Finite-element based validation of nonrigid registration using single-and multilevel free-form deformations: application to contrast-enhanced MR mammography

J A Schnabel; C Tanner; A D Castellano-Smith; A Degenhard; C Hayes; M O Leach; D R Hose; D L G Hill; D J Hawkes

Finite-element based validation of nonrigid registration using single-and multilevel free-form deformations: application to contrast-enhanced MR mammography

J A Schnabel, C Tanner, A D Castellano-Smith, A Degenhard, C Hayes, M O Leach, D R Hose, D L G Hill, D J Hawkes

King's College London

Research output: Chapter in Book/Report/Conference proceeding › Conference paper

Abstract

This work presents a validation study for non-rigid registration of 3D contrast enhanced magnetic resonance mammography images. We are using our previously developed methodology for simulating physically plausible, biomechanical tissue deformations using finite element methods to compare two non-rigid registration algorithms based on single-level and multi-level free-form deformations using B-splines and normalized mutual information. We have constructed four patient-specific finite element models and applied the solutions to the original post-contrast scans of the patients, simulating tissue deformation between image acquisitions. The original image pairs were registered to the FEM-deformed post-contrast images using different free-form deformation mesh resolutions. The target registration error was computed for each experiment with respect to the simulated gold standard on a voxel basis. Registration error and single-level free-form deformation resolution were found to be intrinsically related: the smaller the spacing, the higher localized errors, indicating local registration failure. For multi-level free-form deformations, the registration errors improved for increasing mesh resolution. This study forms an important milestone in making our non-rigid registration framework applicable for clinical routine use. (27 References).

Original language	English
Title of host publication	Proceedings of SPIE - the International Society for Optical Engineering
Publisher	SPIE-Int. Soc. Opt. Eng.
Pages	550 - 561
Number of pages	12
Publication status	Published - 2002
Event	Medical Imaging 2002 Conference - SAN DIEGO, CALIFORNIA Duration: 24 Feb 2002 → 26 Feb 2002

Conference

Conference	Medical Imaging 2002 Conference
City	SAN DIEGO, CALIFORNIA
Period	24/02/2002 → 26/02/2002

Cite this

Schnabel, J. A., Tanner, C., Castellano-Smith, A. D., Degenhard, A., Hayes, C., Leach, M. O., Hose, D. R., Hill, D. L. G., & Hawkes, D. J. (2002). Finite-element based validation of nonrigid registration using single-and multilevel free-form deformations: application to contrast-enhanced MR mammography. In Proceedings of SPIE - the International Society for Optical Engineering (pp. 550 - 561). SPIE-Int. Soc. Opt. Eng..

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title = "Finite-element based validation of nonrigid registration using single-and multilevel free-form deformations: application to contrast-enhanced MR mammography",

abstract = "This work presents a validation study for non-rigid registration of 3D contrast enhanced magnetic resonance mammography images. We are using our previously developed methodology for simulating physically plausible, biomechanical tissue deformations using finite element methods to compare two non-rigid registration algorithms based on single-level and multi-level free-form deformations using B-splines and normalized mutual information. We have constructed four patient-specific finite element models and applied the solutions to the original post-contrast scans of the patients, simulating tissue deformation between image acquisitions. The original image pairs were registered to the FEM-deformed post-contrast images using different free-form deformation mesh resolutions. The target registration error was computed for each experiment with respect to the simulated gold standard on a voxel basis. Registration error and single-level free-form deformation resolution were found to be intrinsically related: the smaller the spacing, the higher localized errors, indicating local registration failure. For multi-level free-form deformations, the registration errors improved for increasing mesh resolution. This study forms an important milestone in making our non-rigid registration framework applicable for clinical routine use. (27 References).",

author = "Schnabel, {J A} and C Tanner and Castellano-Smith, {A D} and A Degenhard and C Hayes and Leach, {M O} and Hose, {D R} and Hill, {D L G} and Hawkes, {D J}",

year = "2002",

language = "English",

pages = "550 -- 561",

booktitle = "Proceedings of SPIE - the International Society for Optical Engineering",

publisher = "SPIE-Int. Soc. Opt. Eng.",

note = "Medical Imaging 2002 Conference ; Conference date: 24-02-2002 Through 26-02-2002",

}

Schnabel, JA, Tanner, C, Castellano-Smith, AD, Degenhard, A, Hayes, C, Leach, MO, Hose, DR, Hill, DLG & Hawkes, DJ 2002, Finite-element based validation of nonrigid registration using single-and multilevel free-form deformations: application to contrast-enhanced MR mammography. in Proceedings of SPIE - the International Society for Optical Engineering. SPIE-Int. Soc. Opt. Eng., pp. 550 - 561, Medical Imaging 2002 Conference, SAN DIEGO, CALIFORNIA, 24/02/2002.

Finite-element based validation of nonrigid registration using single-and multilevel free-form deformations: application to contrast-enhanced MR mammography. / Schnabel, J A; Tanner, C; Castellano-Smith, A D et al.
Proceedings of SPIE - the International Society for Optical Engineering. SPIE-Int. Soc. Opt. Eng., 2002. p. 550 - 561.

Research output: Chapter in Book/Report/Conference proceeding › Conference paper

TY - CHAP

T1 - Finite-element based validation of nonrigid registration using single-and multilevel free-form deformations: application to contrast-enhanced MR mammography

AU - Schnabel, J A

AU - Tanner, C

AU - Castellano-Smith, A D

AU - Degenhard, A

AU - Hayes, C

AU - Leach, M O

AU - Hose, D R

AU - Hill, D L G

AU - Hawkes, D J

PY - 2002

Y1 - 2002

N2 - This work presents a validation study for non-rigid registration of 3D contrast enhanced magnetic resonance mammography images. We are using our previously developed methodology for simulating physically plausible, biomechanical tissue deformations using finite element methods to compare two non-rigid registration algorithms based on single-level and multi-level free-form deformations using B-splines and normalized mutual information. We have constructed four patient-specific finite element models and applied the solutions to the original post-contrast scans of the patients, simulating tissue deformation between image acquisitions. The original image pairs were registered to the FEM-deformed post-contrast images using different free-form deformation mesh resolutions. The target registration error was computed for each experiment with respect to the simulated gold standard on a voxel basis. Registration error and single-level free-form deformation resolution were found to be intrinsically related: the smaller the spacing, the higher localized errors, indicating local registration failure. For multi-level free-form deformations, the registration errors improved for increasing mesh resolution. This study forms an important milestone in making our non-rigid registration framework applicable for clinical routine use. (27 References).

AB - This work presents a validation study for non-rigid registration of 3D contrast enhanced magnetic resonance mammography images. We are using our previously developed methodology for simulating physically plausible, biomechanical tissue deformations using finite element methods to compare two non-rigid registration algorithms based on single-level and multi-level free-form deformations using B-splines and normalized mutual information. We have constructed four patient-specific finite element models and applied the solutions to the original post-contrast scans of the patients, simulating tissue deformation between image acquisitions. The original image pairs were registered to the FEM-deformed post-contrast images using different free-form deformation mesh resolutions. The target registration error was computed for each experiment with respect to the simulated gold standard on a voxel basis. Registration error and single-level free-form deformation resolution were found to be intrinsically related: the smaller the spacing, the higher localized errors, indicating local registration failure. For multi-level free-form deformations, the registration errors improved for increasing mesh resolution. This study forms an important milestone in making our non-rigid registration framework applicable for clinical routine use. (27 References).

M3 - Conference paper

SP - 550

EP - 561

BT - Proceedings of SPIE - the International Society for Optical Engineering

PB - SPIE-Int. Soc. Opt. Eng.

T2 - Medical Imaging 2002 Conference

Y2 - 24 February 2002 through 26 February 2002

ER -

Finite-element based validation of nonrigid registration using single-and multilevel free-form deformations: application to contrast-enhanced MR mammography

Abstract

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