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Evaluation of current algorithms for segmentation of scar tissue from late Gadolinium enhancement cardiovascular magnetic resonance of the left atrium: An open-access grand challenge
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نویسنده
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karim r. ,housden r.j. ,balasubramaniam m. ,chen z. ,perry d. ,uddin a. ,al-beyatti y. ,palkhi e. ,acheampong p. ,obom s. ,hennemuth a. ,lu y. ,bai w. ,shi w. ,gao y. ,peitgen h.-o. ,radau p. ,razavi r. ,tannenbaum a. ,rueckert d. ,cates j. ,schaeffter t. ,peters d. ,macleod r. ,rhode k.
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منبع
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journal of cardiovascular magnetic resonance - 2013 - دوره : 15 - شماره : 1
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چکیده
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Background: late gadolinium enhancement (lge) cardiovascular magnetic resonance (cmr) imaging can be used to visualise regions of fibrosis and scarring in the left atrium (la) myocardium. this can be important for treatment stratification of patients with atrial fibrillation (af) and for assessment of treatment after radio frequency catheter ablation (rfca). in this paper we present a standardised evaluation benchmarking framework for algorithms segmenting fibrosis and scar from lge cmr images. the algorithms reported are the response to an open challenge that was put to the medical imaging community through an isbi (ieee international symposium on biomedical imaging) workshop. methods. the image database consisted of 60 multicenter,multivendor lge cmr image datasets from patients with af,with 30 images taken before and 30 after rfca for the treatment of af. a reference standard for scar and fibrosis was established by merging manual segmentations from three observers. furthermore,scar was also quantified using 2,3 and 4 standard deviations (sd) and full-width-at-half-maximum (fwhm) methods. seven institutions responded to the challenge: imperial college (ic),mevis fraunhofer (mv),sunnybrook health sciences (sy),harvard/boston university (hb),yale school of medicine (yl),king's college london (kcl) and utah carma (uta,utb). there were 8 different algorithms evaluated in this study. results: some algorithms were able to perform significantly better than sd and fwhm methods in both pre- and post-ablation imaging. segmentation in pre-ablation images was challenging and good correlation with the reference standard was found in post-ablation images. overlap scores (out of 100) with the reference standard were as follows: pre: ic = 37,mv = 22,sy = 17,yl = 48,kcl = 30,uta = 42,utb = 45; post: ic = 76,mv = 85,sy = 73,hb = 76,yl = 84,kcl = 78,uta = 78,utb = 72. conclusions: the study concludes that currently no algorithm is deemed clearly better than others. there is scope for further algorithmic developments in la fibrosis and scar quantification from lge cmr images. benchmarking of future scar segmentation algorithms is thus important. the proposed benchmarking framework is made available as open-source and new participants can evaluate their algorithms via a web-based interface. © 2013 karim et al.; licensee biomed central ltd.
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کلیدواژه
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Algorithm benchmarking; Atrial fibrillation; Cardiovascular magnetic resonance; Late gadolinium enhancement; Segmentation
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آدرس
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department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom, department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom, department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom, department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom, utah center for advanced imaging research,university of utah,salt lake city,ut, United States, department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom, department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom, department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom, department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom, department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom, fraunhofer institute for medical image computing,fraunhofer mevis,bremen, Germany, imaging research,sunnybrook health sciences centre,toronto, Canada, department of computing,imperial college london,london, United Kingdom, department of computing,imperial college london,london, United Kingdom, psychiatry neuroimaging lab,harvard medical school,boston, United States, fraunhofer institute for medical image computing,fraunhofer mevis,bremen, Germany, imaging research,sunnybrook health sciences centre,toronto, Canada, department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom, school of electrical and computer engineering,boston university,boston, United States, department of computing,imperial college london,london, United Kingdom, utah center for advanced imaging research,university of utah,salt lake city,ut, United States, department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom, magnetic resonance research centre,yale school of medicine,yale university,new haven,united states,beth israel deaconess medical center,harvard medical school,boston, United States, utah center for advanced imaging research,university of utah,salt lake city,ut, United States, department of imaging sciences and biomedical engineering,king's college london,london, United Kingdom
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