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623 results on '"Laissue, J"'

1. X-Ray Phase Contrast 3D Virtual Histology: Evaluation of Lung Alterations After Microbeam Irradiation

Author

Romano, M, Bravin, A, Wright, M, Jacques, L, Miettinen, A, Hlushchuk, R, Dinkel, J, Bartzsch, S, Laissue, J, Djonov, V, Coan, P, Romano M., Bravin A., Wright M. D., Jacques L., Miettinen A., Hlushchuk R., Dinkel J., Bartzsch S., Laissue J. A., Djonov V., Coan P., Romano, M, Bravin, A, Wright, M, Jacques, L, Miettinen, A, Hlushchuk, R, Dinkel, J, Bartzsch, S, Laissue, J, Djonov, V, Coan, P, Romano M., Bravin A., Wright M. D., Jacques L., Miettinen A., Hlushchuk R., Dinkel J., Bartzsch S., Laissue J. A., Djonov V., and Coan P.

Abstract

Purpose: This study provides the first experimental application of multiscale 3-dimensional (3D) x-ray phase contrast imaging computed tomography (XPCI-CT) virtual histology for the inspection and quantitative assessment of the late-stage effects of radio-induced lesions on lungs in a small animal model. Methods and Materials: Healthy male Fischer rats were irradiated with x-ray standard broad beams and microbeam radiation therapy, a high-dose rate (14 kGy/s), FLASH spatially fractionated x-ray therapy to avoid beamlet smearing owing to cardiosynchronous movements of the organs during the irradiation. After organ dissection, ex vivo XPCI-CT was applied to all the samples and the results were quantitatively analyzed and correlated to histologic data. Results: XPCI-CT enables the 3D visualization of lung tissues with unprecedented contrast and sensitivity, allowing alveoli, vessel, and bronchi hierarchical visualization. XPCI-CT discriminates in 3D radio-induced lesions such as fibrotic scars and Ca/Fe deposits and allows full-organ accurate quantification of the fibrotic tissue within the irradiated organs. The radiation-induced fibrotic tissue content is less than 10% of the analyzed volume for all microbeam radiation therapy–treated organs and reaches 34% in the case of irradiations with 50 Gy using a broad beam. Conclusions: XPCI-CT is an effective imaging technique able to provide detailed 3D information for the assessment of lung pathology and treatment efficacy in a small animal model.

Published
2022

4. Spacial Fractionation A MULTISCALE AND MULTI-TECHNIQUE APPROACH FOR THE CHARACTERIZATION OF THE EFFECTS OF SPATIALLY FRACTIONATED X-RAY FLASH IRRADIATION IN LUNGS AND BRAINS

Author

Romano, M., primary, Alunni-Fabbroni, M., additional, Barbone, G., additional, Bartzsch, S., additional, Bouchet, A., additional, Bunk, O., additional, Dinkel, J., additional, Djonov, V., additional, Eckhardt, A., additional, Giannini, C., additional, Giese, A., additional, Hirner-Eppeneder, H., additional, Hlushchuk, R., additional, Jacques, L., additional, Laissue, J., additional, Miettinen, A., additional, Mittone, A., additional, Ricke, J., additional, Ruf, V., additional, Sancey, L., additional, Wright, M., additional, Bravin, A., additional, and Coan, P., additional

Published
2022
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13. Non-conventional Ultra-High Dose Rate (FLASH) Microbeam Radiotherapy Provides Superior Normal Tissue Sparing in Rat Lung Compared to Non-conventional Ultra-High Dose Rate (FLASH) Radiotherapy

Author

Wright, M, Romanelli, P, Bravin, A, Le Duc, G, Brauer-Krisch, E, Requardt, H, Bartzsch, S, Hlushchuk, R, Laissue, J, Djonov, V, Wright, Michael D, Romanelli, Pantaleo, Bravin, Alberto, Le Duc, Geraldine, Brauer-Krisch, Elke, Requardt, Herwig, Bartzsch, Stefan, Hlushchuk, Ruslan, Laissue, Jean-Albert, Djonov, Valentin, Wright, M, Romanelli, P, Bravin, A, Le Duc, G, Brauer-Krisch, E, Requardt, H, Bartzsch, S, Hlushchuk, R, Laissue, J, Djonov, V, Wright, Michael D, Romanelli, Pantaleo, Bravin, Alberto, Le Duc, Geraldine, Brauer-Krisch, Elke, Requardt, Herwig, Bartzsch, Stefan, Hlushchuk, Ruslan, Laissue, Jean-Albert, and Djonov, Valentin

Abstract

Conventional radiotherapy is a widely used non-invasive form of treatment for many types of cancer. However, due to a low threshold in the lung for radiation-induced normal tissue damage, it is of less utility in treating lung cancer. For this reason, surgery is the preferred treatment for lung cancer, which has the detriment of being highly invasive. Non-conventional ultra-high dose rate (FLASH) radiotherapy is currently of great interest in the radiotherapy community due to demonstrations of reduced normal tissue toxicity in lung and other anatomy. This study investigates the effects of FLASH microbeam radiotherapy, which in addition to ultra-high dose rate incorporates a spatial segmentation of the radiation field, on the normal lung tissue of rats. With a focus on fibrotic damage, this work demonstrates that FLASH microbeam radiotherapy provides an order of magnitude increase in normal tissue radio-resistance compared to FLASH radiotherapy. This result suggests FLASH microbeam radiotherapy holds promise for much improved noninvasive control of lung cancer.

Published
2021

21. Animal Models in Microbeam Radiation Therapy: A Scoping Review

Author

Fernandez-Palomo, C, Fazzari, J, Trappetti, V, Smyth, L, Janka, H, Laissue, J, Djonov, V, Fernandez-Palomo, C, Fazzari, J, Trappetti, V, Smyth, L, Janka, H, Laissue, J, and Djonov, V

Abstract

BACKGROUND: Microbeam Radiation Therapy (MRT) is an innovative approach in radiation oncology where a collimator subdivides the homogeneous radiation field into an array of co-planar, high-dose beams which are tens of micrometres wide and separated by a few hundred micrometres. OBJECTIVE: This scoping review was conducted to map the available evidence and provide a comprehensive overview of the similarities, differences, and outcomes of all experiments that have employed animal models in MRT. METHODS: We considered articles that employed animal models for the purpose of studying the effects of MRT. We searched in seven databases for published and unpublished literature. Two independent reviewers screened citations for inclusion. Data extraction was done by three reviewers. RESULTS: After screening 5688 citations and 159 full-text papers, 95 articles were included, of which 72 were experimental articles. Here we present the animal models and pre-clinical radiation parameters employed in the existing MRT literature according to their use in cancer treatment, non-neoplastic diseases, or normal tissue studies. CONCLUSIONS: The study of MRT is concentrated in brain-related diseases performed mostly in rat models. An appropriate comparison between MRT and conventional radiotherapy (instead of synchrotron broad beam) is needed. Recommendations are provided for future studies involving MRT.

Published
2020

24. O098 - Spacial Fractionation A MULTISCALE AND MULTI-TECHNIQUE APPROACH FOR THE CHARACTERIZATION OF THE EFFECTS OF SPATIALLY FRACTIONATED X-RAY FLASH IRRADIATION IN LUNGS AND BRAINS

Author

Romano, M., Alunni-Fabbroni, M., Barbone, G., Bartzsch, S., Bouchet, A., Bunk, O., Dinkel, J., Djonov, V., Eckhardt, A., Giannini, C., Giese, A., Hirner-Eppeneder, H., Hlushchuk, R., Jacques, L., Laissue, J., Miettinen, A., Mittone, A., Ricke, J., Ruf, V., Sancey, L., Wright, M., Bravin, A., and Coan, P.

Published
2022
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27. Exogene chemische und physikalische Schädigungen des kindlichen Skelets : Toxische und medikamentös bedingte Schädigungen des wachsenden Skelets

Author

Oehme, J., Laissue, J., Roos, B., Cottier, H., Opitz, H., editor, Schmid, F., editor, Weicker, H., editor, Althoff, H., editor, Baumgartner, G., editor, Beckmann, R., editor, Betke, K., editor, Bettex, M., editor, Burgio, G. R., editor, Cottier, H., editor, Damerow, R., editor, Degenhardt, K.-H., editor, Diemer, K., editor, Emrich, R., editor, Fey, F., editor, Fichsel, H., editor, Flatz, G., editor, Garby, L., editor, Gasser, C., editor, Gugler, E., editor, Hansen, H. G., editor, Hauke, H., editor, Haupt, H., editor, Hitzig, W. H., editor, Hövels, O., editor, Jacobi, H., editor, Jéquier, S., editor, Jonxis, J. H. P., editor, Kaufmann, H. J., editor, Kleihauer, E. F., editor, Künzer, W., editor, Kuhnke, E., editor, Laissue, J., editor, Leiber, B., editor, Lüscher, E. F., editor, Maier, W. A., editor, Marti, H. R., editor, Merker, H., editor, Murken, J.-D., editor, Oehme, J., editor, Ofteringer, K., editor, Plenert, W., editor, Rind, H. J., editor, Rogner, G., editor, Roos, B., editor, Ruhrmann, G., editor, Schönenberg, H., editor, Schröder, G., editor, Spranger, J., editor, Stobbe, H., editor, Theiler, K., editor, Thomas, G., editor, Tönz, O., editor, Versé, H., editor, Vest, M., editor, Weippl, G., editor, Weyers, H., editor, Wiedemann, H.-R., editor, and Wilhelm, G., editor

Published
1967
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28. Computational modelling of the cerebral cortical microvasculature: Effect of x-ray microbeams versus broad beam irradiation

Author

Merrem, A, Bartzsch, S, Laissue, J, and Oelfke, U

Subjects
Paper, Cerebral Cortex, synchrotron radiation, X-Rays, mathematical modeling, vascular trees, Radiation Dosage, blood vessels, radiation damage, Microvessels, computer simulation, Humans, microbeam radiation therapy, Synchrotrons
Abstract

Microbeam Radiation Therapy is an innovative pre-clinical strategy which uses arrays of parallel, tens of micrometres wide kilo-voltage photon beams to treat tumours. These x-ray beams are typically generated on a synchrotron source. It was shown that these beam geometries allow exceptional normal tissue sparing from radiation damage while still being effective in tumour ablation. A final biological explanation for this enhanced therapeutic ratio has still not been found, some experimental data support an important role of the vasculature. In this work, the effect of microbeams on a normal microvascular network of the cerebral cortex was assessed in computer simulations and compared to the effect of homogeneous, seamless exposures at equal energy absorption. The anatomy of a cerebral microvascular network and the inflicted radiation damage were simulated to closely mimic experimental data using a novel probabilistic model of radiation damage to blood vessels. It was found that the spatial dose fractionation by microbeam arrays significantly decreased the vascular damage. The higher the peak-to-valley dose ratio, the more pronounced the sparing effect. Simulations of the radiation damage as a function of morphological parameters of the vascular network demonstrated that the distribution of blood vessel radii is a key parameter determining both the overall radiation damage of the vasculature and the dose-dependent differential effect of microbeam irradiation.

Published
2017

30. Morphologie des Dickdarms

Author

Gebbers, J.-O., Laissue, J. A., Blum, André Louis, editor, Siewert, Jörg Rüdiger, editor, Ottenjann, Rudolf, editor, and Fahrländer, Hansjürg, editor

Published
1983
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34. Radiation therapy using synchrotron radiation: Preclinical studies toward clinical trials

Author

Adam, J, Balosso, J, Bobyk, L, Charvet, A, Deman, P, Edouard, M, Elleaume, H, Estève, F, Le Bas, J, Rousseau, J, Serduc, R, Vautrin, M, Chabrol, T, Depaulis, A, Pouyatos, B, Baruchel, J, Berkvens, P, Berruyer, G, Bouchet, A, Bräuer-Krisch, E, Bravin, A, Brochard, T, Dalléry, D, Le Duc, G, Nemoz, C, Martínez-Rovira, I, Prezado, Y, Renier, M, Requardt, H, Benkebil, M, Laissue, J, Adam J. F., Balosso J., Bobyk L., Charvet A.M., Deman P., Edouard M., Elleaume H., Estève F., Le Bas J.F., Rousseau J., Serduc R., Vautrin M., Chabrol T., Depaulis A., Pouyatos B., Baruchel J., Berkvens P., Berruyer G., Bouchet A., Bräuer-Krisch E., Bravin A, Brochard T., Dalléry D., Le Duc G., Nemoz C., Martínez-Rovira I., Prezado Y., Renier M., Requardt H., Benkebil M., Laissue J., Adam, J, Balosso, J, Bobyk, L, Charvet, A, Deman, P, Edouard, M, Elleaume, H, Estève, F, Le Bas, J, Rousseau, J, Serduc, R, Vautrin, M, Chabrol, T, Depaulis, A, Pouyatos, B, Baruchel, J, Berkvens, P, Berruyer, G, Bouchet, A, Bräuer-Krisch, E, Bravin, A, Brochard, T, Dalléry, D, Le Duc, G, Nemoz, C, Martínez-Rovira, I, Prezado, Y, Renier, M, Requardt, H, Benkebil, M, Laissue, J, Adam J. F., Balosso J., Bobyk L., Charvet A.M., Deman P., Edouard M., Elleaume H., Estève F., Le Bas J.F., Rousseau J., Serduc R., Vautrin M., Chabrol T., Depaulis A., Pouyatos B., Baruchel J., Berkvens P., Berruyer G., Bouchet A., Bräuer-Krisch E., Bravin A, Brochard T., Dalléry D., Le Duc G., Nemoz C., Martínez-Rovira I., Prezado Y., Renier M., Requardt H., Benkebil M., and Laissue J.

Published
2011

35. Vascular toxicity of microbeam irradiation depends on the stage of capillary maturation

Author

Sabatasso, S, Laissue, J, Hlushchuk, R, Brauer-Krisch, E, Bravin, A, Blattmann, H, Michaud, K, Djonov, V, Sabatasso S., Laissue J. A., Hlushchuk R., Brauer-Krisch E., Bravin A, Blattmann H., Michaud K., Djonov V., Sabatasso, S, Laissue, J, Hlushchuk, R, Brauer-Krisch, E, Bravin, A, Blattmann, H, Michaud, K, Djonov, V, Sabatasso S., Laissue J. A., Hlushchuk R., Brauer-Krisch E., Bravin A, Blattmann H., Michaud K., and Djonov V.

Published
2010

36. Microbeam radiation therapy - Grid therapy and beyond: A clinical perspective

Author

Schültke, E, Balosso, J, Breslin, T, Cavaletti, G, Djonov, V, Esteve, F, Grotzer, M, Hildebrandt, G, Valdman, A, Laissue, J, Schültke, E, Balosso, J, Breslin, T, Cavaletti, G, Djonov, V, Esteve, F, Grotzer, M, Hildebrandt, G, Valdman, A, and Laissue, J

Abstract

Microbeam irradiation is spatially fractionated radiation on a micrometer scale. Microbeam irradiation with therapeutic intent has become known as microbeam radiation therapy (MRT). The basic concept of MRT was developed in the 1980s, but it has not yet been tested in any human clinical trial, even though there is now a large number of animal studies demonstrating its marked therapeutic potential with an exceptional normal tissue sparing effect. Furthermore, MRT is conceptually similar to macroscopic grid based radiation therapy which has been used in clinical practice for decades. In this review, the potential clinical applications of MRT are analysed for both malignant and non-malignant diseases.

Published
2017

37. Memory and survival after microbeam radiation therapy

Author

Schultke, E, Juurlink, B, Ataelmannan, K, Laissue, J, Blattmann, H, Brauer-Krisch, E, Bravin, A, Minczewska, J, Crosbie, J, Taherian, H, Frangou, E, Wysokinsky, T, Chapman, L, Griebel, R, Fourney, D, Schultke E, Juurlink B HJ, Ataelmannan K, Laissue J, Blattmann H, Brauer-Krisch E, Bravin A, Minczewska Joanna, Crosbie Jeffrey, Taherian Hadi, Frangou Evan, Wysokinsky Tomasz, Chapman LD, Griebel R, Fourney D, Schultke, E, Juurlink, B, Ataelmannan, K, Laissue, J, Blattmann, H, Brauer-Krisch, E, Bravin, A, Minczewska, J, Crosbie, J, Taherian, H, Frangou, E, Wysokinsky, T, Chapman, L, Griebel, R, Fourney, D, Schultke E, Juurlink B HJ, Ataelmannan K, Laissue J, Blattmann H, Brauer-Krisch E, Bravin A, Minczewska Joanna, Crosbie Jeffrey, Taherian Hadi, Frangou Evan, Wysokinsky Tomasz, Chapman LD, Griebel R, and Fourney D

Abstract

Background: Disturbances of memory function are frequently observed in patients with malignant brain tumours and as adverse effects after radiotherapy to the brain. Experiments in small animal models of malignant brain turnout using synchrotron-based microbeam radiation therapy (MRT) have shown a promising prolongation of survival times. Materials and methods: Two animal models of malignant brain turnout were used to Study survival and memory development after MRT. Thirteen days after implantation of tumour cells, animals were submitted to MRT either with or without adjuvant therapy (buthionine-SR-sulfoximine = BSO or glutamine). We used two orthogonal 1-cm wide arrays of 50 microplanar quasiparallel microbeams of 25 mu m width and a center-to-center distance of about 200 mu m, created by a multislit collimator, with a skin entrance dose of 350 Gy for each direction. Object recognition tests were performed at day 13 after tumour cell implantation and in monthly intervals Lip 10 1 year after tumour cell implantation. Results: In both animal models, MRT with and without adjuvant therapy significantly increased survival times. BSO had detrimental effects on memory function early after therapy, while administration of glutamine resulted in improved memory.

Published
2008

39. Effect of microbeam radiation exposure to the microvasculature of healthy mouse brain

Author

Remy, C, Serduc, R, Verant, P, Vial, J, Farion, R, Brauer, E, Bravin, A, Laissue, J, Segebarth, C, van der Sanden, B, Remy C, Serduc R, Verant P, Vial J, Farion R, Brauer E, Bravin A, Laissue J, Segebarth C, van der Sanden B, Remy, C, Serduc, R, Verant, P, Vial, J, Farion, R, Brauer, E, Bravin, A, Laissue, J, Segebarth, C, van der Sanden, B, Remy C, Serduc R, Verant P, Vial J, Farion R, Brauer E, Bravin A, Laissue J, Segebarth C, and van der Sanden B

Published
2005

40. New irradiation geometry for microbeam radiation therapy

Author

Brauer-Krisch, E, Requardt, H, Regnard, P, Corde, S, Siegbahn, E, Leduc, G, Brochard, T, Blattmann, H, Laissue, J, Bravin, A, Brauer-Krisch E, Requardt H, Regnard P, Corde S, Siegbahn E, LeDuc G, Brochard T, Blattmann H, Laissue J, Bravin A, Brauer-Krisch, E, Requardt, H, Regnard, P, Corde, S, Siegbahn, E, Leduc, G, Brochard, T, Blattmann, H, Laissue, J, Bravin, A, Brauer-Krisch E, Requardt H, Regnard P, Corde S, Siegbahn E, LeDuc G, Brochard T, Blattmann H, Laissue J, and Bravin A

Abstract

Microbeam radiation therapy (MRT) has the potential to treat infantile brain tumours when other kinds of radiotherapy would be excessively toxic to the developing normal brain. MRT uses extraordinarily high doses of x-rays but provides unusual resistance to radioneurotoxicity, presumably from the migration of endothelial cells from 'valleys' into 'peaks', i.e., into directly irradiated microslices of tissues. We present a novel irradiation geometry which results in a tolerable valley dose for the normal tissue and a decreased peak-to-valley dose ratio (PVDR) in the tumour area by applying an innovative cross-firing technique. We propose an MRT technique to orthogonally crossfire two arrays of parallel, nonintersecting, mutually interspersed microbeams that produces tumouricidal doses with small PVDRs where the arrays meet and tolerable radiation doses to normal tissues between the microbeams proximal and distal to the tumour in the paths of the arrays.

Published
2005

41. Exploiting geometrical irradiation possibilities in MRT application

Author

Brauer-Krisch, E, Requardt, H, Regnard, P, Corde, S, Siegbahn, E, Leduc, G, Blattmann, H, Laissue, J, Bravin, A, Brauer-Krisch E, Requardt H, Regnard P, Corde S, Siegbahn EA, LeDuc G, Blattmann H, Laissue J, Bravin A, Brauer-Krisch, E, Requardt, H, Regnard, P, Corde, S, Siegbahn, E, Leduc, G, Blattmann, H, Laissue, J, Bravin, A, Brauer-Krisch E, Requardt H, Regnard P, Corde S, Siegbahn EA, LeDuc G, Blattmann H, Laissue J, and Bravin A

Abstract

Microbeam Radiation Therapy (MRT) has the potential to treat infantile brain tumors when other kinds of radiotherapy would be excessively toxic to the developing normal brain. MRT uses extraordinarily high doses of X-rays but provides unusual resistance to radioneurotoxicity, presumably from the rapid migration of regenerative endothelial cells from dose "valleys" into dose "peaks", i.e., into directly irradiated micro-slices of tissues. We will present a novel irradiation geometry which results in a tolerable valley dose for the normal tissue and a decreased peak-to-valley dose ratio (PVDR) in the tumor area by applying an innovative cross-firing technique. We propose an MRT technique to orthogonally crossfire two arrays of parallel, nonintersecting, mutually interspersed microbeams that produces tumoricidal doses with small PVDRs where the arrays meet and tolerable radiation doses to normal tissues between the microbeams proximal and distal to the tumor in the paths of the arrays.

Published
2004

42. Synchrotron X-ray microtransections: a non invasive approach for epileptic seizures arising from eloquent cortical areas

Author

Pouyatos, B., primary, Nemoz, C., additional, Chabrol, T., additional, Potez, M., additional, Bräuer, E., additional, Renaud, L., additional, Pernet-Gallay, K., additional, Estève, F., additional, David, O., additional, Kahane, P., additional, Laissue, J. A., additional, Depaulis, A., additional, and Serduc, R., additional

Published
2016
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43. Effect of microbeam radiation exposure to the microvasculature of healthy mouse brain

Author

Remy, C., Serduc, R., Verant, P., Vial, J., Farion, R., Brauer, E., Alberto Bravin, Laissue, J., Segebarth, C., Sanden, B., Remy, C, Serduc, R, Verant, P, Vial, J, Farion, R, Brauer, E, Bravin, A, Laissue, J, Segebarth, C, and van der Sanden, B

Subjects
microbeams, microvasculature, FIS/07 - FISICA APPLICATA (A BENI CULTURALI, AMBIENTALI, BIOLOGIA E MEDICINA)
Published
2005

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