Non-Euclidean classification of medically imaged objects via s-reps

Hong, Jun‐Pyo; Vicory, Jared; Schulz, Jörn; Styner, Martin; Marron, J. S.; Pizer, Stephen M.

doi:10.1016/j.media.2016.01.007

Cited by 21 publications

(15 citation statements)

References 37 publications

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“…This observation is consistent with [4, 22, 61] that the use of point information alone ignores many of the higher order geometric features that s-reps provide, such as orientation and width.…”

Section: Evaluation and Resultssupporting

confidence: 89%

Skeletal Shape Correspondence Through Entropy

Styner

Vicory

et al. 2018

IEEE Trans. Med. Imaging

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We present a novel approach for improving the shape statistics of medical image objects by generating correspondence of skeletal points. Each object’s interior is modeled by an s-rep, i.e., by a sampled, folded, 2-sided skeletal sheet with spoke vectors proceeding from the skeletal sheet to the boundary. The skeleton is divided into three parts: the up side, the down side and the fold curve. The spokes on each part are treated separately and, using spoke interpolation, are shifted along that skeleton in each training sample so as to tighten the probability distribution on those spokes’ geometric properties while sampling the object interior regularly. As with the surface/boundary-based correspondence method of Cates et al., entropy is used to measure both the probability distribution tightness and sampling regularity, here of the spokes’ geometric properties. Evaluation on synthetic and real world lateral ventricle and hippocampus datasets demonstrate improvement in the performance of statistics using the resulting probability distributions. This improvement is greater than that achieved by an entropy-based correspondence method on the boundary points.

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Section: Evaluation and Resultssupporting

confidence: 89%

Skeletal Shape Correspondence Through Entropy

Styner

Vicory

et al. 2018

IEEE Trans. Med. Imaging

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“…10 It has been shown in various publications to be more powerful in capturing the interior of most non-branching anatomic objects and providing efficient shape statistical summaries when compared to boundary point distribution models (PDMs). 10, 13–15 An s-rep fitting procedure starts with an initial template model of the object and a distance map that was computed from the binary image of the target object. The fitting process is based on thin plate spline transformation of a spherical harmonic representation of the surfaces of the template (initial caudate model) as well as the target objects.…”

Section: Methodsmentioning

confidence: 99%

A segmentation editing framework based on shape change statistics

et al. 2017

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Segmentation is a key task in medical image analysis because its accuracy significantly affects successive steps. Automatic segmentation methods often produce inadequate segmentations, which require the user to manually edit the produced segmentation slice by slice. Because editing is time-consuming, an editing tool that enables the user to produce accurate segmentations by only drawing a sparse set of contours would be needed. This paper describes such a framework as applied to a single object. Constrained by the additional information enabled by the manually segmented contours, the proposed framework utilizes object shape statistics to transform the failed automatic segmentation to a more accurate version. Instead of modeling the object shape, the proposed framework utilizes shape change statistics that were generated to capture the object deformation from the failed automatic segmentation to its corresponding correct segmentation. An optimization procedure was used to minimize an energy function that consists of two terms, an external contour match term and an internal shape change regularity term. The high accuracy of the proposed segmentation editing approach was confirmed by testing it on a simulated data set based on 10 in-vivo infant magnetic resonance brain data sets using four similarity metrics. Segmentation results indicated that our method can provide efficient and adequately accurate segmentations (Dice segmentation accuracy increase of 10%), with very sparse contours (only 10%), which is promising in greatly decreasing the work expected from the user.

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“…. , b n , and condition (5) ensures that this ball is inscribed in φ t O, and thus an MIB in φ t O. Note that conditions (3) and (4) only involve local geometry of φ t B O around the tuple, while condition (5) requires the knowledge of the entire φ t B O .…”

Section: Medial Structure Preservation Under Diffeomorphic Flowmentioning

confidence: 99%

“…Medial models have also been used to impose geometrical constraints on automatic segmentation of sheet-like structures, e.g., imposing prior knowledge about heart wall thickness during myocardium segmentation [11]. Medial modeling methods include m-reps [10] and s-reps [5] (which approximate medial axis surfaces using discrete primitives), cm-reps [12] (which use splines and subdivision surfaces to model medial axis surfaces), and boundary-constrained m-reps [13] (which implicitly model medial geometry by imposing symmetry constraints on a boundary-based model).…”

Section: Introductionmentioning

confidence: 99%

Diffeomorphic Medial Modeling

Yushkevich

Aly

Wang

et al. 2019

Lecture Notes in Computer Science

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Deformable shape modeling approaches that describe objects in terms of their medial axis geometry (e.g., m-reps [10]) yield rich geometrical features that can be useful for analyzing the shape of sheet-like biological structures, such as the myocardium. We present a novel shape analysis approach that combines the benefits of medial shape modeling and diffeomorphometry. Our algorithm is formulated as a problem of matching shapes using diffeomorphic flows under constraints that approximately preserve medial axis geometry during deformation. As the result, correspondence between the medial axes of similar shapes is maintained. The approach is evaluated in the context of modeling the shape of the left ventricular wall from 3D echocardiography images. 1

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Non-Euclidean classification of medically imaged objects via s-reps

Cited by 21 publications

References 37 publications

Skeletal Shape Correspondence Through Entropy

Skeletal Shape Correspondence Through Entropy

A segmentation editing framework based on shape change statistics

Diffeomorphic Medial Modeling

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