A. Latorre-Musoll scite author profile

The Exradin W1 response is energy independent for high energy x-rays and electron beams, and only one calibration coefficient is needed. A temperature correction factor should be applied to keep uncertainties around 2% for absolute dose measurements and around 1% for relative measurements in high-energy photon and electron beams. The Exradin W1 scintillator is an excellent alternative to detectors such as diodes for relative dose measurements.

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Pseudo skin flash on VMAT in breast radiotherapy: Optimization of virtual bolus thickness and HU values

Lizondo

Latorre-Musoll

Ribas

et al. 2019

Physica Medica

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Response to “Comment on ‘Characterization of the Exradin W1 scintillator for use in radiotherapy’ ” [Med. Phys. 42, 297–304 (2015)]

et al. 2015

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PO-0918 Optimal parameters to perform the Pseudo Skin-Flash on VMAT on breast radiotherapy

Lizondo¹,

Latorre-Musoll²,

Espinosa³

et al. 2019

Radiotherapy and Oncology

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Transit-guided radiation therapy: proof of concept of an on-line technique for correcting position errors using transit portal images

Latorre-Musoll¹,

Delgado-Tapia²,

Gisbert³

et al. 2022

Phys. Med. Biol.

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Objective. Transit in vivo dosimetry methods monitor that the dose distribution is delivered as planned. However, they have a limited ability to identify and to quantify the cause of a given disagreement, especially those caused by position errors. This paper describes a proof of concept of a simple in vivo technique to infer a position error from a transit portal image (TPI). Approach. For a given treatment field, the impact of a position error is modeled as a perturbation of the corresponding reference (unperturbed) TPI. The perturbation model determines the patient translation, described by a shift vector, by comparing a given in vivo TPI to the corresponding reference TPI. Patient rotations can also be determined by applying this formalism to independent regions of interest over the patient. Eight treatment plans have been delivered to an anthropomorphic phantom under a large set of couch shifts (<15 mm) and rotations (<10°) to experimentally validate this technique, which we have named Transit-Guided Radiation Therapy (TGRT). Main results. The root mean squared error (RMSE) between the determined and the true shift magnitudes was 1.0/2.4/4.9 mm for true shifts ranging between 0-5/5-10/10-15 mm, respectively. The angular accuracy of the determined shift directions was 12°±14°. The RMSE between the determined and the true rotations was 0.5°. The TGRT technique decoupled translations and rotations satisfactorily. In 96% of the cases, the TGRT technique decreased the existing position error. The detection threshold of the TGRT technique was around 1 mm and it was nearly independent of the tumor site, delivery technique, beam energy or patient thickness. Significance. TGRT is a promising technique that not only provides reliable determinations of the position errors without increasing the required equipment, acquisition time or patient dose, but it also adds on-line correction capabilities to existing methods currently using TPIs.

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EP-1662: Dosimetric impact of respiratory movements for dynamic IMRT breast irradiation with a SIB technique

Fez¹,

Jornet²,

Latorre-Musoll³

et al. 2014

Radiotherapy and Oncology

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Role of 18FDG-PET/CT for radiotherapy planning in head and neck cancer

Farré¹,

Díez²,

Rojas³

et al. 2013

Reports of Practical Oncology & Radiotherapy

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EP-1495: Should we use correction factors for skin dose measurements with radiochromic films?

Fez¹,

Duch²,

Duque-Muñoz³

et al. 2017

Radiotherapy and Oncology

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A. Latorre-Musoll

Characterization of the Exradin W1 scintillator for use in radiotherapy

Pseudo skin flash on VMAT in breast radiotherapy: Optimization of virtual bolus thickness and HU values

Response to “Comment on ‘Characterization of the Exradin W1 scintillator for use in radiotherapy’ ” [Med. Phys. 42, 297–304 (2015)]

PO-0918 Optimal parameters to perform the Pseudo Skin-Flash on VMAT on breast radiotherapy

Transit-guided radiation therapy: proof of concept of an on-line technique for correcting position errors using transit portal images

EP-1662: Dosimetric impact of respiratory movements for dynamic IMRT breast irradiation with a SIB technique

Role of 18FDG-PET/CT for radiotherapy planning in head and neck cancer

EP-1495: Should we use correction factors for skin dose measurements with radiochromic films?

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