Your search keyword '"Walsh DWM"' showing total 13 results

1. The biomedical sensor Cell-Fit-HD4D, reveals individual tumor cell fate in response to microscopic ion deposition

Author

Niklas, M, primary, Schlegel, J, additional, Liew, H, additional, Walsh, DWM, additional, Zimmermann, F, additional, Dzyubachyk, O, additional, Holland-Letz, T, additional, Rahmanian, S, additional, Greilich, S, additional, Runz, A, additional, Debus, J, additional, and Abdollahi, A, additional

Published

2020

2. Biosensor for deconvolution of individual cell fate in response to ion beam irradiation.

Author

Niklas M, Schlegel J, Liew H, Zimmermann F, Rein K, Walsh DWM, Dzyubachyk O, Holland-Letz T, Rahmanian S, Greilich S, Runz A, Jäkel O, Debus J, and Abdollahi A

Subjects

Radiometry methods, Heavy Ion Radiotherapy methods, Biosensing Techniques

Abstract

Clonogenic survival assay constitutes the gold standard method for quantifying radiobiological effects. However, it neglects cellular radiation response variability and heterogeneous energy deposition by ion beams on the microscopic scale. We introduce "Cell-Fit-HD 4D " a biosensor that enables a deconvolution of individual cell fate in response to the microscopic energy deposition as visualized by optical microscopy. Cell-Fit-HD 4D enables single-cell dosimetry in clinically relevant complex radiation fields by correlating microscopic beam parameters with biological endpoints. Decrypting the ion beam's energy deposition and molecular effects at the single-cell level has the potential to improve our understanding of radiobiological dose concepts as well as radiobiological study approaches in general., Competing Interests: The authors declare no competing interests., (© 2022 The Authors.)

Published

2022

3. FLASH Dose Rate Helium Ion Beams: First In Vitro Investigations.

Author

Tessonnier T, Mein S, Walsh DWM, Schuhmacher N, Liew H, Cee R, Galonska M, Scheloske S, Schömers C, Weber U, Brons S, Debus J, Haberer T, Abdollahi A, Mairani A, and Dokic I

Subjects

Cell Line, Tumor, Cell Survival, Humans, Ions, Oxygen, Helium, Linear Energy Transfer

Abstract

Purpose: To establish and investigate the effects of dose, linear energy transfer (LET), and O 2 concentration on biologic response to ultrahigh dose rate (uHDR; FLASH) helium ion beams compared with standard dose rate (SDR) irradiation., Methods and Materials: Beam delivery settings for raster-scanned helium ions at both uHDR and SDR were tuned to achieve >100 Gy/s and ∼0.1 Gy/s, respectively. For both SDR and uHDR, plan optimization and calibration for 10 × 10-mm 2 fields were performed to assess in vitro response at an LET range of 4.5 to 16 keV/µm. Clonogenic survival assay was conducted at doses ranging from 2 to 12 Gy in 2 human lung epithelial cell lines (A549 and H1437). Radiation-induced nuclear γH2AX foci (RIF) were assessed in both epithelial cell lines and primary human pulmonary fibroblasts., Results: Average dose rates achieved were 185 Gy/s and 0.12 Gy/s for uHDR and SDR, respectively. No differences in cellular response to SDR versus uHDR were observed for all tested doses at 21% O 2 , and at 2 and 4 Gy at 1% O 2 . In contrast, at 1% O 2 and a dose threshold of ≳8 Gy cell survival was higher and correlated with reduced nuclear γH2AX RIF signal, indicating FLASH sparing effect in the investigated cell lines irradiated with uHDR compared with SDR., Conclusions: The first uHDR delivery of raster-scanned particle beams was achieved using helium ions, reaching FLASH-level dose-rates of >100 Gy/s. Baseline oxygen levels and delivered dose (≳8 Gy) play a pivotal role, irrespective of the studied cell lines, for observation of a sparing effect for helium ions., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

4. Author Correction: DNA damage interactions on both nanometer and micrometer scale determine overall cellular damage.

Author

Friedrich T, Ilicic K, Greubel C, Girst S, Reindl J, Sammer M, Schwarz B, Siebenwirth C, Walsh DWM, Schmid TE, Scholz M, and Dollinger G

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

5. Carbon ion dosimetry on a fluorescent nuclear track detector using widefield microscopy.

Author

Walsh DWM, Liew H, Schlegel J, Mairani A, Abdollahi A, and Niklas M

Subjects

Linear Energy Transfer, Carbon, Microscopy, Fluorescence, Radiometry methods

Abstract

Fluorescent nuclear track detectors (FNTDs) are solid-state dosimeters used in a wide range of dosimetric and biomedical applications in research worldwide. FNTDs are a core but currently underutilized dosimetry tool in the field of radiation biology which are inherently capable of visualizing the tracks of ions used in hadron therapy. The ions that traverse the FNTD deposit their energy according to their linear energy transfer and transform colour centres to form trackspots around their trajectory. These trackspots have fluorescent properties which can be visualized by fluorescence microscopy enabling a well-defined dosimetric readout with a spatial component indicating the trajectory of individual ions. The current method used to analyse the FNTDs is laser scanning confocal microscopy (LSM). LSM enables a precise localization of track spots in x, y and z however due to the scanning of the laser spot across the sample, requires a long time for large samples. This body of work conclusively shows for the first time that the readout of the trackspots present after 0.5 Gy carbon ion irradiation in the FNTD can be captured with a widefield microscope (WF). The WF readout of the FNTD is a factor ∼10 faster, for an area 2.97 times the size making the method nearly a factor 19 faster in track acquisition than LSM. The dramatic decrease in image acquisition time in WF presents an alternative to LSM in FNTD workflows which are limited by time, such as biomedical sensors which combine FNTDs with live cell imaging.

Published

2020

6. Proton pencil minibeam irradiation of an in-vivo mouse ear model spares healthy tissue dependent on beam size.

Author

Sammer M, Zahnbrecher E, Dobiasch S, Girst S, Greubel C, Ilicic K, Reindl J, Schwarz B, Siebenwirth C, Walsh DWM, Combs SE, Dollinger G, and Schmid TE

Subjects

Animals, Cell Survival radiation effects, Clone Cells, Dose-Response Relationship, Radiation, Keratinocytes radiation effects, Mice, Inbred BALB C, Skin radiation effects, Ear radiation effects, Organ Sparing Treatments, Protons

Abstract

Proton radiotherapy using minibeams of sub-millimeter dimensions reduces side effects in comparison to conventional proton therapy due to spatial fractionation. Since the proton minibeams widen with depth, the homogeneous irradiation of a tumor can be ensured by adjusting the beam distances to tumor size and depth to maintain tumor control as in conventional proton therapy. The inherent advantages of protons in comparison to photons like a limited range that prevents a dosage of distal tissues are maintained by proton minibeams and can even be exploited for interlacing from different beam directions. A first animal study was conducted to systematically investigate and quantify the tissue-sparing effects of proton pencil minibeams as a function of beam size and dose distributions, using beam widths between σ = 95, 199, 306, 411, 561 and 883 μm (standard deviation) at a defined center-to-center beam distance (ctc) of 1.8 mm. The average dose of 60 Gy was distributed in 4x4 minibeams using 20 MeV protons (LET ~ 2.7 keV/μm). The induced radiation toxicities were measured by visible skin reactions and ear swelling for 90 days after irradiation. The largest applied beam size to ctc ratio (σ/ctc = 0.49) is similar to a homogeneous irradiation and leads to a significant 3-fold ear thickness increase compared to the control group. Erythema and desquamation was also increased significantly 3-4 weeks after irradiation. With decreasing beam sizes and thus decreasing σ/ctc, the maximum skin reactions are strongly reduced until no ear swelling or other visible skin reactions should occur for σ/ctc < 0.032 (extrapolated from data). These results demonstrate that proton pencil minibeam radiotherapy has better tissue-sparing for smaller σ/ctc, corresponding to larger peak-to-valley dose ratios PVDR, with the best effect for σ/ctc < 0.032. However, even quite large σ/ctc (e.g. σ/ctc = 0.23 or 0.31, i.e. PVDR = 10 or 2.7) show less acute side effects than a homogeneous dose distribution. This suggests that proton minibeam therapy spares healthy tissue not only in the skin but even for dose distributions appearing in deeper layers close to the tumor enhancing its benefits for clinical proton therapy., Competing Interests: The authors have declared that no competing interests exist.

Published

2019

7. Local inhibition of rRNA transcription without nucleolar segregation after targeted ion irradiation of the nucleolus.

Author

Siebenwirth C, Greubel C, Drexler GA, Reindl J, Walsh DWM, Schwarz B, Sammer M, Baur I, Pospiech H, Schmid TE, Dollinger G, and Friedl AA

Subjects

Cell Line, Tumor, DNA Breaks, Double-Stranded, DNA, Ribosomal genetics, Humans, Nucleolus Organizer Region genetics, Nucleolus Organizer Region metabolism, Poly (ADP-Ribose) Polymerase-1 genetics, Transcription, Genetic genetics, Cell Nucleolus metabolism, Pol1 Transcription Initiation Complex Proteins genetics, RNA, Ribosomal genetics

Abstract

Nucleoli have attracted interest for their role as cellular stress sensors and as potential targets for cancer treatment. The effect of DNA double-strand breaks (DSBs) in nucleoli on rRNA transcription and nucleolar organisation appears to depend on the agent used to introduce DSBs, DSB frequency and the presence (or not) of DSBs outside the nucleoli. To address the controversy, we targeted nucleoli with carbon ions at the ion microbeam SNAKE. Localized ion irradiation with 1-100 carbon ions per point (about 0.3-30 Gy per nucleus) did not lead to overall reduced ribonucleotide incorporation in the targeted nucleolus or other nucleoli of the same cell. However, both 5-ethynyluridine incorporation and Parp1 protein levels were locally decreased at the damaged nucleolar chromatin regions marked by γH2AX, suggesting localized inhibition of rRNA transcription. This locally restricted transcriptional inhibition was not accompanied by nucleolar segregation, a structural reorganisation observed after inhibition of rRNA transcription by treatment with actinomycin D or UV irradiation. The presented data indicate that even multiple complex DSBs do not lead to a pan-nucleolar response if they affect only a subnucleolar region., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2019. Published by The Company of Biologists Ltd.)

Published

2019

8. Beam size limit for pencil minibeam radiotherapy determined from side effects in an in-vivo mouse ear model.

Author

Sammer M, Teiluf K, Girst S, Greubel C, Reindl J, Ilicic K, Walsh DWM, Aichler M, Walch A, Combs SE, Wilkens JJ, Dollinger G, and Schmid TE

Subjects

Animals, Ear physiology, Erythema etiology, Female, Mice, Mice, Inbred BALB C, Models, Animal, Radiation Dosimeters, Skin metabolism, Skin radiation effects, Ear radiation effects, Gamma Rays adverse effects, Skin pathology

Abstract

Side effects caused by radiation are a limiting factor to the amount of dose that can be applied to a tumor volume. A novel method to reduce side effects in radiotherapy is the use of spatial fractionation, in which a pattern of sub-millimeter beams (minibeams) is applied to spare healthy tissue. In order to determine the skin reactions in dependence of single beam sizes, which are relevant for spatially fractionated radiotherapy approaches, single pencil beams of submillimeter to 6 millimeter size were applied in BALB/c mice ears at a Small Animal Radiation Research Platform (SARRP) with a plateau dose of 60 Gy. Radiation toxicities in the ears were observed for 25 days after irradiation. Severe radiation responses were found for beams ≥ 3 mm diameter. The larger the beam diameter the stronger the observed reactions. No ear swelling and barely reddening or desquamation were found for the smallest beam sizes (0.5 and 1 mm). The findings were confirmed by histological sections. Submillimeter beams are preferred in minibeam therapy to obtain optimized tissue sparing. The gradual increase of radiation toxicity with beam size shows that also larger beams are capable of healthy tissue sparing in spatial fractionation., Competing Interests: The authors have declared that no competing interests exist.

Published

2019

9. Acute Skin Damage and Late Radiation-Induced Fibrosis and Inflammation in Murine Ears after High-Dose Irradiation.

Author

Dombrowsky AC, Schauer J, Sammer M, Blutke A, Walsh DWM, Schwarz B, Bartzsch S, Feuchtinger A, Reindl J, Combs SE, Dollinger G, and Schmid TE

Abstract

The use of different scoring systems for radiation-induced toxicity limits comparability between studies. We examined dose-dependent tissue alterations following hypofractionated X-ray irradiation and evaluated their use as scoring criteria. Four dose fractions (0, 5, 10, 20, 30 Gy/fraction) were applied daily to ear pinnae. Acute effects (ear thickness, erythema, desquamation) were monitored for 92 days after fraction 1. Late effects (chronic inflammation, fibrosis) and the presence of transforming growth factor beta 1 (TGFβ1)-expressing cells were quantified on day 92. The maximum ear thickness displayed a significant positive correlation with fractional dose. Increased ear thickness and erythema occurred simultaneously, followed by desquamation from day 10 onwards. A significant dose-dependency was observed for the severity of erythema, but not for desquamation. After 4 × 20 and 4 × 30 Gy, inflammation was significantly increased on day 92, whereas fibrosis and the abundance of TGFβ1-expressing cells were only marginally increased after 4 × 30 Gy. Ear thickness significantly correlated with the severity of inflammation and fibrosis on day 92, but not with the number of TGFβ1-expressing cells. Fibrosis correlated significantly with inflammation and fractional dose. In conclusion, the parameter of ear thickness can be used as an objective, numerical and dose-dependent quantification criterion to characterize the severity of acute toxicity and allow for the prediction of late effects.

Published

2019

10. DNA damage interactions on both nanometer and micrometer scale determine overall cellular damage.

Author

Friedrich T, Ilicic K, Greubel C, Girst S, Reindl J, Sammer M, Schwarz B, Siebenwirth C, Walsh DWM, Schmid TE, Scholz M, and Dollinger G

Subjects

DNA Repair radiation effects, Humans, Linear Energy Transfer, Radiation, Ionizing, Biophysical Phenomena, DNA Breaks, Double-Stranded radiation effects, DNA Damage radiation effects

Abstract

DNA double strand breaks (DSB) play a pivotal role for cellular damage, which is a hazard encountered in toxicology and radiation protection, but also exploited e.g. in eradicating tumors in radiation therapy. It is still debated whether and in how far clustering of such DNA lesions leads to an enhanced severity of induced damage. Here we investigate - using focused spots of ionizing radiation as damaging agent - the spatial extension of DNA lesion patterns causing cell inactivation. We find that clustering of DNA damage on both the nm and µm scale leads to enhanced inactivation compared to more homogeneous lesion distributions. A biophysical model interprets these observations in terms of enhanced DSB production and DSB interaction, respectively. We decompose the overall effects quantitatively into contributions from these lesion formation processes, concluding that both processes coexist and need to be considered for determining the resulting damage on the cellular level.

Published

2018

11. Increased cell survival and cytogenetic integrity by spatial dose redistribution at a compact synchrotron X-ray source.

Author

Burger K, Ilicic K, Dierolf M, Günther B, Walsh DWM, Schmid E, Eggl E, Achterhold K, Gleich B, Combs SE, Molls M, Schmid TE, Pfeiffer F, and Wilkens JJ

Subjects

Animals, CHO Cells, Cricetulus, HeLa Cells, Humans, X-Rays, Cell Survival, Chromosome Aberrations radiation effects, Synchrotrons

Abstract

X-ray microbeam radiotherapy can potentially widen the therapeutic window due to a geometrical redistribution of the dose. However, high requirements on photon flux, beam collimation, and system stability restrict its application mainly to large-scale, cost-intensive synchrotron facilities. With a unique laser-based Compact Light Source using inverse Compton scattering, we investigated the translation of this promising radiotherapy technique to a machine of future clinical relevance. We performed in vitro colony-forming assays and chromosome aberration tests in normal tissue cells after microbeam irradiation compared to homogeneous irradiation at the same mean dose using 25 keV X-rays. The microplanar pattern was achieved with a tungsten slit array of 50 μm slit size and a spacing of 350 μm. Applying microbeams significantly increased cell survival for a mean dose above 2 Gy, which indicates fewer normal tissue complications. The observation of significantly less chromosome aberrations suggests a lower risk of second cancer development. Our findings provide valuable insight into the mechanisms of microbeam radiotherapy and prove its applicability at a compact synchrotron, which contributes to its future clinical translation.

Published

2017

12. Live cell imaging of mitochondria following targeted irradiation in situ reveals rapid and highly localized loss of membrane potential.

Author

Walsh DWM, Siebenwirth C, Greubel C, Ilicic K, Reindl J, Girst S, Muggiolu G, Simon M, Barberet P, Seznec H, Zischka H, Multhoff G, Schmid TE, and Dollinger G

Subjects

A549 Cells, Fluorescent Dyes metabolism, Humans, MCF-7 Cells, Mitochondria metabolism, Mitochondria radiation effects, Organometallic Compounds metabolism, Staining and Labeling methods, Image Processing, Computer-Assisted methods, Membrane Potential, Mitochondrial, Microscopy, Fluorescence methods, Mitochondria pathology, Protons

Abstract

The reliance of all cell types on the mitochondrial function for survival makes mitochondria an interesting target when trying to understand their role in the cellular response to ionizing radiation. By harnessing highly focused carbon ions and protons using microbeams, we have performed in situ live cell imaging of the targeted irradiation of individual mitochondria stained with Tetramethyl rhodamine ethyl ester (TMRE), a cationic fluorophore which accumulates electrophoretically in polarized mitochondria. Targeted irradiation with both carbon ions and protons down to beam spots of <1 μm induced a near instant loss of mitochondrial TMRE fluorescence signal in the targeted area. The loss of TMRE after targeted irradiation represents a radiation induced change in mitochondrial membrane potential. This is the first time such mitochondrial responses have been documented in situ after targeted microbeam irradiation. The methods developed and the results obtained have the ability to shed new light on not just mitochondria's response to radiation but to further elucidate a putative mechanism of radiation induced depolarization and mitochondrial response.

Published

2017

13. Proton Minibeam Radiation Therapy Reduces Side Effects in an In Vivo Mouse Ear Model.

Author

Girst S, Greubel C, Reindl J, Siebenwirth C, Zlobinskaya O, Walsh DWM, Ilicic K, Aichler M, Walch A, Wilkens JJ, Multhoff G, Dollinger G, and Schmid TE

Subjects

Animals, Ear Diseases etiology, Ear Diseases pathology, Erythema etiology, Erythema pathology, Female, Mice, Mice, Inbred BALB C, Models, Animal, Otitis Externa etiology, Otitis Externa pathology, Radiation Dosage, Radiation Injuries, Experimental pathology, Ear Auricle radiation effects, Proton Therapy adverse effects, Proton Therapy methods, Radiation Injuries, Experimental prevention & control

Abstract

Purpose: Proton minibeam radiation therapy is a novel approach to minimize normal tissue damage in the entrance channel by spatial fractionation while keeping tumor control through a homogeneous tumor dose using beam widening with an increasing track length. In the present study, the dose distributions for homogeneous broad beam and minibeam irradiation sessions were simulated. Also, in an animal study, acute normal tissue side effects of proton minibeam irradiation were compared with homogeneous irradiation in a tumor-free mouse ear model to account for the complex effects on the immune system and vasculature in an in vivo normal tissue model., Methods and Materials: At the ion microprobe SNAKE, 20-MeV protons were administered to the central part (7.2 × 7.2 mm(2)) of the ear of BALB/c mice, using either a homogeneous field with a dose of 60 Gy or 16 minibeams with a nominal 6000 Gy (4 × 4 minibeams, size 0.18 × 0.18 mm(2), with a distance of 1.8 mm). The same average dose was used over the irradiated area., Results: No ear swelling or other skin reactions were observed at any point after minibeam irradiation. In contrast, significant ear swelling (up to fourfold), erythema, and desquamation developed in homogeneously irradiated ears 3 to 4 weeks after irradiation. Hair loss and the disappearance of sebaceous glands were only detected in the homogeneously irradiated fields., Conclusions: These results show that proton minibeam radiation therapy results in reduced adverse effects compared with conventional homogeneous broad-beam irradiation and, therefore, might have the potential to decrease the incidence of side effects resulting from clinical proton and/or heavy ion therapy., (Copyright © 2016 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2016