Modality comparison for small animal radiotherapy: A simulation study

Purpose: Small animal radiation therapy has advanced significantly in recent years. Whereas in the past dose was delivered using a single beam and a lead shield for sparing of healthy tissue, conformal doses can be now delivered using more complex dedicated small animal radiotherapy systems with ima...

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Vydané v:Medical physics (Lancaster) Ročník 41; číslo 1; s. 011710 - n/a
Hlavní autori: Bazalova, Magdalena, Nelson, Geoff, Noll, John M., Graves, Edward E.
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: United States American Association of Physicists in Medicine 01.01.2014
Predmet:
Anatomy
ANIMAL TISSUES
Animals
BEAMS
biomedical equipment
bone
Cancer
Collimators
Computerised tomographs
computerised tomography
CRITICAL ORGANS
dosimetry
Dosimetry/exposure assessment
HEART
lung
LUNGS
Medical imaging
Medical treatment planning
MICE
microCT
Monte Carlo
MONTE CARLO METHOD
Monte Carlo methods
NEOPLASMS
neurophysiology
OPTIMIZATION
Orthopaedic methods or devices for non‐surgical treatment of bones or joints; Nursing devices
orthopaedics
RADIATION DOSE DISTRIBUTIONS
RADIATION DOSES
radiation therapy
Radiation Therapy Physics
RADIOLOGY AND NUCLEAR MEDICINE
RADIOSENSITIVITY
RADIOTHERAPY
Radiotherapy Dosage
Radiotherapy Planning, Computer-Assisted
Radiotherapy, Conformal - methods
SARRP
Scintigraphy
SHIELDS
single‐field irradiator
SKELETON
small animal radiotherapy
SPINAL CORD
Therapeutic applications, including brachytherapy
Time Factors
tumours
Vacuum tubes
microCT
SARRP
Monte Carlo
single-field irradiator
small animal radiotherapy
ISSN:0094-2405, 2473-4209, 2473-4209, 0094-2405
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Abstract Purpose: Small animal radiation therapy has advanced significantly in recent years. Whereas in the past dose was delivered using a single beam and a lead shield for sparing of healthy tissue, conformal doses can be now delivered using more complex dedicated small animal radiotherapy systems with image guidance. The goal of this paper is to investigate dose distributions for three small animal radiation treatment modalities. Methods: This paper presents a comparison of dose distributions generated by the three approaches—a single-field irradiator with a 200 kV beam and no image guidance, a small animal image-guided conformal system based on a modified microCT scanner with a 120 kV beam developed at Stanford University, and a dedicated conformal system, SARRP, using a 220 kV beam developed at Johns Hopkins University. The authors present a comparison of treatment plans for the three modalities using two cases: a mouse with a subcutaneous tumor and a mouse with a spontaneous lung tumor. A 5 Gy target dose was calculated using the EGSnrc Monte Carlo codes. Results: All treatment modalities generated similar dose distributions for the subcutaneous tumor case, with the highest mean dose to the ipsilateral lung and bones in the single-field plan (0.4 and 0.4 Gy) compared to the microCT (0.1 and 0.2 Gy) and SARRP (0.1 and 0.3 Gy) plans. The lung case demonstrated that due to the nine-beam arrangements in the conformal plans, the mean doses to the ipsilateral lung, spinal cord, and bones were significantly lower in the microCT plan (2.0, 0.4, and 1.9 Gy) and the SARRP plan (1.5, 0.5, and 1.8 Gy) than in single-field irradiator plan (4.5, 3.8, and 3.3 Gy). Similarly, the mean doses to the contralateral lung and the heart were lowest in the microCT plan (1.5 and 2.0 Gy), followed by the SARRP plan (1.7 and 2.2 Gy), and they were highest in the single-field plan (2.5 and 2.4 Gy). For both cases, dose uniformity was greatest in the single-field irradiator plan followed by the SARRP plan due to the sensitivity of the lower energy microCT beam to target heterogeneities and image noise. Conclusions: The two treatment planning examples demonstrate that modern small animal radiotherapy techniques employing image guidance, variable collimation, and multiple beam angles deliver superior dose distributions to small animal tumors as compared to conventional treatments using a single-field irradiator. For deep-seated mouse tumors, however, higher-energy conformal radiotherapy could result in higher doses to critical organs compared to lower-energy conformal radiotherapy. Treatment planning optimization for small animal radiotherapy should therefore be developed to take full advantage of the novel conformal systems.
AbstractList Purpose: Small animal radiation therapy has advanced significantly in recent years. Whereas in the past dose was delivered using a single beam and a lead shield for sparing of healthy tissue, conformal doses can be now delivered using more complex dedicated small animal radiotherapy systems with image guidance. The goal of this paper is to investigate dose distributions for three small animal radiation treatment modalities. Methods: This paper presents a comparison of dose distributions generated by the three approaches—a single-field irradiator with a 200 kV beam and no image guidance, a small animal image-guided conformal system based on a modified microCT scanner with a 120 kV beam developed at Stanford University, and a dedicated conformal system, SARRP, using a 220 kV beam developed at Johns Hopkins University. The authors present a comparison of treatment plans for the three modalities using two cases: a mouse with a subcutaneous tumor and a mouse with a spontaneous lung tumor. A 5 Gy target dose was calculated using the EGSnrc Monte Carlo codes. Results: All treatment modalities generated similar dose distributions for the subcutaneous tumor case, with the highest mean dose to the ipsilateral lung and bones in the single-field plan (0.4 and 0.4 Gy) compared to the microCT (0.1 and 0.2 Gy) and SARRP (0.1 and 0.3 Gy) plans. The lung case demonstrated that due to the nine-beam arrangements in the conformal plans, the mean doses to the ipsilateral lung, spinal cord, and bones were significantly lower in the microCT plan (2.0, 0.4, and 1.9 Gy) and the SARRP plan (1.5, 0.5, and 1.8 Gy) than in single-field irradiator plan (4.5, 3.8, and 3.3 Gy). Similarly, the mean doses to the contralateral lung and the heart were lowest in the microCT plan (1.5 and 2.0 Gy), followed by the SARRP plan (1.7 and 2.2 Gy), and they were highest in the single-field plan (2.5 and 2.4 Gy). For both cases, dose uniformity was greatest in the single-field irradiator plan followed by the SARRP plan due to the sensitivity of the lower energy microCT beam to target heterogeneities and image noise. Conclusions: The two treatment planning examples demonstrate that modern small animal radiotherapy techniques employing image guidance, variable collimation, and multiple beam angles deliver superior dose distributions to small animal tumors as compared to conventional treatments using a single-field irradiator. For deep-seated mouse tumors, however, higher-energy conformal radiotherapy could result in higher doses to critical organs compared to lower-energy conformal radiotherapy. Treatment planning optimization for small animal radiotherapy should therefore be developed to take full advantage of the novel conformal systems.
Purpose: Small animal radiation therapy has advanced significantly in recent years. Whereas in the past dose was delivered using a single beam and a lead shield for sparing of healthy tissue, conformal doses can be now delivered using more complex dedicated small animal radiotherapy systems with image guidance. The goal of this paper is to investigate dose distributions for three small animal radiation treatment modalities. Methods: This paper presents a comparison of dose distributions generated by the three approaches—a single-field irradiator with a 200 kV beam and no image guidance, a small animal image-guided conformal system based on a modified microCT scanner with a 120 kV beam developed at Stanford University, and a dedicated conformal system, SARRP, using a 220 kV beam developed at Johns Hopkins University. The authors present a comparison of treatment plans for the three modalities using two cases: a mouse with a subcutaneous tumor and a mouse with a spontaneous lung tumor. A 5 Gy target dose was calculated using the EGSnrc Monte Carlo codes. Results: All treatment modalities generated similar dose distributions for the subcutaneous tumor case, with the highest mean dose to the ipsilateral lung and bones in the single-field plan (0.4 and 0.4 Gy) compared to the microCT (0.1 and 0.2 Gy) and SARRP (0.1 and 0.3 Gy) plans. The lung case demonstrated that due to the nine-beam arrangements in the conformal plans, the mean doses to the ipsilateral lung, spinal cord, and bones were significantly lower in the microCT plan (2.0, 0.4, and 1.9 Gy) and the SARRP plan (1.5, 0.5, and 1.8 Gy) than in single-field irradiator plan (4.5, 3.8, and 3.3 Gy). Similarly, the mean doses to the contralateral lung and the heart were lowest in the microCT plan (1.5 and 2.0 Gy), followed by the SARRP plan (1.7 and 2.2 Gy), and they were highest in the single-field plan (2.5 and 2.4 Gy). For both cases, dose uniformity was greatest in the single-field irradiator plan followed by the SARRP plan due to the sensitivity of the lower energy microCT beam to target heterogeneities and image noise. Conclusions: The two treatment planning examples demonstrate that modern small animal radiotherapy techniques employing image guidance, variable collimation, and multiple beam angles deliver superior dose distributions to small animal tumors as compared to conventional treatments using a single-field irradiator. For deep-seated mouse tumors, however, higher-energy conformal radiotherapy could result in higher doses to critical organs compared to lower-energy conformal radiotherapy. Treatment planning optimization for small animal radiotherapy should therefore be developed to take full advantage of the novel conformal systems.
Small animal radiation therapy has advanced significantly in recent years. Whereas in the past dose was delivered using a single beam and a lead shield for sparing of healthy tissue, conformal doses can be now delivered using more complex dedicated small animal radiotherapy systems with image guidance. The goal of this paper is to investigate dose distributions for three small animal radiation treatment modalities.PURPOSESmall animal radiation therapy has advanced significantly in recent years. Whereas in the past dose was delivered using a single beam and a lead shield for sparing of healthy tissue, conformal doses can be now delivered using more complex dedicated small animal radiotherapy systems with image guidance. The goal of this paper is to investigate dose distributions for three small animal radiation treatment modalities.This paper presents a comparison of dose distributions generated by the three approaches-a single-field irradiator with a 200 kV beam and no image guidance, a small animal image-guided conformal system based on a modified microCT scanner with a 120 kV beam developed at Stanford University, and a dedicated conformal system, SARRP, using a 220 kV beam developed at Johns Hopkins University. The authors present a comparison of treatment plans for the three modalities using two cases: a mouse with a subcutaneous tumor and a mouse with a spontaneous lung tumor. A 5 Gy target dose was calculated using the EGSnrc Monte Carlo codes.METHODSThis paper presents a comparison of dose distributions generated by the three approaches-a single-field irradiator with a 200 kV beam and no image guidance, a small animal image-guided conformal system based on a modified microCT scanner with a 120 kV beam developed at Stanford University, and a dedicated conformal system, SARRP, using a 220 kV beam developed at Johns Hopkins University. The authors present a comparison of treatment plans for the three modalities using two cases: a mouse with a subcutaneous tumor and a mouse with a spontaneous lung tumor. A 5 Gy target dose was calculated using the EGSnrc Monte Carlo codes.All treatment modalities generated similar dose distributions for the subcutaneous tumor case, with the highest mean dose to the ipsilateral lung and bones in the single-field plan (0.4 and 0.4 Gy) compared to the microCT (0.1 and 0.2 Gy) and SARRP (0.1 and 0.3 Gy) plans. The lung case demonstrated that due to the nine-beam arrangements in the conformal plans, the mean doses to the ipsilateral lung, spinal cord, and bones were significantly lower in the microCT plan (2.0, 0.4, and 1.9 Gy) and the SARRP plan (1.5, 0.5, and 1.8 Gy) than in single-field irradiator plan (4.5, 3.8, and 3.3 Gy). Similarly, the mean doses to the contralateral lung and the heart were lowest in the microCT plan (1.5 and 2.0 Gy), followed by the SARRP plan (1.7 and 2.2 Gy), and they were highest in the single-field plan (2.5 and 2.4 Gy). For both cases, dose uniformity was greatest in the single-field irradiator plan followed by the SARRP plan due to the sensitivity of the lower energy microCT beam to target heterogeneities and image noise.RESULTSAll treatment modalities generated similar dose distributions for the subcutaneous tumor case, with the highest mean dose to the ipsilateral lung and bones in the single-field plan (0.4 and 0.4 Gy) compared to the microCT (0.1 and 0.2 Gy) and SARRP (0.1 and 0.3 Gy) plans. The lung case demonstrated that due to the nine-beam arrangements in the conformal plans, the mean doses to the ipsilateral lung, spinal cord, and bones were significantly lower in the microCT plan (2.0, 0.4, and 1.9 Gy) and the SARRP plan (1.5, 0.5, and 1.8 Gy) than in single-field irradiator plan (4.5, 3.8, and 3.3 Gy). Similarly, the mean doses to the contralateral lung and the heart were lowest in the microCT plan (1.5 and 2.0 Gy), followed by the SARRP plan (1.7 and 2.2 Gy), and they were highest in the single-field plan (2.5 and 2.4 Gy). For both cases, dose uniformity was greatest in the single-field irradiator plan followed by the SARRP plan due to the sensitivity of the lower energy microCT beam to target heterogeneities and image noise.The two treatment planning examples demonstrate that modern small animal radiotherapy techniques employing image guidance, variable collimation, and multiple beam angles deliver superior dose distributions to small animal tumors as compared to conventional treatments using a single-field irradiator. For deep-seated mouse tumors, however, higher-energy conformal radiotherapy could result in higher doses to critical organs compared to lower-energy conformal radiotherapy. Treatment planning optimization for small animal radiotherapy should therefore be developed to take full advantage of the novel conformal systems.CONCLUSIONSThe two treatment planning examples demonstrate that modern small animal radiotherapy techniques employing image guidance, variable collimation, and multiple beam angles deliver superior dose distributions to small animal tumors as compared to conventional treatments using a single-field irradiator. For deep-seated mouse tumors, however, higher-energy conformal radiotherapy could result in higher doses to critical organs compared to lower-energy conformal radiotherapy. Treatment planning optimization for small animal radiotherapy should therefore be developed to take full advantage of the novel conformal systems.
Small animal radiation therapy has advanced significantly in recent years. Whereas in the past dose was delivered using a single beam and a lead shield for sparing of healthy tissue, conformal doses can be now delivered using more complex dedicated small animal radiotherapy systems with image guidance. The goal of this paper is to investigate dose distributions for three small animal radiation treatment modalities. This paper presents a comparison of dose distributions generated by the three approaches-a single-field irradiator with a 200 kV beam and no image guidance, a small animal image-guided conformal system based on a modified microCT scanner with a 120 kV beam developed at Stanford University, and a dedicated conformal system, SARRP, using a 220 kV beam developed at Johns Hopkins University. The authors present a comparison of treatment plans for the three modalities using two cases: a mouse with a subcutaneous tumor and a mouse with a spontaneous lung tumor. A 5 Gy target dose was calculated using the EGSnrc Monte Carlo codes. All treatment modalities generated similar dose distributions for the subcutaneous tumor case, with the highest mean dose to the ipsilateral lung and bones in the single-field plan (0.4 and 0.4 Gy) compared to the microCT (0.1 and 0.2 Gy) and SARRP (0.1 and 0.3 Gy) plans. The lung case demonstrated that due to the nine-beam arrangements in the conformal plans, the mean doses to the ipsilateral lung, spinal cord, and bones were significantly lower in the microCT plan (2.0, 0.4, and 1.9 Gy) and the SARRP plan (1.5, 0.5, and 1.8 Gy) than in single-field irradiator plan (4.5, 3.8, and 3.3 Gy). Similarly, the mean doses to the contralateral lung and the heart were lowest in the microCT plan (1.5 and 2.0 Gy), followed by the SARRP plan (1.7 and 2.2 Gy), and they were highest in the single-field plan (2.5 and 2.4 Gy). For both cases, dose uniformity was greatest in the single-field irradiator plan followed by the SARRP plan due to the sensitivity of the lower energy microCT beam to target heterogeneities and image noise. The two treatment planning examples demonstrate that modern small animal radiotherapy techniques employing image guidance, variable collimation, and multiple beam angles deliver superior dose distributions to small animal tumors as compared to conventional treatments using a single-field irradiator. For deep-seated mouse tumors, however, higher-energy conformal radiotherapy could result in higher doses to critical organs compared to lower-energy conformal radiotherapy. Treatment planning optimization for small animal radiotherapy should therefore be developed to take full advantage of the novel conformal systems.
Author Bazalova, Magdalena
Noll, John M.
Nelson, Geoff
Graves, Edward E.
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Monte Carlo
single-field irradiator
small animal radiotherapy
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Author to whom correspondence should be addressed. Electronic mail: bazalova@stanford.edu; Telephone: (650) 721-5475; Fax: (650) 498-4015.
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References Vanrongen, Madhuizen, Tan, Durham, Gijbels (c15) 1990; 17
Motomura, Bazalova, Zhou, Keall, Graves (c31) 2010; 37
Hildebrandt, Su, Weber (c42) 2008; 49
Graves, Quon, Loo, Image (c36) 2007; 6
Wong (c22) 2008; 71
Adler, Chang, Murphy, Doty, Geis, Hancock (c1) 1997; 69
Rodriguez, Zhou, Keall, Graves (c18) 2009; 54
Ali, Rogers (c25) 2008; 53
Devic (c34) 2005; 32
Hayden (c12) 2002; 120
Bazalova, Graves (c26) 2011; 38
Jen, Hendry (c14) 1991; 64
Matinfar, Ford, Iordachita, Wong, Kazanzides (c21) 2009; 54
Nyaruba, Yamamoto, Kimura, Morita (c37) 1998; 39
Zhou (c19) 2010; 77
Bazalova, Zhou, Keall, Graves (c30) 2009; 36
Verhaegen, Nahum, Van de Putte, Namito (c35) 1999; 44
Moulder, Fish (c40) 1989; 16
Scalliet, Landuyt, Vanderschueren (c10) 1987; 10
Van Esch (c24) 2006; 33
Jockovich (c13) 2007; 48
Hewitt, Wilson (c4) 1959; 13
Song, Schaly, Bauman, Battista, Van Dyk (c3) 2006; 64
Safwat, Nielsen, Elbakky, Overgaard (c41) 1995; 34
Kal, Sissingh (c6) 1974; 47
Kal, Barendsen, Bakkervanhauwe, Roelse (c7) 1975; 63
Chow, Leung (c20) 2007; 34
Liao, Travis, Tucker (c38) 1995; 32
Frindel, Tubiana, Hahn, Robaglia (c8) 1972; 32
Kal, Barendse (c5) 1972; 45
Taghian, Dubois, Budach, Baumann, Freeman, Suit (c11) 1995; 32
Stojadinovic (c16) 2006; 33
Van Bekkum, Bohre, Houben, Knaan-Shanzer (c39) 1989; 86
Makinodan, Peterson, Kastenbaum (c9) 1962; 88
Mackie (c2) 1993; 20
Stojadinovic (c17) 2007; 34
Clarkson (c23) 2011; 38
2010; 77
1987; 10
2010; 37
1989; 86
1990; 17
2006; 33
1997; 69
1995; 34
1993; 20
1995; 32
2007
1999; 44
2006
2008; 53
2011; 38
1972; 45
2007; 34
2008; 71
1974; 47
2009; 36
1998; 39
2006; 64
2009; 54
2002; 120
1991; 64
2008; 49
2007; 6
2005; 32
1972; 32
1975; 63
1962; 88
2013
1989; 16
2007; 48
1959; 13
References_xml – volume: 120
  start-page: 353
  year: 2002
  ident: c12
  article-title: Hyperfractionated external beam radiation therapy in the treatment of murine transgenic retinoblastoma
  publication-title: Arch. Ophthalmol.
– volume: 53
  start-page: 1527
  year: 2008
  ident: c25
  article-title: Benchmarking EGSnrc in the kilovoltage energy range against experimental measurements of charged particle backscatter coefficients
  publication-title: Phys. Med. Biol.
– volume: 48
  start-page: 5371
  year: 2007
  ident: c13
  article-title: Mechanism of retinoblastoma tumor cell death after focal chemotherapy, radiation, and vascular targeting therapy in a mouse model
  publication-title: Invest. Ophthalmol. Visual Sci.
– volume: 33
  start-page: 4130
  year: 2006
  ident: c24
  article-title: Testing of the analytical anisotropic algorithm for photon dose calculation
  publication-title: Med. Phys.
– volume: 32
  start-page: 1359
  year: 1995
  ident: c38
  article-title: Damage and morbidity from pneumonitis after irradiation of partial volumes of mouse lung
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– volume: 49
  start-page: 17
  year: 2008
  ident: c42
  article-title: Anesthesia and other considerations for in vivo imaging of small animals
  publication-title: ILAR J.
– volume: 38
  start-page: 845
  year: 2011
  ident: c23
  article-title: Characterization of image quality and image-guidance performance of a preclinical microirradiator
  publication-title: Med. Phys.
– volume: 20
  start-page: 1709
  year: 1993
  ident: c2
  article-title: Tomotherapy - A new concept for the delivery of dynamic conformal radiotherapy
  publication-title: Med. Phys.
– volume: 32
  start-page: 2096
  year: 1972
  ident: c8
  article-title: Responses of bone-marrow and tumor-cells to acute and protracted irradiation
  publication-title: Cancer Res.
– volume: 32
  start-page: 99
  year: 1995
  ident: c11
  article-title: radiation sensitivity of glioblastoma-multiforme
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– volume: 6
  start-page: 111
  year: 2007
  ident: c36
  article-title: An open-source tool for investigating PET in radiation oncology
  publication-title: Technol. Cancer Res. Treat.
– volume: 33
  start-page: 3834
  year: 2006
  ident: c16
  article-title: Progress toward a microradiation therapy small animal conformal irradiator
  publication-title: Med. Phys.
– volume: 64
  start-page: 142
  year: 1991
  ident: c14
  article-title: Acute response of mouse kidney clonogens to fractionated-irradiation and then assayed in primary culture
  publication-title: Br. J. Radiol.
– volume: 34
  start-page: 4706
  year: 2007
  ident: c17
  article-title: MicroRT - Small animal conformal irradiator
  publication-title: Med. Phys.
– volume: 34
  start-page: 203
  year: 1995
  ident: c41
  article-title: Renal damage after total-body irradiation in a mouse model for bone-marrow transplantation - Effect of radiation-dose rate
  publication-title: Radiother. Oncol.
– volume: 88
  start-page: 31
  year: 1962
  ident: c9
  article-title: Radiosensitivity of spleen cells from normal and preimmunized mice and its significance to intact animals
  publication-title: J. Immunol. Suppl.
– volume: 71
  start-page: 1591
  year: 2008
  ident: c22
  article-title: High-resolution, small animal radiation research platform with X-ray tomographic guidance capabilities
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– volume: 36
  start-page: 4991
  year: 2009
  ident: c30
  article-title: Kilovoltage beam Monte Carlo dose calculations in submillimeter voxels for small animal radiotherapy
  publication-title: Med. Phys.
– volume: 32
  start-page: 2245
  year: 2005
  ident: c34
  article-title: Precise radiochromic film dosimetry using a flat-bed document scanner
  publication-title: Med. Phys.
– volume: 63
  start-page: 521
  year: 1975
  ident: c7
  article-title: Increased radiosensitivity of rat rhabdomyosarcoma cells induced by protracted irradiation
  publication-title: Radiat. Res.
– volume: 39
  start-page: 43
  year: 1998
  ident: c37
  article-title: Bone fragility induced by X-ray irradiation in relation to cortical bone-mineral content
  publication-title: Acta Radiol.
– volume: 77
  start-page: 384
  year: 2010
  ident: c19
  article-title: Development of a micro-computed tomography-based image-guided conformal radiotherapy system for small animals
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– volume: 16
  start-page: 1501
  year: 1989
  ident: c40
  article-title: Late toxicity of total-body irradiation with bone-marrow transplantation in a rat model
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– volume: 13
  start-page: 69
  year: 1959
  ident: c4
  article-title: A survival curve for mammalian leukaemia cells irradiated (implications for the treatment of mouse leukaemia by whole-body irradiation)
  publication-title: Br. J. Cancer
– volume: 69
  start-page: 124
  year: 1997
  ident: c1
  article-title: The cyberknife: A frameless robotic system for radiosurgery
  publication-title: Stereotact. Funct. Neurosurg.
– volume: 10
  start-page: 39
  year: 1987
  ident: c10
  article-title: Effect of decreasing the dose-rate of irradiation on the mouse lip mucosa - Comparison with fractionated irradiations
  publication-title: Radiother. Oncol.
– volume: 34
  start-page: 4810
  year: 2007
  ident: c20
  article-title: Treatment planning for a small animal using Monte Carlo simulation
  publication-title: Med. Phys.
– volume: 64
  start-page: 289
  year: 2006
  ident: c3
  article-title: Evaluation of image-guided radiation therapy (IGRT) technologies and their impact on the outcomes of hypofractionated prostate cancer treatments: A radiobiologic analysis
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– volume: 17
  start-page: 323
  year: 1990
  ident: c15
  article-title: Early and late effects of fractionated-irradiation and the kinetics of repair in rat lung
  publication-title: Radiother. Oncol.
– volume: 86
  start-page: 10090
  year: 1989
  ident: c39
  article-title: Regression of adjuvant-induced arthritis in rats following bone marrow transplantation
  publication-title: Proc. Natl. Acad. Sci. U.S.A.
– volume: 54
  start-page: 3727
  year: 2009
  ident: c18
  article-title: Commissioning of a novel microCT/RT system for small animal conformal radiotherapy
  publication-title: Phys. Med. Biol.
– volume: 44
  start-page: 1767
  year: 1999
  ident: c35
  article-title: Monte Carlo modelling of radiotherapy kV x-ray units
  publication-title: Phys. Med. Biol.
– volume: 45
  start-page: 279
  year: 1972
  ident: c5
  article-title: Effects of continuous irradiation at low dose-rates on a rat rhabdomyosarcoma
  publication-title: Br. J. Radiol.
– volume: 37
  start-page: 590
  year: 2010
  ident: c31
  article-title: Investigation of the effects of treatment planning variables in small animal radiotherapy dose distributions
  publication-title: Med. Phys.
– volume: 38
  start-page: 3039
  year: 2011
  ident: c26
  article-title: The importance of tissue segmentation for dose calculations for kilovoltage radiation therapy
  publication-title: Med. Phys.
– volume: 54
  start-page: 891
  year: 2009
  ident: c21
  article-title: Image-guided small animal radiation research platform: Calibration of treatment beam alignment
  publication-title: Phys. Med. Biol.
– volume: 47
  start-page: 673
  year: 1974
  ident: c6
  article-title: Effectiveness of continuous low dose-rate gamma-irradiation on rat skin
  publication-title: Br. J. Radiol.
– volume: 64
  start-page: 142
  year: 1991
  end-page: 148
  article-title: Acute response of mouse kidney clonogens to fractionated‐irradiation and then assayed in primary culture
  publication-title: Br. J. Radiol.
– volume: 54
  start-page: 3727
  year: 2009
  end-page: 3740
  article-title: Commissioning of a novel microCT/RT system for small animal conformal radiotherapy
  publication-title: Phys. Med. Biol.
– volume: 17
  start-page: 323
  year: 1990
  end-page: 337
  article-title: Early and late effects of fractionated‐irradiation and the kinetics of repair in rat lung
  publication-title: Radiother. Oncol.
– volume: 13
  start-page: 69
  year: 1959
  end-page: 75
  article-title: A survival curve for mammalian leukaemia cells irradiated (implications for the treatment of mouse leukaemia by whole‐body irradiation)
  publication-title: Br. J. Cancer
– volume: 10
  start-page: 39
  year: 1987
  end-page: 47
  article-title: Effect of decreasing the dose‐rate of irradiation on the mouse lip mucosa ‐ Comparison with fractionated irradiations
  publication-title: Radiother. Oncol.
– volume: 120
  start-page: 353
  year: 2002
  end-page: 359
  article-title: Hyperfractionated external beam radiation therapy in the treatment of murine transgenic retinoblastoma
  publication-title: Arch. Ophthalmol.
– volume: 37
  start-page: 590
  year: 2010
  end-page: 599
  article-title: Investigation of the effects of treatment planning variables in small animal radiotherapy dose distributions
  publication-title: Med. Phys.
– volume: 48
  start-page: 5371
  year: 2007
  end-page: 5376
  article-title: Mechanism of retinoblastoma tumor cell death after focal chemotherapy, radiation, and vascular targeting therapy in a mouse model
  publication-title: Invest. Ophthalmol. Visual Sci.
– volume: 39
  start-page: 43
  year: 1998
  end-page: 46
  article-title: Bone fragility induced by X‐ray irradiation in relation to cortical bone‐mineral content
  publication-title: Acta Radiol.
– year: 2007
– volume: 33
  start-page: 4130
  year: 2006
  end-page: 4148
  article-title: Testing of the analytical anisotropic algorithm for photon dose calculation
  publication-title: Med. Phys.
– volume: 32
  start-page: 99
  year: 1995
  end-page: 104
  article-title: radiation sensitivity of glioblastoma‐multiforme
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– volume: 88
  start-page: 31
  year: 1962
  end-page: 37
  article-title: Radiosensitivity of spleen cells from normal and preimmunized mice and its significance to intact animals
  publication-title: J. Immunol. Suppl.
– volume: 36
  start-page: 4991
  year: 2009
  end-page: 4999
  article-title: Kilovoltage beam Monte Carlo dose calculations in submillimeter voxels for small animal radiotherapy
  publication-title: Med. Phys.
– year: 2013
  article-title: High throughput film dosimetry in homogeneous and heterogeneous media for a small animal irradiator
  publication-title: Physica Medica
– volume: 20
  start-page: 1709
  year: 1993
  end-page: 1719
  article-title: Tomotherapy ‐ A new concept for the delivery of dynamic conformal radiotherapy
  publication-title: Med. Phys.
– volume: 45
  start-page: 279
  year: 1972
  end-page: 283
  article-title: Effects of continuous irradiation at low dose‐rates on a rat rhabdomyosarcoma
  publication-title: Br. J. Radiol.
– volume: 32
  start-page: 2096
  year: 1972
  end-page: 2103
  article-title: Responses of bone‐marrow and tumor‐cells to acute and protracted irradiation
  publication-title: Cancer Res.
– volume: 38
  start-page: 3039
  year: 2011
  end-page: 3049
  article-title: The importance of tissue segmentation for dose calculations for kilovoltage radiation therapy
  publication-title: Med. Phys.
– volume: 32
  start-page: 1359
  year: 1995
  end-page: 1370
  article-title: Damage and morbidity from pneumonitis after irradiation of partial volumes of mouse lung
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– volume: 77
  start-page: 384
  year: 2010
  end-page: 391
  article-title: Development of a micro‐computed tomography‐based image‐guided conformal radiotherapy system for small animals
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– volume: 44
  start-page: 1767
  year: 1999
  end-page: 1789
  article-title: Monte Carlo modelling of radiotherapy kV x‐ray units
  publication-title: Phys. Med. Biol.
– volume: 34
  start-page: 4810
  year: 2007
  end-page: 4817
  article-title: Treatment planning for a small animal using Monte Carlo simulation
  publication-title: Med. Phys.
– volume: 38
  start-page: 845
  year: 2011
  end-page: 856
  article-title: Characterization of image quality and image‐guidance performance of a preclinical microirradiator
  publication-title: Med. Phys.
– volume: 64
  start-page: 289
  year: 2006
  end-page: 300
  article-title: Evaluation of image‐guided radiation therapy (IGRT) technologies and their impact on the outcomes of hypofractionated prostate cancer treatments: A radiobiologic analysis
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– volume: 63
  start-page: 521
  year: 1975
  end-page: 530
  article-title: Increased radiosensitivity of rat rhabdomyosarcoma cells induced by protracted irradiation
  publication-title: Radiat. Res.
– volume: 34
  start-page: 203
  year: 1995
  end-page: 209
  article-title: Renal damage after total‐body irradiation in a mouse model for bone‐marrow transplantation ‐ Effect of radiation‐dose rate
  publication-title: Radiother. Oncol.
– volume: 33
  start-page: 3834
  year: 2006
  end-page: 3845
  article-title: Progress toward a microradiation therapy small animal conformal irradiator
  publication-title: Med. Phys.
– volume: 6
  start-page: 111
  year: 2007
  end-page: 121
  article-title: An open‐source tool for investigating PET in radiation oncology
  publication-title: Technol. Cancer Res. Treat.
– year: 2006
– volume: 34
  start-page: 4706
  year: 2007
  end-page: 4716
  article-title: MicroRT ‐ Small animal conformal irradiator
  publication-title: Med. Phys.
– volume: 86
  start-page: 10090
  year: 1989
  end-page: 10094
  article-title: Regression of adjuvant‐induced arthritis in rats following bone marrow transplantation
  publication-title: Proc. Natl. Acad. Sci. U.S.A.
– volume: 53
  start-page: 1527
  year: 2008
  end-page: 1543
  article-title: Benchmarking EGSnrc in the kilovoltage energy range against experimental measurements of charged particle backscatter coefficients
  publication-title: Phys. Med. Biol.
– volume: 49
  start-page: 17
  year: 2008
  end-page: 26
  article-title: Anesthesia and other considerations for in vivo imaging of small animals
  publication-title: ILAR J.
– volume: 54
  start-page: 891
  year: 2009
  end-page: 905
  article-title: Image‐guided small animal radiation research platform: Calibration of treatment beam alignment
  publication-title: Phys. Med. Biol.
– volume: 69
  start-page: 124
  year: 1997
  end-page: 128
  article-title: The cyberknife: A frameless robotic system for radiosurgery
  publication-title: Stereotact. Funct. Neurosurg.
– volume: 71
  start-page: 1591
  year: 2008
  end-page: 1599
  article-title: High‐resolution, small animal radiation research platform with X‐ray tomographic guidance capabilities
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– volume: 47
  start-page: 673
  year: 1974
  end-page: 678
  article-title: Effectiveness of continuous low dose‐rate gamma‐irradiation on rat skin
  publication-title: Br. J. Radiol.
– volume: 32
  start-page: 2245
  year: 2005
  end-page: 2253
  article-title: Precise radiochromic film dosimetry using a flat‐bed document scanner
  publication-title: Med. Phys.
– volume: 16
  start-page: 1501
  year: 1989
  end-page: 1509
  article-title: Late toxicity of total‐body irradiation with bone‐marrow transplantation in a rat model
  publication-title: Int. J. Radiat. Oncol., Biol., Phys.
– year: 2013
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Snippet Purpose: Small animal radiation therapy has advanced significantly in recent years. Whereas in the past dose was delivered using a single beam and a lead...
Small animal radiation therapy has advanced significantly in recent years. Whereas in the past dose was delivered using a single beam and a lead shield for...
Purpose: Small animal radiation therapy has advanced significantly in recent years. Whereas in the past dose was delivered using a single beam and a lead...
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osti
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SourceType Open Access Repository
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StartPage 011710
SubjectTerms Anatomy
ANIMAL TISSUES
Animals
BEAMS
biomedical equipment
bone
Cancer
Collimators
Computerised tomographs
computerised tomography
CRITICAL ORGANS
dosimetry
Dosimetry/exposure assessment
HEART
lung
LUNGS
Medical imaging
Medical treatment planning
MICE
microCT
Monte Carlo
MONTE CARLO METHOD
Monte Carlo methods
NEOPLASMS
neurophysiology
OPTIMIZATION
Orthopaedic methods or devices for non‐surgical treatment of bones or joints; Nursing devices
orthopaedics
RADIATION DOSE DISTRIBUTIONS
RADIATION DOSES
radiation therapy
Radiation Therapy Physics
RADIOLOGY AND NUCLEAR MEDICINE
RADIOSENSITIVITY
RADIOTHERAPY
Radiotherapy Dosage
Radiotherapy Planning, Computer-Assisted
Radiotherapy, Conformal - methods
SARRP
Scintigraphy
SHIELDS
single‐field irradiator
SKELETON
small animal radiotherapy
SPINAL CORD
Therapeutic applications, including brachytherapy
Time Factors
tumours
Vacuum tubes
Title Modality comparison for small animal radiotherapy: A simulation study
URI http://dx.doi.org/10.1118/1.4842415
https://onlinelibrary.wiley.com/doi/abs/10.1118%2F1.4842415
https://www.ncbi.nlm.nih.gov/pubmed/24387502
https://www.proquest.com/docview/1490750445
https://www.osti.gov/biblio/22250753
https://pubmed.ncbi.nlm.nih.gov/PMC3888460
Volume 41
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