Collimator optimization for small animal radiation therapy at a micro-CT

In radiation therapy of small animals treatment depths range from a few millimetres to several centimetres. In order to spare surrounding organs at risk steep dose gradients are necessary. To minimize the treatment time, and therefore the strain to the animals, a high dose rate is required. A descri...

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Bibliographic Details
Published in:Zeitschrift für medizinische Physik 2017-03, Vol.27 (1), p.56-64
Main Authors: Felix, Manuela C., Glatting, Gerhard, Giordano, Frank A., Brockmann, Marc A., Wenz, Frederik, Fleckenstein, Jens
Format: Article
Language:English
Subjects:
Animals
Calibration
collimator design
film dosimetry
Filmdosimetrie
Germany
Kleinfeld-Dosimetrie
Kollimatorbauweise
kV-Dosimetrie
kV-dosimetry
Phantoms, Imaging
Radiation Exposure - prevention & control
Radiometry
Radiotherapy Dosage
Small animal radiation therapy
small field dosimetry
Strahlentherapie bei Kleintieren
X-Ray Microtomography - instrumentation
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Summary:In radiation therapy of small animals treatment depths range from a few millimetres to several centimetres. In order to spare surrounding organs at risk steep dose gradients are necessary. To minimize the treatment time, and therefore the strain to the animals, a high dose rate is required. A description how these parameters can be optimized through an appropriate choice of collimators with different source surface distances (SSD) as well as different materials and geometries is presented. An industrial micro-CT unit (Y.Fox, YXLON GmbH, Hamburg, Germany) was converted into a precision irradiator for small animals. Different collimators of either stainless steel (Fe) with cylindrical bores (SSD=42mm) or tungsten (W) with conical bores (SSD=14mm) were evaluated. The dosimetry of very small radiation fields presents a challenge and was performed with GafChromic EBT3 films (Ashland, Vayne, KY, USA) in a water phantom. The films were calibrated with an ionization chamber in the uncollimated field. Treatments were performed via a rotation of the objects with a fixed radiation source. As expected, the shorter SSD of the W-collimators resulted in a (4.5±1.6)-fold increase of the dose rates compared to the corresponding Fe-collimators. The ratios of the dose rates at 1mm and 10mm depth in the water phantom was (2.6±0.2) for the Fe- and (4.5±0.1) for the W-collimators. For rotational treatments in a cylindrical plastic phantom maximum dose rates of up to 1.2Gy/min for Fe- and 5.1Gy/min for W-collimators were measured. Choosing the smallest possible SSD leads to a high dose rate and a high surface dose, which is of advantage for the treatment of superficial target volumes. For larger SSD the dose rate is lower and the depth dose curve is shallower. This leads to a reduction of the surface dose and is best suited for treatments of deeper seated target volumes. Divergent collimator bores have, due to the reduced scatter within the collimators, a steeper penumbra. The dosimetry of small kilovoltage beams with Gafchromic EBT3 films in a water phantom has proven successful. Zur Strahlenbehandlung kleiner Labortiere sind Behandlungstiefen von wenigen Millimetern bis zu mehreren Zentimetern erforderlich. Zur Schonung der umgebenden Risikoorgane sind steile Dosisgradienten nötig. Um die Behandlungsdauer und damit die Belastung der Tiere zu minimieren, ist eine ausreichend hohe Dosisleistung erforderlich. Nachfolgend wird beschrieben, wie durch eine geeignete Auswahl von Koll
ISSN:0939-3889
1876-4436
DOI:10.1016/j.zemedi.2016.05.003