Your search keyword '"Flint DB"' showing total 11 results

1. SU-E-T-592: OSL Response of Al2O3:C Detectors Exposed to Therapeutic Proton Beams

Author

Granville, DA, primary, Flint, DB, additional, and Sawakuchi, GO, additional

Published

2015

2. PARP inhibition radiosensitizes BRCA1 wildtype and mutated breast cancer to proton therapy.

Author

Ben Kacem M, Bright SJ, Moran E, Flint DB, Martinus DKJ, Turner BX, Qureshi I, Kolachina R, Manandhar M, Marinello PC, Shaitelman SF, and Sawakuchi GO

Subjects

Humans, Female, Cell Line, Tumor, Animals, Mice, Radiation-Sensitizing Agents pharmacology, Radiation Tolerance drug effects, Radiation Tolerance genetics, DNA Damage drug effects, Poly(ADP-ribose) Polymerase Inhibitors pharmacology, Breast Neoplasms genetics, Breast Neoplasms radiotherapy, Breast Neoplasms pathology, Breast Neoplasms drug therapy, Breast Neoplasms metabolism, Proton Therapy, BRCA1 Protein genetics, BRCA1 Protein metabolism, Mutation

Abstract

Aggressive breast cancers often fail or acquire resistance to radiotherapy. To develop new strategies to improve the outcome of aggressive breast cancer patients, we studied how PARP inhibition radiosensitizes breast cancer models to proton therapy, which is a radiotherapy modality that generates more DNA damage in the tumor than standard radiotherapy using photons. Two human BRCA1-mutated breast cancer cell lines and their isogenic BRCA1-recovered pairs were treated with a PARP inhibitor and irradiated with photons or protons. Protons (9.9 and 3.85 keV/µm) induced higher cell kill independent of BRCA1 status. PARP inhibition amplified the cell kill effect to both photons and protons (9.9 and 3.85 keV/µm) independent of BRCA1 status. Numbers of γH2AX foci, micronuclei, and cGAS-positive micronuclei were significantly higher in BRCA1-mutated cells. Cell cycle distribution and stress-induced senescence were not affected by PARP inhibition in our cell lines. In vivo, the combination of protons (3.99 keV/µm) and PARP inhibition induced the greatest tumor growth delay and the highest survival. We found that PARP inhibition increases radiosensitization independent of BRCA1 status for both protons and photons. The combination of protons and PARP inhibition was the most effective in decreasing clonogenic cell survival, increasing DNA damage, and delaying tumor growth., Competing Interests: Declarations. Competing interests: GOS has or had research agreements with Alpha Tau Medical, Artios Pharma, Convergent Radiotherapy and Radiosurgery, TAE Life Sciences and grant funding from DoD and NIH. SFS had contracted research agreements with Alpha Tau Medical, Artios Pharma, TAE Life Sciences, ExactSciences and grant funding from the Emerson Collective Foundation and NIH. SJB had grant funding with the American Association of Physicists in Medicine. MBK, SJB, EM, DBF, DKJM, BXT, IQ, RK, MM, PCM declare no competing interests., (© 2024. The Author(s).)

Published

2024

3. An empirical model of carbon-ion relative biological effectiveness based on the linear correlation between radiosensitivity to photons and carbon ions.

Author

Flint DB, Bright SJ, McFadden C, Konishi T, Martinus DKJ, Manandhar M, Ben Kacem M, Bronk L, and Sawakuchi GO

Subjects

Radiation Tolerance, Humans, Models, Biological, Cell Survival radiation effects, Photons therapeutic use, Relative Biological Effectiveness, Carbon, Linear Energy Transfer

Abstract

Objective. To develop an empirical model to predict carbon ion (C-ion) relative biological effectiveness (RBE). Approach. We used published cell survival data comprising 360 cell line/energy combinations to characterize the linear energy transfer (LET) dependence of cell radiosensitivity parameters describing the dose required to achieve a given survival level, e.g. 5% (D 5% ), which are linearly correlated between photon and C-ion radiations. Based on the LET response of the metrics D 5% and D 37% , we constructed a model containing four free parameters that predicts cells' linear quadratic model (LQM) survival curve parameters for C-ions, α C and β C , from the reference LQM parameters for photons, α X and β X , for a given C-ion LET value. We fit our model's free parameters to the training dataset and assessed its accuracy via leave-one out cross-validation. We further compared our model to the local effect model (LEM) and the microdosimetric kinetic model (MKM) by comparing its predictions against published predictions made with those models for clinically relevant LET values in the range of 23-107 keV μ m -1 . Main Results. Our model predicted C-ion RBE within ±7%-15% depending on cell line and dose which was comparable to LEM and MKM for the same conditions. Significance. Our model offers comparable accuracy to the LEM or MKM but requires fewer input parameters and is less computationally expensive and whose implementation is so simple we provide it coded into a spreadsheet. Thus, our model can serve as a pragmatic alternative to these mechanistic models in cases where cell-specific input parameters cannot be obtained, the models cannot be implemented, or for which their computational efficiency is paramount., (Creative Commons Attribution license.)

Published

2024

4. ATR inhibition radiosensitizes cells through augmented DNA damage and G2 cell cycle arrest abrogation.

Author

Bright SJ, Manandhar M, Flint DB, Kolachina R, Ben Kacem M, Martinus DK, Turner BX, Qureshi I, McFadden CH, Marinello PC, Shaitelman SF, and Sawakuchi GO

Subjects

Humans, Mice, Animals, Cell Line, Tumor, Pyrimidines pharmacology, Female, Xenograft Model Antitumor Assays, Tumor Microenvironment drug effects, Tumor Microenvironment radiation effects, Breast Neoplasms pathology, Breast Neoplasms radiotherapy, Breast Neoplasms drug therapy, Morpholines pharmacology, Sulfoxides pharmacology, Radiation Tolerance drug effects, Pyrazoles pharmacology, Indoles, Sulfonamides, Ataxia Telangiectasia Mutated Proteins antagonists & inhibitors, Ataxia Telangiectasia Mutated Proteins metabolism, DNA Damage drug effects, DNA Damage radiation effects, G2 Phase Cell Cycle Checkpoints drug effects, G2 Phase Cell Cycle Checkpoints radiation effects, Radiation-Sensitizing Agents pharmacology

Abstract

Ataxia telangiectasia and Rad3-related protein (ATR) is a key DNA damage response protein that facilitates DNA damage repair and regulates cell cycle progression. As such, ATR is an important component of the cellular response to radiation, particularly in cancer cells, which show altered DNA damage response and aberrant cell cycle checkpoints. Therefore, ATR's pharmacological inhibition could be an effective radiosensitization strategy to improve radiotherapy. We assessed the ability of an ATR inhibitor, AZD6738, to sensitize cancer cell lines of various histologic types to photon and proton radiotherapy. We found that radiosensitization took place through persistent DNA damage and abrogated G2 cell cycle arrest. We also found that AZD6738 increased the number of micronuclei after exposure to radiotherapy. We found that combining radiation with AZD6738 led to tumor growth delay and prolonged survival relative to radiation alone in a breast cancer model. Combining AZD6738 with photons or protons also led to increased macrophage infiltration at the tumor microenvironment. These results provide a rationale for further investigation of ATR inhibition in combination with radiotherapy and with other agents such as immune checkpoint blockade.

Published

2024

5. Targeted Inhibition of DNA-PKcs, ATM, ATR, PARP, and Rad51 Modulate Response to X Rays and Protons.

Author

Bright SJ, Flint DB, Martinus DKJ, Turner BX, Manandhar M, Ben Kacem M, McFadden CH, Yap TA, Shaitelman SF, and Sawakuchi GO

Subjects

Ataxia Telangiectasia Mutated Proteins metabolism, DNA, DNA Damage, DNA Repair, Humans, Poly(ADP-ribose) Polymerase Inhibitors pharmacology, Poly(ADP-ribose) Polymerase Inhibitors therapeutic use, Protons, Rad51 Recombinase metabolism, X-Rays, Neoplasms drug therapy, Radiation-Sensitizing Agents pharmacology

Abstract

Small molecule inhibitors are currently in preclinical and clinical development for the treatment of selected cancers, particularly those with existing genetic alterations in DNA repair and DNA damage response (DDR) pathways. Keen interest has also been expressed in combining such agents with other targeted antitumor strategies such as radiotherapy. Radiotherapy exerts its cytotoxic effects primarily through DNA damage-induced cell death; therefore, inhibiting DNA repair and the DDR should lead to additive and/or synergistic radiosensitizing effects. In this study we screened the response to X-ray or proton radiation in cell lines treated with DDR inhibitors (DDRis) targeting ATM, ATR, DNA-PKcs, Rad51, and PARP, with survival metrics established using clonogenic assays. We observed that DDRis generate significant radiosensitization in cancer and primary cells derived from normal tissue. Existing genetic defects in cancer cells appear to be an important consideration when determining the optimal inhibitor to use for synergistic combination with radiation. We also show that while greater radiosensitization can be achieved with protons (9.9 keV/µm) combined with DDRis, the relative biological effectiveness is unchanged or in some cases reduced. Our results indicate that while targeting the DDR can significantly radiosensitize cancer cells to such combinations, normal cells may also be equally or more severely affected, depending on the DDRi used. These data highlight the importance of identifying genetic defects as predictive biomarkers of response for combination treatment., (©2022 by Radiation Research Society. All rights of reproduction in any form reserved.)

Published

2022

6. An empirical model of proton RBE based on the linear correlation between x-ray and proton radiosensitivity.

Author

Flint DB, Ruff CE, Bright SJ, Yepes P, Wang Q, Manandhar M, Ben Kacem M, Turner BX, Martinus DKJ, Shaitelman SF, and Sawakuchi GO

Subjects

Bayes Theorem, Radiation Tolerance, Relative Biological Effectiveness, X-Rays, Proton Therapy methods, Protons

Abstract

Background: Proton relative biological effectiveness (RBE) is known to depend on physical factors of the proton beam, such as its linear energy transfer (LET), as well as on cell-line specific biological factors, such as their ability to repair DNA damage. However, in a clinical setting, proton RBE is still considered to have a fixed value of 1.1 despite the existence of several empirical models that can predict proton RBE based on how a cell's survival curve (linear-quadratic model [LQM]) parameters α and β vary with the LET of the proton beam. Part of the hesitation to incorporate variable RBE models in the clinic is due to the great noise in the biological datasets on which these models are trained, often making it unclear which model, if any, provides sufficiently accurate RBE predictions to warrant a departure from RBE = 1.1., Purpose: Here, we introduce a novel model of proton RBE based on how a cell's intrinsic radiosensitivity varies with LET, rather than its LQM parameters., Methods and Materials: We performed clonogenic cell survival assays for eight cell lines exposed to 6 MV x-rays and 1.2, 2.6, or 9.9 keV/µm protons, and combined our measurements with published survival data (n = 397 total cell line/LET combinations). We characterized how radiosensitivity metrics of the form D SF% , (the dose required to achieve survival fraction [SF], e.g., D 10% ) varied with proton LET, and calculated the Bayesian information criteria associated with different LET-dependent functions to determine which functions best described the underlying trends. This allowed us to construct a six-parameter model that predicts cells' proton survival curves based on the LET dependence of their radiosensitivity, rather than the LET dependence of the LQM parameters themselves. We compared the accuracy of our model to previously established empirical proton RBE models, and implemented our model within a clinical treatment plan evaluation workflow to demonstrate its feasibility in a clinical setting., Results: Our analyses of the trends in the data show that D SF% is linearly correlated between x-rays and protons, regardless of the choice of the survival level (e.g., D 10% , D 37% , or D 50% are similarly correlated), and that the slope and intercept of these correlations vary with proton LET. The model we constructed based on these trends predicts proton RBE within 15%-30% at the 68.3% confidence level and offers a more accurate general description of the experimental data than previously published empirical models. In the context of a clinical treatment plan, our model generally predicted higher RBE-weighted doses than the other empirical models, with RBE-weighted doses in the distal portion of the field being up to 50.7% higher than the planned RBE-weighted doses (RBE = 1.1) to the tumor., Conclusions: We established a new empirical proton RBE model that is more accurate than previous empirical models, and that predicts much higher RBE values in the distal edge of clinical proton beams., (© 2022 American Association of Physicists in Medicine.)

Published

2022

7. Effect of boron compounds on the biological effectiveness of proton therapy.

Author

Manandhar M, Bright SJ, Flint DB, Martinus DKJ, Kolachina RV, Ben Kacem M, Titt U, Martin TJ, Lee CL, Morrison K, Shaitelman SF, and Sawakuchi GO

Subjects

Boron Compounds pharmacology, Boron Compounds therapeutic use, Humans, Male, Phenylalanine pharmacology, Phenylalanine therapeutic use, Protons, Relative Biological Effectiveness, Boron Neutron Capture Therapy, Prostatic Neoplasms drug therapy, Prostatic Neoplasms radiotherapy, Proton Therapy

Abstract

Purpose: We assessed whether adding sodium borocaptate (BSH) or 4-borono-l-phenylalanine (BPA) to cells irradiated with proton beams influenced the biological effectiveness of those beams against prostate cancer cells to investigate if the alpha particles generated through proton-boron nuclear reactions would be sufficient to enhance the biological effectiveness of the proton beams., Methods: We measured clonogenic survival in DU145 cells treated with 80.4-ppm BSH or 86.9-ppm BPA, or their respective vehicles, after irradiation with 6-MV X-rays, 1.2-keV/μm (low linear energy transfer [LET]) protons, or 9.9-keV/μm (high-LET) protons. We also measured γH2AX and 53BP1 foci in treated cells at 1 and 24 h after irradiation with the same conditions., Results: We found that BSH radiosensitized DU145 cells across all radiation types. However, no difference was found in relative radiosensitization, characterized by the sensitization enhancement ratio or the relative biological effectiveness, for vehicle- versus BSH-treated cells. No differences were found in numbers of γH2AX or 53BP1 foci or γH2AX/53BP1 colocalized foci for vehicle- versus BSH-treated cells across radiation types. BPA did not radiosensitize DU145 cells nor induced any significant differences when comparing vehicle- versus BPA-treated cells for clonogenic cell survival or γH2AX and 53BP1 foci or γH2AX/53BP1 colocalized foci., Conclusions: Treatment with 11 B, at concentrations of 80.4 ppm from BSH or 86.9 ppm from BPA, had no effect on the biological effectiveness of proton beams in DU145 prostate cancer cells. Our results agree with published theoretical calculations indicating that the contribution of alpha particles from such reactions to the total absorbed dose and biological effectiveness is negligible. We also found that BSH radiosensitized DU145 cells to X-rays, low-LET protons, and high-LET protons but that the radiosensitization was not related to DNA damage., (© 2022 American Association of Physicists in Medicine.)

Published

2022

8. Cell lines of the same anatomic site and histologic type show large variability in intrinsic radiosensitivity and relative biological effectiveness to protons and carbon ions.

Author

Flint DB, Bright SJ, McFadden CH, Konishi T, Ohsawa D, Turner B, Lin SH, Grosshans DR, Chiu HS, Sumazin P, Shaitelman SF, and Sawakuchi GO

Subjects

Carbon, Cell Line, Cell Survival, Humans, Protons, Radiation Tolerance, Relative Biological Effectiveness, Carcinoma, Non-Small-Cell Lung, Lung Neoplasms

Abstract

Purpose: To show that intrinsic radiosensitivity varies greatly for protons and carbon (C) ions in addition to photons, and that DNA repair capacity remains important in governing this variability., Methods: We measured or obtained from the literature clonogenic survival data for a number of human cancer cell lines exposed to photons, protons (9.9 keV/μm), and C-ions (13.3-77.1 keV/μm). We characterized their intrinsic radiosensitivity by the dose for 10% or 50% survival (D 10% or D 50% ), and quantified the variability at each radiation quality by the coefficient of variation (COV) in D 10% and D 50% . We also treated cells with DNA repair inhibitors prior to irradiation to assess how DNA repair capacity affects their variability., Results: We found no statistically significant differences in the COVs of D 10% or D 50% between any of the radiation qualities investigated. The same was true regardless of whether the cells were treated with DNA repair inhibitors, or whether they were stratified into histologic subsets. Even within histologic subsets, we found remarkable differences in radiosensitivity for high LET C-ions that were often greater than the variations in RBE, with brain cancer cells varying in D 10% (D 50% ) up to 100% (131%) for 77.1 keV/μm C-ions, and non-small cell lung cancer and pancreatic cancer cell lines varying up to 55% (76%) and 51% (78%), respectively, for 60.5 keV/μm C-ions. The cell lines with modulated DNA repair capacity had greater variability in intrinsic radiosensitivity across all radiation qualities., Conclusions: Even for cell lines of the same histologic type, there are remarkable variations in intrinsic radiosensitivity, and these variations do not differ significantly between photon, proton or C-ion radiation. The importance of DNA repair capacity in governing the variability in intrinsic radiosensitivity is not significantly diminished for higher LET radiation., (© 2021 American Association of Physicists in Medicine.)

Published

2021

9. Isolation of time-dependent DNA damage induced by energetic carbon ions and their fragments using fluorescent nuclear track detectors.

Author

McFadden CH, Rahmanian S, Flint DB, Bright SJ, Yoon DS, O'Brien DJ, Asaithamby A, Abdollahi A, Greilich S, and Sawakuchi GO

Subjects

Cell Line, Tumor, Cell Survival, Humans, Molecular Imaging, Time Factors, Carbon, DNA Damage, Fluorescent Dyes metabolism, Linear Energy Transfer

Abstract

Purpose: High energetic carbon (C-) ion beams undergo nuclear interactions with tissue, producing secondary nuclear fragments. Thus, at depth, C-ion beams are composed of a mixture of different particles with different linear energy transfer (LET) values. We developed a technique to enable isolation of DNA damage response (DDR) in mixed radiation fields using beam line microscopy coupled with fluorescence nuclear track detectors (FNTDs)., Methods: We imaged live cells on a coverslip made of FNTDs right after C-ion, proton or photon irradiation using an in-house built confocal microscope placed in the beam path. We used the FNTD to link track traversals with DNA damage and separated DNA damage induced by primary particles from fragments., Results: We were able to spatially link physical parameters of radiation tracks to DDR in live cells to investigate spatiotemporal DDR in multi-ion radiation fields in real time, which was previously not possible. We demonstrated that the response of lesions produced by the high-LET primary particles associates most strongly with cell death in a multi-LET radiation field, and that this association is not seen when analyzing radiation induced foci in aggregate without primary/fragment classification., Conclusions: We report a new method that uses confocal microscopy in combination with FNTDs to provide submicrometer spatial-resolution measurements of radiation tracks in live cells. Our method facilitates expansion of the radiation-induced DDR research because it can be used in any particle beam line including particle therapy beam lines., Category: Biological Physics and Response Prediction., (© 2019 American Association of Physicists in Medicine.)

Published

2020

10. Nonhomologous End Joining Is More Important Than Proton Linear Energy Transfer in Dictating Cell Death.

Author

Bright SJ, Flint DB, Chakraborty S, McFadden CH, Yoon DS, Bronk L, Titt U, Mohan R, Grosshans DR, Sumazin P, Shaitelman SF, Asaithamby A, and Sawakuchi GO

Subjects

Calcium-Binding Proteins genetics, Cell Line, Tumor, Cell Survival genetics, Cell Survival radiation effects, DNA Breaks, Double-Stranded, Gene Silencing, Histones analysis, Humans, Mutation, Rad51 Recombinase genetics, Radiation Tolerance genetics, Radiation Tolerance radiation effects, Time Factors, Cell Death genetics, DNA End-Joining Repair physiology, Genes, BRCA1, Homologous Recombination physiology, Linear Energy Transfer, Photons, Protons

Abstract

Purpose: This study seeks to identify biological factors that may yield a therapeutic advantage of proton therapy versus photon therapy. Specifically, we address the role of nonhomologous end-joining (NHEJ) and homologous recombination (HR) in the survival of cells in response to clinical photon and proton beams., Methods and Materials: We irradiated HT1080, M059K (DNA-PKcs +/+ ), and HCC1937 human cancer cell lines and their isogenic counterparts HT1080-shDNA-PKcs, HT1080-shRAD51 IND , M059J (DNA-PKcs -/- ), and HCC1937-BRCA1 (BRCA1 complemented) to assess cell clonogenic survival and γ-H2AX radiation-induced foci. Cells were irradiated with either clinically relevant photons or 1 of 3 proton linear energy transfer (LET) values., Results: Our results indicate that NHEJ deficiency is more important in dictating cell survival than proton LET. Cells with disrupted HR through BRCA1 mutation showed increased radiosensitivity only for high-LET protons whereas RAD51 depletion showed increased radiosensitivity for both photons and protons. DNA double strand breaks, assessed by γ-H2AX radiation-induced foci, showed greater numbers after 24 hours in cells exposed to higher LET protons. We also observed that NHEJ-deficient cells were unable to repair the vast majority of double strand breaks after 24 hours., Conclusions: BRCA1 mutation significantly sensitizes cells to protons, but not photons. Loss of NHEJ renders cells hypersensitive to radiation, whereas the relative importance of HR increases with LET across several cell lines. This may be attributable to the more clustered damage induced by higher LET protons, which are harder to repair through NHEJ. This highlights the importance of tumor biology in dictating treatment modality and suggests BRCA1 as a potential biomarker for proton therapy response. Our data also support the use of pharmacologic inhibitors of DNA repair to enhance the sensitivity to different radiation types, although this raises issues for normal tissue toxicity., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

11. Time-Lapse Monitoring of DNA Damage Colocalized With Particle Tracks in Single Living Cells.

Author

McFadden CH, Hallacy TM, Flint DB, Granville DA, Asaithamby A, Sahoo N, Akselrod MS, and Sawakuchi GO

Subjects

Cell Line, Tumor, Cell Tracking methods, DNA, Neoplasm ultrastructure, Humans, Linear Energy Transfer physiology, Linear Energy Transfer radiation effects, Microscopy, Fluorescence methods, Neoplasms, Experimental genetics, Proton Therapy methods, Protons, DNA Damage physiology, DNA, Neoplasm radiation effects, Linear Energy Transfer genetics, Microscopy, Confocal methods, Neoplasms, Experimental radiotherapy, Time-Lapse Imaging methods

Abstract

Purpose: Understanding the DNA damage and repair induced by hadron therapy (HT) beams is crucial for developing novel strategies to maximize the use of HT beams to treat cancer patients. However, spatiotemporal studies of DNA damage and repair for beam energies relevant to HT have been challenging. We report a technique that enables spatiotemporal measurement of radiation-induced damage in live cells and colocalization of this damage with charged particle tracks over a broad range of clinically relevant beam energies. The technique uses novel fluorescence nuclear track detectors with fluorescence confocal laser scanning microscopy in the beam line to visualize particle track traversals within the subcellular compartments of live cells within seconds after injury., Methods and Materials: We designed and built a portable fluorescence confocal laser scanning microscope for use in the beam path, coated fluorescence nuclear track detectors with fluorescent-tagged live cells (HT1080 expressing enhanced green fluorescent protein tagged to XRCC1, a single-strand break repair protein), placed the entire assembly into a proton therapy beam line, and irradiated the cells with a fluence of ∼1 × 10(6) protons/cm(2)., Results: We successfully obtained confocal images of proton tracks and foci of DNA single-strand breaks immediately after irradiation., Conclusions: This technique represents an innovative method for analyzing biological responses in any HT beam line at energies and dose rates relevant to therapy. It allows precise determination of the number of tracks traversing a subcellular compartment and monitoring the cellular damage therein, and has the potential to measure the linear energy transfer of each track from therapeutic beams., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016