On the use of EPID‐based implanted marker tracking for 4D radiotherapy

Keall, P.; Todor, Andrei; Vedam, S; Bartee, C.; Siebers, Jeffrey V.; Kini, V. R.; Mohan, Radhe

doi:10.1118/1.1812608

Cited by 98 publications

(74 citation statements)

References 38 publications

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“…Multiple images can be taken to monitor patient movement and to readjust patient position between fields if such movement occurs. However, for applications involving continuous tracking of patient movement, such as for respiratory motion tracking or gating using an internal surrogate, (22) images have to be taken at a much higher frequency

(> 10 / s)

to reduce potential time delays (23) . The total dose could be significant, and optimal technical settings should be used in such an application.…”

Section: Discussionmentioning

confidence: 99%

Clinical assessment and characterization of a dual‐tube kilovoltage X‐ray localization system in the radiotherapy treatment room

Lee

Jin

Guan

et al. 2008

J Applied Clin Med Phys

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Although flat‐panel kilovoltage X‐ray imaging devices have been well tested for clinical use in diagnostic radiology, their use as a part of an image‐guided radiation therapy (IGRT) system in a treatment room is new and requires systematic assessment.We used the Novalis IGRT system (BrainLAB, Feldkirchen, Germany) for the present study. The system consists of two floor‐mounted kilovoltage X‐ray tubes projecting obliquely onto two flat‐panel detectors mounted on the ceiling. The system can automatically fuse two‐dimensional localization images with three‐dimensional simulation computed tomography images to provide positioning guidance. We evaluated these system parameters: Overall performance of the IGRT system, including isocenter correlation between the IGRT system and the linear accelerator (LINAC)Image quality of the systemExposure received by patients for a pair of imagesLinearity, uniformity, and repeatability of the system The Novalis system uses a daily isocenter calibration procedure to ensure consistency of isocenters between the IGRT and the LINAC systems. The localization accuracy was about 1 mm. We measured the relative modulation transfer function (RMTF) to quantify the spatial resolution of the imaging device, with f50 being 0.7 – 0.9 line pairs per millimeter. The maximal exposure of an image was 95 mR. We derived an empirical relationship between the exposure and the X‐ray technical settings. The other parameters of the system were quantitatively measured and generally met the requirements.The IGRT system is safe and reliable for clinical use as a target localization device. The measured data can be used as a benchmark for a quality assurance procedure.PACS number: 87.56‐v

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(> 10 / s)

to reduce potential time delays (23) . The total dose could be significant, and optimal technical settings should be used in such an application.…”

Section: Discussionmentioning

confidence: 99%

Clinical assessment and characterization of a dual‐tube kilovoltage X‐ray localization system in the radiotherapy treatment room

Lee

Jin

Guan

et al. 2008

J Applied Clin Med Phys

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“…The time taken to acquire a volume of data, t vol , is proportional to the product of the imaging depth (ID), the number of lines (L), and the number of frames (F). To track organ motion due to respiration in real-time, assuming a breathing cycle of 3-5 seconds, we require a volume acquisition rate, 1/t vol , of ~10 Hz (Keall et al 2004). To achieve this volume acquisition rate without restricting the field of view to a few cubic centimetres, spatial resolution has to be sacrificed using techniques such as parallel beam forming in receive mode (Smith et al 1991) or by reducing the spatial sampling frequency (so as to reduce L or F).…”

Section: Introductionmentioning

confidence: 99%

Performance of ultrasound based measurement of 3D displacement using a curvilinear probe for organ motion tracking

Harris

Miller²,

Bamber³

et al. 2007

Phys. Med. Biol.

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Three-dimensional (3D) soft tissue tracking is of interest for monitoring organ motion during therapy. Our goal is to assess the tracking performance of a curvilinear 3D ultrasound probe in terms of the accuracy and precision of measured displacements. The first aim was to examine the depth dependence of the tracking performance. This is of interest because the spatial resolution varies with distance from the elevational focus and because the curvilinear geometry of the transducer Page 2 of 39 causes the spatial sampling frequency to decrease with depth. Our second aim was to assess tracking performance as a function of the spatial sampling setting (low, medium or high sampling). These settings are incorporated onto 3D ultrasound machines to allow the user to control the trade-off between spatial sampling and temporal resolution. Volume images of a speckle-producing phantom were acquired before and after the probe had been moved by a known displacement (1, 2 or 8 mm).This allowed us to assess the optimum performance of the tracking algorithm, in the absence of motion. 3D speckle tracking was performed using 3D cross-correlation and sub-voxel displacements were estimated. The tracking performance was found to be best for y displacements and poorest for z displacements. In general, the performance decreased with depth, although the nature of the depth dependence was complex.Under certain conditions, the tracking performance was sufficient to be useful for monitoring organ motion. For example, at the highest sampling setting, for a 2 mm displacement, good accuracy and precision (an error and standard deviation of <0.4mm) were observed at all depths and for all directions of displacement. The trade-off between spatial sampling, temporal resolution and size of field of view is discussed.

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“…Of more concern is the fact that the beam is triggered by the breathing signal and often there is no real-time verification of the actual tumour position during beam-on time. However, it has been shown that it is achievable using implanted markers (Berbeco et al, 2005b;Keall et al, 2004). Another approach, to be discussed now, is tracking the tumour during irradiation and correcting for it in real-time (Keall et al, 2001;Murphy, 2004).…”

Section: Dynamic Compensation For Intra-fractional Tumour Movementmentioning

confidence: 99%

On the Use of a Hexapod Table to Improve Tumour Targeting in Radiation Therapy

Meyer¹,

Gückenberger²,

Wilbert³

et al. 2007

Bioinspiration and Robotics Walking and Climbing Robots

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On the use of EPID‐based implanted marker tracking for 4D radiotherapy

Cited by 98 publications

References 38 publications

Clinical assessment and characterization of a dual‐tube kilovoltage X‐ray localization system in the radiotherapy treatment room

Clinical assessment and characterization of a dual‐tube kilovoltage X‐ray localization system in the radiotherapy treatment room

Performance of ultrasound based measurement of 3D displacement using a curvilinear probe for organ motion tracking

On the Use of a Hexapod Table to Improve Tumour Targeting in Radiation Therapy

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