Your search keyword '"HAMPEL, G"' showing total 7 results

1. Dose calculation in biological samples in a mixed neutron-gamma field at the TRIGA reactor of the University of Mainz.

Author

Schmitz T, Blaickner M, Schütz C, Wiehl N, Kratz JV, Bassler N, Holzscheiter MH, Palmans H, Sharpe P, Otto G, and Hampel G

Subjects

Boron Neutron Capture Therapy instrumentation, Cell Line, Tumor, Colorectal Neoplasms pathology, Colorectal Neoplasms radiotherapy, Germany, Hep G2 Cells, Hospitals, University, Humans, Liver Neoplasms radiotherapy, Liver Neoplasms secondary, Models, Biological, Radiotherapy Dosage, Radiotherapy Planning, Computer-Assisted instrumentation, Validation Studies as Topic, Boron Neutron Capture Therapy methods, Gamma Rays therapeutic use, Neutrons therapeutic use, Nuclear Reactors instrumentation, Radiotherapy Planning, Computer-Assisted methods

Abstract

To establish Boron Neutron Capture Therapy (BNCT) for non-resectable liver metastases and for in vitro experiments at the TRIGA Mark II reactor at the University of Mainz, Germany, it is necessary to have a reliable dose monitoring system. The in vitro experiments are used to determine the relative biological effectiveness (RBE) of liver and cancer cells in our mixed neutron and gamma field. We work with alanine detectors in combination with Monte Carlo simulations, where we can measure and characterize the dose. To verify our calculations we perform neutron flux measurements using gold foil activation and pin-diodes. Material and methods. When L-α-alanine is irradiated with ionizing radiation, it forms a stable radical which can be detected by electron spin resonance (ESR) spectroscopy. The value of the ESR signal correlates to the amount of absorbed dose. The dose for each pellet is calculated using FLUKA, a multipurpose Monte Carlo transport code. The pin-diode is augmented by a lithium fluoride foil. This foil converts the neutrons into alpha and tritium particles which are products of the (7)Li(n,α)(3)H-reaction. These particles are detected by the diode and their amount correlates to the neutron fluence directly. Results and discussion. Gold foil activation and the pin-diode are reliable fluence measurement systems for the TRIGA reactor, Mainz. Alanine dosimetry of the photon field and charged particle field from secondary reactions can in principle be carried out in combination with MC-calculations for mixed radiation fields and the Hansen & Olsen alanine detector response model. With the acquired data about the background dose and charged particle spectrum, and with the acquired information of the neutron flux, we are capable of calculating the dose to the tissue. Conclusion. Monte Carlo simulation of the mixed neutron and gamma field of the TRIGA Mainz is possible in order to characterize the neutron behavior in the thermal column. Currently we also speculate on sensitizing alanine to thermal neutrons by adding boron compounds.

Published

2010

2. Determination of the irradiation field at the research reactor TRIGA Mainz for BNCT.

Author

Duvinage C, Nagels S, Hampel G, Kratz JV, Aguilar AL, Minouchehr S, Otto G, Schmidberger H, Schütz C, Vogtländer L, and Wortmann B

Subjects

Boron therapeutic use, Boron Neutron Capture Therapy statistics & numerical data, Energy Transfer, Fast Neutrons therapeutic use, Fluorides, Gamma Rays therapeutic use, Germany, Humans, In Vitro Techniques, Isotopes therapeutic use, Lithium Compounds, Liver Neoplasms radiotherapy, Liver Neoplasms secondary, Liver Neoplasms surgery, Liver Transplantation, Phantoms, Imaging, Radiation-Sensitizing Agents therapeutic use, Radiotherapy Planning, Computer-Assisted statistics & numerical data, Thermoluminescent Dosimetry, Transplantation, Autologous, Boron Neutron Capture Therapy instrumentation, Nuclear Reactors statistics & numerical data

Abstract

For the application of the BNCT for the excorporal treatment of organs at the TRIGA Mainz, the basic characteristics of the radiation field in the thermal column as beam geometry, neutron and gamma ray energies, angular distributions, neutron flux, as well as absorbed gamma and neutron doses must be determined in a reproducible way. To determine the mixed irradiation field thermoluminescence detectors (TLD) made of CaF(2):Tm with a newly developed energy-compensation filter system and LiF:Mg,Ti materials with different (6)Li concentrations and different thicknesses as well as thin gold foils were used.

Published

2009

3. Irradiation facility at the TRIGA Mainz for treatment of liver metastases.

Author

Hampel G, Wortmann B, Blaickner M, Knorr J, Kratz JV, Lizón Aguilar A, Minouchehr S, Nagels S, Otto G, Schmidberger H, Schütz C, and Vogtländer L

Subjects

Boron Neutron Capture Therapy statistics & numerical data, Fast Neutrons therapeutic use, Germany, Humans, In Vitro Techniques, Models, Statistical, Monte Carlo Method, Radiotherapy Planning, Computer-Assisted statistics & numerical data, Boron Neutron Capture Therapy instrumentation, Liver Neoplasms radiotherapy, Liver Neoplasms secondary, Nuclear Reactors statistics & numerical data

Abstract

The TRIGA Mark II reactor at the University of Mainz provides ideal conditions for duplicating BNCT treatment as performed in Pavia, Italy, in 2001 and 2003 [Pinelli, T., Zonta, A., Altieri, S., Barni, S., Braghieri, A., Pedroni, P., Bruschi, P., Chiari, P., Ferrari, C., Fossati, F., Nano, R., Ngnitejeu Tata, S., Prati, U., Ricevuti, G., Roveda, L., Zonta, C., 2002. TAOrMINA: from the first idea to the application to the human liver. In: Sauerwein et al. (Eds.), Research and Development in Neutron Capture Therapy. Proceedings of the 10th International Congress on Neutron Capture Therapy, Monduzzi editore, Bologna, pp. 1065-1072]. In order to determine the optimal parameters for the planned therapy and therefore for the design of the thermal column, calculations were conducted using the MCNP-code and the transport code ATTILA. The results of the parameter study as well as a possible configuration for the irradiation of the liver are presented.

Published

2009

4. Determination of the irradiation field at the research reactor TRIGA Mainz for BNCT

Author

Nagels, S., Hampel, G., Kratz, J.V., Aguilar, A.L., Minouchehr, S., Otto, G., Schmidberger, H., Schütz, C., Vogtländer, L., and Wortmann, B.

Subjects

*NUCLEAR reactors, *IRRADIATION, *BORON-neutron capture therapy, *THERMAL neutron beams, *THERAPEUTICS, *GAMMA rays, *RADIATION dosimetry

Abstract

Abstract: For the application of the BNCT for the excorporal treatment of organs at the TRIGA Mainz, the basic characteristics of the radiation field in the thermal column as beam geometry, neutron and gamma ray energies, angular distributions, neutron flux, as well as absorbed gamma and neutron doses must be determined in a reproducible way. To determine the mixed irradiation field thermoluminescence detectors (TLD) made of CaF2:Tm with a newly developed energy-compensation filter system and LiF:Mg,Ti materials with different 6Li concentrations and different thicknesses as well as thin gold foils were used. [Copyright &y& Elsevier]

Published

2009

5. Erratum to “Determination of the irradiation field at the research reactor TRIGA Mainz for BNCT” [J. Appl. Radiat. Isot. 67 (2009) S242–S246].

Author

Duvinage (née Krey), C., Nagels, S., Hampel, G., Kratz, J.V., Aguilar, A.L., Minouchehr, S., Otto, G., Schmidberger, H., Schütz, C., Vogtländer, L., Wortmann, B., and Burgkhardt, B.

Subjects

*PUBLISHED errata, *IRRADIATION, *NUCLEAR reactors

Published

2016

6. Comparison of EPR response of alanine and Gd2O3-alanine dosimeters exposed to TRIGA Mainz reactor.

Author

Marrale, M., Schmitz, T., Gallo, S., Hampel, G., Longo, A., Panzeca, S., and Tranchina, L.

Subjects

*ELECTRON paramagnetic resonance, *ALANINE, *DOSIMETERS, *NUCLEAR reactors, *GADOLINIUM, *RADIATION dosimetry, *THERAPEUTICS

Abstract

In this work we report some preliminary results regarding the analysis of electron paramagnetic resonance (EPR) response of alanine pellets and alanine pellets added with gadolinium used for dosimetry at the TRIGA research reactor in Mainz, Germany. Two set-ups were evaluated: irradiation inside PMMA phantom and irradiation inside boric acid phantom. We observed that the presence of Gd 2 O 3 inside alanine pellets increases the EPR signal by a factor of 3.45 and 1.24 in case of PMMA and boric acid phantoms, respectively. We can conclude that in the case of neutron beam with a predominant thermal neutron component the addition of gadolinium oxide can significantly improve neutron sensitivity of alanine pellets. Monte Carlo (MC) simulations of both response of alanine and Gd-added alanine pellets with FLUKA code were performed and a good agreement was achieved for pure alanine dosimeters. For Gd 2 O 3 -alanine deviations between MC simulations and experimental data were observed and discussed. [ABSTRACT FROM AUTHOR]

Published

2015

7. Cubic boron nitride: A new prospective material for ultracold neutron application

Author

Sobolev, Yu., Lauer, Th., Borisov, Yu., Daum, M., du Fresne, N., Göltl, L., Hampel, G., Heil, W., Knecht, A., Keunecke, M., Kratz, J.V., Lang, T., Meister, M., Plonka-Spehr, Ch., Pokotilovski, Yu., Reichert, P., Schmidt, U., Krist, Th., Wiehl, N., and Zenner, J.

Subjects

*BORON nitride, *ULTRACOLD neutrons, *NUCLEAR reactors, *TIME-of-flight mass spectrometry, *POTENTIAL theory (Physics), *SURFACE coatings

Abstract

Abstract: At the ultracold neutron (UCN) source of the TRIGA research reactor in Mainz, we have measured for the first time the material optical wall-potential of cubic boron nitride. The measurements were performed with a time-of-flight (TOF) spectrometer. The samples investigated had a wall-potential of . This value is in good agreement with the result extracted from neutron reflectometry data and theoretical expectations. Because of its high critical velocity for UCN and its good dielectric characteristics, cubic boron nitride coatings (isotopically enriched) will be useful for a number of applications in UCN experiments. [Copyright &y& Elsevier]

Published

2010