Intrinsic spatial resolution limitations due to differences between positron emission position and annihilation detection localization

Autores

  • Pedro Pérez
  • Francisco Malano
  • Mauro Valente

DOI:

https://doi.org/10.29384/rbfm.2012.v6.n1.p7-12

Resumo

Since its successful implementation for clinical diagnostic, positron emission tomography (PET) represents the most promising medical imaging technique. The recent major growth of PET imaging is mainly due to its ability to trace the biologic pathways of different compounds in the patient’s body, assuming the patient can be labeled with some PET isotope. Regardless of the type of isotope, the PET imaging method is based on the detection of two 511-keV gamma photons being emitted in opposite directions, with almost 180o between them, as a consequence of electronpositron annihilation. Therefore, this imaging method is intrinsically limited by random uncertainties in spatial resolutions, related with differences between the actual position of positron emission and the location of the detected annihilation. This study presents an approach with the Monte Carlo method to analyze the influence of this effect on different isotopes of potential implementation in PET.

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Pérez, P., Malano, F., & Valente, M. (2015). Intrinsic spatial resolution limitations due to differences between positron emission position and annihilation detection localization. Revista Brasileira De Física Médica, 6(1), 7–12. https://doi.org/10.29384/rbfm.2012.v6.n1.p7-12

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