A proof of concept kilovoltage intensity modulated radiotherapy platform for the treatment of glioblastoma multiforme

Loughery, Brian; Halford, Robert; Dess, Kathryn; Rakowski, J; Cox, M. A.; Koh, Joseph; Mayville, Alan; Riess, Jeffery; Snyder, Michael

doi:10.1088/2057-1976/ab36c1

Cited by 4 publications

(8 citation statements)

References 34 publications

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“…Another source of error in MC simulations of the NPs stems from the electron transport algorithm and electron energy cut-offs. The authors believe that using a new version of MCNP code with a more accurate electron transport method of ''single-event'' and lower energy cuff-off of 10 eV 21 gave rise to more reliable values compared to previous studies of Schultz et al 10 and Loughery et al 13 Our results demonstrate the feasibility of NP-aided RT with orthovoltage beams in a clinical setting. More importantly, if the higher targeting capabilities of the INPs for tumor cells were achieved, it would create a significant opportunity for INPs to be accumulated inside the tumor cells and irradiated by orthovoltage beams more accurately than other modalities.…”

Section: Discussionsupporting

confidence: 52%

Section: Discussionmentioning

confidence: 84%

“…In the comprehensive study by Loughery et al, 13 both MC and experimental dosimetry methods were utilized to validate the kilovoltage intensity–modulated radiotherapy for the treatment of GBM tumors. In an MC study, 17 cross-firing beams were employed to treat a centrally located tumor in the brain.…”

Section: Discussionmentioning

confidence: 99%

“…Recently, Loughery et al 13 introduced a novel technique for the treatment of GBM tumors, which employed an iodine contrast agent as a radiosensitizer and orthovoltage intensity–modulated photon beams. In their study, the skull dose was found to be a limiting factor in dose escalation for iodine-loaded brain tumors.…”

Section: Introductionmentioning

confidence: 99%

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In silico analysis of optimum photon energy spectra and beam parameters for iodine nanoparticle–aided orthovoltage radiation therapy of brain tumors

et al. 2022

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In this study, the effect of photon energy spectra on the dose enhancement factor (DEF) and other influencing parameters such as skull–tumor dose ratios were estimated for a confined tumor loaded with iodine nanoparticles (INPs). A mathematical brain phantom with a brain tumor was simulated by the MCNP6 Monte Carlo code. A validated commercial computed tomography model consisting of an X-ray tube, Al–Cu filters, and collimators was used to simulate the rotational conformal treatment of the tumor. INPs with a diameter of 20 nm and concentrations of 10–50 mg/g were introduced inside the tumor as homogenously distributed spherical particles. The dose distribution inside the phantom was scored for several orthovoltage beams with the peak voltages of 140, 200, and 320 kVp as well as two 3.5 and 6 MV megavoltage beams. A significant rise of DEF values with nanoparticle (NP) concentration for orthovoltage beams is revealed; no significant dose enhancement was obtained for megavoltage beams. The highest DEF and skull–tumor dose ratio were obtained for the 140 kVp beam which decreased with the number of directional fields. The clinically optimal plan for a brain tumor, with high DEFs of 2.81–2.24 and acceptable skull–tumor dose ratios of 0.61–0.51, would be feasible for treatment using 200 and 320 kVp beams, an iodine concentration of 20 mg/g, and 8–15 fields. Our calculations show that clinically significant radiation dose enhancements can be obtained for tumors loaded with INPs using orthovoltage beams. Optimal treatment regimens are feasible using a proper selection of photon beam spectrum and sufficient numbers of cross-firing beams. The limiting effect of skull bone could be minimized by increasing the number of radiation fields and the use of higher quality of orthovoltage beams.

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Section: Discussionsupporting

confidence: 52%

Section: Discussionmentioning

confidence: 84%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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In silico analysis of optimum photon energy spectra and beam parameters for iodine nanoparticle–aided orthovoltage radiation therapy of brain tumors

et al. 2022

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“…In 2019, a group at Wayne State University presented a MC computer model and a proof-of-principle experiment for a kilovoltage intensity modulated radiotherapy (IMRT) for the treatment of GBM by means of CERT with iodine [57]. They used Geant4 to simulate dose deposition in a 15-cm diameter spherical water phantom with a 1.4-cm thick spherical shell mimicking the skull and a target of 1.8-cm in diameter filled with 10 mg/mL of iodine.…”

Section: Kilovoltage Intensity Modulated Radiotherapymentioning

confidence: 99%

External beam radiation therapy with kilovoltage x-rays

Breitkreutz

M²,

Bazalova‐Carter

2020

Physica Medica

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Kilovoltage (kV) x-rays are most commonly used for diagnostic imaging due to their sensitivity to tissue composition. In radiation therapy (RT), due to their fast attenuation, kV x-rays are typically only used for superficial irradiation of skin cancer and for intra-operative RT (IORT). Recently, however, a number of kV RT techniques have emerged. In this review article, we provide a brief overview of the use of kV x-rays for RT. Various kV x-ray source technologies suitable for RT, such as conventional x-ray tubes as well as novel x-ray sources, are first described. This x-ray source section is then followed by a section on their implementation in terms of clinical, veterinary and preclinical applications. Specifically, IORT, superficial RT and dose enhancement with iodine and gold nanoparticles, as well as microbeam RT and FLASH RT are discussed in this context. Then, a number of kV x-ray RT applications in modeling and proof-of-principle stages, such as breast external beam RT with rotational sources, kilovoltage arc therapy and the BriXS Compton pulsed x-ray sources, are reviewed. Finally, some clinical and economic considerations for the development of kV RT techniques are discussed.

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Roadmap for metal nanoparticles in radiation therapy: current status, translational challenges, and future directions

Schuemann¹,

Bagley²,

Berbeco³

et al. 2020

Phys. Med. Biol.

110

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A proof of concept kilovoltage intensity modulated radiotherapy platform for the treatment of glioblastoma multiforme

Cited by 4 publications

References 34 publications

In silico analysis of optimum photon energy spectra and beam parameters for iodine nanoparticle–aided orthovoltage radiation therapy of brain tumors

In silico analysis of optimum photon energy spectra and beam parameters for iodine nanoparticle–aided orthovoltage radiation therapy of brain tumors

External beam radiation therapy with kilovoltage x-rays

Roadmap for metal nanoparticles in radiation therapy: current status, translational challenges, and future directions

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