Your search keyword '"Paino, Jason"' showing total 18 results

1. Accurate and fast deep learning dose prediction for a preclinical microbeam radiation therapy study using low-statistics Monte Carlo simulations

Author

Mentzel, Florian, Paino, Jason, Barnes, Micah, Cameron, Matthew, Corde, Stéphanie, Engels, Elette, Kröninger, Kevin, Lerch, Michael, Nackenhorst, Olaf, Rosenfeld, Anatoly, Tehei, Moeva, Tsoi, Ah Chung, Vogel, Sarah, Weingarten, Jens, Hagenbuchner, Markus, and Guatelli, Susanna

Subjects

Physics - Medical Physics

Abstract

Microbeam radiation therapy (MRT) utilizes coplanar synchrotron radiation beamlets and is a proposed treatment approach for several tumour diagnoses that currently have poor clinical treatment outcomes, such as gliosarcomas. Prescription dose estimations for treating preclinical gliosarcoma models in MRT studies at the Imaging and Medical Beamline at the Australian Synchrotron currently rely on Monte Carlo (MC) simulations. The steep dose gradients associated with the 50$\,\mu$m wide coplanar beamlets present a significant challenge for precise MC simulation of the MRT irradiation treatment field in a short time frame. Much research has been conducted on fast dose estimation methods for clinically available treatments. However, such methods, including GPU Monte Carlo implementations and machine learning (ML) models, are unavailable for novel and emerging cancer radiation treatment options like MRT. In this work, the successful application of a fast and accurate machine learning dose prediction model in a retrospective preclinical MRT rodent study is presented for the first time. The ML model predicts the peak doses in the path of the microbeams and the valley doses between them, delivered to the gliosarcoma in rodent patients. The predictions of the ML model show excellent agreement with low-noise MC simulations, especially within the investigated tumour volume. This agreement is despite the ML model being deliberately trained with MC-calculated samples exhibiting significantly higher statistical uncertainties. The successful use of high-noise training set data samples, which are much faster to generate, encourages and accelerates the transfer of the ML model to different treatment modalities for other future applications in novel radiation cancer therapies.

Published

2022

2. A step towards treatment planning for microbeam radiation therapy: fast peak and valley dose predictions with 3D U-Nets

Author

Mentzel, Florian, Barnes, Micah, Kröninger, Kevin, Lerch, Michael, Nackenhorst, Olaf, Paino, Jason, Rosenfeld, Anatoly, Saraswati, Ayu, Tsoi, Ah Chung, Weingarten, Jens, Hagenbuchner, Markus, and Guatelli, Susanna

Subjects

Physics - Medical Physics

Abstract

Fast and accurate dose predictions are one of the bottlenecks in treatment planning for microbeam radiation therapy (MRT). In this paper, we propose a machine learning (ML) model based on a 3D U-Net. Our approach predicts separately the large doses of the narrow high intensity synchrotron microbeams and the lower valley doses between them. For this purpose, a concept of macro peak doses and macro valley doses is introduced, describing the respective doses not on a microscopic level but as macroscopic quantities in larger voxels. The ML model is trained to mimic full Monte Carlo (MC) data. Complex physical effects such as polarization are therefore automatically taking into account by the model. The macro dose distribution approach described in this study allows for superimposing single microbeam predictions to a beam array field making it an interesting candidate for treatment planning. It is shown that the proposed approach can overcome a main obstacle with microbeam dose predictions by predicting a full microbeam irradiation field in less than a minute while maintaining reasonable accuracy., Comment: accepted for publication in the IFMBE Proceedings on the World Congress on Medical Physics and Biomedical Engineering 2022

Published

2022

3. Fast and accurate dose predictions for novel radiotherapy treatments in heterogeneous phantoms using conditional 3D-UNet generative adversarial networks

Author

Mentzel, Florian, Kröninger, Kevin, Lerch, Michael, Nackenhorst, Olaf, Paino, Jason, Rosenfeld, Anatoly, Saraswati, Ayu, Tsoi, Ah Chung, Weingarten, Jens, Hagenbuchner, Markus, and Guatelli, Susanna

Subjects

Physics - Medical Physics

Abstract

Novel radiotherapy techniques like synchrotron X-ray microbeam radiation therapy (MRT), require fast dose distribution predictions that are accurate at the sub-mm level, especially close to tissue/bone/air interfaces. Monte Carlo physics simulations are recognised to be one of the most accurate tools to predict the dose delivered in a target tissue but can be very time consuming and therefore prohibitive for treatment planning. Faster dose prediction algorithms are usually developed for clinically deployed treatments only. In this work, we explore a new approach for fast and accurate dose estimations suitable for novel treatments using digital phantoms used in pre-clinical development and modern machine learning techniques. We develop a generative adversarial network (GAN) model, which is able to emulate the equivalent Geant4 Monte Carlo simulation with adequate accuracy, and use it to predict the radiation dose delivered by a broad synchrotron beam to various phantoms. The energy depositions used for the training of the GAN are obtained using full Geant4 Monte Carlo simulations of a synchrotron radiation broad beam passing through the phantoms. The energy deposition is scored and predicted in voxel matrices of size 140x18x18 with a voxel edge length of 1 mm. The GAN model consists of two competing 3D convolutional neural networks, which are conditioned on the photon beam and phantom properties. The energy deposition predictions inside all phantom geometries under investigation show deviations of less than 3% of the maximum deposited energy from the simulation for roughly 99% of the voxels in the field of the beam. The computing time for a single prediction is reduced from several hundred hours using Geant4 simulation to less than a second using the GAN model., Comment: Accepted for publication in Medical Physics

Published

2022

4. Review on high spatial resolution dosimetry with pixelated semiconductor detectors for radiation therapy

Author

Filipev, Ilia, Paino, Jason, Poder, Joel, Cutajar, Dean, Hardcastle, Nicholas, Guatelli, Susanna, Petasecca, Marco, Lerch, Michael, Feygelman, Vladimir, Kron, Tomas, and Rosenfeld, Anatoly

Published

2024

5. Characterization of selected additive manufacturing materials for synchrotron monochromatic imaging and broad-beam radiotherapy at the Australian synchrotron- imaging and medical beamline

Author

Bustillo, John Paul Ortiz, primary, Paino, Jason, additional, Barnes, Micah, additional, Cameron, Matthew, additional, Rosenfeld, Anatoly B, additional, and Lerch, Michael L F, additional

Published

2024

6. Microbeam Irradiation of the Beating Rodent Heart: An Ex Vivo Study of Acute and Subacute Effects on Cardiac Function

Author

Lange, Falko, Kirschstein, Timo, Davis, Jeremy, Paino, Jason, Barnes, Micah, Klein, Mitzi, Porath, Katrin, Stöhlmacher, Paula, Fiedler, Stefan, Frank, Marcus, Köhling, Rüdiger, Hildebrandt, Guido, Hausermann, Daniel, Lerch, Michael, and Schültke, Elisabeth

Published

2022

7. Monte Carlo Studies for Microbeam Radiation Therapy

Author

Guatelli, Susanna, primary, Bartzsch, Stefan, additional, Cameron, Matthew, additional, Lerch, Michael L. F., additional, and Paino, Jason, additional

Published

2021

8. Modulating Synchrotron Microbeam Radiation Therapy Doses for Preclinical Brain Cancer

Author

Engels, Elette, primary, Paino, Jason R., additional, Vogel, Sarah E., additional, Valceski, Michael, additional, Khochaiche, Abass, additional, Li, Nan, additional, Davis, Jeremy A., additional, O’Keefe, Alice, additional, Dipuglia, Andrew, additional, Cameron, Matthew, additional, Barnes, Micah, additional, Stevenson, Andrew W., additional, Rosenfeld, Anatoly, additional, Lerch, Michael, additional, Corde, Stéphanie, additional, and Tehei, Moeava, additional

Published

2023

9. A Novel Anthropomorphic Phantom Composed of Tissue-Equivalent Materials for Use in Experimental Radiotherapy: Design, Dosimetry and Biological Pilot Study

Author

Breslin, Thomas, primary, Paino, Jason, additional, Wegner, Marie, additional, Engels, Elette, additional, Fiedler, Stefan, additional, Forrester, Helen, additional, Rennau, Hannes, additional, Bustillo, John, additional, Cameron, Matthew, additional, Häusermann, Daniel, additional, Hall, Christopher, additional, Krause, Dieter, additional, Hildebrandt, Guido, additional, Lerch, Michael, additional, and Schültke, Elisabeth, additional

Published

2023

10. The Spinal Cord as Organ of Risk: Assessment for Acute and Subacute Neurological Adverse Effects after Microbeam Radiotherapy in a Rodent Model

Author

Jaekel, Felix, primary, Paino, Jason, additional, Engels, Elette, additional, Klein, Mitzi, additional, Barnes, Micah, additional, Häusermann, Daniel, additional, Hall, Christopher, additional, Zheng, Gang, additional, Wang, Hongxin, additional, Hildebrandt, Guido, additional, Lerch, Michael, additional, and Schültke, Elisabeth, additional

Published

2023

11. Accurate and Fast Deep Learning Dose Prediction for a Preclinical Microbeam Radiation Therapy Study Using Low-Statistics Monte Carlo Simulations

Author

Mentzel, Florian, primary, Paino, Jason, additional, Barnes, Micah, additional, Cameron, Matthew, additional, Corde, Stéphanie, additional, Engels, Elette, additional, Kröninger, Kevin, additional, Lerch, Michael, additional, Nackenhorst, Olaf, additional, Rosenfeld, Anatoly, additional, Tehei, Moeava, additional, Tsoi, Ah Chung, additional, Vogel, Sarah, additional, Weingarten, Jens, additional, Hagenbuchner, Markus, additional, and Guatelli, Susanna, additional

Published

2023

12. DoseMRT : A Software Package for Individualised Monte Carlo Dose Calculations of Synchrotron-Generated Microbeam Radiation Therapy.

Author

Paino, Jason, Cameron, Matthew, Large, Matthew, Barnes, Micah, Engels, Elette, Vogel, Sarah, Tehei, Moeava, Corde, Stéphanie, Guatelli, Susanna, Rosenfeld, Anatoly, and Lerch, Michael

Published

2023

13. Modification of the Langendorff system of the isolated beating heart for experimental radiotherapy at a synchrotron: 4000 Gy in a heart beat

Author

Schültke, Elisabeth, primary, Lerch, Michael, additional, Kirschstein, Timo, additional, Lange, Falko, additional, Porath, Katrin, additional, Fiedler, Stefan, additional, Davis, Jeremy, additional, Paino, Jason, additional, Engels, Elette, additional, Barnes, Micah, additional, Klein, Mitzi, additional, Hall, Christopher, additional, Häusermann, Daniel, additional, and Hildebrandt, Guido, additional

Published

2022

14. Fast and accurate dose predictions for novel radiotherapy treatments in heterogeneous phantoms using conditional 3D‐UNet generative adversarial networks

Author

Mentzel, Florian, primary, Kröninger, Kevin, additional, Lerch, Michael, additional, Nackenhorst, Olaf, additional, Paino, Jason, additional, Rosenfeld, Anatoly, additional, Saraswati, Ayu, additional, Tsoi, Ah Chung, additional, Weingarten, Jens, additional, Hagenbuchner, Markus, additional, and Guatelli, Susanna, additional

Published

2022

15. Evaluation of silicon strip detectors in transmission mode for online beam monitoring in microbeam radiation therapy at the Australian Synchrotron

Author

Davis, Jeremy, primary, Dipuglia, Andrew, additional, Cameron, Matthew, additional, Paino, Jason, additional, Cullen, Ashley, additional, Guatelli, Susanna, additional, Petasecca, Marco, additional, Rosenfeld, Anatoly, additional, and Lerch, Michael, additional

Published

2022

16. Incorporating Clinical Imaging into the Delivery of Microbeam Radiation Therapy

Author

Paino, Jason, primary, Barnes, Micah, additional, Engels, Elette, additional, Davis, Jeremy, additional, Guatelli, Susanna, additional, de Veer, Michael, additional, Hall, Chris, additional, Häusermann, Daniel, additional, Tehei, Moeava, additional, Corde, Stéphanie, additional, Rosenfeld, Anatoly, additional, and Lerch, Michael, additional

Published

2021

17. Towards high spatial resolution tissue‐equivalent dosimetry for microbeam radiation therapy using organic semiconductors.

Author

Posar, Jessie A., Large, Matthew, Alnaghy, Saree, Paino, Jason R., Butler, Duncan J., Griffith, Matthew J., Hood, Sean, Lerch, Michael L. F., Rosenfeld, Anatoly, Sellin, Paul J., Guatelli, Susanna, and Petasecca, Marco

Subjects

ORGANIC semiconductors, RADIATION dosimetry, RADIOTHERAPY, SYNCHROTRON radiation, RADIATION tolerance, PACKAGING materials, GAMMA rays

Abstract

Spatially fractionated ultra‐high‐dose‐rate beams used during microbeam radiation therapy (MRT) have been shown to increase the differential response between normal and tumour tissue. Quality assurance of MRT requires a dosimeter that possesses tissue equivalence, high radiation tolerance and spatial resolution. This is currently an unsolved challenge. This work explored the use of a 500 nm thick organic semiconductor for MRT dosimetry on the Imaging and Medical Beamline at the Australian Synchrotron. Three beam filters were used to irradiate the device with peak energies of 48, 76 and 88 keV with respective dose rates of 3668, 500 and 209 Gy s−1. The response of the device stabilized to 30% efficiency after an irradiation dose of 30 kGy, with a 0.5% variation at doses of 35 kGy and higher. The calibration factor after pre‐irradiation was determined to be 1.02 ± 0.005 µGy per count across all three X‐ray energy spectra, demonstrating the unique advantage of using tissue‐equivalent materials for dosimetry. The percentage depth dose curve was within ±5% of the PTW microDiamond detector. The broad beam was fractionated into 50 microbeams (50 µm FHWM and 400 µm centre‐to‐centre distance). For each beam filter, the FWHMs of all 50 microbeams were measured to be 51 ± 1.4, 53 ± 1.4 and 69 ± 1.9 µm, for the highest to lowest dose rate, respectively. The variation in response suggested the photodetector possessed dose‐rate dependence. However, its ability to reconstruct the microbeam profile was affected by the presence of additional dose peaks adjacent to the one generated by the X‐ray microbeam. Geant4 simulations proved that the additional peaks were due to optical photons generated in the barrier film coupled to the sensitive volume. The simulations also confirmed that the amplitude of the additional peak in comparison with the microbeam decreased for spectra with lower peak energies, as observed in the experimental data. The material packaging can be optimized during fabrication by solution processing onto a flexible substrate with a non‐fluorescent barrier film. With these improvements, organic photodetectors show promising prospects as a cost‐effective high spatial resolution tissue‐equivalent flexible dosimeter for synchrotron radiation fields. [ABSTRACT FROM AUTHOR]

Published

2021

18. Design, construction, and dosimetry of 3D printed heterogeneous phantoms for synchrotron brain cancer radiation therapy quality assurance.

Author

Bustillo JPO, Paino J, Barnes M, Cayley J, de Rover V, Cameron M, Engels EEM, Tehei M, Beirne S, Wallace GG, Rosenfeld AB, and Lerch MLF

Subjects

Rats, Animals, Radiotherapy Dosage, Monte Carlo Method, Quality Assurance, Health Care, Equipment Design, Printing, Three-Dimensional, Phantoms, Imaging, Synchrotrons, Radiometry instrumentation, Brain Neoplasms radiotherapy, Brain Neoplasms diagnostic imaging

Abstract

Objective. This study aims to design, manufacture, and test 3D printed quality assurance (QA) dosimetry phantoms for synchrotron brain cancer radiation therapy at the Australian synchrotron. Approach. Fabricated 3D printed phantoms from simple slab phantoms, a preclinical rat phantom, and an anthropomorphic head phantom were fabricated and characterized. Attenuation measurements of various polymers, ceramics and metals were acquired using synchrotron monochromatic micro-computed tomography (CT) imaging. Polylactic acid plus, VeroClear, Durable resin, and tricalcium phosphate were used in constructing the phantoms. Furthermore, 3D printed bone equivalent materials were compared relative to ICRU bone and hemihydrate plaster. Homogeneous and heterogeneous rat phantoms were designed and fabricated using tissue-equivalent materials. Geometric accuracy, CT imaging, and consistency were considered. Moreover, synchrotron broad-beam x-rays were delivered using a 3 Tesla superconducting multipole wiggler field for four sets of synchrotron radiation beam qualities. Dose measurements were acquired using a PinPoint ionization chamber and compared relative to a water phantom and a RMI457 Solid Water phantom. Experimental depth doses were compared relative to calculated doses using a Geant4 Monte Carlo simulation. Main results. Polylactic acid (PLA+) shows to have a good match with the attenuation coefficient of ICRU water, while both tricalcium phosphate and hydroxyapatite have good attenuation similarity with ICRU bone cortical. PLA+ material can be used as substitute to RMI457 slabs for reference dosimetry with a maximum difference of 1.84%. Percent depth dose measurement also shows that PLA+ has the best match with water and RMI457 within ±2.2% and ±1.6%, respectively. Overall, PLA+ phantoms match with RMI457 phantoms within ±3%. Significance and conclusion. The fabricated phantoms are excellent tissue equivalent equipment for synchrotron radiation dosimetry QA measurement. Both the rat and the anthropomorphic head phantoms are useful in synchrotron brain cancer radiotherapy dosimetry, experiments, and future clinical translation of synchrotron radiotherapy and imaging., (Creative Commons Attribution license.)

Published

2024