Ingrid Kristensen

Volumetric and dosimetric evaluation of radiation treatment plans: radiation conformity index

PURPOSE The use of conformal radiation therapy has grown substantially during the last years since three-dimensional (3D) treatment planning systems with beams-eye-view planning has become commercially available. We studied the degree of conformity reached in clinical routines for some common diagnoses treated at our department by calculating a radiation conformity index (RCI). METHODS AND MATERIALS The radiation conformity index, determined as the ratio between the target volume (PTV) and the irradiated volume, has been evaluated for 57 patients treated with 3D treatment plans. RESULTS AND CONCLUSION The RCI was found to vary from 0.3 to 0.6 (average 0.4), a surprisingly low figure. The higher RCI is typical for pelvic treatments (e.g., prostate) and stereotactic treatments. The lower RCI is found for extended tumors, such as mammary carcinomas where the adjacent nodes are included. The latter is also valid for most lung cancer patients studied. The RCI gives a consistent method for quantifying the degree of conformity based on isodose surfaces and volumes. Care during interpretation of RCI must always be taken, since small changes in the minimum dose can dramatically change the treated volume.

Telemedicine as a tool for sharing competence in paediatric radiotherapy – Implementation and initial experiences from a Swedish project

Telemedicine as a tool for sharing competence in paediatric radiotherapy : implementation and initial experiences from a Swedish project.

A national approach for automated collection of standardized and population-based radiation therapy data in Sweden.

PURPOSE To develop an infrastructure for structured and automated collection of interoperable radiation therapy (RT) data into a national clinical quality registry. MATERIALS AND METHODS The present study was initiated in 2012 with the participation of seven of the 15 hospital departments delivering RT in Sweden. A national RT nomenclature and a database for structured unified storage of RT data at each site (Medical Information Quality Archive, MIQA) have been developed. Aggregated data from the MIQA databases are sent to a national RT registry located on the same IT platform (INCA) as the national clinical cancer registries. RESULTS The suggested naming convention has to date been integrated into the clinical workflow at 12 of 15 sites, and MIQA is installed at six of these. Involvement of the remaining 3/15 RT departments is ongoing, and they are expected to be part of the infrastructure by 2016. RT data collection from ARIA®, Mosaiq®, Eclipse™, and Oncentra® is supported. Manual curation of RT-structure information is needed for approximately 10% of target volumes, but rarely for normal tissue structures, demonstrating a good compliance to the RT nomenclature. Aggregated dose/volume descriptors are calculated based on the information in MIQA and sent to INCA using a dedicated service (MIQA2INCA). Correct linkage of data for each patient to the clinical cancer registries on the INCA platform is assured by the unique Swedish personal identity number. CONCLUSIONS An infrastructure for structured and automated prospective collection of syntactically interoperable RT data into a national clinical quality registry for RT data is under implementation. Future developments include adapting MIQA to other treatment modalities (e.g. proton therapy and brachytherapy) and finding strategies to harmonize structure delineations. How the RT registry should comply with domain-specific ontologies such as the Radiation Oncology Ontology (ROO) is under discussion.

Comparative Proton and Photon Treatment Planning in Pediatric Patients with Various Diagnoses

Abstract Purpose: Radiation therapy with protons, owing to its physical properties, can be advantageous for the treatment of children. This study was conducted in order to quantify the advantages of proton therapy from a treatment planning point of view in a consecutive, realistic, and mixed pediatric/adolescent population with varying diagnoses and target locations. Patients and Methods: Forty-five patients treated with conventional 3-dimensional conformal radiation therapy photon radiation therapy were retrospectively re-planned with scanned proton beams. Treatment sites represented were the central nervous system, head and neck, thorax, and abdomen. Median age was 8 years (range, 2-18 years). All plans were optimized with intensity-modulated proton therapy (multi-field optimization). We analyzed a number of dose-volume descriptors for planned target volumes (PTVs). Organ-specific mean doses and relevant DV -values were derived for organs at risk. In addition, homogeneity index, conformity index, treate...

Assessment of volume segmentation in radiotherapy of adolescents :: a treatment planning study by the Swedish Workgroup for Paediatric Radiotherapy.

Abstract Background and purpose. The variability in target delineation for similar cases between centres treating paediatric and adolescent patients, and the apparent differences in interpretation of radiotherapy guidelines in the treatment protocols encouraged us to perform a dummy-run study as a part of our quality assurance work. The aim was to identify and quantify differences in the segmentation of target volumes and organs at risk (OARs) and to analyse the treatment plans and dose distributions. Materials and methods. Four patient cases were selected: Wilms tumour, Hodgkins disease, rhabdomyosarcoma of the prostate and chordoma of the skull base. The five participating centres received the same patient-related material. They introduced the cases in their treatment planning system, delineated target volumes and OARs and created treatment plans. Dose-volume histograms were retrieved for relevant structures and volumes and dose metrics were derived and compared, e.g. target volumes and their concordance, dose homogeneity index (HI), treated and irradiated volumes, remaining volume at risk and relevant Vx and Dx values. Results. We found significant differences in target segmentation in the majority of the cases. The planning target volumes (PTVs) varied two- to four-fold and conformity indices were in the range of 0.3–0.6. This resulted in large variations in dose distributions to OARs as well as in treated and irradiated volumes even though the treatment plans showed good conformity to the PTVs. Potential reasons for the differences in target delineation were analysed. Conclusion. Considerations of the growing child and difficulties in interpretation of the radiotherapy information in the treatment protocols were identified as reasons for the variation. As a result, clarified translated detailed radiotherapy guidelines for paediatric/adolescent patients have been recognised as a way to reduce this variation.

A dose based approach for evaluation of inter-observer variations in target delineation

Highlights • Uses consensus volume to visualise inter-observer variation in dosimetric terms.• Using DVHs in absolute volume adds information to evaluate uniformity.• DVH for consensus volume adds information hidden in concordance indices.• Report together with other measures.• Completes the evaluation of delineation studies.

261 Distributed radiotherapy — the use of telemedicine as a tool for decision making in paediatric radiation oncology ? a report from SWPR

Distributed radiotherapy - The use of telemedicine as a tool for decision making in paediatric radiation oncology ? : - A report from SWPR