Administering the correct amount of therapeutic activity to patients is of utmost importance in personalized molecular radiotherapy. Typically, (inter)national guidelines recommend stricter accuracy demands (±5%) for therapeutic than for diagnostic radionuclides (±5-10%) [6-8]. However, in case of theragnostics, where the therapeutic activity is optimized based on pre-therapeutic dosimetry/uptake calculations using diagnostic imaging, accurate quantification of the diagnostic activity is of equal importance as accurate therapeutic activity quantification. Therefore, to prevent introducing a substantial error in the therapeutic doses delivered to patients, we advocate to apply the ±5% accuracy limit also for diagnostic radionuclides in a theragnostic setting.
In our study we found one radionuclide calibrator (E1) that showed large deviations (> 10% underestimations) for all radionuclides, therefore appearing to be malfunctioning. This system was recently installed and was not yet (fully) validated nor released for clinical use. These observations indicate that extensive validation of all clinically-used radionuclides is of vital importance.
Individual radionuclides
This intercomparison shows that radionuclide calibrator measurements of 99mTc, still the workhorse of nuclear medicine, are (nearly) always correct, in agreement with values reported in literature [9,14]. The same cannot be said for the other diagnostic radionuclides evaluated. For 111In, 123I and 124I measurement deviations frequently exceeded the ±5% and often even the ±10% limits. This is in agreement with values reported in literature for 111In and 123I [9,10,12]. To the best of our knowledge, no multi-center data are available on the typical accuracy of 124I clinical activity measurements. In particular, these radionuclides (111In, 123I and 124I) show a large dependence on sample geometry (particularly sample container) caused by self-absorption of the emitted low-energy X-rays within the sample itself. Consequently, accurate activity measurement of these radionuclides requires specific calibration or correction factors for the sample geometry [22,23]. When factory settings dedicated to specific sample configurations are available, they must be experimentally verified prior to clinical use, as they might not be accurate for the specific containers used locally. This was the case for many activity measurements of 123I, 111In and 124I. Alternatively, selective absorption of low-energy X-rays using a copper/aluminum filter is an effective method to minimize the variability in activity measurements caused by sample geometry [23,24]. In this intercomparison a copper filter was available for two systems, but appropriate calibration factors for measurements with filter had yet to be determined.
Regarding the therapeutic radionuclides, 177Lu measurements were almost always within ±5% from the reference activity, and never deviated by more than ±10%, in agreement with values previously reported for Capintec systems [13]. A tendency to overestimate the reference activity values by typically a few percent was observed, which might (partially) be attributed to the calibrators being sensitive to the presence of the 177mLu impurity. Our study presents new data for 177Lu, particularly on the accuracy of medical calibrators from different suppliers, and using clinical sample configurations. Similar as for 177Lu, the majority of calibrators were accurate for measuring 131I albeit with a slightly higher deviation (sometimes > ±5%, rarely > ±10%). This is in agreement with values reported in literature [15]. In contrast, for 90Y some systems showed incorrect measurements to an unacceptable level: the deviation ranged from a 72% underestimation to a 424% overestimation. Indeed, in literature large measurement errors up to ±50% have been reported [13]. In particular, although all Isomed devices used factory-set corrections for sample geometry, they were highly sensitive to the sample container and volume of solution and large measurement deviations were observed. Also, two systems (D1 and H2) showed extremely high overestimations for the syringe measurements, but not for the vials. Interestingly, this effect was not observed for other systems of the same type and with the same (factory-set) calibration factors. Most likely, in these two systems high-energy beta radiation was able to reach the ionization chamber in the syringe samples but not in the vial samples. Indeed, the radionuclide calibrator response to high-energy beta particles is highly sensitive to even small variations in the material and design specifications of the measurement set-up [4]. This clearly indicates the importance of extensive validation of each individual system for each radionuclide and clinically-used sample geometry.
Theragnostic applications
The present study sets the first reference on typical combined errors associated to clinical radiopharmaceutical activity measurements in a theragnostic setting. Considering 5 clinically-relevant theragnostic pairs (131I/123I, 131I/124I, 177Lu/111In, 90Y/99mTc, 90Y/111In), this intercomparison study showed that poor accuracy in radionuclide calibrator activity measurements of therapeutic and diagnostic radionuclides can introduce a relatively large (> ±10%) bias in the therapeutic doses delivered to patients in theragnostic applications. Such errors should be minimized as much as practically possible, therefore the recommendation to apply a standard ±5% accuracy limit to calibrator activity measurements of both therapeutic and diagnostic radionuclides.
The best way to limit the error in the administration of activity is to ensure accurate and reproducible activity measurements of both radionuclides involved in the theragnostic application. This can be achieved by proper evaluation of the accuracy of the measurement settings of the calibrators for the radionuclides and sample configurations found in clinical practice, together with an assessment of other sources of uncertainty in the activity measurements and proper maintenance through a quality assurance program [6]. These procedures may lead to re-calibration of the device or determination of appropriate correction factors, and optimization of the source configurations (e.g. choice of container) or other measurement settings or procedures used for activity measurements. After all, the error in the assessment of patient administered activities is only one of the several sources of uncertainty in the dosimetry process [25]. Minimizing its contribution to the overall uncertainty is the best starting point towards patient treatment optimization in molecular radiotherapy.
Uncertainties in the clinical activity measurements of this study
As reported in detail by Gadd et al [5], radioactivity measurements using radionuclide calibrators are affected by different sources of uncertainty, including: the accuracy of calibration factors, sample geometry effects, photon-emitting radionuclide impurities, background variability, system non-linear response, short-term response variability, reproducibility of sample position, influence of external shielding, etc. These uncertainty components are dependent on the specific measurement set-up (calibrator unit and its accessories, shielding, local background field), the radionuclide and/or the level of activity (ionization current) being measured.
In this study the clinical measurement accuracy of radionuclide calibrators was tested for 7 radionuclides used in theragnostics, each in 4 sample configurations.
The effect of the sample type of container (syringe vs vial) was evaluated. As previously addressed, this effect was a significant source of variability in the activity measurements of all the radionuclides, with the magnitude of the effect (median) being large (> ±5%) for 90Y, 123I, 111In and 124I, mostly small (±2%) for 131I and 99mTc, and small (±1%) for 177Lu.
The influence of the short-term response variability in the activity measurements was reduced by taking the average of three consecutive activity readings. Although the measurement statistical uncertainty um was within 0.7% for the large majority (> 75%) of the activity datasets, which indicates a good short-term measurement reproducibility; it is not negligible and in a clinical setting (where an average value is generally not estimated) would cause a spread in the activity assessment.
The background reading was subtracted from all activity measurements. Yet, the uncertainty due to background variability was not assessed. This uncertainty can have an important bearing in the measurement of low activities and radionuclides with a low response per unit activity, such as 90Y. In this study the highest background-to-sample reading ratios were obtained, as expected, with the vials with 1 mL (samples with low activity), and were ≤ 3.7% for 90Y, 1.7% for 177Lu and 0.9% for the other radionuclides. For the vials filled with 10 mL (samples with the highest activity) background fractions were considerably lower (less or equal to 0.6% for 90Y and 0.2% for the other radionuclides). Assuming a high uncertainty of 10% in the background measurement, the potential error introduced in the estimated net activities of the low-activity vial samples of this study would be ≤ ±0.38% (90Y), ±0.17% (177Lu) and ±0.09% (other radionuclides). Although such potential error is not negligible for 90Y and 177Lu, it is much lower compared to the measurement deviations observed in this intercomparison for the vial and syringe samples with 1-3 mL, suggesting that it is not the main cause of the spread in 90Y and 177Lu measurements of the samples with the lowest activities. For the other samples and radionuclides the potential error from the background uncertainty is negligible.
All radionuclide solutions were checked for the presence of photon-emitting impurities by high-resolution gamma spectrometry. Impurities were detected only in 123I (125I), 124I (125I) and 177Lu (177mLu). From these impurities, only the 177mLu impurity has a significant effect on activity measurements in a radionuclide calibrator (0.51% over-response for the Fidelis). Since the activities measured with the hospital calibrators were not corrected for this effect, this remains a source of uncertainty in the 177Lu intercomparison results.
Information regarding other sources of uncertainty was not gathered from the participating hospitals. Yet, hospitals were encouraged to make a more detailed uncertainty assessment for their activity measurements, since this is essential to evaluate the agreement with the reference values and determine which corrective actions are needed to improve the accuracy and reliability of their activity measurements. In general, that assessment should be within the practical reach of hospitals, since most of the sources of error mentioned above can be quantified by following a thorough quality control program [5,6,8].
Study limitations
It should be noted that not all the calibrator systems tested were clinically used to measure all the radionuclides considered in this study. Since hospitals may validate a device only for the specific radionuclides used in their clinical practice, some specific results of this study may not fully represent the local (hospital) measurement capability.
Clinical activity measurements can bear additional uncertainties beyond those accounted in this study. The amounts of activities administered to patients in nuclear medicine theragnostics are in the range of tens to several hundred MBq for imaging studies and a couple to several GBq for therapeutic purposes, whereas in this study the sample activities were in the range of 4–162 MBq for diagnostic radionuclides and 9–312 MBq for therapeutic radionuclides (see values per radionuclide in Table 1). Linearity effects, which are typically in the range of ± 1% to few percent [3,5], become more important for the much broader range of activities measured in clinical applications. Also, in clinical practice therapeutic and diagnostic radionuclides are often not measured using the same (sample) measurement geometry. For instance, 90Y is often assayed using manufacturer-supplied vials and/or acrylic shields. Indeed, the (combined) errors in theragnostic activity measurements will depend on the specific measurement settings used for each radionuclide. Moreover, the response of a radionuclide calibrator to 90Y also depends on the physicochemical form of the 90Y compound [26]. In this study 90Y samples were prepared based on a 90Y chloride aqueous solution. Yet, in liver radioembolization procedures, which represent the main clinical application of the theragnostic pair 90Y/99mTc, 90Y is administered to patients in the form of suspensions of resin/glass microspheres. Activity measurements of 90Y microspheres may require the use of different calibration factors and present further challenges whose associated errors might not be reflected in the overall measurement performance obtained here using 90Y chloride.