Keyword search (4,164 papers available)

"Segmentation" Keyword-tagged Publications:

Title Authors PubMed ID
1 Towards user-centered interactive medical image segmentation in VR with an assistive AI agent Spiegler P; Harirpoush A; Xiao Y; 41509996
ENCS
2 MedCLIP-SAMv2: Towards universal text-driven medical image segmentation Koleilat T; Asgariandehkordi H; Rivaz H; Xiao Y; 40779830
ENCS
3 Exploring interaction paradigms for segmenting medical images in virtual reality Jones Z; Drouin S; Kersten-Oertel M; 40402355
ENCS
4 MRI as a viable alternative to CT for 3D surgical planning of Cavitary bone tumors Chae Y; Cheers GM; Kim M; Reidler P; Klein A; Fevens T; Holzapfel BM; Mayer-Wagner S; 40049253
ENCS
5 Open access segmentations of intraoperative brain tumor ultrasound images Behboodi B; Carton FX; Chabanas M; de Ribaupierre S; Solheim O; Munkvold BKR; Rivaz H; Xiao Y; Reinertsen I; 39047165
SOH
6 FishSegSSL: A Semi-Supervised Semantic Segmentation Framework for Fish-Eye Images Paul S; Patterson Z; Bouguila N; 38535151
ENCS
7 Impaired performance of rapid grip in people with Parkinson's disease and motor segmentation Rebecca J Daniels 38507858
PSYCHOLOGY
8 PILLAR: ParaspInaL muscLe segmentAtion pRoject - a comprehensive online resource to guide manual segmentation of paraspinal muscles from magnetic resonance imaging Anstruther M; Rossini B; Zhang T; Liang T; Xiao Y; Fortin M; 37996857
SOH
9 Compatible-domain Transfer Learning for Breast Cancer Classification with Limited Annotated Data Shamshiri MA; Krzyzak A; Kowal M; Korbicz J; 36758326
ENCS
10 Measures of motor segmentation from rapid isometric force pulses are reliable and differentiate Parkinson's disease from age-related slowing Howard SL; Grenet D; Bellumori M; Knight CA; 35768733
PSYCHOLOGY
11 Spoken Word Segmentation in First and Second Language: When ERP and Behavioral Measures Diverge Gilbert AC; Lee JG; Coulter K; Wolpert MA; Kousaie S; Gracco VL; Klein D; Titone D; Phillips NA; Baum SR; 34603133
PSYCHOLOGY
12 Sharp U-Net: Depthwise convolutional network for biomedical image segmentation Zunair H; Ben Hamza A; 34348214
ENCS
13 LUMINOUS database: lumbar multifidus muscle segmentation from ultrasound images Belasso CJ; Behboodi B; Benali H; Boily M; Rivaz H; Fortin M; 33097024
PERFORM
14 Two-stage ultrasound image segmentation using U-Net and test time augmentation. Amiri M; Brooks R; Behboodi B; Rivaz H; 32350786
IMAGING
15 Statistical learning of multiple speech streams: A challenge for monolingual infants. Benitez VL, Bulgarelli F, Byers-Heinlein K, Saffran JR, Weiss DJ 31444822
CONCORDIA
16 High resolution atlas of the venous brain vasculature from 7 T quantitative susceptibility maps. Huck J, Wanner Y, Fan AP, Jäger AT, Grahl S, Schneider U, Villringer A, Steele CJ, Tardif CL, Bazin PL, Gauthier CJ 31278570
PSYCHOLOGY
17 The first MICCAI challenge on PET tumor segmentation. Hatt M, Laurent B, Ouahabi A, Fayad H, Tan S, Li L, Lu W, Jaouen V, Tauber C, Czakon J, Drapejkowski F, Dyrka W, Camarasu-Pop S, Cervenansky F, Girard P, Glatard T, Kain M, Yao Y, Barillot C, Kirov A, Visvikis D 29268169
IMAGING
18 A dataset of multi-contrast population-averaged brain MRI atlases of a Parkinson׳s disease cohort. Xiao Y, Fonov V, Chakravarty MM, Beriault S, Al Subaie F, Sadikot A, Pike GB, Bertrand G, Collins DL 28491942
PERFORM

 

Title:The first MICCAI challenge on PET tumor segmentation.
Authors:Hatt MLaurent BOuahabi AFayad HTan SLi LLu WJaouen VTauber CCzakon JDrapejkowski FDyrka WCamarasu-Pop SCervenansky FGirard PGlatard TKain MYao YBarillot CKirov AVisvikis D
Link:https://www.ncbi.nlm.nih.gov/pubmed/29268169?dopt=Abstract
DOI:10.1016/j.media.2017.12.007
Publication:Medical image analysis
Keywords:Comparative studyImage segmentationMICCAI challengePET functional volumes
PMID:29268169 Category:Med Image Anal Date Added:2019-06-20
Dept Affiliation: IMAGING
1 LaTIM, UMR 1101, INSERM, IBSAM, UBO, UBL, Brest, France. Electronic address: hatt@univ-brest.fr.
2 LaTIM, UMR 1101, INSERM, IBSAM, UBO, UBL, Brest, France.
3 Key Laboratory of Image Processing and Intelligent Control of Ministry of Education of China, School of Automation, Huazhong University of Science and Technology, Wuhan 430074, China.
4 Memorial Sloan-Kettering Cancer Center, New-York, USA.
5 INSERM, UMR 930, Imaging and brain, University of Tours, France.
6 Stermedia Sp. z o. o., ul. A. Ostrowskiego 13, Wroclaw, Poland.
7 Stermedia Sp. z o. o., ul. A. Ostrowskiego 13, Wroclaw, Poland; Wroclaw University of Science and Technology, Faculty of Fundamental Problems of Technology, Department of Biomedical Engineering, Poland.
8 Université de Lyon, CREATIS, CNRS UMR5220, INSERM UMR 1044, INSA-Lyon, Université Lyon 1, Lyon, France.
9 Department of Computer Science and Software Engineering, Concordia University, Montreal, Canada.
10 INRIA, Visages project-team, CNRS, IRISA 6074, INSERM, Visages, UMR 1228, University of Rennes I, Rennes Cx 35042, France.

Description:

The first MICCAI challenge on PET tumor segmentation.

Med Image Anal. 2018 02;44:177-195

Authors: Hatt M, Laurent B, Ouahabi A, Fayad H, Tan S, Li L, Lu W, Jaouen V, Tauber C, Czakon J, Drapejkowski F, Dyrka W, Camarasu-Pop S, Cervenansky F, Girard P, Glatard T, Kain M, Yao Y, Barillot C, Kirov A, Visvikis D

Abstract

INTRODUCTION: Automatic functional volume segmentation in PET images is a challenge that has been addressed using a large array of methods. A major limitation for the field has been the lack of a benchmark dataset that would allow direct comparison of the results in the various publications. In the present work, we describe a comparison of recent methods on a large dataset following recommendations by the American Association of Physicists in Medicine (AAPM) task group (TG) 211, which was carried out within a MICCAI (Medical Image Computing and Computer Assisted Intervention) challenge.

MATERIALS AND METHODS: Organization and funding was provided by France Life Imaging (FLI). A dataset of 176 images combining simulated, phantom and clinical images was assembled. A website allowed the participants to register and download training data (n?=?19). Challengers then submitted encapsulated pipelines on an online platform that autonomously ran the algorithms on the testing data (n?=?157) and evaluated the results. The methods were ranked according to the arithmetic mean of sensitivity and positive predictive value.

RESULTS: Sixteen teams registered but only four provided manuscripts and pipeline(s) for a total of 10 methods. In addition, results using two thresholds and the Fuzzy Locally Adaptive Bayesian (FLAB) were generated. All competing methods except one performed with median accuracy above 0.8. The method with the highest score was the convolutional neural network-based segmentation, which significantly outperformed 9 out of 12 of the other methods, but not the improved K-Means, Gaussian Model Mixture and Fuzzy C-Means methods.

CONCLUSION: The most rigorous comparative study of PET segmentation algorithms to date was carried out using a dataset that is the largest used in such studies so far. The hierarchy amongst the methods in terms of accuracy did not depend strongly on the subset of datasets or the metrics (or combination of metrics). All the methods submitted by the challengers except one demonstrated good performance with median accuracy scores above 0.8.

PMID: 29268169 [PubMed - indexed for MEDLINE]




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