Medical image segmentation on GPUs – A comprehensive review

Smistad, Erik; Falch, Thomas L.; Bozorgi, Mohammadmehdi; Elster, Anne C.; Lindseth, Frank

doi:10.1016/j.media.2014.10.012

Cited by 246 publications

(177 citation statements)

References 69 publications

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“…This article mentioned few GPU based image processing registration and segmentation. Smistad et al, presented a review about medical image segmentation on GPU [13]. They gave some basics of CUDA model and explain various segmentation methods like thresholding, region growing, watershed and active contours on GPU.…”

Section: Related Workmentioning

confidence: 99%

Performance of Medical Image Processing Algorithms Implemented in CUDA running on GPU based Machine

Kalaiselvi¹,

Sriramakrishnan²,

Somasundaram³

2018

IJISA

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Abstract-This paper illustrates the design and performance evaluation of few algorithms used for analysing the medical image volumes on the massive parallel graphics processing unit (GPU) with compute unified device architecture (CUDA). These algorithms are selected from the general framework, devised for computer aided diagnostic (CAD) system. The CAD system used for analysing large medical image datasets are usually a pipeline processing that includes a variety of image processing operations. A MRI scanner captures the 3D human head into a series of 2D images. Considerable time spent in pre and post processing of these images. Noise filters, segmentation, image diffusion and enhancement are few such methods. The algorithms are chosen for study requires local information, available in few pixels or global information available in the entire image. These problems are best candidates for GPU implementation, since the parallelism is naturally provided by the proposed Per-Pixel Threading (PPT) or Per-Slice Threading (PST) operations. In this paper implement the algorithms for adaptive filtering, anisotropic diffusion, bilateral filtering, non-local means (NLM) filtering, K-Means segmentation and feature extraction in 1536 core's NVIDIA GPU and estimated the speed up gained. Our experiments show that the GPU based implementation achieved typical speedup values in the range of 3-338 times compared to conventional central processing unit (CPU) processor in PPT model and up to 30 times in PST model.

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Section: Related Workmentioning

confidence: 99%

Performance of Medical Image Processing Algorithms Implemented in CUDA running on GPU based Machine

Kalaiselvi¹,

Sriramakrishnan²,

Somasundaram³

2018

IJISA

View full text Add to dashboard Cite

show abstract

“…Graphics processing unit (GPU) technology is proposed for medical image segmentation (Smistad et al, 2015), or deformable models using spring-mass-damper or tensor-mass methods (Rasmusson et al, 2008) as well as implicit FE (Cecka et al, 2011;Wong et al, 2015). The Total Lagrangian Explicit Dynamic FE algorithm (TLED) (Miller et al, 2007) fits the GPU programming model well given: (1) most element and nodal operations are pleasingly parallel (independent of one another), and (2) memory requirements are very low.…”

Section: Gpu-accelerated Explicit Fe Analysismentioning

confidence: 99%

Rupture risk in abdominal aortic aneurysms: A realistic assessment of the explicit GPU approach

Štrbac

Pierce

Rodríguez-Vila

et al. 2017

Journal of Biomechanics

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Accurate estimation of peak wall stress (PWS) is the crux of biomechanically motivated rupture risk assessment for abdominal aortic aneurysms aimed to improve clinical outcomes. Such assessments often use the finite element (FE) method to obtain PWS, albeit at a high computational cost, motivating simplifications in material or element formulations. These simplifications, while useful, come at a cost of reliability and accuracy. We achieve research-standard accuracy and maintain clinically applicable speeds by using novel computational technologies. We present a solution using our custom finite element code based on graphics processing unit (GPU) technology that is able to account for added complexities involved with more physiologically relevant solutions, e.g. strong anisotropy and heterogeneity. We present solutions up to 17x faster relative to an established finite element code using state-of-the-art nonlinear, anisotropic and nearly-incompressible material descriptions. We show a realistic assessment of the explicit GPU FE approach by using complex problem geometry, biofidelic material law, doubleprecision floating point computation and full element integration. Due to the increased solution speed without loss of accuracy, shown on five clinical cases of abdominal aortic aneurysms, the method shows promise for clinical use in determining rupture risk of abdominal aortic aneurysms.

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“…However, envelope detection on CPU can be a time-consuming process. To accelerate the computation, parallel GPUs, especially the GPGPU for general purpose computing on GPU, have been used in many fields including machine learning and medical image processing [21,22].…”

Section: Discussionmentioning

confidence: 99%

Real-time envelope detection of ultrasound radiofrequency signals using OpenCV GPU framework

Zhou¹,

Wang²,

Shuicai³

et al. 2017

Med Devices Diagn Eng

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Medical image segmentation on GPUs – A comprehensive review

Cited by 246 publications

References 69 publications

Performance of Medical Image Processing Algorithms Implemented in CUDA running on GPU based Machine

Performance of Medical Image Processing Algorithms Implemented in CUDA running on GPU based Machine

Rupture risk in abdominal aortic aneurysms: A realistic assessment of the explicit GPU approach

Real-time envelope detection of ultrasound radiofrequency signals using OpenCV GPU framework

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