Multi-Atlas-Based Segmentation of Pelvic Structures from CT Scans for Planning in Prostate Cancer Radiotherapy

Acosta, Oscar; Dowling, Jason; Dréan, Gwenola Le; Simon, Antoine; Crevoisier, R. de; Haigron, Pascal

doi:10.1007/978-1-4614-8498-1_24

Cited by 30 publications

(53 citation statements)

References 57 publications

(61 reference statements)

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“…Outside brain imaging, the prevalence of prostate cancer in men has sparked interest in applications within prostate imaging, using modalities such as MRI (Langerak et al, 2010; Litjens et al, 2014; Rivest-Hénault et al, 2014), CT (Acosta et al, 2011; Sjöberg et al, 2013; Acosta et al, 2014) and ultrasound (Nouranian et al, 2014). Likewise, interest in radiotherapy treatment planning has been the main driver of applications in head, neck, and thoracic CT segmentation (Han et al, 2008; Wang et al, 2014c), which have mainly focused on segmenting tumors (Ramus and Malandain, 2010), organs at risk (e.g, the parotid glands, Fritscher et al 2014; Gorthi et al 2010; Han et al 2010; Hollensen et al 2010; Yang et al 2010 or mediastinal lymph nodes, Liu et al 2014) and lymph node metastases (Sjöberg et al, 2013; Teng et al, 2010).…”

Section: Survey Of Applicationsmentioning

confidence: 99%

Multi-atlas segmentation of biomedical images: A survey

Iglesias

Sabuncu

2015

Medical Image Analysis

578

457

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Multi-atlas segmentation (MAS), first introduced and popularized by the pioneering work of Rohlfing, Brandt, Menzel and Maurer Jr (2004), Klein, Mensh, Ghosh, Tourville and Hirsch (2005), and Heckemann, Hajnal, Aljabar, Rueckert and Hammers (2006), is becoming one of the most widely-used and successful image segmentation techniques in biomedical applications. By manipulating and utilizing the entire dataset of “atlases” (training images that have been previously labeled, e.g., manually by an expert), rather than some model-based average representation, MAS has the flexibility to better capture anatomical variation, thus offering superior segmentation accuracy. This benefit, however, typically comes at a high computational cost. Recent advancements in computer hardware and image processing software have been instrumental in addressing this challenge and facilitated the wide adoption of MAS. Today, MAS has come a long way and the approach includes a wide array of sophisticated algorithms that employ ideas from machine learning, probabilistic modeling, optimization, and computer vision, among other fields. This paper presents a survey of published MAS algorithms and studies that have applied these methods to various biomedical problems. In writing this survey, we have three distinct aims. Our primary goal is to document how MAS was originally conceived, later evolved, and now relates to alternative methods. Second, this paper is intended to be a detailed reference of past research activity in MAS, which now spans over a decade (2003 – 2014) and entails novel methodological developments and application-specific solutions. Finally, our goal is to also present a perspective on the future of MAS, which, we believe, will be one of the dominant approaches in biomedical image segmentation.

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Section: Survey Of Applicationsmentioning

confidence: 99%

Multi-atlas segmentation of biomedical images: A survey

Iglesias

Sabuncu

2015

Medical Image Analysis

578

457

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“…As shown in figure A2(Supplemental material), more similar atlas yields a better segmentations if only one single atlas was used for segmentation . Then, adding multiple atlases improves the accuracy when fusing labels from the closest atlas [29]. Other global or local features based on CT intensity or shape descriptors may have been proposed (mutual information, cross correlation, SPHARM, etc.…”

Section: Discussionmentioning

confidence: 99%

“…This allows to overcome the interindividual variability and registration issues. Previous works have shown the benefits of combining multiple atlases in improving segmentation accuracy [20,22,23,[27][28][29].…”

Section: Introductionmentioning

confidence: 99%

Multi-atlas-based segmentation of prostatic urethra from planning CT imaging to quantify dose distribution in prostate cancer radiotherapy

Acosta

Mylona

Dain

et al. 2017

Radiotherapy and Oncology

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“…CT accurately outlines the bone, some soft tissue and blood vessels inside body; it is geometrically accurate, with short scan times and high resolution. CT fails to characterize tissue, transverse slices and there is a restriction on intensity of X-rays for short scan times and lastly the radiation can be harmful and not recommended for patients diagnosed with cancer or pregnant women [12,23].…”

Section: Biomedical Imaging Techniquesmentioning

confidence: 99%

“…CT is also used in radiation therapy and planning prostate cancer radiotherapy [7,11]. The latest research trends in CT are in areas of registration, segmentation of veins, tumors in brain, lesion in liver, aorta, prostrate, reconstruction of CT images, generation of 3D CT images, superposition of cone-based CT images and generation of synthetic 4D CT images for image guided surgery [4,[12][13][14][15][16][17][18][19][20][21][22]. CT accurately outlines the bone, some soft tissue and blood vessels inside body; it is geometrically accurate, with short scan times and high resolution.…”

Section: Biomedical Imaging Techniquesmentioning

confidence: 99%

Advances in Biomedical Imaging and Image Fusion

Chandrashekar¹,

Sreedevi²

2018

IJCA

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Biomedical imaging is a series of procedures which create images of the human body, or parts of the body, to help screen for possible illness or injury, diagnose the likely cause of symptoms and monitor health conditions or the effects of treatment. The objective of the paper is to provide an overview about various bio medical imaging techniques used in detection and diagnosis of Cancer. Each of these imaging techniques provides information about the anatomy, chemical or physiologic phenomena of the human body which are studied independently by doctors to identify Cancer. The biomedical imaging systems, applications, benefits, drawbacks and research challenges are discussed. Image Fusion and its role in Bio medical imaging is also discussed. Image Fusion is the process of fusing two or more bio medical images which contain complementary information into a single composite image. These enrich image quality and avoid redundancy thereby increase the clinical applicability of medical images for cancer detection, prognosis and treatment planning of Cancer.

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Multi-Atlas-Based Segmentation of Pelvic Structures from CT Scans for Planning in Prostate Cancer Radiotherapy

Cited by 30 publications

References 57 publications

Multi-atlas segmentation of biomedical images: A survey

Multi-atlas segmentation of biomedical images: A survey

Multi-atlas-based segmentation of prostatic urethra from planning CT imaging to quantify dose distribution in prostate cancer radiotherapy

Advances in Biomedical Imaging and Image Fusion

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