Respiratory motion management for external radiotherapy treatment.

We present the update of the recommendations of the French society of oncological radiotherapy on respiratory motion management for external radiotherapy treatment. Since twenty years and the report 62 of ICRU, motion management during the course of radiotherapy treatment has become an increasingly significant concern, particularly with the development of hypofractionated treatments under stereotactic conditions, using reduced safety margins. This article related orders of motion amplitudes for different organs as well as the definition of the margins in radiotherapy. An updated review of the various movement management strategies is presented as well as main technological solutions enabling them to be implemented: when acquiring anatomical data, during planning and when carrying out treatment. Finally, the management of these moving targets, such as it can be carried out in radiotherapy departments, will be detailed for a few concrete examples of localizations (abdominal, thoracic and hepatic).

Mid-position treatment strategy for locally advanced lung cancer: a dosimetric study.

OBJECTIVE: The internal target volume (ITV) strategy generates larger planning target volumes (PTVs) in locally advanced non-small cell lung cancer (LA-NSCLC) than the Mid-position (Mid-p) strategy. We investigated the benefit of the Mid-p strategy regarding PTV reduction and dose to the organs at risk (OARs). METHODS: 44 patients with LA-NSCLC were included in a randomized clinical study to compare ITV and Mid-p strategies. GTV were delineated by a physician on maximum intensity projection images and on Mid-p images from four-dimensional CTs. CTVs were obtained by adding 6 mm uniform margin for microscopic extension. CTV to PTV margins were calculated using the van Herk's recipe for setup and delineation errors. For the Mid-p strategy, the mean target motion amplitude was added as a random error. For both strategies, three-dimensional conformal plans delivering 60-66 Gy to PTV were performed. PTVs, dose-volume parameters for OARs (lung, esophagus, heart, spinal cord) were reported and compared. RESULTS: With the Mid-p strategy, the median of volume reduction was 23.5 cm3 (p = 0.012) and 8.8 cm3 (p = 0.0083) for PTVT and PTVN respectively; the median mean lung dose reduction was 0.51 Gy (p = 0.0057). For 37.1% of the patients, delineation errors led to smaller PTV with the ITV strategy than with the Mid-p strategy. CONCLUSION: PTV and mean lung dose were significantly reduced using the Mid-p strategy. Delineation uncertainty can unfavorably impact the advantage. ADVANCES IN KNOWLEDGE: To the best of our knowledge, this is the first dosimetric comparison study between ITV and Mid-p strategies for LA-NSCLC.

[Interobserver variability study for daily cone beam computed tomography registration of prostate volumetric modulated arc therapy]. / Tomographie conique quotidienne pour les traitements pelviens et prostatiques: étude interobservateurs.

PURPOSE: This work evaluated the interobserver variability in cone beam computed tomography (CBCT) registration for prostate cancers treated with intensity-modulated radiotherapy. MATERIAL AND METHODS: Twelve technologists realized 286 CBCT/CT registrations (bone registration followed by prostate to prostate registration). The registration results were compared to those obtained by two radiation oncologists (reference). Each technologist reported the shifts calculated by the software in all three axes. A statistical analysis allowed us to calculate the minimum threshold under which 95% of the observers found similar values. A variance analysis followed by the post hoc test were used to find differences in interobserver registration variability and determine whether any individual users performed registrations which differed significantly from those of the other users. RESULTS: The registration differences compared to the reference in the three directions in terms of 95th percentile are: 2.1mm left-right, 3.5mm target-gun, 7.3mm anterior-posterior. In the posterior direction, 4% of the observers have found differences superior to 8mm, margin used in routine without the use of a daily CBCT. The variance test revealed a P-value <0.05 only for target-gun and for all observers there was no significant difference compared to the reference. CONCLUSION: This study confirmed the interest of a 3D tissue registration for prostate treatments. The registration study showed a good interobserver reproducibility. This showed the importance of a daily CBCT/CT registration in prostate treatment with the possibility of a planning target volume margin reduction in the three directions. An evaluation of a partial delegation of registration to technologists should be done by the radiation oncologists.

[Intensity-modulated radiation therapy in non-small cell lung cancers]. / Radiothérapie conformationnelle avec modulation d'intensité dans les carcinomes bronchiques non à petites cellules.

Intensity modulated radiotherapy is increasingly used in non-small-cell lung cancers despite a low level of evidence. A literature review was conducted. Several critical physical and dosimetric uncertainties are however unsolved. Methods to circumvent these limitations are being developed. In several retrospective studies, survival rates were at least similar with intensity-modulated radiotherapy as those reported with three-dimensional irradiation. To date, intensity modulated radiotherapy might be authorized in complex anatomical situations such as tumours close to the spinal cord (such as Pancoast Tobias, paraspinal and paracardiac tumours) or with limited motion amplitudes. Dosimetric benefits should also account for 4D dose distribution issues. The reduction of intermediate and high doses in the organs at risk with intensity modulated radiotherapy is advantageous. However, the effect of low doses in large volumes (lung, bone, unspecified tissues along beam paths) and the effect of increasing integral dose are still poorly known. In conclusion, dose-volume correlations need to be better documented and prospective randomized trials should be encouraged.

[Scan acquisition parameter optimization for the treatment of moving tumors in radiotherapy]. / Optimisation des paramètres d'acquisition scanographique pour la radiothérapie des tumeurs mobiles.

AIM OF THE STUDY: In the case of lung tumor treatment, to adjust 3D helical computed tomography (CT) acquisition parameters using a dynamic phantom and compare to the theory the volumes of a moving object. MATERIALS AND METHODS: Three helical CT acquisitions were compared using a Big Bore CT scan : an "initial" 3D CT scan (constructor parameters), an "optimized" 3D CT scan which parameters are chosen to obtain an axial slow scan like acquisition and a 4D CT scan. We used a phantom composed by a ball filled with water set on a dynamic platform moving in the antero-posterior or cranio-caudal direction with a 14 mm amplitude and a 4s period. For each acquisition and modality (static and dynamic), we quantified the ball volume by automatic contouring and we estimated relative errors. RESULTS: For an antero-posterior displacement, the volume of the moving ball is under estimated by 14.1 % with the "initial" scan, by 0.2 % with the "optimized" scan and over estimated by 0.8 % with the averaged 4D scan. For a cranio-caudal displacement, it is under estimated by about 22 % with the "initial" scan and by about 1 % with the "optimized" scan and the averaged 4D scan. CONCLUSION: Volume measurements performed with the dynamic phantom allowed us to validate the "optimized" 3D CT scan parameters because it accurately reflects the volume of a moving object. Radiotherapy departments without 4D CT should adapt scan parameters for internal target volume definition.