Image-guided robotic radiosurgery in a rat glioma model

Thomas G. Psarros; B. Mickey; K. Gall; J. Gilio; J. Delp; C. White; J. Drees; M. Willis; D. Pistemmna; C. A. Giller

doi:10.1055/s-2004-830076

Image-guided robotic radiosurgery in a rat glioma model

Thomas G. Psarros, B. Mickey, K. Gall, J. Gilio, J. Delp, C. White, J. Drees, M. Willis, D. Pistemmna, C. A. Giller

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

Despite the proven efficacy of radiosurgery for the treatment of brain tumors, limited histological information is available after treatment that might allow a better understanding of the relationship between radiation dose, the volume treated, and the response of the surrounding brain to the delivered radiation. The use of an animal model could provide the opportunity to clarify these relationships and answer several other key questions arising in clinical practice. We show here that treatment of small animals with radiosurgery is feasible using a robotically controlled linear accelerator, which offers the advantages of radiosurgery and preserves the potential for fractionated regimens without rigid immobilization. Specifically, we demonstrate the use of a robotically driven linear accelerator to provide radiosurgical treatment to a rat brain tumor model.

Original language	English (US)
Pages (from-to)	266-272
Number of pages	7
Journal	Minimally Invasive Neurosurgery
Volume	47
Issue number	5
DOIs	https://doi.org/10.1055/s-2004-830076
State	Published - Oct 1 2004

Keywords

9L glioma
Cyberknife
Radiosurgery

ASJC Scopus subject areas

Surgery
Clinical Neurology

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10.1055/s-2004-830076

Cite this

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title = "Image-guided robotic radiosurgery in a rat glioma model",

abstract = "Despite the proven efficacy of radiosurgery for the treatment of brain tumors, limited histological information is available after treatment that might allow a better understanding of the relationship between radiation dose, the volume treated, and the response of the surrounding brain to the delivered radiation. The use of an animal model could provide the opportunity to clarify these relationships and answer several other key questions arising in clinical practice. We show here that treatment of small animals with radiosurgery is feasible using a robotically controlled linear accelerator, which offers the advantages of radiosurgery and preserves the potential for fractionated regimens without rigid immobilization. Specifically, we demonstrate the use of a robotically driven linear accelerator to provide radiosurgical treatment to a rat brain tumor model.",

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AU - Mickey, B.

AU - Gall, K.

AU - Gilio, J.

AU - Delp, J.

AU - White, C.

AU - Drees, J.

AU - Willis, M.

AU - Pistemmna, D.

AU - Giller, C. A.

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AB - Despite the proven efficacy of radiosurgery for the treatment of brain tumors, limited histological information is available after treatment that might allow a better understanding of the relationship between radiation dose, the volume treated, and the response of the surrounding brain to the delivered radiation. The use of an animal model could provide the opportunity to clarify these relationships and answer several other key questions arising in clinical practice. We show here that treatment of small animals with radiosurgery is feasible using a robotically controlled linear accelerator, which offers the advantages of radiosurgery and preserves the potential for fractionated regimens without rigid immobilization. Specifically, we demonstrate the use of a robotically driven linear accelerator to provide radiosurgical treatment to a rat brain tumor model.

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Image-guided robotic radiosurgery in a rat glioma model

Abstract

Keywords

ASJC Scopus subject areas

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