The effects of computed tomography image characteristics and knot spacing on the spatial accuracy of B-spline deformable image registration in the head and neck geometry

Charlotte L. Brouwer; Roel G J Kierkels; Aart A. van t Veld; Nanna M. Sijtsema; Harm Meertens

doi:10.1186/1748-717X-9-169

The effects of computed tomography image characteristics and knot spacing on the spatial accuracy of B-spline deformable image registration in the head and neck geometry

Charlotte L. Brouwer^*, Roel G J Kierkels, Aart A. van t Veld, Nanna M. Sijtsema, Harm Meertens

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

5 Citations (Scopus)

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Abstract

Objectives: To explore the effects of computed tomography (CT) image characteristics and B-spline knot spacing (BKS) on the spatial accuracy of a B-spline deformable image registration (DIR) in the head-and-neck geometry.

Methods: The effect of image feature content, image contrast, noise, and BKS on the spatial accuracy of a B-spline DIR was studied. Phantom images were created with varying feature content and varying contrast-to-noise ratio (CNR), and deformed using a known smooth B-spline deformation. Subsequently, the deformed images were repeatedly registered with the original images using different BKSs. The quality of the DIR was expressed as the mean residual displacement (MRD) between the known imposed deformation and the result of the B-spline DIR. Finally, for three patients, head-and-neck planning CT scans were deformed with a realistic deformation field derived from a rescan CT of the same patient, resulting in a simulated deformed image and an a-priori known deformation field. Hence, a B-spline DIR was performed between the simulated image and the planning CT at different BKSs. Similar to the phantom cases, the DIR accuracy was evaluated by means of MRD.

Results: In total, 162 phantom registrations were performed with varying CNR and BKSs. MRD-values <1.0 mm were observed with a BKS between 10-20 mm for image contrast >= +/- 250 HU and noise <+/- 200 HU. Decreasing the image feature content resulted in increased MRD-values at all BKSs. Using BKS = 15 mm for the three clinical cases resulted in an average MRD <1.0 mm.

Conclusions: For synthetically generated phantoms and three real CT cases the highest DIR accuracy was obtained for a BKS between 10-20 mm. The accuracy decreased with decreasing image feature content, decreasing image contrast, and higher noise levels. Our results indicate that DIR accuracy in clinical CT images (typical noise levels <+/- 100 HU) will not be effected by the amount of image noise.

Original language	English
Number of pages	10
Journal	Radiation oncology
Volume	9
Issue number	169
DOIs	https://doi.org/10.1186/1748-717X-9-169
Publication status	Published - 29-Jul-2014

Keywords

Deformable image registration
B-spline transformation model
Spatial accuracy
B-spline knot spacing
Contrast-to-noise ratio
Head-and-neck
Computed tomography
ADAPTIVE RADIATION-THERAPY
NONRIGID REGISTRATION
GUIDED RADIOTHERAPY
CANCER
VALIDATION
ALGORITHM
CT

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@article{c9b94eaedd9a4df4a664b3907767ba02,

title = "The effects of computed tomography image characteristics and knot spacing on the spatial accuracy of B-spline deformable image registration in the head and neck geometry",

abstract = "Objectives: To explore the effects of computed tomography (CT) image characteristics and B-spline knot spacing (BKS) on the spatial accuracy of a B-spline deformable image registration (DIR) in the head-and-neck geometry.Methods: The effect of image feature content, image contrast, noise, and BKS on the spatial accuracy of a B-spline DIR was studied. Phantom images were created with varying feature content and varying contrast-to-noise ratio (CNR), and deformed using a known smooth B-spline deformation. Subsequently, the deformed images were repeatedly registered with the original images using different BKSs. The quality of the DIR was expressed as the mean residual displacement (MRD) between the known imposed deformation and the result of the B-spline DIR. Finally, for three patients, head-and-neck planning CT scans were deformed with a realistic deformation field derived from a rescan CT of the same patient, resulting in a simulated deformed image and an a-priori known deformation field. Hence, a B-spline DIR was performed between the simulated image and the planning CT at different BKSs. Similar to the phantom cases, the DIR accuracy was evaluated by means of MRD.Results: In total, 162 phantom registrations were performed with varying CNR and BKSs. MRD-values <1.0 mm were observed with a BKS between 10-20 mm for image contrast >= +/- 250 HU and noise <+/- 200 HU. Decreasing the image feature content resulted in increased MRD-values at all BKSs. Using BKS = 15 mm for the three clinical cases resulted in an average MRD <1.0 mm.Conclusions: For synthetically generated phantoms and three real CT cases the highest DIR accuracy was obtained for a BKS between 10-20 mm. The accuracy decreased with decreasing image feature content, decreasing image contrast, and higher noise levels. Our results indicate that DIR accuracy in clinical CT images (typical noise levels <+/- 100 HU) will not be effected by the amount of image noise.",

keywords = "Deformable image registration, B-spline transformation model, Spatial accuracy, B-spline knot spacing, Contrast-to-noise ratio, Head-and-neck, Computed tomography, ADAPTIVE RADIATION-THERAPY, NONRIGID REGISTRATION, GUIDED RADIOTHERAPY, CANCER, VALIDATION, ALGORITHM, CT",

author = "Brouwer, {Charlotte L.} and Kierkels, {Roel G J} and {van t Veld}, {Aart A.} and Sijtsema, {Nanna M.} and Harm Meertens",

year = "2014",

month = jul,

day = "29",

doi = "10.1186/1748-717X-9-169",

language = "English",

volume = "9",

journal = "Radiation oncology",

issn = "1748-717X",

publisher = "BMC",

number = "169",

}

The effects of computed tomography image characteristics and knot spacing on the spatial accuracy of B-spline deformable image registration in the head and neck geometry. / Brouwer, Charlotte L.; Kierkels, Roel G J; van t Veld, Aart A. et al.
In: Radiation oncology, Vol. 9, No. 169, 29.07.2014.

Research output: Contribution to journal › Article › Academic › peer-review

TY - JOUR

T1 - The effects of computed tomography image characteristics and knot spacing on the spatial accuracy of B-spline deformable image registration in the head and neck geometry

AU - Brouwer, Charlotte L.

AU - Kierkels, Roel G J

AU - van t Veld, Aart A.

AU - Sijtsema, Nanna M.

AU - Meertens, Harm

PY - 2014/7/29

Y1 - 2014/7/29

N2 - Objectives: To explore the effects of computed tomography (CT) image characteristics and B-spline knot spacing (BKS) on the spatial accuracy of a B-spline deformable image registration (DIR) in the head-and-neck geometry.Methods: The effect of image feature content, image contrast, noise, and BKS on the spatial accuracy of a B-spline DIR was studied. Phantom images were created with varying feature content and varying contrast-to-noise ratio (CNR), and deformed using a known smooth B-spline deformation. Subsequently, the deformed images were repeatedly registered with the original images using different BKSs. The quality of the DIR was expressed as the mean residual displacement (MRD) between the known imposed deformation and the result of the B-spline DIR. Finally, for three patients, head-and-neck planning CT scans were deformed with a realistic deformation field derived from a rescan CT of the same patient, resulting in a simulated deformed image and an a-priori known deformation field. Hence, a B-spline DIR was performed between the simulated image and the planning CT at different BKSs. Similar to the phantom cases, the DIR accuracy was evaluated by means of MRD.Results: In total, 162 phantom registrations were performed with varying CNR and BKSs. MRD-values <1.0 mm were observed with a BKS between 10-20 mm for image contrast >= +/- 250 HU and noise <+/- 200 HU. Decreasing the image feature content resulted in increased MRD-values at all BKSs. Using BKS = 15 mm for the three clinical cases resulted in an average MRD <1.0 mm.Conclusions: For synthetically generated phantoms and three real CT cases the highest DIR accuracy was obtained for a BKS between 10-20 mm. The accuracy decreased with decreasing image feature content, decreasing image contrast, and higher noise levels. Our results indicate that DIR accuracy in clinical CT images (typical noise levels <+/- 100 HU) will not be effected by the amount of image noise.

AB - Objectives: To explore the effects of computed tomography (CT) image characteristics and B-spline knot spacing (BKS) on the spatial accuracy of a B-spline deformable image registration (DIR) in the head-and-neck geometry.Methods: The effect of image feature content, image contrast, noise, and BKS on the spatial accuracy of a B-spline DIR was studied. Phantom images were created with varying feature content and varying contrast-to-noise ratio (CNR), and deformed using a known smooth B-spline deformation. Subsequently, the deformed images were repeatedly registered with the original images using different BKSs. The quality of the DIR was expressed as the mean residual displacement (MRD) between the known imposed deformation and the result of the B-spline DIR. Finally, for three patients, head-and-neck planning CT scans were deformed with a realistic deformation field derived from a rescan CT of the same patient, resulting in a simulated deformed image and an a-priori known deformation field. Hence, a B-spline DIR was performed between the simulated image and the planning CT at different BKSs. Similar to the phantom cases, the DIR accuracy was evaluated by means of MRD.Results: In total, 162 phantom registrations were performed with varying CNR and BKSs. MRD-values <1.0 mm were observed with a BKS between 10-20 mm for image contrast >= +/- 250 HU and noise <+/- 200 HU. Decreasing the image feature content resulted in increased MRD-values at all BKSs. Using BKS = 15 mm for the three clinical cases resulted in an average MRD <1.0 mm.Conclusions: For synthetically generated phantoms and three real CT cases the highest DIR accuracy was obtained for a BKS between 10-20 mm. The accuracy decreased with decreasing image feature content, decreasing image contrast, and higher noise levels. Our results indicate that DIR accuracy in clinical CT images (typical noise levels <+/- 100 HU) will not be effected by the amount of image noise.

KW - Deformable image registration

KW - B-spline transformation model

KW - Spatial accuracy

KW - B-spline knot spacing

KW - Contrast-to-noise ratio

KW - Head-and-neck

KW - Computed tomography

KW - ADAPTIVE RADIATION-THERAPY

KW - NONRIGID REGISTRATION

KW - GUIDED RADIOTHERAPY

KW - CANCER

KW - VALIDATION

KW - ALGORITHM

KW - CT

U2 - 10.1186/1748-717X-9-169

DO - 10.1186/1748-717X-9-169

M3 - Article

SN - 1748-717X

VL - 9

JO - Radiation oncology

JF - Radiation oncology

IS - 169

ER -

The effects of computed tomography image characteristics and knot spacing on the spatial accuracy of B-spline deformable image registration in the head and neck geometry

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