Technical Note: On the feasibility of performing dosimetry in target and organ at risk using polymer dosimetry gel and thermoluminescence detectors in an anthropomorphic, deformable, and multimodal pelvis phantom

Marot, M; Elter, A.; Mann, P.; Schwahofer, A.; Lang, Clemens; Johnen, W.; Körber, S; Beuthien‐Baumann, Bettina; Gillmann, Clarissa

doi:10.1002/mp.15096

Cited by 4 publications

(5 citation statements)

References 33 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…If the delivery under evaluation involves motion management, then the phantom will have to be able to be integrated into some commercial or in-house built motion testing system [129,130,178,179]. For some RT deliveries the E2E QA phantoms may need to be more anthropomorphic in external appearance (e.g., if the delivery requires phantom set-up in some patient immobilization system with set-up validation and repositioning) or to simulate internal structure heterogeneity with organ mimicking structures (e.g., if the E2E testing is being applied to RT delivery to specific anatomy and the assessment includes target conformity) [89,102,104,106,111,180,181]. The material for the phantom need not be exactly tissue or water equivalent although it should be similar to any organs of interest and should be well characterised by CT, and perhaps MR imaging, before use [174].…”

Section: Implementing In-house E2e Testing Into a Clinical Qm Programmentioning

confidence: 99%

End-to-End QA in Radiation Therapy Quality Management

Schreiner

2023

J. Phys.: Conf. Ser.

View full text Add to dashboard Cite

End-to-End (E2E) testing is a method originating from computer science that is designed to determine whether an application communicates as required with hardware, networks, databases, and other applications. This paper is to advocate that the quality management (QM) of modern radiation therapy (RT) would benefit from more regular use of E2E based quality assurance (QA) in the local clinic. The argument is that modern RT delivery is performed through some process linked by a chain of interdependent stages and actions mediated by complex interchanges during the patient’s treatment. These actions along the chain are often modified due to decisions by clinical staff who are interpreting information acquired along the process. While physics QA can validate that each of these steps are technically achievable (e.g., through machine QA) such conventional QA does not guarantee that the overall process is being carried out as planned even when it has been described by a well-defined protocol and delivered by well-trained staff. The paper briefly reviews the changes in programmatic design as RT has become more complex, the associated changes in RT QM, and some past examples of E2E testing in RT clinics, usually performed during the implementation of some new RT technique or during external audits of the clinic’s practice. The paper then makes the case for increased E2E QA based on the lessons learned from this experience and ends with some suggestions for implementing effective and sustainable E2E testing in a clinic’s QM program.

show abstract

Section: Implementing In-house E2e Testing Into a Clinical Qm Programmentioning

confidence: 99%

End-to-End QA in Radiation Therapy Quality Management

Schreiner

2023

J. Phys.: Conf. Ser.

View full text Add to dashboard Cite

show abstract

“…The experiment was carried out using the so-called ADAM-PETer (Anthropomorphic, Deformable And Multimodal pelvis phantom with positron emission tomography (PET) Extension for Radiotherapy), which was initially designed to perform a variety of different end-to-end tests in radiotherapy (Gillmann et al 2021, Marot et al 2021. In the present study, however, no PET measurements were performed and the included lymph node system was not used.…”

Section: Phantommentioning

confidence: 99%

“…Other studies have suggested the use of thermoluminescence detectors (TLDs) to renormalize the absolute PG dose distribution (Mann et al 2019, Schwahofer et al 2020 as well as to combine PG and TLDs for dose measurements within the updated version of the ADAM phantom (ADAM-PETer, Marot et al (2021)). Marot et al (2021) applied the same phantom as used in the present study equipped with a PG-filled prostate and TLDs in the rectum. However, the phantom was used only statically without employing MR-guidance or online adaption of the treatment plan.…”

Section: Introductionmentioning

confidence: 99%

End-to-end test for fractionated online adaptive MR-guided radiotherapy using a deformable anthropomorphic pelvis phantom

Elter¹,

Rippke²,

Johnen³

et al. 2021

Phys. Med. Biol.

Self Cite

View full text Add to dashboard Cite

Objective: In MR-guided radiotherapy (MRgRT) for prostate cancer treatments inter-fractional anatomy changes such as bladder and rectum fillings may be corrected by an online adaption of the treatment plan. To clinically implement such complex treatment procedures, however, specific end-to-end tests are required that are able to validate the overall accuracy of all treatment steps from pre-treatment imaging to dose delivery. Approach: In this study, an end-to-end test of a fractionated and online adapted MRgRT prostate irradiation was performed using the so-called ADAM-PETer phantom. The phantom was adapted to perform 3D polymer gel (PG) dosimetry in the prostate and rectum. Furthermore, thermoluminescence detectors (TLDs) were placed at the center and on the surface of the prostate for additional dose measurements as well as for an external dose renormalization of the PG. For the end-to-end test, a total of five online adapted irradiations were applied in sequence with different bladder and rectum fillings, respectively. Main results: A good agreement of measured and planned dose was found represented by high γ-index passing rates (3 %⁄ 3 mm criterion) of the PG evaluation of 98.9 % in the prostate and 93.7 % in the rectum. TLDs used for PG renormalization at the center of the prostate showed a deviation of -2.3 %. Significance: The presented end-to-end test, which allows for 3D dose verification in the prostate and rectum, demonstrates the feasibility and accuracy of fractionated and online-adapted prostate irradiations in presence of inter-fractional anatomy changes. Such tests are of high clinical importance for the commissioning of new image-guided treatment procedures such as online adaptive MRgRT.

show abstract

“…Whereas the luminescence properties of inorganic rare‐earths compounds have been widely studied, [ 17–21 ] there is practically no information on the TL of lanthanide coordination compounds, although there is available information on TL in organic compounds, as well as in polymers. [ 22–25 ]…”

Section: Introductionmentioning

confidence: 99%

“…Whereas the luminescence properties of inorganic rare-earths compounds have been widely studied, [17][18][19][20][21] there is practically no information on the TL of lanthanide coordination compounds, although there is available information on TL in organic compounds, as well as in polymers. [22][23][24][25] Previously, we obtained interesting coordination compounds of terbium and dysprosium, which are able to store the energy from ultraviolet (UV) and X-ray radiation. [26,27] The energy from UV and X-ray radiation stored by these materials can be stored indefinitely at a low temperature even if the external excitation is removed.…”

Section: Introductionmentioning

confidence: 99%

Thermoluminescent Tb(III) and Dy(III) complexes with redox‐active ligands: experimental and theoretical study

Emelina

Мирочник

2022

Luminescence

View full text Add to dashboard Cite

Thermoluminescence and persistent luminescent materials with unique delayed emission have attracted much attention and exhibit great promise in optical information storage. In this manuscript, to reveal the thermoluminescence mechanism, a combined experimental and theoretical study of ternary Ln(NO3)2Acac(Phen)2 complexes, where Ln is Tb(III), Dy(III), Eu(III), Acac is acetylacetonate anion, and Phen is 1,10‐phenanthroline, was carried out. The terbium and dysprosium complexes had thermoluminescence properties, while the europium complex did not. A thermoluminescence mechanism is proposed: the powerful double π‐conjugate phenanthroline system appearance upon photoexcitation, the peculiarities of frontier orbitals, the abnormally small highest occupied molecular orbital–lowest unoccupied molecular orbital gap, and the geometrical changes in the terbium and dysprosium complexes led us to suggest that phenanthroline molecules serve as ‘chemical’ electron traps. Therefore, we succeeded in ‘freezing’ and storing the excited state of complexes I and II indefinitely. The obtained thermoluminescent materials with ‘chemical’ traps of electrons are capable of storing the energy from incident photons and exhibit a great opportunity in optical information storage and anticounterfeiting applications.

show abstract

Technical Note: On the feasibility of performing dosimetry in target and organ at risk using polymer dosimetry gel and thermoluminescence detectors in an anthropomorphic, deformable, and multimodal pelvis phantom

Cited by 4 publications

References 33 publications

End-to-End QA in Radiation Therapy Quality Management

End-to-End QA in Radiation Therapy Quality Management

End-to-end test for fractionated online adaptive MR-guided radiotherapy using a deformable anthropomorphic pelvis phantom

Thermoluminescent Tb(III) and Dy(III) complexes with redox‐active ligands: experimental and theoretical study

Contact Info

Product

Resources

About