Quality Assessment of Stereotactic Radiosurgery of a Melanoma Brain Metastases Model Using a Mouselike Phantom and the Small Animal Radiation Research Platform

Wu, Cheng; Chaudhary, Kunal; Na, Yong Hum; Welch, David; Black, Paul; Sonabend, Adam M.; Canoll, Peter; Saenger, Yvonne M.; Wang, Tony J. C.; Hei, Tom K.; Cheng, Simon K.

doi:10.1016/j.ijrobp.2017.05.016

Cited by 12 publications

(16 citation statements)

References 20 publications

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“…Conventional facilities, like X-ray cabinets or cesium/cobalt sources, have no onboard CT imaging system allowing brain visualization and do not permit accurate irradiation of such small fields and the localization of millimetric brain structures 21 , 35 . Conversely, the technological properties of SARRP facilities and the parallel recording of MR and CBCT images that favor visualization of structures of interest allowed this high millimetric ballistic specificity 36 – 41 . Until now, experimental studies with the SARRP have been performed to irradiate brain regions at high doses of IR to mimic radiotherapy protocols 38 – 40 , 42 or to inhibit neurogenesis 37 , 43 .…”

Section: Discussionmentioning

confidence: 99%

Development of whole brain versus targeted dentate gyrus irradiation model to explain low to moderate doses of exposure effects in mice

Santos¹,

Kereselidze²,

Gloaguen³

et al. 2018

Sci Rep

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Evaluation of the consequences of low to moderate doses of ionizing radiation (IR) remains a societal challenge, especially for children exposed to CT scans. Appropriate experimental models are needed to improve scientific understanding of how exposure of the postnatal brain to IR affects behavioral functions and their related pathophysiological mechanisms, considering brain complex functional organization. In the brain, the dorsal and ventral hippocampal dentate gyrus can be involved in distinct major behavioral functions. To study the long term behavioral effects of brain exposure at low to moderate doses of IR (doses range 0.25–1 Gy), we developed three new experimental models in 10-day-old mice: a model of brain irradiation and two targeted irradiation models of the dorsal and ventral dentate gyrus. We used the technological properties of the SARRP coupled with MR imaging. Our irradiation strategy has been twofold endorsed. The millimetric ballistic specificity of our models was first validated by measuring gamma-H2AX increase after irradiation. We then demonstrated higher anxiety/depressive-like behavior, preferentially mediate by the ventral part of the dentate gyrus, in mice after brain and ventral dentate gyrus IR exposure. This work provides new tools to enhance scientific understanding of how to protect children exposed to IR.

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Section: Discussionmentioning

confidence: 99%

Development of whole brain versus targeted dentate gyrus irradiation model to explain low to moderate doses of exposure effects in mice

Santos¹,

Kereselidze²,

Gloaguen³

et al. 2018

Sci Rep

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“…Welch et al. and Wu et al . accomplished this by using materials that closely mimicked the physical properties of the corresponding anatomy and precise micromachining techniques; unfortunately, the proposed methodology remained laborious and costly.…”

Section: Introductionmentioning

confidence: 99%

“…More recently, groups have found success creating anatomically accurate mouse phantoms for improved quality assurance in small animal imaging and therapeutic applications. Welch et al 18,19 and Wu et al 20 accomplished this by using materials that closely mimicked the physical properties of the corresponding anatomy and precise micromachining techniques; unfortunately, the proposed methodology remained laborious and costly. Bache et al, 21 on the other hand, used comparatively affordable 3D printed molds, based on rat CT data, to form a homogeneous, tissue-equivalent 3D dosimeter out of radiochromic Presage â material with dose readout accomplished via optical-CT. Zhang et al 22 similarly utilized 3D printing to generate accurate bony and superficial (skin shell) anatomy to enable the construction of a heterogeneous mouse phantom compatible with CT, MRI, and PET imaging.…”

Section: Introductionmentioning

confidence: 99%

Technical Note: Manufacturing of a realistic mouse phantom for dosimetry of radiobiology experiments

2019

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Purpose The goal of this work was to design a realistic mouse phantom as a useful tool for accurate dosimetry in radiobiology experiments. Methods A subcutaneous tumor‐bearing mouse was scanned in a microCT scanner, its organs manually segmented and contoured. The resulting geometries were converted into a stereolithographic file format (STL) and sent to a multimaterial 3D printer. The phantom was split into two parts to allow for lung excavation and 3D‐printed with an acrylic‐like material and consisted of the main body (mass density ρ=1.18 g/cm3) and bone (ρ=1.20 g/cm3). The excavated lungs were filled with polystyrene (ρ=0.32 g/cm3). Three cavities were excavated to allow the placement of a 1‐mm diameter plastic scintillator dosimeter (PSD) in the brain, the center of the body and a subcutaneous tumor. Additionally, a laser‐cut Gafchromic film can be placed in between the two phantom parts for 2D dosimetric evaluation. The expected differences in dose deposition between mouse tissues and the mouse phantom for a 220‐kVp beam delivered by the small animal radiation research platform (SARRP) were calculated by Monte Carlo (MC). Results MicroCT scans of the phantom showed excellent material uniformity and confirmed the material densities given by the manufacturer. MC dose calculations revealed that the dose measured by tissue‐equivalent dosimeters inserted into the phantom in the brain, abdomen, and subcutaneous tumor would be underestimated by 3–5%, which is deemed to be an acceptable error assuming the proposed 5% accuracy of radiobiological experiments. Conclusions The low‐cost mouse phantom can be easily manufactured and, after a careful dosimetric characterization, may serve as a useful tool for dose verification in a range of radiobiology experiments.

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“…To date, a variety of anatomically accurate phantoms have been produced for both imaging and radiotherapeutic applications, few of these, however, have had a comprehensive evaluation with respect to their utility as tools for preclinical dosimetry. Welch et al .…”

Section: Introductionmentioning

confidence: 99%

“…Welch et al . and Wu et al, utilized an anatomically accurate mouse phantom comprised of materials that closely mimicked the physical properties of the component anatomy; however, their phantom was fabricated using less‐economical micromachining techniques which did not preserve the outer contours of the mouse model. Bache et al, in contrast, used comparatively affordable 3D printed molds, based on rat CT data, to form a homogeneous, tissue‐equivalent 3D dosimeter out of radiochromic Presage ® material with dose readout accomplished via optical‐CT.…”

Section: Introductionmentioning

confidence: 99%

Preclinical dose verification using a 3D printed mouse phantom for radiobiology experiments

Esplen¹,

Therriault‐Proulx²,

Beaulieu³

et al. 2019

Medical Physics

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Purpose: Dose verification in preclinical radiotherapy is often challenged by a lack of standardization in the techniques and technologies commonly employed along with the inherent difficulty of dosimetry associated with small-field kilovoltage sources. As a consequence, the accuracy of dosimetry in radiobiological research has been called into question. Fortunately, the development and characterization of realistic small-animal phantoms has emerged as an effective and accessible means of improving dosimetric accuracy and precision in this context. The application of three-dimensional (3D) printing, in particular, has enabled substantial improvements in the conformity of representative phantoms with respect to the small animals they are modeled after. In this study, our goal was to evaluate a fully 3D printed mouse phantom for use in preclinical treatment verification of sophisticated therapies for various anatomical targets of therapeutic interest. Methods: An anatomically realistic mouse phantom was 3D printed based on segmented microCT data of a tumor-bearing mouse. The phantom was modified to accommodate both laser-cut EBT3 radiochromic film within the mouse thorax and a plastic scintillator dosimeter (PSD), which may be placed within the brain, abdomen, or 1-cm flank subcutaneous tumor. Various treatments were delivered on an image-guided small-animal irradiator in order to determine the doses to isocenter using a PSD and validate lateral-and depth-dose distributions using film dosimeters. On-board cone-beam CT imaging was used to localize isocenter to the film plane or PSD active element prior to irradiation. The PSD irradiations comprised a 3 9 3 mm 2 brain arc, 5 9 5 mm 2 parallel-opposed pair (POP), and 5-beam 10 9 10 mm 2 abdominal coplanar arrangement while two-dimensional (2D) film dose distributions were acquired using a 3 9 3 mm 2 arc and both 5 9 5 and 10 9 10 mm 2 3-beam coplanar plans. A validated Monte Carlo (MC) model of the source was used as to verify the accuracy of the film and PSD dose measurements. computer-aided design (CAD) geometries for the mouse phantom and dosimeters were imported directly into the MC code to allow for highly accurate reproduction of the physical experiment conditions. Experimental and MC-derived film data were co-registered and film dose profiles were compared for points above 90% of the dose maximum. Point dose measurements obtained with the PSD were similarly compared for each of the candidate (brain, abdomen, and tumor) treatment sites. Results: For each treatment configuration and anatomical target, the MC-calculated and measured doses met the proposed 5% agreement goal for dose accuracy in radiobiology experiments. The 2D film and MC dose distributions were successfully registered and mean doses for lateral profiles were found to agree to within 2.3% in all cases. Isocentric point-dose measurements taken with the PSD were similarly consistent, with a maximum percentage deviation of 3.2%. Conclusions: Our study confirms the utility of 3D printed phantom design ...

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Quality Assessment of Stereotactic Radiosurgery of a Melanoma Brain Metastases Model Using a Mouselike Phantom and the Small Animal Radiation Research Platform

Cited by 12 publications

References 20 publications

Development of whole brain versus targeted dentate gyrus irradiation model to explain low to moderate doses of exposure effects in mice

Development of whole brain versus targeted dentate gyrus irradiation model to explain low to moderate doses of exposure effects in mice

Technical Note: Manufacturing of a realistic mouse phantom for dosimetry of radiobiology experiments

Preclinical dose verification using a 3D printed mouse phantom for radiobiology experiments

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