Your search keyword '"MANTI, LORENZO"' showing total 14 results

1. Raman spectroscopy monitoring of MCF10A cells irradiated by protons at clinical doses.

Author

Lasalvia M, Perna G, Manti L, Rasero J, Stramaglia S, and Capozzi V

Subjects

Cells, Cultured, DNA Damage, Female, Humans, Breast radiation effects, Proton Therapy, Spectrum Analysis, Raman methods

Abstract

Purpose: Proton therapy has been recently proposed as a radiotherapy form for breast cancer treatment in view of its potentially decreased normal-tissue toxicity compared with conventional photon-based radiotherapy. However, the risks for the healthy tissue cannot be completely eliminated. In the present study, the suitability of Raman spectroscopy to monitor the radiosensitivity of normal cells exposed to clinical proton beam was investigated., Materials and Methods: MCF10A normal human breast cells were irradiated at two different proton doses: 0.5 Gy and 4 Gy. They were fixed immediately after irradiation and measured by means of Raman spectroscopy technique. The obtained data were analyzed both by evaluating the intensity ratio of specific Raman spectral peaks and through Multivariate Distance Matrix Regression technique., Results: Certain Raman peaks associated with DNA showed a systematic suppression at both dose levels. In particular, the intensity of a Raman peak at 784 cm -1 , related to a stretching mode inside the phosphate group of DNA, is very sensitive to the proton beam exposure, even at the lowest investigated dose. Therefore, it could be considered as a spectral marker of cytogenetic damage., Conclusions: The obtained results are encouraging for the future of Raman spectroscopy in radiobiology research, particularly for improving risk assessment in the field of proton radiotherapy. Specifically, these findings validate Raman spectroscopy to measure biological response in human breast cells exposed to standard proton therapy doses used in clinical setting.

Published

2019

2. Gene expression profiling of breast cancer cell lines treated with proton and electron radiations.

Author

Bravatà V, Minafra L, Cammarata FP, Pisciotta P, Lamia D, Marchese V, Petringa G, Manti L, Cirrone GA, Gilardi MC, Cuttone G, Forte GI, and Russo G

Subjects

Adenocarcinoma genetics, Adenocarcinoma radiotherapy, Breast Neoplasms metabolism, Breast Neoplasms radiotherapy, Carcinoma, Ductal, Breast genetics, Carcinoma, Ductal, Breast radiotherapy, Cell Line, Cell Line, Tumor radiation effects, Gene Expression, Humans, Linear Energy Transfer, Oligonucleotide Array Sequence Analysis, Precision Medicine, Radiation Tolerance, Breast Neoplasms genetics, Electrons therapeutic use, Gene Expression Profiling, Proton Therapy

Abstract

Objective: Technological advances in radiation therapy are evolving with the use of hadrons, such as protons, indicated for tumors where conventional radiotherapy does not give significant advantages or for tumors located in sensitive regions, which need the maximum of dose-saving of the surrounding healthy tissues. The genomic response to conventional and non-conventional linear energy transfer exposure is a poor investigated topic and became an issue of radiobiological interest. The aim of this work was to analyze and compare molecular responses in term of gene expression profiles, induced by electron and proton irradiation in breast cancer cell lines., Methods: We studied the gene expression profiling differences by cDNA microarray activated in response to electron and proton irradiation with different linear energy transfer values, among three breast cell lines (the tumorigenic MCF7 and MDA-MB-231 and the non-tumorigenic MCF10A), exposed to the same sublethal dose of 9 Gy., Results: Gene expression profiling pathway analyses showed the activation of different signaling and molecular networks in a cell line and radiation type-dependent manner. MCF10A and MDA-MB-231 cell lines were found to induce factors and pathways involved in the immunological process control., Conclusion: Here, we describe in a detailed way the gene expression profiling and pathways activated after electron and proton irradiation in breast cancer cells. Summarizing, although specific pathways are activated in a radiation type-dependent manner, each cell line activates overall similar molecular networks in response to both these two types of ionizing radiation. Advances in knowledge: In the era of personalized medicine and breast cancer target-directed intervention, we trust that this study could drive radiation therapy towards personalized treatments, evaluating possible combined treatments, based on the molecular characterization.

Published

2018

3. Relative biological effectiveness variation along monoenergetic and modulated Bragg peaks of a 62-MeV therapeutic proton beam: a preclinical assessment.

Author

Chaudhary P, Marshall TI, Perozziello FM, Manti L, Currell FJ, Hanton F, McMahon SJ, Kavanagh JN, Cirrone GA, Romano F, Prise KM, and Schettino G

Subjects

Cell Line, Tumor, Cell Survival, Cyclotrons, Fibroblasts physiology, Fibroblasts radiation effects, Glioma radiotherapy, Humans, Linear Energy Transfer, Proton Therapy, Protons, Radiation Tolerance, Relative Biological Effectiveness

Abstract

Purpose: The biological optimization of proton therapy can be achieved only through a detailed evaluation of relative biological effectiveness (RBE) variations along the full range of the Bragg curve. The clinically used RBE value of 1.1 represents a broad average, which disregards the steep rise of linear energy transfer (LET) at the distal end of the spread-out Bragg peak (SOBP). With particular attention to the key endpoint of cell survival, our work presents a comparative investigation of cell killing RBE variations along monoenergetic (pristine) and modulated (SOBP) beams using human normal and radioresistant cells with the aim to investigate the RBE dependence on LET and intrinsic radiosensitvity., Methods and Materials: Human fibroblasts (AG01522) and glioma (U87) cells were irradiated at 6 depth positions along pristine and modulated 62-MeV proton beams at the INFN-LNS (Catania, Italy). Cell killing RBE variations were measured using standard clonogenic assays and were further validated using Monte Carlo simulations and the local effect model (LEM)., Results: We observed significant cell killing RBE variations along the proton beam path, particularly in the distal region showing strong dose dependence. Experimental RBE values were in excellent agreement with the LEM predicted values, indicating dose-averaged LET as a suitable predictor of proton biological effectiveness. Data were also used to validate a parameterized RBE model., Conclusions: The predicted biological dose delivered to a tumor region, based on the variable RBE inferred from the data, varies significantly with respect to the clinically used constant RBE of 1.1. The significant RBE increase at the distal end suggests also a potential to enhance optimization of treatment modalities such as LET painting of hypoxic tumors. The study highlights the limitation of adoption of a constant RBE for proton therapy and suggests approaches for fast implementation of RBE models in treatment planning., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

4. Impact on the Transcriptome of Proton Beam Irradiation Targeted at Healthy Cardiac Tissue of Mice.

Author

Sala, Claudia, Tarozzi, Martina, Simonetti, Giorgia, Pazzaglia, Martina, Cammarata, Francesco Paolo, Russo, Giorgio, Acquaviva, Rosaria, Cirrone, Giuseppe Antonio Pablo, Petringa, Giada, Catalano, Roberto, Elia, Valerio Cosimo, Fede, Francesca, Manti, Lorenzo, Castellani, Gastone, Remondini, Daniel, and Zironi, Isabella

Subjects

HEART anatomy, HEART physiology, PROTON therapy, RADIOTHERAPY, ELECTROMAGNETISM, RESEARCH funding, RADIATION, HEART, MICE, ENERGY metabolism, GENE expression, GENE expression profiling, ANIMAL experimentation, RADIATION doses

Abstract

Simple Summary: The nature of different types of ionizing radiation is central to the modality of affecting biological targets. The main data library on radiotherapy effects we can access is on photon sources, and any other type of radiation is compared to that, not always considering that different physical features might contribute in quite different ways to the quality of visible effects. A large body of study already supports this vision, but a lot of work is still to be done, particularly on irradiated healthy tissue in the vicinity of the cancer target. This study aims to gain information on the effects of anti-cancer therapeutic protons as a function of radiation dose and time post-irradiation on healthy cardiac tissue through the analysis of transcriptionally activated genes and relative molecular pathways. Proton beam therapy is considered a step forward with respect to electromagnetic radiation, thanks to the reduction in the dose delivered. Among unwanted effects to healthy tissue, cardiovascular complications are a known long-term radiotherapy complication. The transcriptional response of cardiac tissue from xenografted BALB/c nude mice obtained at 3 and 10 days after proton irradiation covering both the tumor region and the underlying healthy tissue was analyzed as a function of dose and time. Three doses were used: 2 Gy, 6 Gy, and 9 Gy. The intermediate dose had caused the greatest impact at 3 days after irradiation: at 2 Gy, 219 genes were differently expressed, many of them represented by zinc finger proteins; at 6 Gy, there were 1109, with a predominance of genes involved in energy metabolism and responses to stimuli; and at 9 Gy, there were 105, mainly represented by zinc finger proteins and molecules involved in the regulation of cardiac function. After 10 days, no significant effects were detected, suggesting that cellular repair mechanisms had defused the potential alterations in gene expression. The nonlinear dose–response curve indicates a need to update the models built on photons to improve accuracy in health risk prediction. Our data also suggest a possible role for zinc finger protein genes as markers of proton therapy efficacy. [ABSTRACT FROM AUTHOR]

Published

2024

5. Evaluation of Proton-Induced Biomolecular Changes in MCF-10A Breast Cells by Means of FT-IR Microspectroscopy.

Author

Ricciardi, Valerio, Portaccio, Marianna, Lasalvia, Maria, Cammarata, Francesco Paolo, Pisciotta, Pietro, Perna, Giuseppe, Capozzi, Vito, Petringa, Giada, Manti, Lorenzo, and Lepore, Maria

Subjects

DNA ligases, PARTICLE beams, MEMBRANE lipids, BREAST, DNA repair, DNA damage, FOURIER transforms

Abstract

Radiotherapy (RT) with accelerated beams of charged particles (protons and carbon ions), also known as hadrontherapy, is a treatment modality that is increasingly being adopted thanks to the several benefits that it grants compared to conventional radiotherapy (CRT) treatments performed by means of high-energy photons/electrons. Hence, information about the biomolecular effects in exposed cells caused by such particles is needed to better realize the underlying radiobiological mechanisms and to improve this therapeutic strategy. To this end, Fourier transform infrared microspectroscopy (μ-FT-IR) can be usefully employed, in addition to long-established radiobiological techniques, since it is currently considered a helpful tool for examining radiation-induced cellular changes. In the present study, MCF-10A breast cells were chosen to evaluate the effects of proton exposure using μ-FT-IR. They were exposed to different proton doses and fixed at various times after exposure to evaluate direct effects due to proton exposure and the kinetics of DNA damage repair. Irradiated and control cells were examined in transflection mode using low-e substrates that have been recently demonstrated to offer a fast and direct way to examine proton-exposed cells. The acquired spectra were analyzed using a deconvolution procedure and a ratiometric approach, both of which showed the different contributions of DNA, protein, lipid, and carbohydrate cell components. These changes were particularly significant for cells fixed 48 and 72 h after exposure. Lipid changes were related to variations in membrane fluidity, and evidence of DNA damage was highlighted. The analysis of the Amide III band also indicated changes that could be related to different enzyme contributions in DNA repair. [ABSTRACT FROM AUTHOR]

Published

2022

6. Radiobiological Outcomes, Microdosimetric Evaluations and Monte Carlo Predictions in Eye Proton Therapy.

Author

Petringa, Giada, Calvaruso, Marco, Conte, Valeria, Bláha, Pavel, Bravatà, Valentina, Cammarata, Francesco Paolo, Cuttone, Giacomo, Forte, Giusi Irma, Keta, Otilija, Manti, Lorenzo, Minafra, Luigi, Petković, Vladana, Petrović, Ivan, Richiusa, Selene, Fira, Aleksandra Ristić, Russo, Giorgio, and Cirrone, Giuseppe Antonio Pablo

Subjects

PROTON therapy, MONTE Carlo method, UVEA, TREATMENT effectiveness, CELL survival, NUCLEAR physics

Abstract

CATANA (Centro di AdroTerapia ed Applicazioni Nucleari Avanzate) was the first Italian protontherapy facility dedicated to the treatment of ocular neoplastic pathologies. It is in operation at the LNS Laboratories of the Italian Institute for Nuclear Physics (INFN-LNS) and to date, 500 patients have been successfully treated. Even though proton therapy has demonstrated success in clinical settings, there is still a need for more accurate models because they are crucial for the estimation of clinically relevant RBE values. Since RBE can vary depending on several physical and biological parameters, there is a clear need for more experimental data to generate predictions. Establishing a database of cell survival experiments is therefore useful to accurately predict the effects of irradiations on both cancerous and normal tissue. The main aim of this work was to compare RBE values obtained from in-vitro experimental data with predictions made by the LEM II (Local Effect Model), Monte Carlo approaches, and semi-empirical models based on LET experimental measurements. For this purpose, the 92.1 uveal melanoma and ARPE-19 cells derived from normal retinal pigmented epithelium were selected and irradiated in the middle of clinical SOBP of the CATANA proton therapy facility. The remarkable results show the potentiality of using microdosimetric spectrum, Monte Carlo simulations and LEM model to predict not only the RBE but also the survival curves. [ABSTRACT FROM AUTHOR]

Published

2021

7. FT-IR Transflection Micro-Spectroscopy Study on Normal Human Breast Cells after Exposure to a Proton Beam.

Author

Ricciardi, Valerio, Portaccio, Marianna, Perna, Giuseppe, Lasalvia, Maria, Capozzi, Vito, Cammarata, Francesco Paolo, Pisciotta, Pietro, Petringa, Giada, Delfino, Ines, Manti, Lorenzo, and Lepore, Maria

Subjects

PROTON beams, IONIZING radiation, CELL anatomy, BREAST, STANDING waves, PROTEIN structure

Abstract

Fourier transform infrared micro-spectroscopy (μ-FT-IR) is nowadays considered a valuable tool for investigating the changes occurring in human cells after exposure to ionizing radiation. Recently, considerable attention has been devoted to the use of this optical technique in the study of cells exposed to proton beams, that are being increasingly adopted in cancer therapy. Different experimental configurations are used for proton irradiation and subsequent spectra acquisition. To facilitate the use of μ-FT-IR, it may be useful to investigate new experimental approaches capable of speeding up and simplifying the irradiation and measurements phases. Here, we propose the use of low-e-substrates slides for cell culture, allowing the irradiation and spectra acquisition in transflection mode in a fast and direct way. In recent years, there has been a wide debate about the validity of these supports, but many researchers agree that the artifacts due to the presence of the electromagnetic standing wave effects are negligible in many practical cases. We investigated human normal breast cells (MCF-10 cell line) fixed immediately after the irradiation with graded proton radiation doses (0, 0.5, 2, and 4 Gy). The spectra obtained in transflection geometry showed characteristics very similar to those present in the spectra acquired in transmission geometry and confirm the validity of the chosen approach. The analysis of spectra indicates the occurrence of significant changes in DNA and lipids components of cells. Modifications in protein secondary structure are also evidenced. [ABSTRACT FROM AUTHOR]

Published

2021

8. Proton-irradiated breast cells: molecular points of view.

Author

Bravatà, Valentina, Cammarata, Francesco P, Minafra, Luigi, Pisciotta, Pietro, Scazzone, Concetta, Manti, Lorenzo, Savoca, Gaetano, Petringa, Giada, Cirrone, Giuseppe A P, Cuttone, Giacomo, Gilardi, Maria C, Forte, Giusi I, and Russo, Giorgio

Subjects

BREAST cancer treatment, CANCER radiotherapy, PROTON therapy

Abstract

Breast cancer (BC) is the most common cancer in women, highly heterogeneous at both the clinical and molecular level. Radiation therapy (RT) represents an efficient modality to treat localized tumor in BC care, although the choice of a unique treatment plan for all BC patients, including RT, may not be the best option. Technological advances in RT are evolving with the use of charged particle beams (i.e. protons) which, due to a more localized delivery of the radiation dose, reduce the dose administered to the heart compared with conventional RT. However, few data regarding proton-induced molecular changes are currently available. The aim of this study was to investigate and describe the production of immunological molecules and gene expression profiles induced by proton irradiation. We performed Luminex assay and cDNA microarray analyses to study the biological processes activated following irradiation with proton beams, both in the non-tumorigenic MCF10A cell line and in two tumorigenic BC cell lines, MCF7 and MDA-MB-231. The immunological signatures were dose dependent in MCF10A and MCF7 cell lines, whereas MDA-MB-231 cells show a strong pro-inflammatory profile regardless of the dose delivered. Clonogenic assay revealed different surviving fractions according to the breast cell lines analyzed. We found the involvement of genes related to cell response to proton irradiation and reported specific cell line- and dose-dependent gene signatures, able to drive cell fate after radiation exposure. Our data could represent a useful tool to better understand the molecular mechanisms elicited by proton irradiation and to predict treatment outcome [ABSTRACT FROM AUTHOR]

Published

2019

9. Evaluation of Proton-Induced Biomolecular Changes in MCF-10A Breast Cells by Means of FT-IR Microspectroscopy

Author

Valerio Ricciardi, Marianna Portaccio, Maria Lasalvia, Francesco Paolo Cammarata, Pietro Pisciotta, Giuseppe Perna, Vito Capozzi, Giada Petringa, Lorenzo Manti, Maria Lepore, Cancer Research Center Groningen (CRCG), Ricciardi, Valerio, Portaccio, Marianna, Lasalvia, Maria, Cammarata, Francesco Paolo, Pisciotta, Pietro, Perna, Giuseppe, Capozzi, Vito, Petringa, Giada, Manti, Lorenzo, and Lepore, Maria

Subjects

Fluid Flow and Transfer Processes, SECONDARY STRUCTURE, Process Chemistry and Technology, General Engineering, MCF-10A breast cells, Fourier transform infrared microspectroscopy, proton therapy, radiation-induced effects, Computer Science Applications, APOPTOSIS, INFRARED MICROSPECTROSCOPY, RAMAN-SPECTROSCOPY, DNA-DAMAGE, TUMOR, SPECTRA, General Materials Science, Instrumentation

Abstract

Radiotherapy (RT) with accelerated beams of charged particles (protons and carbon ions), also known as hadrontherapy, is a treatment modality that is increasingly being adopted thanks to the several benefits that it grants compared to conventional radiotherapy (CRT) treatments performed by means of high-energy photons/electrons. Hence, information about the biomolecular effects in exposed cells caused by such particles is needed to better realize the underlying radiobiological mechanisms and to improve this therapeutic strategy. To this end, Fourier transform infrared microspectroscopy (μ-FT-IR) can be usefully employed, in addition to long-established radiobiological techniques, since it is currently considered a helpful tool for examining radiation-induced cellular changes. In the present study, MCF-10A breast cells were chosen to evaluate the effects of proton exposure using μ-FT-IR. They were exposed to different proton doses and fixed at various times after exposure to evaluate direct effects due to proton exposure and the kinetics of DNA damage repair. Irradiated and control cells were examined in transflection mode using low-e substrates that have been recently demonstrated to offer a fast and direct way to examine proton-exposed cells. The acquired spectra were analyzed using a deconvolution procedure and a ratiometric approach, both of which showed the different contributions of DNA, protein, lipid, and carbohydrate cell components. These changes were particularly significant for cells fixed 48 and 72 h after exposure. Lipid changes were related to variations in membrane fluidity, and evidence of DNA damage was highlighted. The analysis of the Amide III band also indicated changes that could be related to different enzyme contributions in DNA repair.

Published

2022

10. FT-IR transflection micro-spectroscopy study on normal human breast cells after exposure to a proton beam

Author

Giada Petringa, Maria Lasalvia, Marianna Portaccio, Ines Delfino, Maria Lepore, Giuseppe Perna, Francesco Paolo Cammarata, Vito Capozzi, Valerio Ricciardi, Lorenzo Manti, Pietro Pisciotta, Ricciardi, Valerio, Portaccio, Marianna, Perna, Giuseppe, Lasalvia, Maria, Capozzi, Vito, Cammarata, Francesco Paolo, Pisciotta, Pietro, Petringa, Giada, Delfino, Ine, Manti, Lorenzo, and Lepore, Maria

Subjects

Materials science, fourier transform infrared micro-spectroscopy, Proton, Infrared, 02 engineering and technology, fourier transform infrared micro-spectroscopy, transflection geometry, proton therapy, radiation dose effects, human breast cells, Astrophysics::Cosmology and Extragalactic Astrophysics, 01 natural sciences, lcsh:Technology, Spectral line, Ionizing radiation, transflection geometry, lcsh:Chemistry, symbols.namesake, Nuclear magnetic resonance, proton therapy, General Materials Science, Irradiation, Fourier transform infrared spectroscopy, Instrumentation, Proton therapy, lcsh:QH301-705.5, radiation dose effects, human breast cells, Astrophysics::Galaxy Astrophysics, Fluid Flow and Transfer Processes, lcsh:T, Process Chemistry and Technology, 010401 analytical chemistry, radiation dose effect, General Engineering, 021001 nanoscience & nanotechnology, lcsh:QC1-999, 0104 chemical sciences, Computer Science Applications, Fourier transform, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, symbols, Astrophysics::Earth and Planetary Astrophysics, 0210 nano-technology, lcsh:Engineering (General). Civil engineering (General), lcsh:Physics

Abstract

Fourier transform infrared micro-spectroscopy (&mu, FT-IR) is nowadays considered a valuable tool for investigating the changes occurring in human cells after exposure to ionizing radiation. Recently, considerable attention has been devoted to the use of this optical technique in the study of cells exposed to proton beams, that are being increasingly adopted in cancer therapy. Different experimental configurations are used for proton irradiation and subsequent spectra acquisition. To facilitate the use of &mu, FT-IR, it may be useful to investigate new experimental approaches capable of speeding up and simplifying the irradiation and measurements phases. Here, we propose the use of low-e-substrates slides for cell culture, allowing the irradiation and spectra acquisition in transflection mode in a fast and direct way. In recent years, there has been a wide debate about the validity of these supports, but many researchers agree that the artifacts due to the presence of the electromagnetic standing wave effects are negligible in many practical cases. We investigated human normal breast cells (MCF-10 cell line) fixed immediately after the irradiation with graded proton radiation doses (0, 0.5, 2, and 4 Gy). The spectra obtained in transflection geometry showed characteristics very similar to those present in the spectra acquired in transmission geometry and confirm the validity of the chosen approach. The analysis of spectra indicates the occurrence of significant changes in DNA and lipids components of cells. Modifications in protein secondary structure are also evidenced.

Published

2021

11. Proton-irradiated breast cells: molecular points of view

Author

Valentina Bravatà 1, Francesco P. Cammarata 1, Luigi Minafra 1, Pietro Pisciotta 1, 2, Concetta Scazzone 3, Lorenzo Manti 4, Gaetano Savoca 1, Giada Petringa 1, Giuseppe A.P. Cirrone 2, Giacomo Cuttone 2, Maria C. Gilardi 1, 5, Giusi I. Forte 1, Giorgio Russo 1, Bravata, V, Cammarata, F, Minafra, L, Pisciotta, P, Scazzone, C, Manti, L, Savoca, G, Petringa, G, Cirrone, G, Cuttone, G, Gilardi, M, Forte, G, Russo, G, Bravata, V., Cammarata, F. P., Minafra, L., Pisciotta, P., Scazzone, C., Manti, L., Savoca, G., Petringa, G., Cirrone, G. A. P., Cuttone, G., Gilardi, M. C., Forte, G. I., Russo, G., Bravatà, Valentina, Cammarata, Francesco P, Minafra, Luigi, Pisciotta, Pietro, Scazzone, Concetta, Manti, Lorenzo, Savoca, Gaetano, Petringa, Giada, Cirrone, Giuseppe A P, Cuttone, Giacomo, Gilardi, Maria C, Forte, Giusi I, and Russo, Giorgio

Subjects

breast cancer, cDNA microarray, gene signature, proton therapy, radiation, Breast, Breast Neoplasms, Cell Line, Tumor, DNA, Complementary, Dose-Response Relationship, Radiation, Female, Gene Expression Profiling, Gene Expression Regulation, Neoplastic, Humans, Inflammation, MCF-7 Cells, Oligonucleotide Array Sequence Analysis, Phenotype, Proton Therapy, Radiation Tolerance, Radiotherapy, Protons, DNA, Complementary, Health, Toxicology and Mutagenesis, medicine.medical_treatment, Breast Neoplasms, Cell fate determination, Radiation Tolerance, gene signature, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, breast cancer, Cell Line, Tumor, Regular Paper, medicine, proton therapy, Humans, Radiology, Nuclear Medicine and imaging, Breast, Clonogenic assay, Biology, Proton therapy, Oligonucleotide Array Sequence Analysis, 030304 developmental biology, Inflammation, cDNA microarray, 0303 health sciences, Radiotherapy, Chemistry, Gene Expression Profiling, radiation, Cancer, Dose-Response Relationship, Radiation, Gene signature, medicine.disease, Gene Expression Regulation, Neoplastic, Gene expression profiling, Radiation therapy, Phenotype, 030220 oncology & carcinogenesis, MCF-7 Cells, Cancer research, Female, Protons

Abstract

Breast cancer (BC) is the most common cancer in women, highly heterogeneous at both the clinical and molecular level. Radiation therapy (RT) represents an efficient modality to treat localized tumor in BC care, although the choice of a unique treatment plan for all BC patients, including RT, may not be the best option. Technological advances in RT are evolving with the use of charged particle beams (i.e. protons) which, due to a more localized delivery of the radiation dose, reduce the dose administered to the heart compared with conventional RT. However, few data regarding proton-induced molecular changes are currently available. The aim of this study was to investigate and describe the production of immunological molecules and gene expression profiles induced by proton irradiation. We performed Luminex assay and cDNA microarray analyses to study the biological processes activated following irradiation with proton beams, both in the non-tumorigenic MCF10A cell line and in two tumorigenic BC cell lines, MCF7 and MDA-MB-231. The immunological signatures were dose dependent in MCF10A and MCF7 cell lines, whereas MDA-MB-231 cells show a strong pro-inflammatory profile regardless of the dose delivered. Clonogenic assay revealed different surviving fractions according to the breast cell lines analyzed. We found the involvement of genes related to cell response to proton irradiation and reported specific cell line- and dose-dependent gene signatures, able to drive cell fate after radiation exposure. Our data could represent a useful tool to better understand the molecular mechanisms elicited by proton irradiation and to predict treatment outcome

Published

2019

12. The radiobiology of laser-driven particle beams: focus on sub-lethal responses of normal human cells

Author

F. M. Perozziello, Lorenzo Manti, D. Gwynne, G.A.P. Cirrone, R. Leanza, Marco Borghesi, A. Tramontana, Pankaj Chaudhary, Domenico Doria, Valentina Scuderi, Fabrizio Romano, Kevin M. Prise, G. Candiano, Lorenzo Romagnani, Manti, Lorenzo, Perozziello, Francesca Margaret, Borghesi, M., Candiano, G., Chaudhary, P., Cirrone, G. A. P., Doria, D., Gwynne, D., Leanza, R., Prise, K. M., Romagnani, L., Romano, F., Scuderi, V., and Tramontana, A.

Subjects

medicine.medical_specialty, Radiobiology, medicine.medical_treatment, 030218 nuclear medicine & medical imaging, Ionizing radiation, 03 medical and health sciences, 0302 clinical medicine, Instrumentation for hadron therapy, SDG 3 - Good Health and Well-being, Accelerator applications, medicine, Medical physics, Radiosensitivity, Irradiation, Instrumentation, Proton therapy, Mathematical Physics, Physics, Radiation therapy, Cell killing, 030220 oncology & carcinogenesis, Cancer cell, Biophysics, Plasma generation (laser-produced, RF, x ray-produced)

Abstract

Accelerated proton beams have become increasingly common for treating cancer. The need for cost and size reduction of particle accelerating machines has led to the pioneering investigation of optical ion acceleration techniques based on laser-plasma interactions as a possible alternative. Laser-matter interaction can produce extremely pulsed particle bursts of ultra-high dose rates (≥ 109 Gy/s), largely exceeding those currently used in conventional proton therapy. Since biological effects of ionizing radiation are strongly affected by the spatio-temporal distribution of DNA-damaging events, the unprecedented physical features of such beams may modify cellular and tissue radiosensitivity to unexplored extents. Hence, clinical applications of laser-generated particles need thorough assessment of their radiobiological effectiveness. To date, the majority of studies have either used rodent cell lines or have focussed on cancer cell killing being local tumour control the main objective of radiotherapy. Conversely, very little data exist on sub-lethal cellular effects, of relevance to normal tissue integrity and secondary cancers, such as premature cellular senescence. Here, we discuss ultra-high dose rate radiobiology and present preliminary data obtained in normal human cells following irradiation by laser-accelerated protons at the LULI PICO2000 facility at Laser Lab Europe, France.

Published

2017

13. Relative biological effectiveness variation along monoenergetic and modulated Bragg peaks of a 62-MeV therapeutic proton beam: A preclinical assessment

Author

Francesco Romano, Joy N. Kavanagh, Frederick Currell, Lorenzo Manti, Kevin M. Prise, Pankaj Chaudhary, F. Hanton, G.A.P. Cirrone, F. M. Perozziello, Giuseppe Schettino, Thomas I. Marshall, Stephen J. McMahon, Chaudhary, P, Marshall, Ti, Perozziello, Francesca Margaret, Manti, Lorenzo, Currell, Fj, Hanton, F, Mcmahon, Sj, Kavanagh, Jn, Cirrone, Gap, Romano, F, Prise, Km, and Schettino, G.

Subjects

Cancer Research, Cell Survival, Physics::Medical Physics, Sobp, Linear energy transfer, Particle therapy, Bragg peak, Radiation Tolerance, Ionizing radiation, Cell Line, Tumor, Relative biological effectiveness, Proton Therapy, Dosimetry, Medicine, Humans, Radiology, Nuclear Medicine and imaging, Linear Energy Transfer, Proton therapy, Radiation, business.industry, Glioma, Cyclotrons, Fibroblasts, Computational physics, CARBON-ION-BEAMS, Cell killing, Oncology, adverse effects, Relative Biological Effectiveness, Protons, Nuclear medicine, business, Relative Biological Effectiveness

Abstract

Purpose The biological optimization of proton therapy can be achieved only through a detailed evaluation of relative biological effectiveness (RBE) variations along the full range of the Bragg curve. The clinically used RBE value of 1.1 represents a broad average, which disregards the steep rise of linear energy transfer (LET) at the distal end of the spread-out Bragg peak (SOBP). With particular attention to the key endpoint of cell survival, our work presents a comparative investigation of cell killing RBE variations along monoenergetic (pristine) and modulated (SOBP) beams using human normal and radioresistant cells with the aim to investigate the RBE dependence on LET and intrinsic radiosensitvity. Methods and Materials Human fibroblasts (AG01522) and glioma (U87) cells were irradiated at 6 depth positions along pristine and modulated 62-MeV proton beams at the INFN-LNS (Catania, Italy). Cell killing RBE variations were measured using standard clonogenic assays and were further validated using Monte Carlo simulations and the local effect model (LEM). Results We observed significant cell killing RBE variations along the proton beam path, particularly in the distal region showing strong dose dependence. Experimental RBE values were in excellent agreement with the LEM predicted values, indicating dose-averaged LET as a suitable predictor of proton biological effectiveness. Data were also used to validate a parameterized RBE model. Conclusions The predicted biological dose delivered to a tumor region, based on the variable RBE inferred from the data, varies significantly with respect to the clinically used constant RBE of 1.1. The significant RBE increase at the distal end suggests also a potential to enhance optimization of treatment modalities such as LET painting of hypoxic tumors. The study highlights the limitation of adoption of a constant RBE for proton therapy and suggests approaches for fast implementation of RBE models in treatment planning.

Published

2014

14. ELIMED a new concept of hadrontherapy with laser-driven beams

Author

Fortunato Caruso, S. Cavallaro, Luciano Calabretta, Georg Korn, Giuseppe Antonio Malfa, Bijan Bji, Lorenzo Torrisi, Francesco Schillaci, E. Zappalà, Biagio Trovato, Daniele Margarone, Mario Maggiore, J. Prokupek, S. Passarello, Francesco Romano, Claudio Cali, Antonio Caruso, Marcella Renis, Barbara Tomasello, A. Tramontana, Lorenzo Manti, P. Cirrone, Giacomo Cuttone, Santo Gammino, The Nuclear and Plasma Sciences Society of the,Institute of Electrical and Electronic Engineers,(IEEE NPSS), Cirrone, Gap, Cuttone, G, Korn, G, Maggiore, M, Margarone, D, Bji, B, Calabretta, L, Cali, C, Caruso, A, Caruso, F, Cavallaro, S, Gammino, S, Malfa, G, Manti, Lorenzo, Passarello, S, Prokupek, J, Renis, M, Romano, F, Schillaci, F, Tomasello, B, Torrisi, L, Tramontana, A, Trovato, B, and Zappala, E.

Subjects

Physics, Spectrometer, Extreme Light Infrastructure, Monte Carlo method, Laser, law.invention, Nuclear physics, Hadron therapy, law, Cancer treatment, Dosimetry, Laser-driven proton beam, Proton therapy, Beam (structure)

Abstract

ELIMED (Medical Applications at Extreme Light Infrastructure) is a task-force originally born by an idea of ELI-Beams (Prague, CZ)and INFN-LNS (Italian Institute for Nuclear Physics of Catania, I) researchers. It now involves other groups interested in the possibility to design and develop a new generation of hadrontherapy facilities using laser-accelerated ion beams. ELIMED main goal is to perform proof-of-principle experiments aimed to demonstrate that laser-accelerated high-energy proton beams (up to 70 MeV in the first phase) can be potentially used for the specific case of ocular proton therapy. For this purpose new devices for beam handling and transport will be developed as well as new methods for radiobiology and dosimetry. The involvement of INFN-LNS group takes advantage of the well-established expertise in dosimetry measurements and Monte Carlo calculations for medical physics, which has been achieved in several years of eye tumor treatments in the CATANA proton therapy facility. Recently, in the framework of an INFN activity, they have also designed, fabricated, calibrated and experimentally tested at PALS laser laboratory (Cz) a Thomson Parabola ion spectrometer with a wide acceptance and able to characterize laser-driven proton beams up to 20 MeV.

Published

2012