The Experts below are selected from a list of 92115 Experts worldwide ranked by ideXlab platform
J Pawelke - One of the best experts on this subject based on the ideXlab platform.
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positron emissIon tomography for quality assurance of cancer therapy with Light Ion beams
Nuclear Physics, 1999Co-Authors: W Enghardt, Jurgen Debus, Thomas Haberer, B G Hasch, Rainer Hinz, Oliver Jakel, M Kramer, K Lauckner, J Pawelke, Falk PonischAbstract:Positron emissIon tomography (PET) offers the possibility of in-situ monitoring the tumour treatment with Light Ion beams by means of imaging the spatial distributIon of β − -activity that is produced as a byproduct of the therapeutic irradiatIon via nuclear fragmentatIon reactIons between the projectiles and the atomic nuclei of the tissue within the target volume. The implementatIon of this PET technique at the experimental tumour therapy facility at the Gesellschaft fur SchwerIonenforschung (GSI) in Darmstadt and first results of its clinical applicatIon are presented.
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the spatial distributIon of positron emitting nuclei generated by relativistic Light Ion beams in organic matter
Physics in Medicine and Biology, 1992Co-Authors: W Enghardt, W D Fromm, H Geissel, H Heller, G Kraft, A Magel, P Manfrass, G Munzenberg, F Nickel, J PawelkeAbstract:The range distributIons of positron emitters generated during the stopping process of relativistic Light Ions in organic matter exhibit a pronounced maximum near the range of the primary particles. The shape of this distributIon can be qualitatively understood from a simple Monte Carlo approach of the stopping, fragmentatIon and decay processes. These results offer the possibility of beam monitoring by means of PET techniques during the tumour therapy with a Light Ion beam. Furthermore, a refinement of this technique may allow the actual dose distributIon to be calculated from PET data.
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the spatial distributIon of positron emitting nuclei generated by relativistic Light Ion beams in organic matter
Physics in Medicine and Biology, 1992Co-Authors: W Enghardt, W D Fromm, H Geissel, H Heller, G Kraft, A Magel, P Manfrass, G Munzenberg, F Nickel, J PawelkeAbstract:The range distributIons of positron emitters generated during the stopping process of relativistic Light Ions in organic matter exhibit a pronounced maximum near the range of the primary particles. The shape of this distributIon can be qualitatively understood from a simple Monte Carlo approach of the stopping, fragmentatIon and decay processes. These results offer the possibility of beam monitoring by means of PET techniques during the tumour therapy with a Light Ion beam. Furthermore, a refinement of this technique may allow the actual dose distributIon to be calculated from PET data.
W Enghardt - One of the best experts on this subject based on the ideXlab platform.
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positron emissIon tomography for quality assurance of cancer therapy with Light Ion beams
Nuclear Physics, 1999Co-Authors: W Enghardt, Jurgen Debus, Thomas Haberer, B G Hasch, Rainer Hinz, Oliver Jakel, M Kramer, K Lauckner, J Pawelke, Falk PonischAbstract:Positron emissIon tomography (PET) offers the possibility of in-situ monitoring the tumour treatment with Light Ion beams by means of imaging the spatial distributIon of β − -activity that is produced as a byproduct of the therapeutic irradiatIon via nuclear fragmentatIon reactIons between the projectiles and the atomic nuclei of the tissue within the target volume. The implementatIon of this PET technique at the experimental tumour therapy facility at the Gesellschaft fur SchwerIonenforschung (GSI) in Darmstadt and first results of its clinical applicatIon are presented.
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the spatial distributIon of positron emitting nuclei generated by relativistic Light Ion beams in organic matter
Physics in Medicine and Biology, 1992Co-Authors: W Enghardt, W D Fromm, H Geissel, H Heller, G Kraft, A Magel, P Manfrass, G Munzenberg, F Nickel, J PawelkeAbstract:The range distributIons of positron emitters generated during the stopping process of relativistic Light Ions in organic matter exhibit a pronounced maximum near the range of the primary particles. The shape of this distributIon can be qualitatively understood from a simple Monte Carlo approach of the stopping, fragmentatIon and decay processes. These results offer the possibility of beam monitoring by means of PET techniques during the tumour therapy with a Light Ion beam. Furthermore, a refinement of this technique may allow the actual dose distributIon to be calculated from PET data.
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the spatial distributIon of positron emitting nuclei generated by relativistic Light Ion beams in organic matter
Physics in Medicine and Biology, 1992Co-Authors: W Enghardt, W D Fromm, H Geissel, H Heller, G Kraft, A Magel, P Manfrass, G Munzenberg, F Nickel, J PawelkeAbstract:The range distributIons of positron emitters generated during the stopping process of relativistic Light Ions in organic matter exhibit a pronounced maximum near the range of the primary particles. The shape of this distributIon can be qualitatively understood from a simple Monte Carlo approach of the stopping, fragmentatIon and decay processes. These results offer the possibility of beam monitoring by means of PET techniques during the tumour therapy with a Light Ion beam. Furthermore, a refinement of this technique may allow the actual dose distributIon to be calculated from PET data.
W D Fromm - One of the best experts on this subject based on the ideXlab platform.
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the spatial distributIon of positron emitting nuclei generated by relativistic Light Ion beams in organic matter
Physics in Medicine and Biology, 1992Co-Authors: W Enghardt, W D Fromm, H Geissel, H Heller, G Kraft, A Magel, P Manfrass, G Munzenberg, F Nickel, J PawelkeAbstract:The range distributIons of positron emitters generated during the stopping process of relativistic Light Ions in organic matter exhibit a pronounced maximum near the range of the primary particles. The shape of this distributIon can be qualitatively understood from a simple Monte Carlo approach of the stopping, fragmentatIon and decay processes. These results offer the possibility of beam monitoring by means of PET techniques during the tumour therapy with a Light Ion beam. Furthermore, a refinement of this technique may allow the actual dose distributIon to be calculated from PET data.
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the spatial distributIon of positron emitting nuclei generated by relativistic Light Ion beams in organic matter
Physics in Medicine and Biology, 1992Co-Authors: W Enghardt, W D Fromm, H Geissel, H Heller, G Kraft, A Magel, P Manfrass, G Munzenberg, F Nickel, J PawelkeAbstract:The range distributIons of positron emitters generated during the stopping process of relativistic Light Ions in organic matter exhibit a pronounced maximum near the range of the primary particles. The shape of this distributIon can be qualitatively understood from a simple Monte Carlo approach of the stopping, fragmentatIon and decay processes. These results offer the possibility of beam monitoring by means of PET techniques during the tumour therapy with a Light Ion beam. Furthermore, a refinement of this technique may allow the actual dose distributIon to be calculated from PET data.
F Nickel - One of the best experts on this subject based on the ideXlab platform.
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the spatial distributIon of positron emitting nuclei generated by relativistic Light Ion beams in organic matter
Physics in Medicine and Biology, 1992Co-Authors: W Enghardt, W D Fromm, H Geissel, H Heller, G Kraft, A Magel, P Manfrass, G Munzenberg, F Nickel, J PawelkeAbstract:The range distributIons of positron emitters generated during the stopping process of relativistic Light Ions in organic matter exhibit a pronounced maximum near the range of the primary particles. The shape of this distributIon can be qualitatively understood from a simple Monte Carlo approach of the stopping, fragmentatIon and decay processes. These results offer the possibility of beam monitoring by means of PET techniques during the tumour therapy with a Light Ion beam. Furthermore, a refinement of this technique may allow the actual dose distributIon to be calculated from PET data.
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the spatial distributIon of positron emitting nuclei generated by relativistic Light Ion beams in organic matter
Physics in Medicine and Biology, 1992Co-Authors: W Enghardt, W D Fromm, H Geissel, H Heller, G Kraft, A Magel, P Manfrass, G Munzenberg, F Nickel, J PawelkeAbstract:The range distributIons of positron emitters generated during the stopping process of relativistic Light Ions in organic matter exhibit a pronounced maximum near the range of the primary particles. The shape of this distributIon can be qualitatively understood from a simple Monte Carlo approach of the stopping, fragmentatIon and decay processes. These results offer the possibility of beam monitoring by means of PET techniques during the tumour therapy with a Light Ion beam. Furthermore, a refinement of this technique may allow the actual dose distributIon to be calculated from PET data.
H Heller - One of the best experts on this subject based on the ideXlab platform.
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the spatial distributIon of positron emitting nuclei generated by relativistic Light Ion beams in organic matter
Physics in Medicine and Biology, 1992Co-Authors: W Enghardt, W D Fromm, H Geissel, H Heller, G Kraft, A Magel, P Manfrass, G Munzenberg, F Nickel, J PawelkeAbstract:The range distributIons of positron emitters generated during the stopping process of relativistic Light Ions in organic matter exhibit a pronounced maximum near the range of the primary particles. The shape of this distributIon can be qualitatively understood from a simple Monte Carlo approach of the stopping, fragmentatIon and decay processes. These results offer the possibility of beam monitoring by means of PET techniques during the tumour therapy with a Light Ion beam. Furthermore, a refinement of this technique may allow the actual dose distributIon to be calculated from PET data.
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the spatial distributIon of positron emitting nuclei generated by relativistic Light Ion beams in organic matter
Physics in Medicine and Biology, 1992Co-Authors: W Enghardt, W D Fromm, H Geissel, H Heller, G Kraft, A Magel, P Manfrass, G Munzenberg, F Nickel, J PawelkeAbstract:The range distributIons of positron emitters generated during the stopping process of relativistic Light Ions in organic matter exhibit a pronounced maximum near the range of the primary particles. The shape of this distributIon can be qualitatively understood from a simple Monte Carlo approach of the stopping, fragmentatIon and decay processes. These results offer the possibility of beam monitoring by means of PET techniques during the tumour therapy with a Light Ion beam. Furthermore, a refinement of this technique may allow the actual dose distributIon to be calculated from PET data.
