Assessment and characterization of the total geometric uncertainty in Gamma Knife radiosurgery using polymer gels.

PURPOSE This work proposes and implements an experimental methodology, based on polymer gels, for assessing the total geometric uncertainty and characterizing its contributors in Gamma Knife (GK) radiosurgery. METHODS A treatment plan consisting of 26, 4-mm GK single shot dose distributions, covering an extended region of the Leksell stereotactic space, was prepared and delivered to a polymer gel filled polymethyl methacrylate (PMMA) head phantom (16 cm diameter) used to accurately reproduce every link in the GK treatment chain. The center of each shot served as a "control point" in the assessment of the GK total geometric uncertainty, which depends on (a) the spatial dose delivery uncertainty of the PERFEXION GK unit used in this work, (b) the spatial distortions inherent in MR images commonly used for target delineation, and (c) the geometric uncertainty contributor associated with the image registration procedure performed by the Leksell GammaPlan (LGP) treatment planning system (TPS), in the case that registration is directly based on the apparent fiducial locations depicted in each MR image by the N-shaped rods on the Leksell localization box. The irradiated phantom was MR imaged at 1.5 T employing a T2-weighted pulse sequence. Four image series were acquired by alternating the frequency encoding axis and reversing the read gradient polarity, thus allowing the characterization of the MR-related spatial distortions. RESULTS MR spatial distortions stemming from main field (B0) inhomogeneity as well as from susceptibility and chemical shift phenomena (also known as sequence dependent distortions) were found to be of the order of 0.5 mm, while those owing to gradient nonlinearities (also known as sequence independent distortions) were found to increase with distance from the MR scanner isocenter extending up to 0.47 mm at an Euclidean distance of 69.6 mm. Regarding the LGP image registration procedure, the corresponding average contribution to the total geometric uncertainty ranged from 0.34 to 0.80 mm. The average total geometric uncertainty, which also includes the GK spatial dose delivery uncertainty, was found equal to (0.88 ± 0.16), (0.88 ± 0.26), (1.02 ± 0.09), and (1.15 ± 0.24) mm for the MR image series acquired with the read gradient polarity (direction) set toward right, left, posterior, and anterior, respectively. CONCLUSIONS The implemented methodology seems capable of assessing the total geometric uncertainty, as well as of characterizing its contributors, ascribed to the entire GK treatment delivery (i.e., from MR imaging to GK dose delivery) for an extended region of the Leksell stereotactic space. Results obtained indicate that the selection of both the frequency encoding axis and the read gradient polarity during MRI acquisition may affect the magnitude as well as the spatial components of the total geometric uncertainty.

[1]  V. Løgager,et al.  Dosimetric and geometric evaluation of an open low-field magnetic resonance simulator for radiotherapy treatment planning of brain tumours. , 2008, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[2]  J. Michael Fitzpatrick,et al.  A technique for accurate magnetic resonance imaging in the presence of field inhomogeneities , 1992, IEEE Trans. Medical Imaging.

[3]  M. Levivier,et al.  Clinical evaluation of targeting accuracy of gamma knife radiosurgery in trigeminal neuralgia. , 2007, International journal of radiation oncology, biology, physics.

[4]  B Gino Fallone,et al.  Characterization, prediction, and correction of geometric distortion in 3 T MR images. , 2007, Medical physics.

[5]  Y. Hirokawa,et al.  Evaluation of dose delivery accuracy of Gamma Knife by polymer gel dosimetry , 2005, Journal of applied clinical medical physics.

[6]  Martin O Leach,et al.  A complete distortion correction for MR images: II. Rectification of static-field inhomogeneities by similarity-based profile mapping , 2005, Physics in medicine and biology.

[7]  P. Jursinic,et al.  Effect of image uncertainty on the dosimetry of trigeminal neuralgia irradiation. , 2005, International journal of radiation oncology, biology, physics.

[8]  P. Jursinic,et al.  Distortion of Magnetic Resonance Images Used in Gamma Knife Radiosurgery Treatment Planning: Implications for Acoustic Neuroma Outcomes , 2005, Otology & neurotology : official publication of the American Otological Society, American Neurotology Society [and] European Academy of Otology and Neurotology.

[9]  D. Dearnaley,et al.  Distortion-corrected T2 weighted MRI: a novel approach to prostate radiotherapy planning. , 2007, The British journal of radiology.

[10]  Yoichi Watanabe,et al.  Image distortion in MRI-based polymer gel dosimetry of gamma knife stereotactic radiosurgery systems. , 2002, Medical physics.

[11]  R. Heros,et al.  Early experience with Matrix detachable coils. , 2006, Journal of neurosurgery.

[12]  B Gino Fallone,et al.  A two-step scheme for distortion rectification of magnetic resonance images. , 2009, Medical physics.

[13]  G. Glover,et al.  Characterization of spatial distortion in magnetic resonance imaging and its implications for stereotactic surgery. , 1994, Neurosurgery.

[14]  Yoichi Watanabe,et al.  Image registration accuracy of GammaPlan: a phantom study. , 2008, Journal of neurosurgery.

[15]  Zbigniew Petrovich,et al.  An image fusion study of the geometric accuracy of magnetic resonance imaging with the Leksell stereotactic localization system1 , 2001, Journal of applied clinical medical physics.

[16]  J Yang,et al.  Investigation of MR image distortion for radiotherapy treatment planning of prostate cancer , 2005, Physics in medicine and biology.

[17]  F. Zanella,et al.  Analyzing 3-tesla magnetic resonance imaging units for implementation in radiosurgery. , 2005, Journal of neurosurgery.

[18]  E. Pantelis,et al.  Characterization of a new polymer gel for radiosurgery dosimetry using Magnetic Resonance Imaging , 2009 .

[19]  A Ertl,et al.  Quality assurance for the Leksell gamma unit: considering magnetic resonance image-distortion and delineation failure in the targeting of the internal auditory canal. , 1999, Medical physics.

[20]  B. Gerbi,et al.  Geometrical accuracy of a 3-tesla magnetic resonance imaging unit in Gamma Knife surgery. , 2006, Journal of neurosurgery.

[21]  M. Torrens,et al.  Gamma knife output factor measurements using VIP polymer gel dosimetry. , 2009, Medical physics.

[22]  Yoichi Watanabe,et al.  Heterogeneity phantoms for visualization of 3D dose distributions by MRI-based polymer gel dosimetry. , 2004, Medical physics.

[23]  Deming Wang,et al.  A novel phantom and method for comprehensive 3-dimensional measurement and correction of geometric distortion in magnetic resonance imaging. , 2004, Magnetic resonance imaging.

[24]  On the Development of the VIPAR Polymer Gel Dosimeter for Three‐Dimensional Dose Measurements , 2007 .

[25]  Alan Pollack,et al.  MRI-based treatment planning for radiotherapy: dosimetric verification for prostate IMRT. , 2004, International journal of radiation oncology, biology, physics.

[26]  C. Yu,et al.  A Phantom Study of the Geometric Accuracy of Computed Tomographic and Magnetic Resonance Imaging Stereotactic Localization with the Leksell Stereotactic System , 2001, Neurosurgery.

[27]  G. Bednarz,et al.  Evaluation of the spatial accuracy of magnetic resonance imaging-based stereotactic target localization for gamma knife radiosurgery of functional disorders. , 1999, Neurosurgery.

[28]  Martin O Leach,et al.  A complete distortion correction for MR images: I. Gradient warp correction , 2005, Physics in medicine and biology.

[29]  E. Pantelis,et al.  On the use of VIP gel dosimetry in HDR brachytherapy , 2009 .

[30]  W. J. Lorenz,et al.  Correction of spatial distortion in magnetic resonance angiography for radiosurgical treatment planning of cerebral arteriovenous malformations. , 1992, Magnetic resonance imaging.

[31]  B G Fallone,et al.  A study on the magnetic resonance imaging (MRI)-based radiation treatment planning of intracranial lesions , 2008, Physics in medicine and biology.

[32]  C Antypas,et al.  Dosimetric characterization of CyberKnife radiosurgical photon beams using polymer gels. , 2008, Medical physics.

[33]  Quality Assurance of Beam Accuracy for Leksell Gamma Unit , 2000, Journal of applied clinical medical physics.

[34]  Kai Schubert,et al.  Open low-field magnetic resonance imaging in radiation therapy treatment planning. , 2002, International journal of radiation oncology, biology, physics.

[35]  J. Vymazal,et al.  Does new magnetic resonance imaging technology provide better geometrical accuracy during stereotactic imaging? , 2005, Journal of neurosurgery.

[36]  F R Korosec,et al.  Development of a unique phantom to assess the geometric accuracy of magnetic resonance imaging for stereotactic localization. , 1999, Neurosurgery.

[37]  A. Jones Diagnostic imaging as a measuring device for stereotactic neurosurgery , 1993, Physiological measurement.

[38]  Bernhard Heck,et al.  Accuracy and stability of positioning in radiosurgery: long-term results of the Gamma Knife system. , 2007, Medical physics.

[39]  E Bellon,et al.  The contribution of magnetic resonance imaging to the three-dimensional treatment planning of localized prostate cancer. , 1999, International journal of radiation oncology, biology, physics.