Spatial Distortion in MRI-Guided Stereotactic Procedures: Evaluation in 1.5-, 3- and 7-Tesla MRI Scanners

Neumann, Jennifer; Giese, Henrik; Biller, Armin; Nagel, Armin M.; Kiening, Karl

doi:10.1159/000441233

Cited by 23 publications

(22 citation statements)

References 19 publications

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“…However, the surgical procedure itself has remained relatively unchanged since its inception over thirty years ago (Benabid et al 1987, Sironi 2011). Although the surgical procedure varies from institution to institution, its success depends on the accurate placement of DBS electrodes into targeted brain structures, supported by precision stereotactic devices (Nakazawa et al 2014, Neumann et al 2015, Seibert et al 2016). The gold-standard traditional stereotactic system- the Leksell™ (Elekta, Stockholm, Sweden)- achieves this precision through a rigid head frame that remains affixed throughout the surgical planning and electrode placement to preserve the precision of the stereotactic coordinate space as mapped to the patient’s anatomy through MR images.…”

Section: Introductionmentioning

confidence: 99%

A novel re-attachable stereotactic frame for MRI-guided neuronavigation and its validation in a large animal and human cadaver model

Edwards

Rusheen

et al. 2018

J. Neural Eng.

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Objective. Stereotactic frame systems are the gold-standard for stereotactic surgeries, such as implantation of deep brain stimulation (DBS) devices for treatment of medically resistant neurologic and psychiatric disorders. However, frame-based systems require that the patient is awake with a stereotactic frame affixed to their head for the duration of the surgical planning and implantation of the DBS electrodes. While frameless systems are increasingly available, a reusable re-attachable frame system provides unique benefits. As such, we created a novel reusable MRI-compatible stereotactic frame system that maintains clinical accuracy through the detachment and reattachment of its stereotactic devices used for MRI-guided neuronavigation. Approach. We designed a reusable arc-centered frame system that includes MRI-compatible anchoring skull screws for detachment and re-attachment of its stereotactic devices. We validated the stability and accuracy of our system through phantom, in vivo mock-human porcine DBS-model and human cadaver testing. Main results. Phantom testing achieved a root mean square error (RMSE) of 0.94 ± 0.23 mm between the ground truth and the frame-targeted coordinates; and achieved an RMSE of 1.11 ± 0.40 mm and 1.33 ± 0.38 mm between the ground truth and the CT- and MRI-targeted coordinates, respectively. In vivo and cadaver testing achieved a combined 3D Euclidean localization error of 1.85 ± 0.36 mm (p < 0.03) between the pre-operative MRI-guided placement and the post-operative CT-guided confirmation of the DBS electrode. Significance. Our system demonstrated consistent clinical accuracy that is comparable to conventional frame and frameless stereotactic systems. Our frame system is the first to demonstrate accurate relocation of stereotactic frame devices during in vivo MRI-guided DBS surgical procedures. As such, this reusable and re-attachable MRI-compatible system is expected to enable more complex, chronic neuromodulation experiments, and lead to a clinically available re-attachable frame that is expected to decrease patient discomfort and costs of DBS surgery002E

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Section: Introductionmentioning

confidence: 99%

A novel re-attachable stereotactic frame for MRI-guided neuronavigation and its validation in a large animal and human cadaver model

Edwards

Rusheen

et al. 2018

J. Neural Eng.

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“…The spatial dependence of gradient fields is mainly determined by the design of the gradient coils and is expected to be effectively corrected by the general image post‐processing provided by the MRI manufacturer. Although strictly speaking this issue needs to be revisited for each MRI system, in our experience the main MRI manufacturers use similar technology and the provided correction for gradient non‐uniformity achieves similar results around the isocenter; the literature confirms that system‐related distortions are clinically acceptable at 3.0 T and at 7.0 T in a wide variety of clinical systems. Studies considering longitudinal changes in geometrical distortion in general suggest stability of the distortion pattern .…”

Section: Discussionmentioning

confidence: 67%

“…Considering the skull, there is widespread consensus in the literature that susceptibility‐induced displacements are most relevant in the vicinity of airspaces, and are emphasized at higher field strength . Duchin et al.…”

Section: Discussionmentioning

confidence: 99%

“…Considering the skull, there is widespread consensus in the literature that susceptibility-induced displacements are most relevant in the vicinity of airspaces, and are emphasized at higher field strength. [17][18][19][20][21] Duchin et al used transformation matrixes from MR-CT co-registration to assess the level of distortion, and only found sub-millimeter errors. 19 Wang et al mapped magnetic field from the top of the head to the bottom of the cerebellum, confirming higher field inhomogeneity surrounding air spaces.…”

Section: Discussionmentioning

confidence: 99%

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Stereotactic radiosurgery planning of vestibular schwannomas: IsMRIat 3 Tesla geometrically accurate?

et al. 2017

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Purpose MRI is a mandatory requirement to accurately plan Stereotactic Radiosurgery (SRS) for Vestibular Schwannomas. However, MRI may be distorted due not only to inhomogeneity of the static magnetic field and gradients but also due to susceptibility‐induced effects, which are more prominent at higher magnetic fields. We assess geometrical distortions around air spaces and consider MRI protocol requirements for SRS planning at 3 T.MethodsHardware‐related distortion and the effect of incorrect shimming were investigated with structured test objects. The magnetic field was mapped over the head on five volunteers to assess susceptibility‐related distortion in the naso‐oro‐pharyngeal cavities (NOPC) and around the internal ear canal (IAC).ResultsHardware‐related geometric displacements were found to be less than 0.45 mm within the head volume, after distortion correction. Shimming errors can lead to displacements of up to 4 mm, but errors of this magnitude are unlikely to arise in practice. Susceptibility‐related field inhomogeneity was under 3.4 ppm, 2.8 ppm, and 2.7 ppm for the head, NOPC region and IAC region, respectively. For the SRS planning protocol (890 Hz/pixel, approximately 1 mm3 isotropic), susceptibility‐related displacements were less than 0.5 mm (head), and 0.4 mm (IAC and NOPC). Large displacements are possible in MRI examinations undertaken with lower receiver bandwidth values, commonly used in clinical MRI. Higher receiver bandwidth makes the protocol less vulnerable to sub‐optimal shimming. The shimming volume and the CT‐MR co‐registration must be considered jointly.ConclusionGeometric displacements can be kept under 1 mm in the vicinity of air spaces within the head at 3 T with appropriate setting of the receiver bandwidth, correct shimming and employing distortion correction.

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“…As MR-CT registration has been shown to reduce positional errors introduced by MRI, minimization of MR distortions becomes even more relevant, when opting for an MR-only workflow [29].…”

Section: Promises Of Synthetic Ct and Mr-only Planningmentioning

confidence: 99%

Magnetic resonance imaging for brain stereotactic radiotherapy

et al. 2020

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Due to its superior soft tissue contrast, magnetic resonance imaging (MRI) is essential for many radiotherapy treatment indications. This is especially true for treatment planning in intracranial tumors, where MRI has a long-standing history for target delineation in clinical practice. Despite its routine use, care has to be taken when selecting and acquiring MRI studies for the purpose of radiotherapy treatment planning. Requirements on MRI are particularly demanding for intracranial stereotactic radiotherapy, where accurate imaging has a critical role in treatment success. However, MR images acquired for routine radiological assessment are frequently unsuitable for high-precision stereotactic radiotherapy as the requirements for imaging are significantly different for radiotherapy planning and diagnostic radiology. To assure that optimal imaging is used for treatment planning, the radiation oncologist needs proper knowledge of the most important requirements concerning the use of MRI in brain stereotactic radiotherapy. In the present review, we summarize and discuss the most relevant issues when using MR images for target volume delineation in intracranial stereotactic radiotherapy.

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Spatial Distortion in MRI-Guided Stereotactic Procedures: Evaluation in 1.5-, 3- and 7-Tesla MRI Scanners

Cited by 23 publications

References 19 publications

A novel re-attachable stereotactic frame for MRI-guided neuronavigation and its validation in a large animal and human cadaver model

A novel re-attachable stereotactic frame for MRI-guided neuronavigation and its validation in a large animal and human cadaver model

Stereotactic radiosurgery planning of vestibular schwannomas: IsMRIat 3 Tesla geometrically accurate?

Magnetic resonance imaging for brain stereotactic radiotherapy

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