Functional stereotactic radiosurgery involving a dedicated linear accelerator and gamma unit: a comparison study

Timothy D. Solberg Ph.D.1, Steven J. Goetsch1, Michael T. Selch M.D.1, William Melega1, Goran Lacan1, and Antonio A. F. DeSalles M.D., Ph.D.1
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  • 1 Department of Radiation Oncology, Division of Neurosurgery, Department of Pharmacology, and Jonsson Comprehensive Cancer Center, University of California, Los Angeles School of Medicine, Los Angeles; and San Diego Gamma Knife Center, La Jolla, California
Page Range:
373–380
Volume/Issue:
Volume 101: Issue Supplement3
DOI link:
https://doi.org/10.3171/sup.2004.101.supplement3.0373
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Object. The purpose of this work was to investigate the targeting and dosimetric characteristics of a linear accelerator (LINAC) system dedicated for stereotactic radiosurgery compared with those of a commercial gamma knife (GK) unit.

Methods. A phantom was rigidly affixed within a Leksell stereotactic frame and axial computerized tomography scans were obtained using an appropriate stereotactic localization device. Treatment plans were performed, film was inserted into a recessed area, and the phantom was positioned and treated according to each treatment plan. In the case of the LINAC system, four 140° arcs, spanning ± 60° of couch rotation, were used. In the case of the GK unit, all 201 sources were left unplugged. Radiation was delivered using 3- and 8-mm LINAC collimators and 4- and 8-mm collimators of the GK unit. Targeting ability was investigated independently on the dedicated LINAC by using a primate model.

Measured 50% spot widths for multisource, single-shot radiation exceeded nominal values in all cases by 38 to 70% for the GK unit and 11 to 33% for the LINAC system. Measured offsets were indicative of submillimeter targeting precision on both devices. In primate studies, the appearance of an magnetic resonance imaging—enhancing lesion coincided with the intended target.

Conclusions. Radiosurgery performed using the 3-mm collimator of the dedicated LINAC exhibited characteristics that compared favorably with those of a dedicated GK unit. Overall targeting accuracy in the submillimeter range can be achieved, and dose distributions with sharp falloff can be expected for both devices.

Volume 101: Issue Supplement3 (Nov 2004)

in Journal of Neurosurgery
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Contributor Notes

Address reprint requests to: Timothy D. Solberg, Ph.D., Department of Radiation Oncology, 200 UCLA Medical Plaza, Suite B265, Los Angeles, California 90095–6951. email: solberg@radonc. ucla.edu.
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