Flies for PET: An Artificial Evolution Strategy for Image Reconstruction in Nuclear Medicine

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

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Flies for PET: An Artificial Evolution Strategy for Image Reconstruction in Nuclear Medicine. / Vidal, F. P.; Louchet, J.; Rocchisani, J.-M. et al.
Yn: Medical Physics, Cyfrol 37, Rhif 6, 01.07.2010, t. 3139.

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

HarvardHarvard

Vidal, FP, Louchet, J, Rocchisani, J-M & Lutton, É 2010, 'Flies for PET: An Artificial Evolution Strategy for Image Reconstruction in Nuclear Medicine', Medical Physics, cyfrol. 37, rhif 6, tt. 3139. https://doi.org/10.1118/1.3468200

APA

Vidal, F. P., Louchet, J., Rocchisani, J.-M., & Lutton, É. (2010). Flies for PET: An Artificial Evolution Strategy for Image Reconstruction in Nuclear Medicine. Medical Physics, 37(6), 3139. https://doi.org/10.1118/1.3468200

CBE

Vidal FP, Louchet J, Rocchisani J-M, Lutton É. 2010. Flies for PET: An Artificial Evolution Strategy for Image Reconstruction in Nuclear Medicine. Medical Physics. 37(6):3139. https://doi.org/10.1118/1.3468200

MLA

VancouverVancouver

Vidal FP, Louchet J, Rocchisani JM, Lutton É. Flies for PET: An Artificial Evolution Strategy for Image Reconstruction in Nuclear Medicine. Medical Physics. 2010 Gor 1;37(6):3139. doi: 10.1118/1.3468200

Author

Vidal, F. P. ; Louchet, J. ; Rocchisani, J.-M. et al. / Flies for PET: An Artificial Evolution Strategy for Image Reconstruction in Nuclear Medicine. Yn: Medical Physics. 2010 ; Cyfrol 37, Rhif 6. tt. 3139.

RIS

TY - JOUR

T1 - Flies for PET: An Artificial Evolution Strategy for Image Reconstruction in Nuclear Medicine

AU - Vidal, F. P.

AU - Louchet, J.

AU - Rocchisani, J.-M.

AU - Lutton, É.

PY - 2010/7/1

Y1 - 2010/7/1

N2 - Purpose: We propose an evolutionary approach for image reconstruction in nuclear medicine. Our method is based on a cooperative coevolution strategy (also called Parisian evolution): the ``fly algorithm''. Method and Materials: Each individual, or fly, corresponds to a 3D point that mimics a radioactive emitter, i.e. a stochastic simulation of annihilation events is performed to compute the fly's illumination pattern. For each annihilation, a photon is emitted in a random direction, and a second photon is emitted in the opposite direction. The line between two detected photons is called line of response (LOR). If both photons are detected by the scanner, the fly's illumination pattern is updated. The LORs of every fly are aggregated to form the population total illumination pattern. Using genetic operations to optimize the position of positrons, the population of flies evolves so that the population total pattern matches measured data. The final population of flies approximates the radioactivity concentration. Results: We have developed numerical phantom models to assess the reconstruction algorithm. To date, no scattering and no tissue attenuation have been considered. Whilst this is not physically correct, it allows us to test and validate our approach in the simplest cases. Preliminary results show the validity of this approach in both 2D and fully-3D modes. In particular, the size of objects, and their relative concentrations can be retrieved in the 2D mode. In fully-3D, complex shapes can be reconstructed. Conclusions: An evolutionary approach for PET reconstruction has been proposed and validated using simple test cases. Further work will therefore include the use of more realistic input data (including random events and scattering), which will finally lead to implement the correction of scattering within our algorithm. A comparison study against ML-EM and/or OS-EM methods will also need to be conducted.

AB - Purpose: We propose an evolutionary approach for image reconstruction in nuclear medicine. Our method is based on a cooperative coevolution strategy (also called Parisian evolution): the ``fly algorithm''. Method and Materials: Each individual, or fly, corresponds to a 3D point that mimics a radioactive emitter, i.e. a stochastic simulation of annihilation events is performed to compute the fly's illumination pattern. For each annihilation, a photon is emitted in a random direction, and a second photon is emitted in the opposite direction. The line between two detected photons is called line of response (LOR). If both photons are detected by the scanner, the fly's illumination pattern is updated. The LORs of every fly are aggregated to form the population total illumination pattern. Using genetic operations to optimize the position of positrons, the population of flies evolves so that the population total pattern matches measured data. The final population of flies approximates the radioactivity concentration. Results: We have developed numerical phantom models to assess the reconstruction algorithm. To date, no scattering and no tissue attenuation have been considered. Whilst this is not physically correct, it allows us to test and validate our approach in the simplest cases. Preliminary results show the validity of this approach in both 2D and fully-3D modes. In particular, the size of objects, and their relative concentrations can be retrieved in the 2D mode. In fully-3D, complex shapes can be reconstructed. Conclusions: An evolutionary approach for PET reconstruction has been proposed and validated using simple test cases. Further work will therefore include the use of more realistic input data (including random events and scattering), which will finally lead to implement the correction of scattering within our algorithm. A comparison study against ML-EM and/or OS-EM methods will also need to be conducted.

U2 - 10.1118/1.3468200

DO - 10.1118/1.3468200

M3 - Article

VL - 37

SP - 3139

JO - Medical Physics

JF - Medical Physics

IS - 6

T2 - American Association of Physicists in Medicine

Y2 - 18 July 2010 through 22 July 2010

ER -