1. Technical Field
The present invention relates to image segmentation, and more particularly to a system and method for a three-dimensional image segmentation using an active polyhedron.
2. Discussion of Related Art
Segmentation is a vital component of many clinical medical imaging applications, including anatomic analysis and modeling, morphological measurement, visualization, and surgical planning. Unfortunately, segmentation is often a challenging problem due to difficulties resulting from noise, limited contrast, and weak boundaries often observed in medical images. While manual segmentation can help address such issues, it requires tedious, labor-intensive work, particularly for three dimensional (3D) data. Consequently, there has been much recent interest in automated segmentation approaches, which can be grouped in to two major categories.
First, deformable surfaces that represent a surface explicitly have been used in numerous medical imaging problems, including the segmentation of anatomical structures. While it is possible to model topological changes using an explicit surface representation, an advantage of the second major category of segmentation approaches, those based on level set methods, is that they rely on an implicit surface representation that can automatically change topology when necessary.
Although the function that controls the speed of each vertex in either the explicit or implicit schemes may depend on a local, global, or region-based statistic or descriptor, the motion of each vertex is not coupled to its neighbor vertices or adjacent faces. As a result, such methods are prone to segmentation errors resulting from local variations in the statistic or descriptor, and can therefore produce erroneous segmentations. In particular, the surface may leak into nearby unrelated regions or break apart into multiple disconnected pieces, or have an irregular shape.
Therefore, a need exists for a system and method for robust 3D image segmentation.
In addition to using a global descriptor function, a system and method according to an embodiment of the present disclosure uses an active polyhedron that integrates the motion of each vertex over the polyhedral faces, effectively providing a lowpass filtering effect on the data measurements. An active polyhedron according to the present disclosure offers increased robustness to noise, particularly in presence of speckle observed in ultrasound data. This type of noise is spatially correlated and contaminates pointwise image measurements. An active polyhedron is less prone to segmentation errors resulting from local variations in the speed function, and in such cases, will be more effective at aligning its faces with the target structure.
According to an embodiment of the present disclosure, a method for three dimensional image segmentation of a volume of interest comprises providing a three dimensional image of the volume of interest, providing an initial polyhedron having a plurality of mesh vertices within the three dimension image and determining an image-based speed at each vertex of the polyhedron using an ordinary differential equation (ODE) that describes the vertex motion of the polyhedron. The method further comprises determining a regularization term at each vertex of the polyhedron, updating the plurality of mesh vertices of the polyhedron, integrating the image-based speed of each vertex over a face of the polyhedron, and determining an output polyhedron approximating a shape of the volume of interest.
The method comprises determining iteratively the image-based speed of each vertex and the regularization term, and updated mesh vertices until the vertices of the polyhedron have converged.
The method comprises performing a mesh operation after updating the plurality of mesh vertices of the polyhedron to grow or shrink a surface of the polyhedron. The mesh operation is one of an edge split, an edge collapse and a face split.
The regularization term prevents a surface of the polyhedron from self-intersecting. The regularization term increases in influence as a vertex approaches a surface of the polyhedron. The regularization term is based on electrostatic principles and does not penalize high curvature.
The method comprises determining a topological change in the polyhedron after updating the plurality of mesh vertices of the polyhedron.
A program storage device is provided readable by machine, tangibly embodying a program of instructions executable by the machine to perform method steps for three dimensional image segmentation of a volume of interest. The method comprises providing a three dimensional image of the volume of interest, providing an initial polyhedron having a plurality of mesh vertices within the three dimension image and determining an image-based speed at each vertex of the polyhedron using an ordinary differential equation (ODE) that describes the vertex motion of the polyhedron. The method further comprises determining a regularization term at each vertex of the polyhedron, updating the plurality of mesh vertices of the polyhedron, integrating the image-based speed of each vertex over a face of the polyhedron, and determining an output polyhedron approximating a shape of the volume of interest.
Preferred embodiments of the present invention will be described below in more detail, with reference to the accompanying drawings:
According to an embodiment of the present disclosure, an active polyhedron is a 3D deformable surface for the segmentation of medical images. Rooted in curve and surface evolution theory, an active polyhedron is a polyhedral surface whose vertices deform to minimize a region-based energy functional. Unlike continuous active surface models, the vertex motion of an active polyhedron is computed by integrating speed terms over polygonal faces of the surface. The resulting ordinary differential equations (ODEs) provide improved robustness to noise and allow for larger time steps compared to continuous active surfaces implemented with level set methods. An electrostatic regularization method achieves global regularization while better preserving sharper local features. Experimental results demonstrate the effectiveness of an active polyhedron in segmenting noisy medical image data.
A method for determining motion for an active polyhedron has been derived by minimizing an energy function using gradient descent. Referring to
where N denotes the outward unit normal to S, and F is chosen so that ∇·F=ƒ,dS is the differential area on the surface, and <·> is the inner product operator. Using a surface parameterization of S(u,v)=(x(u,v),y(u,v),z(u,v)), this surface integral may be re-expressed as
where Su and Sv are the derivatives of S with respect to u and v. Taking the derivative of E(S) with respect to a variable p whose variation affects the geometry of the surface, but is independent of the parameterization variables (u,v) can be shown to have the form
Eq. (3) applies both to a continuous active surface as well as a surface discretely sampled using a polygonal mesh.
A constraint that S be a mesh of N triangles is added. Si, the ith triangle of S, can be parameterized as
Si(u,v)=v1i+ue1i+ve2i, (4)
where points v1i, v2i, and v3i are triangle vertices, triangle edge vectors e1i=v2i−v1i, e2i=v3i−v1i, and uε[0,1] and vε[0,1−u] are the parameterization variables over which the integrals in the equations below will be evaluated. A depiction appears in
The vertices and edges used in the parameterization of a triangle are shown in
With this parameterization, Siu=e1i, Siv=e2i, dSi=∥e1i·e2i∥, Eq. (3) may be expressed as a sum of piecewise continuous integrals over the triangle faces,
Sip is defined for vertex vk as
where Dk is the set of M surface triangles that neighbor vertex vk, as depicted in
If a time variable t is introduced and coordinates (xi,yi,zi) are evolved in the gradient directions given above, the following gradient flow is obtained for the vertex vk,
Eq. (7) is an ordinary differential equation (ODE) that describes the vertex motion of the active polyhedron (see
The flow of an active polyhedron may, under the sole influence of a data term, become irregular when a vertex becomes infinitesimally close to a non-neighbor face of the polyhedron. To address this issue, a natural regularization term a based on electrostatic principles is incorporated.
The electrostatic regularization technique models a uniform charge density λ along each surface triangle. This charge density induces a global electric field GεR3 that applies a repulsive force at each vertex. To determine the electric field at a general point pεR3, the differential electric field dG(p) exerted by a charged particle at location xi on triangle Si needs to be considered. As given by Coulomb's law, the electric force is inversely proportional to the square of the Euclidean distance ∥p−xi∥2 between the charged particles, and directed along the vector (p−xi)/∥p−xi∥.
where xi=(v1i+ue1i+ve2i) is a point on Si, and n=4.
While using n=3 in Eq. (8) imparts a repulsive force to a surface vertex, it fails to become singular as the vertex approaches the surface. This can be demonstrated if one considers a vertex p=[0,0,z]T directly above a disk of uniform charge and radius r as depicted in
Preferring an electric field that goes to infinity in the limit as the vertex moves towards the charged surface in order to prevent the surface from self-intersecting; n may be set to 4 in Eq. (8).
There are several ways to make use of Eq. (8) to displace vertex vk to regularize the surface. Perhaps the most thorough method would be to integrate the field G at each point pεDk, weighted by (1−u−v) so that points closer to vk contribute more to the regularization,
where each G(xj) is computed over the L triangles Ck=S\Dk (to avoid infinities). However, for each vertex, such an approach includes solving sums of quadruple integrals, which has computational complexity of LMK4 operations.
To reduce the computational load, the vertex displacement (see
which, for each vertex, has computational complexity of LK2 operations. In practice, this approach offers sufficient regularization and is reasonably fast. This electric force is designed to be insignificant when vk is not very close to the surface triangles in Ck, but becomes influential, even dominant, when the vertex gets very close to triangles in Ck.
Referring now to an implementation of a method according to an embodiment of the present disclosure, a combination of Eq. (7) and Eq. (10) yields the vertex flow (see
where α is a constant that weights the data term relative to the regularization term. In practice, a value of α=0.95 offers desirable performance. With this heavier weight on the data term, the regularization contributes significantly to the flow when degeneracy occurs, allowing for the data term to govern the evolution during most of the evolution. Since updating a single vertex includes (L+M)K2=NK2 operations, the complexity of a method according to an embodiment of the present disclosure is N2K2 operations for each time step.
The implementation of the active polyhedron supports mesh operations including edge splitting and collapsing, so that the mesh maintains a proper vertex density during evolution. These operations allow the surface to grow and to shrink. Topological changes can be modeled as well.
Referring to mesh operations (see
The edge split operation splits any edge whose length goes above a maximum length. A new vertex is placed at the center of the edge, and each triangle that included the edge is split into two, as shown in
These operations allow the surface to grow and to shrink without the need to support topological changes. For many applications this is an advantage rather than a disadvantage. Topological changes may introduce complexities into the topology of the level-set surface due to surface breaks or leaks into surrounding unrelated regions while propagating. It should be understood that topology adaptivity can be added to an active polyhedron according to an embodiment of the present disclosure. For example, topological transformations including merging, splitting, creation, and deletion may be implemented.
A speed term is introduced. For region-based functional for segmentation, the image-based speed term ƒ described in Eq. (7) has a form that can be customized for specific tasks. For image segmentation, a piecewise constant region-based energy function that uses mean statistics is implemented as:
ƒ(x)=−(I(x)−mi)2+(I(x)−mo)2 (12)
where I is the 3D image, x is a point on the surface, mi and mo are the mean values of I inside and outside the polyhedron, respectively. This speed function is well suited to the segmentation of noisy images, as it does not rely on the image gradients. The voxels inside and outside the surface are found via scanline rasterization of the polyhedron.
Referring to a speed term for a boundary-based functional for reconstruction from unorganized points; For reconstructing surfaces from unorganized points, a gradient flow on a distance volume is used to find the minimal distance surface. That is,
ƒ(x)=−∇D(x)·N(x) (13)
where D is a distance volume formed by placing the unorganized points into a volumetric grid and determining the unsigned distance at each voxel to the closest unorganized point, and N is the surface normal.
The deformation and mesh operations continue until convergence of the vertices (see
Experimental results show an active polyhedron's ability to segment 3D image data. A first example consists of a 1283 volume of synthetic ultrasound data. The data suffers poor contrast and corruption by speckle noise. Inside the volume is a darker cylindrical structure that simulates a blood vessel. This data is segmented by placing a cube inside and at one end of the vessel, and evolve the active polyhedron using a regional data term based on the mean inside vs. the mean outside the surface and the electrostatic regularizer.
In
It is to be understood that a method for 3D image segmentation using an active polyhedron according to an embodiment of the present disclosure may be implemented in various forms of hardware, software, firmware, special purpose processors, or a combination thereof. In one embodiment, a method for 3D image segmentation using an active polyhedron may be implemented in software as an application program tangibly embodied on a program storage device. The application program may be uploaded to, and executed by, a machine comprising any suitable architecture.
Referring to
The computer platform 701 also includes an operating system and micro instruction code. The various processes and functions described herein may either be part of the micro instruction code or part of the application program (or a combination thereof) which is executed via the operating system. In addition, various other peripheral devices may be connected to the computer platform such as an additional data storage device and a printing device.
It is to be further understood that, because some of the constituent system components and method steps depicted in the accompanying figures may be implemented in software, the actual connections between the system components (or the process steps) may differ depending upon the manner in which the present invention is programmed. Given the teachings of the present invention provided herein, one of ordinary skill in the related art will be able to contemplate these and similar implementations or configurations of the present invention.
Having described embodiments for a system and method for a 3D image segmentation using an active polyhedron, it is noted that modifications and variations can be made by persons skilled in the art in light of the above teachings. It is therefore to be understood that changes may be made in the particular embodiments of the invention disclosed which are within the scope and spirit of the invention as defined by the appended claims. Having thus described the invention with the details and particularity required by the patent laws, what is claimed and desired protected by Letters Patent is set forth in the appended claims.
This application claims priority to U.S. Provisional Application Ser. No. 60/549,468, filed on Mar. 2, 2004, which is herein incorporated by reference in its entirety.
Number | Name | Date | Kind |
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5903664 | Hartley et al. | May 1999 | A |
6249594 | Hibbard | Jun 2001 | B1 |
Number | Date | Country | |
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20050195185 A1 | Sep 2005 | US |
Number | Date | Country | |
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60549468 | Mar 2004 | US |