System and methods of organ segmentation and applications of same

US 7,519,209 B2
Filed: 06/23/2005
Issued: 04/14/2009
Est. Priority Date: 06/23/2004
Status: Active Grant

First Claim

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1. A method for segmentation of an organ of a living subject with a variable shape and boundary and surrounded by structures and tissues in connection with an image containing the organ, wherein the boundary of the organ is embedded as a zero level set of an embedding function, Φ

, comprising the steps of;

a. initializing a contour inside the organ in the image;

b. introducing a speed function that is capable of accumulating spatial and temporal information of a propagating front of the contour, wherein the speed function has a term, g₀;

c. defining an image-dependent static term, g_base;

d. setting the term g₀=g_base;

e. computing {(x,y,z)|Φ

(x,y,z)=0} at iteration n, so as to obtain a set of points in the zero level set of the embedding function Φ

, wherein n=1, 2, 3, . . . , and coordinates (x, y, z) represent a point on the propagating front of the contour;

f. retrieving the static term g_base(x, y, z) for each of the set of points in the zero level set of the embedding function Φ

;

g. extending the retrieved static term g_base(x, y, z) to a narrow band in which the embedding function Φ

is computed so as to generate an extended term g_ext;

h. updating the term g₀=g₀g_extso as to update the speed function;

i. computing the embedding function Φ

at iteration (n+1) using the updated speed function; and

j. iteratively repeating steps (e)-(i) by a computer for a predetermined number of iterations or until the propagating front of the contour does not move,wherein the front of the contour corresponds to the boundary of the organ.

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Abstract

A method for segmentation of an organ of a living subject with a variable shape and boundary and surrounded by structures and tissues in connection with an image containing the organ. In one embodiment, the method includes the steps of initializing a contour inside the organ in the image, introducing a speed function that is capable of accumulating spatial and temporal information of a propagating front of the contour, and evolving the contour toward the boundary of the organ using the introduced speed function so as to segment the organ.

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24 Claims

1. A method for segmentation of an organ of a living subject with a variable shape and boundary and surrounded by structures and tissues in connection with an image containing the organ, wherein the boundary of the organ is embedded as a zero level set of an embedding function, Φ
- , comprising the steps of;
  
  a. initializing a contour inside the organ in the image;
  
  b. introducing a speed function that is capable of accumulating spatial and temporal information of a propagating front of the contour, wherein the speed function has a term, g₀;
  
  c. defining an image-dependent static term, g_base;
  
  d. setting the term g₀=g_base;
  
  e. computing {(x,y,z)|Φ
  
  (x,y,z)=0} at iteration n, so as to obtain a set of points in the zero level set of the embedding function Φ
  
  , wherein n=1, 2, 3, . . . , and coordinates (x, y, z) represent a point on the propagating front of the contour;
  
  f. retrieving the static term g_base(x, y, z) for each of the set of points in the zero level set of the embedding function Φ
  
  ;
  
  g. extending the retrieved static term g_base(x, y, z) to a narrow band in which the embedding function Φ
  
  is computed so as to generate an extended term g_ext;
  
  h. updating the term g₀=g₀g_extso as to update the speed function;
  
  i. computing the embedding function Φ
  
  at iteration (n+1) using the updated speed function; and
  
  j. iteratively repeating steps (e)-(i) by a computer for a predetermined number of iterations or until the propagating front of the contour does not move,wherein the front of the contour corresponds to the boundary of the organ.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18)
- - 2. The method of claim 1, wherein the extending step comprises the step of computing the extended term g_extthat satisfies an equation of ∇
    - g_ext·
      
      ∇
      
      θ
      
      =0, ∇
      
      θ
      
      being a standard signed distance function computed from the zero level set of the embedding function Φ
      
      .
  - 3. The method of claim 2, wherein the computing step is performed with a fast marching method.
  - 4. The method of claim 3, wherein the extended term g_ext(x,y,z)=g_base(c(x,y,z)) for points (x,y,z) close to the zero level set, c(x,y,z) being the closest point in the zero level set of the embedding function Φ
    - .
  - 5. The method of claim 1, wherein the embedding function Φ
    - is governed by a level set equation, Φ
      
      _t+F|∇
      
      Φ
      
      |=0, wherein the speed function F=g₀(1−
      
      ε
      
      κ
      
      ).
  - 6. The method of claim 1, wherein the embedding function Φ
    - is governed by a level set equation, Φ
      
      _t−
      
      Sign(g_base)((|g₀|−
      
      ε
      
      κ
      
      )|∇
      
      Φ
      
      |)=0, wherein the speed function F=−
      
      Sign(g_base)(|g₀|−
      
      ε
      
      κ
      
      ) and Sign(g_base) is a sign function of g_base.
  - 7. The method of claim 6, wherein the static term g_baseis in the form of g_base=g_gradg_gray, wherein g_gradand g_greycomprise intensity gradient information and gray value information of the image, respectively.
  - 8. The method of claim 1, further comprising the step of localizing an inner boundary of the structures surrounding the organ as a shape constraint for the propagating front of the contour.
  - 9. The method of claim 8, wherein the structures comprise a set of ribs.
  - 10. The method of claim 9, wherein the localizing step comprises the steps of;
    - a. converting the image into a binary image;
      
      b. localizing a skin surface from the converted binary image, wherein the localized skin surface comprises a skin circumference;
      
      c. identifying a set of candidate pixels, P_candidate={P_candidate(j)}, from the converted binary image, j=1, 2, . . . , N_c, N_cbeing the number of the set of candidate pixels P_candidate;
      
      d. determining a set of rib pixels, P_rib={P_rib(i)}, from the set of candidate pixels P_candidate, each of the set of rib pixels P_ribcorresponding to one of the set of ribs in the converted binary image, i=1, 2, . . . , N_r, N_rbeing the number of the set of rib pixels P_rib;
      
      e. segmenting the set of rib pixels P_ribinto a plurality of sections, S={S(k)}, along the skin circumference in the converted binary image, k=1, 2, . . . , N_s, N_sbeing the number of the plurality of sections S;
      
      f. calculating distances of each rib pixel in a segmented section S(k) to its closest skin pixels on the skin circumference in the segmented section S(k) so as to obtain the mean value D_skin(k) and the standard deviation D_std(k) of these distances in the segmented section S(k), respectively, k=1, 2, . . . , N_s;
      
      g. defining a skin-rib distance, d_skin-rib(k)= D_skin(k)+2D_std(k) for the segmented section S(k), k=1, 2, . . . , N_s; and
      
      h. connecting the plurality of segmented sections S together to form the inner boundary of the plurality of ribs,P_in={(x,y)|d(x,y)=Td_skin-rib(C_Map(x,y))}, wherein d(x,y) is distance of pixel (x,y) to the skin circumference, C_Map(x,y) is the closest point of pixel (x,y) on the skin circumference, and Td_skin-ribis a lookup table that stores the skin-rib distance d_skin-ribfor each pixel along the skin circumference.
  - 11. The method of claim 10, wherein the converting step comprises the step of thresholding the image with a threshold, I_skin.
  - 12. The method of claim 11, wherein the set of rib pixels P_rib={(x,y)|(x,y)∈
    - P_candidate, and D_skin(x,y)<
      
      d_{rib max}}, d_ribmaxbeing a maximum possible distance from a rib to the skin circumference.
  - 13. The method of claim 10, wherein the connecting step is performed with an interpolation scheme.
  - 14. The method of claim 1, further comprising the step of performing a stiff band algorithm on the propagating front of the contour.
  - 15. The method of claim 14, wherein the performing step comprises the steps of:
    - a. defining a neighborhood for each of pixels {P_i} along the contour, wherein P_irepresents the ith pixel on the contour, i=1, 2, . . . , N, N being the number of the pixels, such that the neighborhood includes a set of pixels that are within ±
      
      ε
      
      pixels, ε
      
      being a non-zero positive number;
      
      b. dividing the pixels of the neighborhood for P_iinto a first set of pixels that are in front of pixel P_ialong a propagating direction of the contour, and a second set of pixels that are behind of pixel P_ialong the propagating direction of the contour;
      
      c. defining a speed limit σ
      
      to classify the neighborhood into several possible states;
      
      d. for each state segmenting the neighborhood of P_i; and
      
      e. iteratively repeating steps (b)-(d) for all pixels {P_i}.
  - 16. The method of claim 1, wherein the organ comprises at least a part of a liver, a heart, a kidney, a stomach, or a lung of a living subject.
  - 17. The method of claim 1, wherein the image comprises a magnetic resonance image.
  - 18. The method of claim 1, wherein the image comprises a computed tomography image.

19. Software stored on a computer readable medium for causing a computing system to perform functions that segment a region of interest of an organ in an image comprising:
- a. initializing a contour inside the region of interest in the image;
  
  b. introducing a speed function that is capable of accumulating spatial and temporal information of a propagating front of the contour, wherein the speed function has a term, g₀;
  
  c. defining an image-dependent static term, g_base;
  
  d. setting the term g₀=g_base;
  
  e. computing {(x,y,z)|Φ
  
  (x,y,z)=0} at iteration n, so as to obtain a set of points in the zero level set of an embedding function Φ
  
  , wherein n=1, 2, 3, . . . , and coordinates (x,y,z) represent a point on the propagating front of the contour;
  
  f. retrieving the static term g_base(x,y,z) for each of the set of points in the zero level set of the embedding function Φ
  
  ;
  
  g. extending the retrieved static term g_base(x,y,z) to a narrow band in which the embedding function Φ
  
  is computed so as to generate an extended term g_ext;
  
  h. updating the term g₀=g₀g_extso as to update the speed function;
  
  i. computing the embedding function Φ
  
  at iteration (n+1) using the updated speed function; and
  
  j. iteratively repeating steps (e)-(i) for a predetermined number of iterations or until the propagating front of the contour does not move,wherein the front of the contour corresponds to the boundary of the region of interest of an organ.
- View Dependent Claims (20, 21)
- - 20. The software of claim 19, wherein the functions further comprise localizing an inner boundary of structures surrounding the organ as a shape constraint for the propagating front of the contour.
  - 21. The software of claim 19, wherein the functions further comprise performing a stiff band algorithm on the propagating front of the contour.

22. Software stored on a computer readable medium for causing a computing system to perform functions that segment a region of interest of an organ in an image comprising:
- a. initializing a contour inside the region of interest in the image;
  
  b. introducing a speed function that is capable of accumulating spatial and temporal information of a propagating front of the contour; and
  
  c. evolving the contour toward the boundary of the organ using the introduced speed function so as to segment the organ, wherein the boundary of the organ is embedded as a zero level set of an embedding function, Φ
  
  , governed by a level set equation;
  
  wherein the evolving function comprises;
  
  d. defining an image-dependent static term, g_base;
  
  e. setting g₀=g_base, wherein g₀is a term used in the speed function;
  
  f. computing {(x,y,z)|Φ
  
  (x,y,z)=0} at iteration n, so as to obtain a set of points in the zero level set of the embedding function Φ
  
  , wherein n=1, 2, 3, . . . , and coordinates (x, y, z) represent a point on the propagating front of the contour;
  
  g. retrieving the static term g_base(x,y,z) for each of the set of points in the zero level set of the embedding function Φ
  
  ;
  
  h. extending the retrieved static term g_base(x , y, Z) to a narrow band in which the embedding function Φ
  
  is computed so as to generate an extended term g_ext;
  
  i. updating the term g₀=g₀g_extso as to update the speed function;
  
  j. computing the embedding function Φ
  
  , at iteration (n+1) using the updated speed function; and
  
  k. iteratively repeating steps (c)-(g) for a predetermined number of iterations or until the propagating front of the contour does not move.
- View Dependent Claims (23, 24)
- - 23. The software of claim 22, wherein the functions further comprise localizing an inner boundary of the structures surrounding the organ as a shape constraint for a propagating front of a contour.
  - 24. The software of claim 22, wherein the functions further comprise performing a stiff band algorithm on the evolution of a contour.

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Current Assignee
Vanderbilt University
Original Assignee
Vanderbilt University
Inventors
Cao, Zhujiang, Dawant, Benoit M.
Primary Examiner(s)
AZARIAN, SEYED H

Application Number

US11/165,565
Publication Number

US 20060013482A1
Time in Patent Office

1,391 Days
Field of Search

382/128, 382/129, 382/130, 382/131, 382/132, 382/133, 382/134, 382/168, 382/171, 382/173, 382/181, 382/194, 382/199, 382/203, 382/224, 382/232, 382/254, 382/274, 382/276, 382/286, 382/287, 382/288, 382/290, 382/291, 382/292, 382/305, 382/312, 378/4, 378/18, 378/20, 378/21, 378/23
US Class Current

382/128
CPC Class Codes

G06T 2207/10081   Computed x-ray tomography [CT]

G06T 2207/10088   Magnetic resonance imaging ...

G06T 2207/20104   Interactive definition of r...

G06T 2207/20161   Level set

G06T 2207/30056   Liver; Hepatic

G06T 7/12   Edge-based segmentation

G06T 7/149   involving deformable models...

System and methods of organ segmentation and applications of same

First Claim

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Abstract

49 Citations

24 Claims

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System and methods of organ segmentation and applications of same

First Claim

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