Exposure to Carbon Ions Triggers Proinflammatory Signals and Changes in Homeostasis and Epidermal Tissue Organization to a Similar Extent as Photons

Simoniello, Palma; Wiedemann, Julia; Zink, Joana; Thoennes, Eva; Stange, Maike; Layer, Paul G.; Kovács, Maximilian; Durante, Marco; Fournier, Claudia

doi:10.3389/fonc.2015.00294

Cited by 16 publications

(13 citation statements)

References 62 publications

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“…Besides standard 2-dimensional mono-cultures, more physiological normal tissue equivalents for, e.g ., skin have been developed and used to study irradiation effects [1] , [46] , [55] . These models contain generally more than one cell type in its organotypic differentiation state and allow for monitoring the cellular behavior over several days.…”

Section: Biological Considerations On Relevance and Assessment Of A Vmentioning

confidence: 99%

Relative biological effectiveness in proton beam therapy – Current knowledge and future challenges

Lühr

Neubeck

Krause

et al. 2018

Clinical and Translational Radiation Oncology

112

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Section: Biological Considerations On Relevance and Assessment Of A Vmentioning

confidence: 99%

Relative biological effectiveness in proton beam therapy – Current knowledge and future challenges

Lühr

Neubeck

Krause

et al. 2018

Clinical and Translational Radiation Oncology

112

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“…Immunohistochemical stainings were performed as described in 19 . Primary antibodies used are anti-Troponin T cardiac isoform (Thermo Scientific); anti-CD45, α-SMA, anti-Cytokeratin 10 and anti-Ki 67 (all from Abcam).…”

Section: Methodsmentioning

confidence: 99%

Biological Cardiac Tissue Effects of High-Energy Heavy Ions – Investigation for Myocardial Ablation

Rapp

Simoniello

Wiedemann

et al. 2019

Sci Rep

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Noninvasive X-ray stereotactic treatment is considered a promising alternative to catheter ablation in patients affected by severe heart arrhythmia. High-energy heavy ions can deliver high radiation doses in small targets with reduced damage to the normal tissue compared to conventional X-rays. For this reason, charged particle therapy, widely used in oncology, can be a powerful tool for radiosurgery in cardiac diseases. We have recently performed a feasibility study in a swine model using high doses of high-energy C-ions to target specific cardiac structures. Interruption of cardiac conduction was observed in some animals. Here we report the biological effects measured in the pig heart tissue of the same animals six months after the treatment. Immunohistological analysis of the target tissue showed (1.) long-lasting vascular damage, i.e. persistent hemorrhage, loss of microvessels, and occurrence of siderophages, (2.) fibrosis and (3.) loss of polarity of targeted cardiomyocytes and wavy fibers with vacuolization. We conclude that the observed physiological changes in heart function are produced by radiation-induced fibrosis and cardiomyocyte functional inactivation. No effects were observed in the normal tissue traversed by the particle beam, suggesting that charged particles have the potential to produce ablation of specific heart targets with minimal side effects.

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“…The use of Dragon's blood, which presents antioxidant and anti-inflammatory properties, did not allow to reduce TNF-α, IFN-γ and IL-6 levels in carbon-irradiated rat brain as it was the case for γ-rays [91]. A recent report on carbon-irradiated normal human skin models showed similar inflammatory processes than after the same dose of X-rays [103].…”

Section: Inflammation and Late Toxicitymentioning

confidence: 97%

Oxidative Stress in Hadrontherapy

Laurent¹

2018

Novel Prospects in Oxidative and Nitrosative Stress

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Conventional radiotherapy has shown its efficiency since decades with large progresses during the 1990s. However, for 15-20% of treated patients, there is no prognosis improvement either due to tumor radiation resistance and/or to side effects on normal tissues representing the limiting dose given during a radiotherapy protocol. A new modality of radiation therapy has emerged representing a technological breakthrough: hadrontherapy. This regroups mainly proton and carbon ion therapy. Dose deposit is in favor of hadrons compared to photons as it occurs at a precise depth in human body sparing upstream and downstream normal tissues. Mechanisms of action of photons and hadrons are different. When photons mainly act by water radiolysis-producing e − aq , H • , • OH, H 2 O 2 , O 2 •− …, carbon ions and protons mainly act by direct effects, i.e. by direct transfer of ion energy to biological macromolecules. Moreover, efficiency of carbon ions is considered threefold higher (1.1 for protons) than X-rays in killing tumor cells, whereas it is considered lower for normal cells. These findings suggest strong advantages of hadrontherapy compared to conventional radiotherapy. However, some recent studies tend to show a stronger increase in oxidative stress in normal cells after protons or carbon ions than X-rays.

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Exposure to Carbon Ions Triggers Proinflammatory Signals and Changes in Homeostasis and Epidermal Tissue Organization to a Similar Extent as Photons

Cited by 16 publications

References 62 publications

Relative biological effectiveness in proton beam therapy – Current knowledge and future challenges

Relative biological effectiveness in proton beam therapy – Current knowledge and future challenges

Biological Cardiac Tissue Effects of High-Energy Heavy Ions – Investigation for Myocardial Ablation

Oxidative Stress in Hadrontherapy

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