian Offline Review software. The new method is basing on the comparison of the precise contours of the same bone structure in the digital reconstruction radiography images and the EPID images, and the contours were fitted with an automatic edge detection algorithm based on gradient images. The average error of the new method was decreased by 44.44%, 28.33%, 49.09% in the translation of X, Y, and Z axes (The traditional vs. the new: X axes, 0.45 mm vs. 0.25 mm; Y axes, 0.75 mm vs. 0.35 mm; Z axes, 0.55 mm vs. 0.28 mm), 42.86% and 40.48% in the rotation of X and Z axes (The traditional vs. the new: X axes, 0.49° vs. 0.28°; Z axes, 0.42° vs. 0.25°), respectively. The average elapsed time in the new method was reduced by 11.14% (The traditional vs. the new: 44 s vs. 39.1 s). The new registration method has significant advantages of accuracy and efficiency compared with the traditional method.

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“…13 An example of approach (3), Hariu et al reduced Compton scattered photons using Monte Carlo simulation to improve the EPID image quality. 14 Moreover, some studies focused on the development of high detective quantum efficiency (DQE) detector configurations, which may improve quality of EPID imaging. As an example, Kairn et al 15 inserted an additional attenuating layer on the surface of the detector to reduce the photon's energy.…”

Section: Related Workmentioning

confidence: 99%

Electronic portal image enhancement based on nonuniformity correction in wavelet domain

et al. 2022

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Electronic portal images are one of the most important tools to verify the ongoing radiotherapy treatment through comparison with a reference image generated during treatment planning. In this procedure, two images are geometrically matched by means of visible bone or other landmarks of interest such as implanted fiducials. However, the intrinsically poor contrast and low spatial resolution of portal images can limit image quality. Methods: In this study, we have provided a multiresolution approach to enhance the quality of portal images acquired from the pelvis treatment fields. The main idea behind this work aims at removing some of the image artifacts that conceal the anatomical information. For this purpose, we have applied the homomorphic filtering on the approximation sub-band of wavelet decomposition to enhance local information. Moreover, in order to sharpen the bone edges, wavelet detail sub-bands were weighted to amplify important image details in the reconstruction of the desired enhanced image. The most appropriate image quality measure was chosen according to the image's characteristics in the spatial domain. By considering the characteristics of portal images as the random and nonperiodic texture, high level of noise, and a nonuniform background, three suitable quality measures of images were assessed:edge content,measure of enhancement, and measure of enhancement by entropy. Results: The higher values of these measures indicate the quality improvement in the processed images through our proposed algorithm. Moreover, the subjective evaluation results indicate that the proposed multiresolution approach significantly enhances the perceived quality of images in comparison with original and the similar approach (p < 0.001). Conclusions: Our proposed wavelet-based enhancement algorithm successfully reduced image intensity nonuniformity and enhanced anatomical featured information, which drastically improved the objective metrics values. Subjective evaluation of enhanced image confirmed this quality improvement.

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Contrast enhancement for portal images by combination of subtraction and reprojection processes for Compton scattering

Cited by 5 publications

References 14 publications

Enhancement of megavoltage electronic portal images for markerless tumor tracking

Enhancement of megavoltage electronic portal images for markerless tumor tracking

A new registration algorithm of electronic portal imaging devices images based on the automatic detection of bone edges during radiotherapy

Electronic portal image enhancement based on nonuniformity correction in wavelet domain

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