Activity quantification and dosimetry in radiopharmaceutical therapy with reference to Lutetium.

Radiopharmaceutical therapy has been widely adopted owing primarily to the development of novel radiopharmaceuticals. To fully utilize the potential of these RPTs in the era of precision medicine, therapy must be optimized to the patient's tumor characteristics. The vastly disparate dosimetry methodologies need to be harmonized as the first step towards this.

Accuracy of two dosimetry software programs for Lu radiopharmaceutical therapy using voxel-based patient-specific phantoms.

Purpose: Virtual dosimetry using voxel-based patient-specific phantoms and Monte Carlo (MC) simulations offer the advantage of having a gold standard against which absorbed doses may be benchmarked to establish the dosimetry accuracy. Furthermore, these reference values assist in investigating the accuracy of the absorbed dose methodologies from different software programs. Therefore, this study aimed to compare the accuracy of the absorbed doses computed using LundADose and OLINDA/EXM 1.

The effect of calibration factors and recovery coefficients on Lu SPECT activity quantification accuracy: a Monte Carlo study.

Background: Different gamma camera calibration factor (CF) geometries have been proposed to convert SPECT data into units of activity concentration. However, no consensus has been reached on a standardised geometry. The CF is dependent on the selected geometry and is further affected by partial volume effects.

The effect of tumour geometry on the quantification accuracy of planar I phantom images.

Introduction: Accurate activity quantification is applied in radiation dosimetry. Planar images are important for quantification of whole-body images, enabling assessment of biodistribution from radionuclide administrations. We evaluated the effect of tumour geometry on quantification accuracy of I planar phantom studies, including various tumour sizes, tumour-liver distances and two tumour-background ratios.