Fully automated segmentation of cartilage from the MR images of knee using a multi‐atlas and local structural analysis method

Lee, June Goo; Gümüş, Serter; Moon, Chan Hong; Kwoh, C. Kent; Bae, Kyongtae T.

doi:10.1118/1.4893533

Cited by 55 publications

(47 citation statements)

References 36 publications

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“…Some methods are directly hierarchical starting with a bone segmentation that then aids the (more difficult) cartilage segmentation with features for distance-from-bone or position-relative-to-bone. 18,36,[38][39][40][41][42] Other methods achieve a similar coarse-to-fine effect by applying atlas-based registration before either nonrigid registration 21,40,43 and/or classifier-based segmentation. 10,22,43 In general, it appears that integration of global information and local features is essential for solving the challenging problem of segmentation of cartilage on the background of multiple other tissue types.…”

Section: Methodology Choicesmentioning

confidence: 99%

“…It would appear that dedicated methods are needed for robust and accurate joint registration-such as articulated-rigid bone registration followed by locally elastic registration in cartilage areas. The third-ranking SKI10 method actually applies a multiatlas nonrigid registration approach to produce an initial segmentation that is used as an input to a graph-cut method, resulting in cartilage overlap errors of 28.3% and 27.6%, corresponding to Dice 0.677 and 0.719 for tibial and femoral cartilages (from UPMC, previous version presented 21 ). The fifth-ranked method 22 also applies multiatlas registration using patch-based label fusion (previously demonstrated to be very applicable for brain MRI segmentation) followed by a specialized three-class classification.…”

Section: Introductionmentioning

confidence: 99%

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Automatic segmentation of high- and low-field knee MRIs using knee image quantification with data from the osteoarthritis initiative

Dam¹,

Lillholm²,

Marques³

et al. 2015

J. Med. Imag

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Abstract. Clinical studies including thousands of magnetic resonance imaging (MRI) scans offer potential for pathogenesis research in osteoarthritis. However, comprehensive quantification of all bone, cartilage, and meniscus compartments is challenging. We propose a segmentation framework for fully automatic segmentation of knee MRI. The framework combines multiatlas rigid registration with voxel classification and was trained on manual segmentations with varying configurations of bones, cartilages, and menisci. The validation included high-and low-field knee MRI cohorts from the Center for Clinical and Basic Research, the osteoarthritis initiative (QAI), and the segmentation of knee images10 (SKI10) challenge. In total, 1907 knee MRIs were segmented during the evaluation. No segmentations were excluded. Our resulting OAI cartilage volume scores are available upon request. The precision and accuracy performances matched manual reader re-segmentation well. The cartilage volume scan-rescan precision was 4.9% (RMS CV). The Dice volume overlaps in the medial/lateral tibial/femoral cartilage compartments were 0.80 to 0.87. The correlations with volumes from independent methods were between 0.90 and 0.96 on the OAI scans. Thus, the framework demonstrated precision and accuracy comparable to manual segmentations. Finally, our method placed second for cartilage segmentation in the SKI10 challenge. The comprehensive validation suggested that automatic segmentation is appropriate for cohorts with thousands of scans.

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Section: Methodology Choicesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Automatic segmentation of high- and low-field knee MRIs using knee image quantification with data from the osteoarthritis initiative

Dam¹,

Lillholm²,

Marques³

et al. 2015

J. Med. Imag

View full text Add to dashboard Cite

show abstract

“…the STAPLE algorithm [34] and different types of machine-learning approaches [27]. The fused segmentation proposal can be further refined into a final segmentation by using graph cut [3,22] or random forest-based methods [9]. For a comprehensive survey of multiatlas segmentation methods and their applications, see [13].…”

Section: Related Workmentioning

confidence: 99%

Multiatlas Segmentation Using Robust Feature-Based Registration

Fejne

Landgren

Alvén

et al. 2017

Cloud-Based Benchmarking of Medical Image Analysis

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This paper presents a pipeline which uses a multiatlas approach for multiorgan segmentation in whole-body CT images. In order to obtain accurate registrations between the target and the atlas images, we develop an adapted featurebased method which uses organ-specific features. These features are learnt during an offline preprocessing step, and thus, the algorithm still benefits from the speed of feature-based registration methods. These feature sets are then used to obtain pairwise non-rigid transformations using RANSAC followed by a thin-plate spline refinement or NiftyReg. The fusion of the transferred atlas labels is performed using a random forest classifier, and finally, the segmentation is obtained using graph cuts with a Potts model as interaction term.

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“…The most successful methods so far have been based on active appearance models, 5 statistical shape models and graph-based optimization, 6 and multi-atlas and local structural analysis. 7 Regardless of the specifics, a common characteristic of all methods is their processing MRI images as arrays of pixels.…”

Section: Introductionmentioning

confidence: 99%

“…Recent literature [4][5][6][7] reports several attempts in automatic segmentation of the knee structures (mainly femur, tibia and cartilage) with various degrees of success. The most successful methods so far have been based on active appearance models, 5 statistical shape models and graph-based optimization, 6 and multi-atlas and local structural analysis.…”

Section: Introductionmentioning

confidence: 99%

Unsupervised segmentation of MRI knees using image partition forests

Marčan

Voiculescu

2016

SPIE Proceedings

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Nowadays many people are affected by arthritis, a condition of the joints with limited prevention measures, but with various options of treatment the most radical of which is surgical. In order for surgery to be successful, it can make use of careful analysis of patient-based models generated from medical images, usually by manual segmentation. In this work we show how to automate the segmentation of a crucial and complex joint -the knee. To achieve this goal we rely on our novel way of representing a 3D voxel volume as a hierarchical structure of partitions which we have named Image Partition Forest (IPF). The IPF contains several partition layers of increasing coarseness, with partitions nested across layers in the form of adjacency graphs. On the basis of a set of properties (size, mean intensity, coordinates) of each node in the IPF we classify nodes into different features. Values indicating whether or not any particular node belongs to the femur or tibia are assigned through node filtering and node-based region growing. So far we have evaluated our method on 15 MRI knee images. Our unsupervised segmentation compared against a hand-segmented gold standard has achieved an average Dice similarity coefficient of 0.95 for femur and 0.93 for tibia, and an average symmetric surface distance of 0.98 mm for femur and 0.73 mm for tibia. The paper also discusses ways to introduce stricter morphological and spatial conditioning in the bone labelling process.

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Fully automated segmentation of cartilage from the MR images of knee using a multi‐atlas and local structural analysis method

Cited by 55 publications

References 36 publications

Automatic segmentation of high- and low-field knee MRIs using knee image quantification with data from the osteoarthritis initiative

Automatic segmentation of high- and low-field knee MRIs using knee image quantification with data from the osteoarthritis initiative

Multiatlas Segmentation Using Robust Feature-Based Registration

Unsupervised segmentation of MRI knees using image partition forests

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