Stereotactic radiosurgery: Dose‐volume analysis of linear accelerator techniques

Serago, Christopher F.; Houdek, Pavel V.; Bauer-Kirpes, Bernhard; Lewin, Alan A.; Abitbol, Andre; Gonzalez‐Arias, Sergio; Marcial-Vega, Víctor; Schwade, James G.

doi:10.1118/1.596931

Cited by 30 publications

(8 citation statements)

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“…Radiosurgical treatment plans were devised using the cobalt-60 and 10 MV beams. The arc geometries were based on treatment plan optimization criteria described by Schell et al 15 and Serago et al, 16 who compared the cumulative dose volume histograms for different noncoplanar and dynamic radiosurgical arc techniques, and reported that the normal tissue dose is minimized when ͑a͒ the arc planes are distributed evenly; ͑b͒ individual arc lengths are less than 180°; and ͑c͒ the total arc traversal is greater than 400°per isocenter. In accordance with these guidelines, the radiosur-gical techniques used in our work consisted of four, six, eight, or ten noncoplanar converging arcs, distributed evenly over the coronal plane between the couch angle limits of Ϯ75°, with each arc traversing 120°for a total minimum arc traversal of 480°.…”

Section: G Evaluation Of Radiosurgical Treatment Plansmentioning

confidence: 99%

Viability of an isocentric cobalt‐60 teletherapy unit for stereotactic radiosurgery

Poffenbarger

Podgoršak

1998

Medical Physics

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This manuscript has been reproduced from the miadilm master. UMI films the text directly from the original or copy submiUed. Thus, m e thesis and dissertation copies are in typewriter face, while others may be from any type of computer printer.The quality of this mproductkn is dependent upon the quality of the copy submitted. Broken or indistinct print, cobred or poor quality illustrations and photographs, print Meedthrough, substandard margins, and improper alignment can adversely affect repmduction.In the unlikely event that Ihe author did not rend UMI a complete manuscript and there are missing pages, Wse will be noted. Also, if unauthorized copyright material had to be removed, a note will indicate the deletion.Oversize materials (e.g., mapsl dnwihgs, charts) are reproduced by sectioning the original, beginning at the upper lefthand comer and continuing from left to right in equal sedans with small overlaps.Photqpphs induded in the original manuscript have been teproducd xerographically in this copy. Higher quality 6 ' x 9" black and white photographic prints are available for any photographs or illustrations appearing in this copy for an additional charge. Contact UMI directly to order. Bll

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Section: G Evaluation Of Radiosurgical Treatment Plansmentioning

confidence: 99%

Viability of an isocentric cobalt‐60 teletherapy unit for stereotactic radiosurgery

Poffenbarger

Podgoršak

1998

Medical Physics

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“…Serago (19) uses arcs technique for most radiosurgical cases: 'Although the dose volume histogram for 4 vs. 6 arcs is essentially identical, we feel, there is a minor safety advantage of using more arcs.' He also adds that the differences between techniques are only appreciated at the lower isodose levels that are not generally clinically significant.…”

Section: Discussionmentioning

confidence: 99%

“…Several authors argue that the DVH is an effective tool in evaluating 3-D plans (11)(12)(13)(14). The use of DVH as a basis for comparison between three-dimensional dose distributions provided by different stereotactic radiotherapy techniques has been reported in the literature (10,(15)(16)(17)(18)(19)(20). In this study a DVH analysis of radiosurgical techniques, based on Linac and Gamma Knife, will be reported.…”

Section: Original Articlementioning

confidence: 95%

Dose-volume Analysis of Different Stereotactic Radiotherapy Mono-isocentric Techniques

Theodorou

Platoni²,

Lefkopoulos³

et al. 2000

Acta Oncologica

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Several stereotactic irradiation techniques, using Linacs with the patient in lying and sitting position and a Gamma Knife Unit, were compared with regard to mono-isocentric three-dimensional dose distributions. Three types of target volumes, a sphere and two ellipsoids, were used for the comparisons. All three targets were centered on a real head, reconstructed from transversal CT scans. The ARTEMIS 3D Treatment Planning System, developed by the Tenon Hospital, Paris, was used for the dosimetry and the dose-volume histogram (DVH) calculation. For the comparative study, several quantitative parameters were used, derived from the dose-volume histogram calculation. Differential DVHs were plotted for each target volume and beam arrangement. Irradiation techniques were compared by deriving quantitative parameters from the DVHs such as mean and integral dose delivered to the target and normal tissue irradiated, as well as by the relative volume of the examined areas. All techniques used in this study produced very similar dose distributions. The small differences confirm the capability of the studied techniques to produce the same irradiation effects. By changing from the spherical target shape to a more elliptical shape, more of the normal tissue was irradiated with higher doses. For elliptical cases we therefore identified a need for more conformal stereotactic planning.

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“…A technique using a target point simulator to verify the stereotactic coordinates prior to treatment has been described by Lutz et al 2 and was used by others in a number of studies. [3][4]8,10 However, the alignment verification of the target simulator has usually been done by visual inspection of portal films, which is slow and usually qualitative. By using the electronic portal imaging device ͑EPID͒, digital images can be quickly acquired and quantitative alignment errors may be calculated by analyzing the digital portal images.…”

Section: Introductionmentioning

confidence: 99%

“…Many investigators have studied the accuracy and precision requirements for this treatment technique. [1][2][3][4][5][6][7][8][9][10] The Brown-Roberts-Wells ͑BRW͒ neurosurgical stereotactic system 11,12 uses computed tomography, angiography, magnetic resonance imaging, or a combination of these to relate the target position to the BRW coordinate system. An important quality assurance step is to verify the alignment of the target center in the BRW coordinate system with the radiation center of a linac.…”

Section: Introductionmentioning

confidence: 99%

Verification of radiosurgery target point alignment with an electronic portal imaging device (EPID)

et al. 1997

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A procedure has been developed using an electronic portal imaging device (EPID) to verify that the center of a patient's lesion is aligned with the center of a treatment cone prior to treatment in a linac-based stereotactic radiosurgery procedure. The coordinates of the lesion center are set on the Brown-Roberts-Wells phantom base using a target simulator. A 3 mm tungsten ball, mounted on the target simulator, is used as the reference point for the planned isocenter. The target simulator is then attached to an adapter mounted on the linac couch, and an EPID image of the simulated target is acquired. The center of the circular-shaped radiation field is calculated from the centroid of the segmented EPID image, and the center of the tungsten ball is identified by an automated computer search algorithm. A summation filter is used to find the position of the lowest radiation intensity coincident with the center of the ball. The alignment error is defined as the difference between the center of the radiation field and the center of the ball. The accuracy of this method was tested and found to be within 0.2 mm. The advantage of the EPID-based procedure is that it can give quantitative offset values quickly for immediate readjustment. We have found that the method is also a convenient tool for testing room laser alignment and the accuracy of the treatment cones.

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Stereotactic radiosurgery: Dose‐volume analysis of linear accelerator techniques

Cited by 30 publications

References 0 publications

Viability of an isocentric cobalt‐60 teletherapy unit for stereotactic radiosurgery

Viability of an isocentric cobalt‐60 teletherapy unit for stereotactic radiosurgery

Dose-volume Analysis of Different Stereotactic Radiotherapy Mono-isocentric Techniques

Verification of radiosurgery target point alignment with an electronic portal imaging device (EPID)

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