TY - JOUR A1 - Lassmann, Michael A1 - Eberlein, Uta T1 - Comparing absorbed doses and radiation risk of the α-emitting bone-seekers [\(^{223}\)Ra]RaCl\(_2\) and [\(^{224}\)Ra]RaCl\(_2\) JF - Frontiers in Medicine N2 - [\(^{223}\)Ra]RaCl\(_2\) and [\(^{224}\)Ra]RaCl\(_2\) are bone seekers, emitting high LET, and short range (< 100 μm) alpha-particles. Both radionuclides show similar decay properties; the total alpha energies are comparable (\(^{223}\)Ra: ≈28 MeV, \(^{224}\)Ra: ≈26 MeV). [\(^{224}\)Ra]RaCl\(_2\) has been used from the mid-1940s until 1990 for treating different bone and joint diseases with activities of up to approximately 50 MBq [\(^{224}\)Ra]RaCl\(_2\). In 2013 [\(^{223}\)Ra]RaCl\(_2\) obtained marketing authorization by the FDA and by the European Union for the treatment of metastatic prostate cancer with an activity to administer of 0.055 MBq per kg body weight for six cycles. For intravenous injections in humans a model calculation using the biokinetic model of ICRP67 shows a ratio of organ absorbed dose coefficients (\(^{224}\)Ra:\(^{223}\)Ra) between 0.37 (liver) and 0.97 except for the kidneys (2.27) and blood (1.57). For the red marrow as primary organ-at-risk, the ratio is 0.57. The differences are mainly caused be the differing half-lives of the decay products of both radium isotopes. Both radionuclides show comparable DNA damage patterns in peripheral blood mononuclear cells after internal ex-vivo irradiation. Data on the long-term radiation-associated side effects are only available for treatment with [\(^{224}\)Ra]RaCl\(_2\). Two epidemiological studies followed two patient groups treated with [\(^{224}\)Ra]RaCl\(_2\) for more than 25 years. One of them was the “Spiess study”, a cohort of 899 juvenile patients who received several injections of [\(^{224}\)Ra]RaCl\(_2\) with a mean specific activity of 0.66 MBq/kg. Another patient group of ankylosing spondylitis patients was treated with 10 repeated intravenous injections of [\(^{224}\)Ra]RaCl\(_2\), 1 MBq each, 1 week apart. In total 1,471 of these patients were followed-up in the “Wick study”. In both studies, an increased cancer mortality by leukemia and solid cancers was observed. Similar considerations on long-term effects likely apply to [\(^{223}\)Ra]RaCl\(_2\) as well since the biokinetics are similar and the absorbed doses in the same range. However, this increased risk will most likely not be observed due to the much shorter life expectancy of prostate cancer patients treated with [\(^{223}\)Ra]RaCl\(_2\). KW - dosimetry KW - biodosimetry KW - 224Ra KW - 223Ra KW - epidemiology Y1 - 2023 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-301509 SN - 2296-858X VL - 9 ER - TY - JOUR A1 - Schumann, S. A1 - Eberlein, U. A1 - Lapa, C. A1 - Müller, J. A1 - Serfling, S. A1 - Lassmann, M. A1 - Scherthan, H. T1 - α-Particle-induced DNA damage tracks in peripheral blood mononuclear cells of [\(^{223}\)Ra]RaCl\(_{2}\)-treated prostate cancer patients JF - European Journal of Nuclear Medicine and Molecular Imaging N2 - Purpose One therapy option for prostate cancer patients with bone metastases is the use of [\(^{223}\)Ra]RaCl\(_{2}\). The α-emitter \(^{223}\)Ra creates DNA damage tracks along α-particle trajectories (α-tracks) in exposed cells that can be revealed by immunofluorescent staining of γ-H2AX+53BP1 DNA double-strand break markers. We investigated the time- and absorbed dose-dependency of the number of α-tracks in peripheral blood mononuclear cells (PBMCs) of patients undergoing their first therapy with [\(^{223}\)Ra]RaCl\(_{2}\). Methods Multiple blood samples from nine prostate cancer patients were collected before and after administration of [\(^{223}\)Ra]RaCl\(_{2}\), up to 4 weeks after treatment. γ-H2AX- and 53BP1-positive α-tracks were microscopically quantified in isolated and immuno-stained PBMCs. Results The absorbed doses to the blood were less than 6 mGy up to 4 h after administration and maximally 16 mGy in total. Up to 4 h after administration, the α-track frequency was significantly increased relative to baseline and correlated with the absorbed dose to the blood in the dose range < 3 mGy. In most of the late samples (24 h - 4 weeks after administration), the α-track frequency remained elevated. Conclusion The γ-H2AX+53BP1 assay is a potent method for detection of α-particle-induced DNA damages during treatment with or after accidental incorporation of radionuclides even at low absorbed doses. It may serve as a biomarker discriminating α- from β-emitters based on damage geometry. KW - γ-H2AX KW - DNA damage KW - nuclear medicine KW - dosimetry KW - α-Emitter KW - biokinetics KW - prostate cancer KW - [\(^{223}\)Ra]RaCl\(_{2}\) KW - 53BP1 Y1 - 2021 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-265462 SN - 1619-7089 VL - 48 IS - 9 ER - TY - JOUR A1 - Aerts, An A1 - Eberlein, Uta A1 - Holm, Sören A1 - Hustinx, Roland A1 - Konijnenberg, Mark A1 - Strigari, Lidia A1 - van Leeuwen, Fijs W. B. A1 - Glatting, Gerhard A1 - Lassmann, Michael T1 - EANM position paper on the role of radiobiology in nuclear medicine JF - European Journal of Nuclear Medicine and Molecular Imaging N2 - With an increasing variety of radiopharmaceuticals for diagnostic or therapeutic nuclear medicine as valuable diagnostic or treatment option, radiobiology plays an important role in supporting optimizations. This comprises particularly safety and efficacy of radionuclide therapies, specifically tailored to each patient. As absorbed dose rates and absorbed dose distributions in space and time are very different between external irradiation and systemic radionuclide exposure, distinct radiation-induced biological responses are expected in nuclear medicine, which need to be explored. This calls for a dedicated nuclear medicine radiobiology. Radiobiology findings and absorbed dose measurements will enable an improved estimation and prediction of efficacy and adverse effects. Moreover, a better understanding on the fundamental biological mechanisms underlying tumor and normal tissue responses will help to identify predictive and prognostic biomarkers as well as biomarkers for treatment follow-up. In addition, radiobiology can form the basis for the development of radiosensitizing strategies and radioprotectant agents. Thus, EANM believes that, beyond in vitro and preclinical evaluations, radiobiology will bring important added value to clinical studies and to clinical teams. Therefore, EANM strongly supports active collaboration between radiochemists, radiopharmacists, radiobiologists, medical physicists, and physicians to foster research toward precision nuclear medicine. KW - radionuclide therapy KW - radiobiology KW - dosimetry KW - biodosimetry KW - biomarkers Y1 - 2021 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-265595 VL - 48 IS - 11 ER - TY - THES A1 - Schumann, Sarah T1 - Zeit- und Dosisabhängigkeit von DNA-Schäden induziert durch interne Bestrahlung mit unterschiedlichen Radionukliden T1 - Time and dose dependence of DNA damage induced by internal irradiation with various radionuclides N2 - In der Nuklearmedizin werden radioaktive Substanzen eingesetzt, um zu therapeutischen Zwecken gezielt bösartiges Gewebe zu zerstören oder in diagnostischen Anwendungen Stoffwechselvorgänge bildlich darzustellen. Die ionisierende Strahlung der eingesetzten Radionuklide kann jedoch auch DNA-Schäden in gesunden Zellen verursachen. DNA-Doppelstrangbrüche gehören dabei zu den kritischsten Läsionen, da sie schwer zu reparieren sind und eine fehlerhafte Reparatur zu Mutationen oder zum Zelltod führen kann. Während Radionuklidtherapien ist daher in Risikoorganen darauf zu achten, dass die deponierte Energie pro Masse, die Energiedosis, bestimmte Werte nicht überschreitet. Zu diesen Risikoorganen gehört auch das blutbildende System. Da eine Abschätzung der Energiedosis im Knochenmark häufig über die Bestimmung der Energiedosis im Blut als Surrogat erfolgt, ist deren Kenntnis von besonderem Interesse. In dieser Arbeit wurden daher Berechnungen der Energiedosis im Blut nach interner Bestrahlung durchgeführt und die Ergebnisse mit der Anzahl an strahlungsinduzierten DNA-Doppelstrangbrüchen in PBMCs korreliert. Zur Quantifizierung der DNA-Schäden wurden die Biomarker \(\gamma\)-H2AX und 53BP1 verwendet, die nach Entstehung eines Doppelstrangbruchs um diesen akkumulieren und sich durch Immunfluoreszenzfärbung als mikroskopische Foci sichtbar machen und quantifizieren lassen. Dadurch ermöglicht der \(\gamma\)-H2AX+53BP1-Assay einen quantitativen Nachweis strahlungsinduzierter Doppelstrangbrüche. Somit konnten im Rahmen dieser Arbeit neue Kenntnisse über die Dosisabhängigkeit von DNA-Schäden in PBMCs während interner Bestrahlung mit unterschiedlichen Radionukliden sowohl ex vivo als auch in vivo gewonnen werden. Ex-vivo-Untersuchungen haben den Vorteil, dass sie unter gleichbleibenden, gut definierten Bedingungen durchgeführt werden können und somit eine Analyse der Induktion von Doppelstrangbrüchen bei festgelegten Energiedosen und einer konstanten Bestrahlungsdauer erlauben. In dieser Arbeit wurden Blutproben von gesunden Versuchspersonen durch Zugabe von Radionukliden in bestimmten Aktivitätskonzentrationen eine Stunde lang intern bestrahlt. Für die Bestrahlung wurden die \(\alpha\)-Emitter \(^{223}\)Ra und \(^{224}\)Ra, die \(\beta\)\(^{-}\)-Emitter \(^{177}\)Lu und \(^{90}\)Y, der \(\beta\)\(^{+}\)-Emitter \(^{68}\)Ga und der \(\gamma\)-Emitter \(^{99m}\)Tc verwendet. Der untersuchte Energiedosisbereich lag zwischen 5 mGy und 136 mGy. Nach der Bestrahlung von Blutproben mit \(\beta\)- beziehungsweise \(\gamma\)-Emittern wurde beobachtet, dass die Anzahl der strahlungsinduzierten \(\gamma\)-H2AX+53BP1-Foci (RIF) in den PBMCs linear mit der Energiedosis im Blut ansteigt. Zudem zeigte sich, dass die Induktion der RIF unabhängig vom verwendeten Radionuklid und unabhängig von der Versuchsperson ist. Nach der Bestrahlung von Blutproben mit \(\alpha\)-Emittern waren zusätzlich zu den nach Expositionen mit \(\beta\)- beziehungsweise \(\gamma\)-Emittern beobachteten kleinen, runden Foci auch \(\gamma\)-H2AX+53BP1 enthaltende Spuren \(\alpha\)-Spuren) in den Zellkernen erkennbar, welche die Trajektorien der emittierten \(\alpha\)-Teilchen darstellten. Es konnte gezeigt werden, dass die Anzahl dieser \(\alpha\)-Spuren linear mit der Energiedosis im Blut zunimmt und damit ein geeigneter Parameter für die Biodosimetrie nach Expositionen mit \(\alpha\)-emittierenden Radionukliden ist. Auch in vivo wurde die Dosisabhängigkeit der DNA-Doppelstrangbrüche während der internen Bestrahlung durch Radionuklide mit unterschiedlichen Emissionseigenschaften untersucht. Aufgrund der neuen, vielversprechenden Entwicklungen von Radiopharmaka zur Therapie und Diagnostik des Prostatakarzinoms in den letzten Jahren wurden dafür Blutproben von Prostatakarzinom-Patienten während Therapie mit [\(^{177}\)Lu]Lu-PSMA I&T, während PET/CT-Diagnostik mit [\(^{68}\)Ga]Ga-PSMA I&T und während Therapie mit [\(^{223}\)Ra]RaCl\(_2\) untersucht. Während Therapie mit [\(^{177}\)Lu]Lu-PSMA I&T zeigte sich, dass die Anzahl der RIF in den ersten Stunden nach Therapiebeginn durch eine lineare Anpassungskurve angenähert werden kann, die mit der Energiedosis im Blut ansteigt, gefolgt von einem Rückgang der RIF zu späteren Zeitpunkten, der durch die DNA-Reparatur erklärt werden kann. Die gesamte Energiedosis im Blut lag im Mittel bei (109 \(\pm\) 28) mGy. Der linear dosisabhängige Anstieg der RIF zu Therapiebeginn gleicht der dosisabhängigen Induktion der RIF ex vivo nach Bestrahlung mit \(\beta\)- und \(\gamma\)-emittierenden Radionukliden und kann gut mit der entsprechenden Ex-vivo-Kalibrierkurve beschrieben werden. Zu späteren Zeitpunkten (48 h und 96 h nach Verabreichung) konnte in dieser Arbeit eine lineare Korrelation zwischen der Anzahl der noch verbleibenden RIF und der Dosisleistung nachgewiesen werden. Eine signifikante Korrelation der Anzahl der RIF 96 h nach Verabreichung mit dem PSA-Wert deutet zudem darauf hin, dass ein Zusammenhang mit klinischen Parametern besteht. Ein signifikanter Anstieg der \(\gamma\)-H2AX+53BP1-Foci konnte auch nach Verabreichung von [\(^{68}\)Ga]Ga-PSMA I&T für diagnostische PET/CT-Untersuchungen beobachtet werden, obwohl die Energiedosen im Blut bis zum PET/CT-Scan nur < 3 mGy betrugen. Im Vergleich zur Ex-vivo-Kalibrierkurve war die Steigung der linearen Anpassungskurve in vivo im Bereich < 3 mGy in dieser Studie etwa um ein Zehnfaches höher, was auf eine mögliche Hypersensitivität im Niedrigdosisbereich hindeuten könnte. Der Beitrag der CT zur Energiedosis im Blut konnte durch Ex-vivo-Experimente auf etwa 12 mGy abgeschätzt werden. Auch während Therapie mit [\(^{223}\)Ra]RaCl\(_2\) lagen die berechneten Energiedosen im Blut im Niedrigdosisbereich < 17 mGy. Trotzdem konnten in dieser Studie erstmalig \(\alpha\)-Spuren in vivo nach der Verabreichung eines \(\alpha\)-emittierenden Radionuklids quantifiziert werden, deren Anzahl 3 h und 4 h nach Verabreichung des Radiopharmakons signifikant erhöht war. Auch zu späten Zeitpunkten, bis vier Wochen nach Therapiebeginn, waren noch \(\alpha\)-Spuren nachweisbar, was auf eine unvollständige Reparatur der komplexen, durch die \(\alpha\)-Teilchen induzierten DNA-Schäden hinweisen könnte. Leider erlaubte die geringe Anzahl an Patienten und Datenpunkten keine zuverlässigen Korrelationen mit der Energiedosis oder mit klinischen Parametern. Nachdem in dieser Arbeit gezeigt werden konnte, dass DNA-Schäden nach interner Bestrahlung mit \(\alpha\)-, \(\beta\)- und \(\gamma\)-emittierenden Radionukliden mit Hilfe des \(\gamma\)-H2AX+53BP1-Assays zuverlässig nachgewiesen und anhand der Schadensgeometrie unterschieden werden können, wäre es in Zukunft interessant, DNA-Schäden auch nach Bestrahlung mit Radionuklidgemischen zu untersuchen. Dies könnte sowohl im Hinblick auf den Nachweis von Inkorporationen bei Strahlenunfällen hilfreich sein als auch zu einem besseren Verständnis der Effekte bei Behandlungen mit Radionuklidgemischen beitragen, welche vielversprechende Möglichkeiten für nuklearmedizinische Therapien bieten. Zudem zeigen die Ergebnisse dieser Arbeit, dass insbesondere im für die Diagnostik relevanten Bereich sehr niedriger Energiedosen < 10 mGy weiterer Forschungsbedarf besteht. Durch die Untersuchung der dosisabhängigen Reparatur der durch interne Bestrahlung induzierten DNA-Schäden könnte beispielsweise analysiert werden, ob die Reparaturfähigkeit im Niedrigdosisbereich eingeschränkt ist. Außerdem wäre es gerade im Bereich niedriger Dosen von Interesse, zu untersuchen, inwiefern Beobachtungen ex vivo das Verhalten in vivo geeignet repräsentieren. Um die erhöhten statistischen Unsicherheiten im Niedrigdosisbereich zu reduzieren, könnten zukünftig Verbesserungen auf dem Gebiet der automatisierten Auswertung der \(\gamma\)-H2AX+53BP1 enthaltenden Foci und Spuren hilfreich sein. Weitere Ziele zukünftiger Forschungsvorhaben könnten gezielte Untersuchungen zu Korrelationen zwischen der dosisabhängigen Induktion und Reparatur von DNA-Schäden und klinischen Parametern sowie die Analyse von DNA-Schäden während mehrerer Therapiezyklen darstellen. In Zusammenhang mit der Analyse klinischer Parameter wäre es denkbar, dass biodosimetrische Auswertungen zukünftig auch zur personalisierten Therapieplanung oder auch zur Vorhersage des Therapieerfolgs dienen und somit langfristig zu einer Optimierung nuklearmedizinischer Therapien beitragen könnten. N2 - In nuclear medicine, radioactive substances are applied for therapeutic purposes to destroy malignant tissue, or in diagnostic applications to visualize metabolic processes. However, the ionizing radiation of the applied radionuclides can also cause DNA damage in healthy cells. Among these, DNA double-strand breaks belong to the most critical lesions because they are difficult to repair and misrepair can lead to mutations or cell death. Therefore, during radionuclide therapies, it is of great importance to ensure that the deposited energy per mass, the absorbed dose, does not exceed certain values in organs at risk. One of these organs at risk is the hematopoietic system. As the absorbed dose to the bone marrow is often estimated by determining the absorbed dose to the blood as a surrogate, knowledge of the latter is of particular interest. Therefore, in this thesis, calculations of the absorbed dose to the blood after internal irradiation were performed and the results were correlated with the number of radiation-induced DNA double-strand breaks in PBMCs. To quantify DNA damage, the biomarkers \(\gamma\)-H2AX and 53BP1 were used, which accumulate around a double-strand break after its formation and which can be visualized and quantified as microscopic foci by immunofluorescence staining. Consequently, the \(\gamma\)-H2AX+53BP1 assay allows a quantitative detection of radiation-induced double-strand breaks. Thus, by combining absorbed dose calculations with a quantitative analysis of DNA damage in PBMCs during internal irradiation with various radionuclides both ex vivo and in vivo, new knowledge was gained in the context of this work. Ex-vivo examinations have the advantage that they can be carried out under constant, well-defined conditions and thus allow an analysis of the induction of double-strand breaks at preset absorbed doses and a constant irradiation duration. In this work, blood samples from healthy test persons were internally irradiated for one hour by adding radionuclides at defined activity concentrations. For the irradiation, the \(\alpha\)-emitters \(^{223}\)Ra and \(^{224}\)Ra, the \(\beta\)\(^{-}\)-emitters \(^{177}\)Lu and \(^{90}\)Y, the \(\beta\)\(^{+}\)-emitter \(^{68}\)Ga and the \(\gamma\)-emitter \(^{99m}\)Tc were used. The absorbed dose ranged from 5 mGy to 136 mGy. After irradiating blood samples with \(\beta\)- and \(\gamma\)-emitters, it was observed that the number of radiation-induced \(\gamma\)-H2AX+53BP1 foci (RIF) in the PBMCs increases linearly with the absorbed dose to the blood. Furthermore, it was shown that the induction of RIF is independent of the radionuclide applied and the test person. After irradiating blood samples with \(\alpha\)-emitters, in addition to the small round foci observed after exposure to \(\beta\)- and \(\gamma\)-emitters, \(\gamma\)-H2AX+53BP1 containing tracks (\(\alpha\)-tracks) were visible in the nuclei, which represented the trajectories of the emitted \(\alpha\)-particles. It was shown that the number of these \(\alpha\)-tracks increases linearly with the absorbed dose to the blood and is, therefore, a suitable parameter for biodosimetry after exposure to \(\alpha\)-emitting radionuclides. The absorbed dose dependence of DNA double-strand breaks during internal irradiation with radionuclides with different emission properties was also investigated in vivo. Due to the promising new developments of radiopharmaceuticals for therapy and diagnostics of prostate cancer in recent years, blood samples from prostate cancer patients were examined during therapy with [\(^{177}\)Lu]Lu-PSMA I&T, during PET/CT diagnostics with [\(^{68}\)Ga]Ga-PSMA I&T and during therapy with [\(^{223}\)Ra]RaCl\(_2\). During therapy with [\(^{177}\)Lu]Lu-PSMA I&T, it was shown that the number of RIF in the first hours after therapy start can be approximated by a linear fitting curve, which increases with the absorbed dose to the blood, followed by a decrease in RIF at later time points, which can be explained by DNA repair. The total absorbed dose to the blood was (109 \(\pm\) 28) mGy on average. The linear absorbed dose-dependent increase in RIF at the beginning of therapy is similar to the absorbed dose-dependent induction of RIF ex vivo after irradiation with \(\beta\)- and \(\gamma\)-emitting radionuclides and can be well described with the corresponding ex-vivo calibration curve. At later time points (48 h and 96 h after administration), a linear correlation between the number of remaining RIF and the dose rate was demonstrated in this work. A significant correlation of the number of RIF 96 h after administration with PSA levels also suggests a link to clinical parameters. A significant increase in \(\gamma\)-H2AX+53BP1 foci was also observed after administration of [\(^{68}\)Ga]Ga-PSMA I&T for diagnostic PET/CT examinations, despite the fact that absorbed doses to the blood were only < 3 mGy by the time of the PET/CT scan. Compared to the ex-vivo calibration curve, the slope of the linear in-vivo fitting curve in the range < 3 mGy in this study was approximately ten times higher, which may indicate a possible hypersensitivity in the low dose range. The contribution of the CT to the absorbed dose to the blood was estimated at approximately 12 mGy by ex-vivo experiments. During therapy with [\(^{223}\)Ra]RaCl\(_2\), the calculated absorbed doses to the blood were also in the low dose range < 17 mGy. Nevertheless, this study was the first to quantify \(\alpha\)-tracks in vivo after the administration of an \(\alpha\)-emitting radionuclide, with a significantly increased number of \(\alpha\)-tracks 3 h and 4 h after administration of the radiopharmaceutical. Even at late time points, up to four weeks after therapy start, \(\alpha\)-tracks were still detectable, which could indicate incomplete repair of the complex DNA damage induced by \(\alpha\)-particles. Unfortunately, the small number of patients and data points did not allow reliable correlations with the absorbed dose or clinical parameters. In this thesis, it was shown that DNA damage after internal irradiation with \(\alpha\)-, \(\beta\)- and \(\gamma\)-emitting radionuclides can be reliably detected by applying the \(\gamma\)-H2AX+53BP1 assay and distinguished by damage geometry. For future work, it would be of interest to additionally investigate DNA damage after irradiation with mixtures of radionuclides. This could be helpful for the detection of incorporations after radiation accidents, and could also contribute to a better understanding of the effects of therapeutic applications of radionuclide mixtures, which offer promising opportunities for nuclear medicine therapies. Furthermore, the results of this work show that there is need for further research, especially in the very low dose range < 10 mGy, which is relevant for diagnostics. By investigating the absorbed dose-dependent repair of DNA damage induced by internal irradiation, for example, it could be analyzed whether the repair capability is limited in the low dose range. Particularly in the range of low doses, it would also be of interest to investigate to what extent observations ex vivo adequately represent the behavior in vivo. In order to reduce the increased statistical uncertainties in the low dose range, future improvements in the field of automated evaluation of \(\gamma\)-H2AX+53BP1 containing foci and tracks could be helpful. Further objectives of future research projects could be investigations focussing on correlations between the absorbed dose-dependent induction and repair of DNA damage and clinical parameters as well as an analysis of DNA damage over several therapy cycles. In the context of the analysis of clinical parameters, it is conceivable that biodosimetric assessments could enhance personalized treatment planning or the prediction of therapy success, thus contributing, in the long-term, to an optimization of nuclear medicine therapies. KW - Nuklearmedizin KW - Dosimetrie KW - Radionuklid KW - DNS-Doppelstrangbruch KW - Biomarker KW - Medizinphysik KW - gamma-H2AX KW - 53BP1 KW - nuclear medicine KW - dosimetry KW - radionuclide KW - DNA damage KW - medical physics Y1 - 2022 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-223904 ER - TY - JOUR A1 - Konijnenberg, Mark A1 - Herrmann, Ken A1 - Kobe, Carsten A1 - Verburg, Frederik A1 - Hindorf, Cecilia A1 - Hustinx, Roland A1 - Lassmann, Michael T1 - EANM position paper on article 56 of the Council Directive 2013/59/Euratom (basic safety standards) for nuclear medicine therapy JF - European Journal of Nuclear Medicine and Molecular Imaging N2 - The EC Directive 2013/59/Euratom states in article 56 that exposures of target volumes in nuclear medicine treatments shall be individually planned and their delivery appropriately verified. The Directive also mentions that medical physics experts should always be appropriately involved in those treatments. Although it is obvious that, in nuclear medicine practice, every nuclear medicine physician and physicist should follow national rules and legislation, the EANM considered it necessary to provide guidance on how to interpret the Directive statements for nuclear medicine treatments. For this purpose, the EANM proposes to distinguish three levels in compliance to the optimization principle in the directive, inspired by the indication of levels in prescribing, recording and reporting of absorbed doses after radiotherapy defined by the International Commission on Radiation Units and Measurements (ICRU): Most nuclear medicine treatments currently applied in Europe are standardized. The minimum requirement for those treatments is ICRU level 1 (“activity-based prescription and patient-averaged dosimetry”), which is defined by administering the activity within 10% of the intended activity, typically according to the package insert or to the respective EANM guidelines, followed by verification of the therapy delivery, if applicable. Non-standardized treatments are essentially those in developmental phase or approved radiopharmaceuticals being used off-label with significantly (> 25% more than in the label) higher activities. These treatments should comply with ICRU level 2 (“activity-based prescription and patient-specific dosimetry”), which implies recording and reporting of the absorbed dose to organs at risk and optionally the absorbed dose to treatment regions. The EANM strongly encourages to foster research that eventually leads to treatment planning according to ICRU level 3 (“dosimetry-guided patient-specific prescription and verification”), whenever possible and relevant. Evidence for superiority of therapy prescription on basis of patient-specific dosimetry has not been obtained. However, the authors believe that a better understanding of therapy dosimetry, i.e. how much and where the energy is delivered, and radiobiology, i.e. radiation-related processes in tissues, are keys to the long-term improvement of our treatments. KW - nuclear medicine therapy KW - dosimetry KW - optimization KW - BSS directive Y1 - 2021 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-235280 SN - 1619-7070 VL - 48 ER - TY - JOUR A1 - Wegener, Sonja A1 - Herzog, Barbara A1 - Sauer, Otto A. T1 - Detector response in the buildup region of small MV fields JF - Medical Physics N2 - Purpose: The model used to calculate dose distributions in a radiotherapy treatment plan relies on the data entered during beam commissioning. The quality of these data heavily depends on the detector choice made, especially in small fields and in the buildup region. Therefore, it is necessary to identify suitable detectors for measurements in the buildup region of small fields. To aid the understanding of a detector's limitations, several factors that influence the detector signal are to be analyzed, for example, the volume effect due to the detector size, the response to electron contamination, the signal dependence on the polarity used, and the effective point of measurement chosen. Methods: We tested the suitability of different small field detectors for measurements of depth dose curves with a special focus on the surface‐near area of dose buildup for fields sized between 10 × 10 and 0.6 × 0.6 cm\(^{2}\). Depth dose curves were measured with 14 different detectors including plane‐parallel chambers, thimble chambers of different types and sizes, shielded and unshielded diodes as well as a diamond detector. Those curves were compared with depth dose curves acquired on Gafchromic film. Additionally, the magnitude of geometric volume corrections was estimated from film profiles in different depths. Furthermore, a lead foil was inserted into the beam to reduce contaminating electrons and to study the resulting changes of the detector response. The role of the effective point of measurement was investigated by quantifying the changes occurring when shifting depth dose curves. Last, measurements for the small ionization chambers taken at opposing biasing voltages were compared to study polarity effects. Results: Depth‐dependent correction factors for relative depth dose curves with different detectors were derived. Film, the Farmer chamber FC23, a 0.13 cm\(^{3}\) scanning chamber CC13 and a plane‐parallel chamber PPC05 agree very well in fields sized 4 × 4 and 10 × 10 cm\(^{2}\). For most detectors and in smaller fields, depth dose curves differ from the film. In general, shielded diodes require larger corrections than unshielded diodes. Neither the geometric volume effect nor the electron contamination can account for the detector differences. The biggest uncertainty arises from the positioning of a detector with respect to the water surface and from the choice of the detector's effective point of measurement. Depth dose curves acquired with small ionization chambers differ by over 15% in the buildup region depending on sign of the biasing voltage used. Conclusions: A scanning chamber or a PPC40 chamber is suitable for fields larger than 4 × 4 cm\(^{2}\). Below that field size, the microDiamond or small ionization chambers perform best requiring the smallest corrections at depth as well as in the buildup region. Diode response changes considerably between the different types of detectors. The position of the effective point of measurement has a huge effect on the resulting curves, therefore detector specific rather than general shifts of half the inner radius of cylindrical ionization chambers for the effective point of measurement should be used. For small ionization chambers, averaging between both polarities is necessary for data obtained near the surface. KW - buildup region KW - diode KW - dosimetry KW - microionization chambers KW - percent depth dose curves Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-214228 VL - 47 IS - 3 ER - TY - JOUR A1 - Schumann, Sarah A1 - Scherthan, Harry A1 - Frank, Torsten A1 - Lapa, Constantin A1 - Müller, Jessica A1 - Seifert, Simone A1 - Lassmann, Michael A1 - Eberlein, Uta T1 - DNA Damage in Blood Leukocytes of Prostate Cancer Patients Undergoing PET/CT Examinations with [\(^{68}\)Ga]Ga-PSMA I&T JF - Cancers N2 - The aim was to investigate the induction and repair of radiation-induced DNA double-strand breaks (DSBs) as a function of the absorbed dose to the blood of patients undergoing PET/CT examinations with [68Ga]Ga-PSMA. Blood samples were collected from 15 patients before and at four time points after [68Ga]Ga-PSMA administration, both before and after the PET/CT scan. Absorbed doses to the blood were calculated. In addition, blood samples with/without contrast agent from five volunteers were irradiated ex vivo by CT while measuring the absorbed dose. Leukocytes were isolated, fixed, and stained for co-localizing γ-H2AX+53BP1 DSB foci that were enumerated manually. In vivo, a significant increase in γ-H2AX+53BP1 foci compared to baseline was observed at all time points after administration, although the absorbed dose to the blood by 68Ga was below 4 mGy. Ex vivo, the increase in radiation-induced foci depended on the absorbed dose and the presence of contrast agent, which could have caused a dose enhancement. The CT-dose contribution for the patients was estimated at about 12 mGy using the ex vivo calibration. The additional number of DSB foci induced by CT, however, was comparable to the one induced by 68Ga. The significantly increased foci numbers after [68Ga]Ga-PSMA administration may suggest a possible low-dose hypersensitivity. KW - DNA double-strand breaks KW - γ-H2AX KW - 53BP1 KW - nuclear medicine KW - dosimetry KW - Ga-68 KW - PSMA KW - PET/CT KW - contrast agent KW - prostate cancer Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-200585 SN - 2072-6694 VL - 12 IS - 2 ER - TY - JOUR A1 - Beykan, Seval A1 - Fani, Melpomeni A1 - Jensen, Svend Borup A1 - Nicolas, Guillaume A1 - Wild, Damian A1 - Kaufmann, Jens A1 - Lassmann, Michael T1 - In vivo biokinetics of \(^{177}\)Lu-OPS201 in Mice and Pigs as a Model for Predicting Human Dosimetry JF - Contrast Media & Molecular Imaging N2 - Introduction. \(^{177}\)Lu-OPS201 is a high-affinity somatostatin receptor subtype 2 antagonist for PRRT in patients with neuroendocrine tumors. The aim is to find the optimal scaling for dosimetry and to compare the biokinetics of \(^{177}\)Lu-OPS201 in animals and humans. Methods. Data on biokinetics of \(^{177}\)Lu-OPS201 were analyzed in athymic nude Foxn1\(^{nu}\) mice (28 F, weight: 26 ± 1 g), Danish Landrace pigs (3 F-1 M, weight: 28 ± 2 kg), and patients (3 F-1 M, weight: 61 ± 17 kg) with administered activities of 0.19–0.27 MBq (mice), 97–113 MBq (pigs), and 850–1086 MBq (patients). After euthanizing mice (up to 168 h), the organ-specific activity contents (including blood) were measured. Multiple planar and SPECT/CT scans were performed until 250 h (pigs) and 72 h (patients) to quantify the uptake in the kidneys and liver. Blood samples were taken up to 23 h (patients) and 300 h (pigs). In pigs and patients, kidney protection was applied. Time-dependent uptake data sets were created for each species and organ/tissue. Biexponential fits were applied to compare the biokinetics in the kidneys, liver, and blood of each species. The time-integrated activity coefficients (TIACs) were calculated by using NUKFIT. To determine the optimal scaling, several methods (relative mass scaling, time scaling, combined mass and time scaling, and allometric scaling) were compared. Results. A fast blood clearance of the compound was observed in the first phase (<56 h) for all species. In comparison with patients, pigs showed higher liver retention. Based on the direct comparison of the TIACs, an underestimation in mice (liver and kidneys) and an overestimation in pigs’ kidneys compared to the patient data (kidney TIAC: mice = 1.4 h, pigs = 7.7 h, and patients = 5.8 h; liver TIAC: mice = 0.7 h, pigs = 4.1 h, and patients = 5.3 h) were observed. Most similar TIACs were obtained by applying time scaling (mice) and combined scaling (pigs) (kidney TIAC: mice = 3.9 h, pigs = 4.8 h, and patients = 5.8 h; liver TIAC: mice = 0.9 h, pigs = 4.7 h, and patients = 5.3 h). Conclusion. If the organ mass ratios between the species are high, the combined mass and time scaling method is optimal to minimize the interspecies differences. The analysis of the fit functions and the TIACs shows that pigs are better mimicking human biokinetics. KW - medicine KW - neuroendocrine tumors KW - biokinetics KW - \(^{177}\)Lu-OPS201 KW - dosimetry Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-177382 VL - 2019 ER - TY - JOUR A1 - Soares Machado, J. A1 - Tran-Gia, J. A1 - Schlögl, S. A1 - Buck, A. K. A1 - Lassmann, M. T1 - Biokinetics, dosimetry, and radiation risk in infants after \(^{99m}\)Tc-MAG3 scans JF - EJNMMI Research N2 - Background: Renal scans are among the most frequent exams performed on infants and toddlers. Due to the young age, this patient group can be classified as a high-risk group with a higher probability for developing stochastic radiation effects compared to adults. As there are only limited data on biokinetics and dosimetry in this patient group, the aim of this study was to reassess the dosimetry and the associated radiation risk for infants undergoing \(^{99m}\)Tc-MAG3 renal scans based on a retrospective analysis of existing patient data. Consecutive data were collected from 20 patients younger than 20 months (14 males; 6 females) with normal renal function undergoing \(^{99m}\)Tc-MAG3 scans. To estimate the patient-specific organ activity, a retrospective calibration was performed based on a set of two 3D-printed infant kidneys filled with known activities. Both phantoms were scanned at different positions along the anteroposterior axis inside a water phantom, providing depth- and size-dependent attenuation correction factors for planar imaging. Time-activity curves were determined by drawing kidney, bladder, and whole-body regions-of-interest for each patient, and subsequently applying the calibration factor for conversion of counts to activity. Patient-specific time-integrated activity coefficients were obtained by integrating the organ-specific time-activity curves. Absorbed and effective dose coefficients for each patient were assessed with OLINDA/EXM for the provided newborn and 1-year-old model. The risk estimation was performed individually for each of the 20 patients with the NCI Radiation Risk Assessment Tool. Results: The mean age of the patients was 7.0 ± 4.5 months, with a weight between 5 and 12 kg and a body size between 60 and 89 cm. The injected activities ranged from 12 to 24 MBq of \(^{99m}\)Tc-MAG3. The patients' organ-specific mean absorbed dose coefficients were 0.04 ± 0.03 mGy/MBq for the kidneys and 0.27 ± 0.24 mGy/MBq for the bladder. The mean effective dose coefficient was 0.02 ± 0.02 mSv/MBq. Based on the dosimetry results, an evaluation of the excess lifetime risk for the development of radiation-induced cancer showed that the group of newborns has a risk of 16.8 per 100,000 persons, which is about 12% higher in comparison with the 1-year-old group with 14.7 per 100,000 persons (all values are given as mean plus/minus one standard deviation except otherwise specified). Conclusion: In this study, we retrospectively derived new data on biokinetics and dosimetry for infants with normal kidney function after undergoing renal scans with \(^{99m}\)Tc-MAG3. In addition, we analyzed the associated age- and gender-specific excess lifetime risk due to ionizing radiation. The radiation-associated stochastic risk increases with the organ doses, taking age- and gender-specific influences into account. Overall, the lifetime radiation risk associated with the \(^{99m}\)Tc-MAG3 scans is very low in comparison to the general population risk for developing cancer. KW - \(^{99m}\)Tc-MAG3 KW - absorbed dose KW - biokinetics KW - dosimetry KW - pediatric patients KW - risk assessment Y1 - 2018 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-175582 VL - 8 IS - 10 ER - TY - JOUR A1 - Beykan, Seval A1 - Dam, Jan S. A1 - Eberlein, Uta A1 - Kaufmann, Jens A1 - Kjærgaard, Benedict A1 - Jødal, Lars A1 - Bouterfa, Hakim A1 - Bejot, Romain A1 - Lassmann, Michael A1 - Jensen, Svend Borup T1 - \(^{177}\)Lu-OPS201 targeting somatostatin receptors: in vivo biodistribution and dosimetry in a pig model JF - EJNMMI Research N2 - Background \(^{177}\)Lu is used in peptide receptor radionuclide therapies for the treatment of neuroendocrine tumors. Based on the recent literature, SST2 antagonists are superior to agonists in tumor uptake. The compound OPS201 is the novel somatostatin antagonist showing the highest SST2 affinity. The aim of this study was to measure the in vivo biodistribution and dosimetry of \(^{177}\)Lu-OPS201 in five anesthetized Danish Landrace pigs as an appropriate substitute for humans to quantitatively assess the absorbed doses for future clinical applications. Results \(^{177}\)Lu-OPS201 was obtained with a specific activity ranging from 10 to 17 MBq/μg. Prior to administration, the radiochemical purity was measured as s > 99.7 % in all cases. After injection, fast clearance of the compound from the blood stream was observed. Less than 5 % of the injected activity was presented in blood 10 min after injection. A series of SPECT/CT and whole-body scans conducted until 10 days after intravenous injection showed uptake mostly in the liver, spine, and kidneys. There was no visible uptake in the spleen. Blood samples were taken to determine the time-activity curve in the blood. Time-activity curves and time-integrated activity coefficients were calculated for the organs showing visible uptake. Based on these data, the absorbed organ dose coefficients for a 70-kg patient were calculated with OLINDA/EXM. For humans after an injection of 5 GBq \(^{177}\)Lu-OPS201, the highest predicted absorbed doses are obtained for the kidneys (13.7 Gy), the osteogenic cells (3.9 Gy), the urinary bladder wall (1.8 Gy), and the liver (1.0 Gy). No metabolites of 177Lu-OPS201 were found by radio HPLC analysis. None of the absorbed doses calculated will exceed organ toxicity levels. Conclusions The \(^{177}\)Lu-OPS201 was well tolerated and caused no abnormal physiological or behavioral signs. In vivo distributions and absorbed doses of pigs are comparable to those observed in other publications. According to the biodistribution data in pigs, presented in this work, the expected radiation exposure in humans will be within the acceptable range. KW - lutetium-177 KW - JR11 KW - antagonist KW - dosimetry KW - neuroendocrine tumor (NET) KW - OPS201 KW - pig model KW - PRRT Y1 - 2016 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-146888 VL - 6 IS - 50 ER -