Your search keyword '"Fukunaga, Hisanori"' showing total 5 results

1. Reply to comment on 'Modeling for predicting survival fraction of cells after ultra-high dose rate irradiation'.

Author

Shiraishi Y, Matsuya Y, and Fukunaga H

Subjects

Radiation Dosage, Humans, Oxygen metabolism, Cell Survival radiation effects, Models, Biological, Dose-Response Relationship, Radiation, DNA Damage

Abstract

Liew and Mairani commented on our paper 'Modeling for predicting survival fraction of cells after ultra-high dose rate irradiation' (Shiraishi et al 2024a Phys. Med. Biol. 015017), which proposed a biophysical model to predict the dose-response curve of surviving cell fractions after ultra-high dose rate irradiation following conventional dose rate irradiation by considering DNA damage yields. They suggested the need to consider oxygen concentration in our prediction model and possible issues related to the data selection process used for the benchmarking test in our paper. In this reply, we discuss the limitations of both the present model and the available experimental data for determining the model's parameters. We also demonstrate that our proposed model can reproduce the experimental survival data even when using only the experimental DNA damage data measured reliably under normoxic conditions.69 015017), which proposed a biophysical model to predict the dose-response curve of surviving cell fractions after ultra-high dose rate irradiation following conventional dose rate irradiation by considering DNA damage yields. They suggested the need to consider oxygen concentration in our prediction model and possible issues related to the data selection process used for the benchmarking test in our paper. In this reply, we discuss the limitations of both the present model and the available experimental data for determining the model's parameters. We also demonstrate that our proposed model can reproduce the experimental survival data even when using only the experimental DNA damage data measured reliably under normoxic conditions., (© 2024 Institute of Physics and Engineering in Medicine.)

Published

2024

2. Modeling for predicting survival fraction of cells after ultra-high dose rate irradiation.

Author

Shiraishi Y, Matsuya Y, Kusumoto T, and Fukunaga H

Subjects

Cell Line, Kinetics, Radiation Tolerance, Radiotherapy Dosage, DNA Damage, DNA Repair

Abstract

Objective . FLASH radiotherapy (FLASH-RT) with ultra-high dose rate (UHDR) irradiation (i.e. > 40 Gy s -1 ) spares the function of normal tissues while preserving antitumor efficacy, known as the FLASH effect. The biological effects after conventional dose rate-radiotherapy (CONV-RT) with ≤0.1 Gy s -1 have been well modeled by considering microdosimetry and DNA repair processes, meanwhile modeling of radiosensitivities under UHDR irradiation is insufficient. Here, we developed an integrated microdosimetric-kinetic ( IMK ) model for UHDR-irradiation enabling the prediction of surviving fraction after UHDR irradiation. Approach. The IMK model for UHDR-irradiation considers the initial DNA damage yields by the modification of indirect effects under UHDR compared to CONV dose rate. The developed model is based on the linear-quadratic (LQ) nature with the dose and dose square coefficients, considering the reduction of DNA damage yields as a function of dose rate. Main results. The estimate by the developed model could successfully reproduce the in vitro experimental dose-response curve for various cell line types and dose rates. Significance. The developed model would be useful for predicting the biological effects under the UHDR irradiation., (© 2023 Institute of Physics and Engineering in Medicine.)

Published

2023

3. An Analytical Method for Quantifying the Yields of DNA Double-Strand Breaks Coupled with Strand Breaks by γ-H2AX Focus Formation Assay Based on Track-Structure Simulation.

Author

Yachi Y, Matsuya Y, Yoshii Y, Fukunaga H, Date H, and Kai T

Subjects

Dose-Response Relationship, Radiation, X-Rays, DNA metabolism, DNA Damage, Cell Nucleus metabolism

Abstract

Complex DNA double-strand break (DSB), which is defined as a DSB coupled with additional strand breaks within 10 bp in this study, induced after ionizing radiation or X-rays, is recognized as fatal damage which can induce cell death with a certain probability. In general, a DSB site inside the nucleus of live cells can be experimentally detected using the γ-H2AX focus formation assay. DSB complexity is believed to be detected by analyzing the focus size using such an assay. However, the relationship between focus size and DSB complexity remains uncertain. In this study, using Monte Carlo (MC) track-structure simulation codes, i.e., an in-house WLTrack code and a Particle and Heavy Ion Transport code System (PHITS), we developed an analytical method for qualifying the DSB complexity induced by photon irradiation from the microscopic image of γ-H2AX foci. First, assuming that events (i.e., ionization and excitation) potentially induce DNA strand breaks, we scored the number of events in a water cube (5.03 × 5.03 × 5.03 nm 3 ) along electron tracks. Second, we obtained the relationship between the number of events and the foci size experimentally measured by the γ-H2AX focus formation assay. Third, using this relationship, we evaluated the degree of DSB complexity induced after photon irradiation for various X-ray spectra using the foci size, and the experimental DSB complexity was compared to the results estimated by the well-verified DNA damage estimation model in the PHITS code. The number of events in a water cube was found to be proportional to foci size, suggesting that the number of events intrinsically related to DSB complexity at the DNA scale. The developed method was applicable to focus data measured for various X-ray spectral situations (i.e., diagnostic kV X-rays and therapeutic MV X-rays). This method would contribute to a precise understanding of the early biological impacts of photon irradiation by means of the γ-H2AX focus formation assay.

Published

2023

4. Modeling for predicting survival fraction of cells after ultra-high dose rate irradiation.

Author

Shiraishi, Yuta, Matsuya, Yusuke, Kusumoto, Tamon, and Fukunaga, Hisanori

Subjects

IRRADIATION, CELL survival, DNA repair, RADIATION tolerance, MICRODOSIMETRY, DNA damage

Abstract

Objective. FLASH radiotherapy (FLASH-RT) with ultra-high dose rate (UHDR) irradiation (i.e. > 40 Gy s−1) spares the function of normal tissues while preserving antitumor efficacy, known as the FLASH effect. The biological effects after conventional dose rate-radiotherapy (CONV-RT) with ≤0.1 Gy s−1 have been well modeled by considering microdosimetry and DNA repair processes, meanwhile modeling of radiosensitivities under UHDR irradiation is insufficient. Here, we developed an integrated microdosimetric-kinetic (IMK) model for UHDR-irradiation enabling the prediction of surviving fraction after UHDR irradiation. Approach. The IMK model for UHDR-irradiation considers the initial DNA damage yields by the modification of indirect effects under UHDR compared to CONV dose rate. The developed model is based on the linear-quadratic (LQ) nature with the dose and dose square coefficients, considering the reduction of DNA damage yields as a function of dose rate. Main results. The estimate by the developed model could successfully reproduce the in vitro experimental dose–response curve for various cell line types and dose rates. Significance. The developed model would be useful for predicting the biological effects under the UHDR irradiation. [ABSTRACT FROM AUTHOR]

Published

2024

5. Microbeam evolution: from single cell irradiation to pre-clinical studies.

Author

Ghita, Mihaela, Fernandez-Palomo, Cristian, Fukunaga, Hisanori, Fredericia, Pil M., Schettino, Giuseppe, Bräuer-Krisch, Elke, Butterworth, Karl T., McMahon, Stephen J., and Prise, Kevin M.

Subjects

IRRADIATION, RADIOTHERAPY, ORGANELLES, CELLULAR mechanics, MEDICAL radiology, DNA damage, SYNCHROTRONS, RADIATION doses

Abstract

Purpose: This review follows the development of microbeam technology from the early days of single cell irradiations, to investigations of specific cellular mechanisms and to the development of new treatment modalities in vivo. A number of microbeam applications are discussed with a focus on pre-clinical modalities and translation towards clinical application. Conclusions: The development of radiation microbeams has been a valuable tool for the exploration of fundamental radiobiological response mechanisms. The strength of micro-irradiation techniques lies in their ability to deliver precise doses of radiation to selected individual cells in vitro or even to target subcellular organelles. These abilities have led to the development of a range of microbeam facilities around the world allowing the delivery of precisely defined beams of charged particles, X-rays, or electrons. In addition, microbeams have acted as mechanistic probes to dissect the underlying molecular events of the DNA damage response following highly localized dose deposition. Further advances in very precise beam delivery have also enabled the transition towards new and exciting therapeutic modalities developed at synchrotrons to deliver radiotherapy using plane parallel microbeams, in Microbeam Radiotherapy (MRT). [ABSTRACT FROM AUTHOR]

Published

2018