Mri image fusion methods and uses thereof

What is claimed is: 1 . A method for generating a Trans-Rectal Ultra-Sound (TRUS)-Magnetic Resonance Imaging (MRI) fusion image of a prostate gland of a subject, said method comprising the following steps: (a) inputting an MRI scan of the prostate gland of said subject; (b) segmenting the MRI scan to produce at least one segmented MRI contour surface of the organ, said contour comprising a plurality of three-dimensional (3D) landmark points; (c) inputting a TRUS scan of the prostate gland of said subject; (d) segmenting the TRUS scan to produce at least one segmented TRUS contour surface of the prostate gland, said contour comprising a plurality of 3D landmark points, wherein the at least one MRI contour surface and the at least one TRUS contour surface correspond to the same anatomical surface; (e) resampling the TRUS and MRI contours to a common geometric space; (f) computing a linear transformation that maps the MRI contour surface onto the TRUS contour surface, the linear transformation being an affine transformation estimated by minimization of the matching cost between the plurality of landmark points on the MRI contour and the plurality of landmark points on the TRUS contour; (g) applying said linear transformation to the MRI contour points to obtain linearly transformed (LT) MRI contour points; (h) computing a local shape descriptor for each LT landmark point of the MRI contour surface and each landmark point of the TRUS contour surface; (i) computing an optimal assignment between said LT landmark MRI and TRUS contour surface points that minimizes a matching cost criterion between the shape descriptors of the matched points, said optimal assignment defining a sparse vector field mapping MRI contour points onto TRUS contour points; (j) computing a dense deformation field by smooth interpolation of said sparse vector field to map any point of the whole MRI volume onto a point of the TRUS volume; and (k) applying the linear and non-linear mapping of steps (f) through (j) to map points of the MRI image into the TRUS image; wherein the performance of steps (a) through (k) generates a Trans-Rectal Ultra-Sound-Magnetic Resonance Imaging fusion image of the prostate of said subject. 2 . The method of claim 1 , wherein said at least one contour surface comprises an external surface of the prostrate or a portion thereof, a contour of an internal surface of the prostate or a portion thereof, a contour of a transitional zone of the prostate or a portion thereof, a contour of a central zone of the prostate or a portion thereof, a contour of a peripheral zone of the prostate or a portion thereof, a contour of an interface between a central zone and a peripheral zone of the prostate or a portion thereof, a contour of a surface bordering the prostate and the urethra or a portion thereof, a contour based on observable calcifications, or any combinations thereof, or any combination thereof. 3 . (canceled) 4 . The method of claim 1 , wherein said minimizes a matching cost criterion of step (i) is computed according to the count distribution of contour points falling within a plurality of histogram bins neighboring each landmark point. 5 . The method of claim 1 , wherein the dense deformation field is constrained to be smooth and invertible. 6 . (canceled) 7 . The method of claim 1 , wherein said subject is undergoing a focal procedure, wherein said focal procedure comprises a prostatectomy, a robotic prostatectomy, a biopsy, an image guided biopsy, brachytherapy, cryotherapy, a high intensity focalized ultrasound therapy, a vascular targeted photodynamic therapy, a radiotherapy, an external beam radiotherapy, or a surgery for removal of a tumor, or any combination thereof. 8 . (canceled) 9 . (canceled) 10 . The method of claim 1 , wherein said method further visualizes and locates the neurovascular bundle adjacent to said prostate gland. 11 . A method of using a fused Trans-Rectal Ultra-Sound (TRUS)-Magnetic Resonance Imaging (MRI) image of a prostate of a subject for improving the accuracy of determining a location of target for a medical procedure, said method comprising the following steps: (a) inputting an MRI scan of the prostate gland of said subject; (b) segmenting the MRI scan to produce at least one segmented MRI contour surface of the organ, said contour comprising a plurality of three-dimensional (3D) landmark points; (c) inputting a TRUS scan of the prostate gland of said subject; (d) segmenting the TRUS scan to produce at least one segmented TRUS contour surface of the prostate gland, said contour comprising a plurality of 3D landmark points, wherein the at least one MRI contour surface and the at least one TRUS contour surface correspond to the same anatomical surface; (e) resampling the TRUS and MRI contours to a common geometric space; (f) computing a linear transformation that maps the MRI contour surface onto the TRUS contour surface, the linear transformation being an affine transformation estimated by minimization of the matching cost between the plurality of landmark points on the MRI contour and the plurality of landmark points on the TRUS contour; (g) applying said linear transformation to the MRI contour points to obtain linearly transformed (LT) MRI contour points; (h) computing a local shape descriptor for each LT landmark point of the MRI contour surface and each landmark point of the TRUS contour surface; (i) computing an optimal assignment between said LT landmark MRI and TRUS contour surface points that minimizes a matching cost criterion between the shape descriptors of the matched points, said optimal assignment defining a sparse vector field mapping MRI contour points onto TRUS contour points; (j) computing a dense deformation field by smooth interpolation of said sparse vector field to map any point of the whole MRI volume onto a point of the TRUS volume; and (k) applying the linear and non-linear mapping of steps (f) through (j) to map points of the MRI image into the TRUS image; wherein the performance of steps (a) through (k) generates a Trans-Rectal Ultra-Sound-Magnetic Resonance Imaging fusion image of said prostate, and wherein said fused image provides improved accuracy of determining said location of target for said medical procedure. 12 . The method of claim 11 , wherein said at least one contour surface comprises an external surface of the prostrate or a portion thereof, a contour of an internal surface of the prostate or a portion thereof, a contour of a transitional zone of the prostate or a portion thereof, a contour of a central zone of the prostate or a portion thereof, a contour of a peripheral zone of the prostate or a portion thereof, a contour of an interface between a central zone and a peripheral zone of the prostate or a portion thereof, a contour of a surface bordering the prostate and the urethra or a portion thereof, a contour based on observable calcifications, or any combinations thereof, or any combination thereof. 13 . (canceled) 14 . The method of claim 11 , wherein said minimizes a matching cost criterion of step (i) is computed according to the count distribution of contour points falling within a plurality of histogram bins neighboring each landmark point. 15 . The method of claim 11 , wherein the dense deformation field is constrained to be smooth and invertible. 16 . (canceled) 17 . The method of claim 11 , wherein said medical procedure comprises a focal procedure, wherein said focal procedure comprises a prostatectomy, a robotic prostatectomy, a biopsy, a