Cardiorespiratory motion characteristics and their dosimetric impact on cardiac stereotactic body radiotherapy.

BACKGROUND Cardiac stereotactic body radiotherapy (CSBRT) is an emerging and promising noninvasive technique for treating refractory arrhythmias utilizing highly precise, single or limited-fraction high-dose irradiations. This method promises to revolutionize the treatment of cardiac conditions by delivering targeted therapy with minimal exposure to surrounding healthy tissues. However, the dynamic nature of cardiorespiratory motion poses significant challenges to the precise delivery of dose in CSBRT, introducing potential variabilities that can impact treatment efficacy. The complexities of the influence of cardiorespiratory motion on dose distribution are compounded by interplay and blurring effects, introducing additional layers of dose uncertainty. These effects, critical to the understanding and improvement of the accuracy of CSBRT, remain unexplored, presenting a gap in current clinical literature. PURPOSE To investigate the cardiorespiratory motion characteristics in arrhythmia patients and the dosimetric impact of interplay and blurring effects induced by cardiorespiratory motion on CSBRT plan quality. METHODS The position and volume variations in the substrate target and cardiac substructures were evaluated in 12 arrhythmia patients using displacement maximum (DMX) and volume metrics. Moreover, a four-dimensional (4D) dose reconstruction approach was employed to examine the dose uncertainty of the cardiorespiratory motion. RESULTS Cardiac pulsation induced lower DMX than respiratory motion but increased the coefficient of variation and relative range in cardiac substructure volumes. The mean DMX of the substrate target was 0.52 cm (range: 0.26-0.80 cm) for cardiac pulsation and 0.82 cm (range: 0.32-2.05 cm) for respiratory motion. The mean DMX of the cardiac structure ranged from 0.15 to 1.56 cm during cardiac pulsation and from 0.35 to 1.89 cm during respiratory motion. Cardiac pulsation resulted in an average deviation of -0.73% (range: -4.01%-4.47%) in V25 between the 3D and 4D doses. The mean deviations in the homogeneity index (HI) and gradient index (GI) were 1.70% (range: -3.10%-4.36%) and 0.03 (range: -0.14-0.11), respectively. For cardiac substructures, the deviations in D50 due to cardiac pulsation ranged from -1.88% to 1.44%, whereas the deviations in Dmax ranged from -2.96% to 0.88% of the prescription dose. By contrast, the respiratory motion led to a mean deviation of -1.50% (range: -10.73%-4.23%) in V25. The mean deviations in HI and GI due to respiratory motion were 4.43% (range: -3.89%-13.98%) and 0.18 (range: -0.01-0.47) (p < 0.05), respectively. Furthermore, the deviations in D50 and Dmax in cardiac substructures for the respiratory motion ranged from -0.28% to 4.24% and -4.12% to 1.16%, respectively. CONCLUSIONS Cardiorespiratory motion characteristics vary among patients, with the respiratory motion being more significant. The intricate cardiorespiratory motion characteristics and CSBRT plan complexity can induce substantial dose uncertainty. Therefore, assessing individual motion characteristics and 4D dose reconstruction techniques is critical for implementing CSBRT without compromising efficacy and safety.

[1]  M. Fast,et al.  STereotactic Arrhythmia Radioablation (STAR): Assessment of cardiac and respiratory heart motion in ventricular tachycardia patients - A STOPSTORM.eu consortium review. , 2023, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[2]  D. de Ruysscher,et al.  A framework for assessing the impact of cardiac and respiratory motion for STereotactic Arrhythmia Radioablation (STAR) using a digital phantom with a 17-segment model - A STOPSTORM.eu consortium study. , 2023, International journal of radiation oncology, biology, physics.

[3]  E. Liehn,et al.  Promising Therapies for Atrial Fibrillation and Ventricular Tachycardia , 2022, International journal of molecular sciences.

[4]  K. Parker,et al.  Recreating the heart’s helical structure-function relationship with focused rotary jet spinning , 2022, Science.

[5]  S. Menon,et al.  Dosimetric comparison of analytical anisotropic algorithm and the two dose reporting modes of Acuros XB dose calculation algorithm in volumetric modulated arc therapy of carcinoma lung and carcinoma prostate. , 2022, Medical dosimetry : official journal of the American Association of Medical Dosimetrists.

[6]  Gang Xu,et al.  Stereotactic Radiotherapy: An Alternative Option for Refractory Ventricular Tachycardia to Drug and Ablation Therapy , 2022, Journal of clinical medicine.

[7]  Y. Duan,et al.  Account for the Full Extent of Esophagus Motion in Radiation Therapy Planning: A Preliminary Study of the IRV of the Esophagus , 2021, Frontiers in Oncology.

[8]  D. Tousoulis,et al.  Stereotactic Arrhythmia Radioablation as a Novel Treatment Approach for Cardiac Arrhythmias: Facts and Limitations , 2021, Biomedicines.

[9]  J. Dunst,et al.  Recommendations regarding cardiac stereotactic body radiotherapy for treatment-refractory ventricular tachycardia. , 2021, Heart rhythm.

[10]  Geoffrey D. Hugo,et al.  Evaluation of motion compensation methods for non-invasive cardiac radioablation of ventricular tachycardia. , 2021, International journal of radiation oncology, biology, physics.

[11]  X. Franceries,et al.  A study of the interplay effect in radiation therapy using a Monte-Carlo model. , 2021, Physica medica : PM : an international journal devoted to the applications of physics to medicine and biology : official journal of the Italian Association of Biomedical Physics.

[12]  Salahuddin Ahmad,et al.  Intensity-modulated proton therapy (IMPT) versus intensity-modulated radiation therapy (IMRT) for the treatment of head and neck cancer: A dosimetric comparison. , 2021, Medical dosimetry : official journal of the American Association of Medical Dosimetrists.

[13]  V. Budach,et al.  Interdisciplinary clinical target volume generation for cardiac radioablation: Multi-center benchmarking for the RAdiosurgery for VENtricular TAchycardia (RAVENTA) trial. , 2021, International journal of radiation oncology, biology, physics.

[14]  P. Keall,et al.  Cardiac radioablation for atrial fibrillation: target motion characterization and treatment delivery considerations. , 2020, Medical physics.

[15]  Geoffrey D. Hugo,et al.  A review of cardiac radioablation (CR) for arrhythmias: procedures, technology and future opportunities. , 2020, International journal of radiation oncology, biology, physics.

[16]  J. Sick,et al.  Interplay effects in highly modulated stereotactic body radiation therapy lung cases treated with volumetric modulated arc therapy , 2020, Journal of applied clinical medical physics.

[17]  G. Antoch,et al.  Analysis of different image-registration algorithms for Fourier decomposition MRI in functional lung imaging , 2020, Acta radiologica.

[18]  A. Reginelli,et al.  4D CT analysis of organs at risk (OARs) in stereotactic radiotherapy. , 2020, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[19]  K. Higgins,et al.  Clinical Experience of Stereotactic Body Radiation For Refractory Ventricular Tachycardia in Advanced Heart Failure Patients. , 2020, Heart rhythm.

[20]  James M. Metz,et al.  Dosimetric Performance and Planning/Delivery Efficiency of a Dual-Layer Stacked and Staggered MLC on Treating Multiple Small Targets: A Planning Study Based on Single-Isocenter Multi-Target Stereotactic Radiosurgery (SRS) to Brain Metastases , 2019, Front. Oncol..

[21]  P. Tchou,et al.  Analysis of cardiac motion without respiratory motion for cardiac stereotactic body radiation therapy , 2018, Journal of applied clinical medical physics.

[22]  Niko Papanikolaou,et al.  Dosimetric and localization accuracy of Elekta high definition dynamic radiosurgery. , 2018, Physica medica : PM : an international journal devoted to the applications of physics to medicine and biology : official journal of the Italian Association of Biomedical Physics.

[23]  Elisabeth Weiss,et al.  Evaluation of Image Registration Accuracy for Tumor and Organs at Risk in the Thorax for Compliance With TG 132 Recommendations , 2018, Advances in radiation oncology.

[24]  L. Court,et al.  Interplay effect on a 6‐MV flattening‐filter‐free linear accelerator with high dose rate and fast multi‐leaf collimator motion treating breast and lung phantoms , 2018, Medical physics.

[25]  Tobias Knopp,et al.  Influence of deformable image registration on 4D dose simulation for extracranial SBRT: A multi-registration framework study. , 2018, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[26]  Y. Nishimura,et al.  Minimizing dose variation from the interplay effect in stereotactic radiation therapy using volumetric modulated arc therapy for lung cancer , 2018, Journal of applied clinical medical physics.

[27]  K. Brock,et al.  Use of image registration and fusion algorithms and techniques in radiotherapy: Report of the AAPM Radiation Therapy Committee Task Group No. 132 , 2017, Medical physics.

[28]  Stefanie Ehrbar,et al.  ITV, mid-ventilation, gating or couch tracking - A comparison of respiratory motion-management techniques based on 4D dose calculations. , 2017, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[29]  Alejandro F. Frangi,et al.  Multiresolution eXtended Free‐Form Deformations (XFFD) for non‐rigid registration with discontinuous transforms , 2017, Medical Image Anal..

[30]  M. Avanzo,et al.  Single-fraction flattening filter-free volumetric modulated arc therapy for lung cancer: Dosimetric results and comparison with flattened beams technique. , 2016, Medical dosimetry : official journal of the American Association of Medical Dosimetrists.

[31]  M. Tyler Quantification of interplay and gradient effects for lung stereotactic ablative radiotherapy (SABR) treatments , 2016, Journal of applied clinical medical physics.

[32]  A. Thiagalingam,et al.  A review of the safety aspects of radio frequency ablation , 2015, International journal of cardiology. Heart & vasculature.

[33]  M. Hiraoka,et al.  Dosimetric comparison of Acuros XB, AAA, and XVMC in stereotactic body radiotherapy for lung cancer. , 2014, Medical physics.

[34]  Kengo Ito,et al.  Evaluation of accuracy of B-spline transformation-based deformable image registration with different parameter settings for thoracic images , 2014, Journal of radiation research.

[35]  James M Lamb,et al.  The relative accuracy of 4D dose accumulation for lung radiotherapy using rigid dose projection versus dose recalculation on every breathing phase , 2014, Medical physics.

[36]  Max Dahele,et al.  Dosimetric impact of the interplay effect during stereotactic lung radiation therapy delivery using flattening filter-free beams and volumetric modulated arc therapy. , 2013, International journal of radiation oncology, biology, physics.

[37]  Jong Hoon Kim,et al.  Four-dimensional dose evaluation using deformable image registration in radiotherapy for liver cancer. , 2012, Medical physics.

[38]  L. Cozzi,et al.  Critical appraisal of Acuros XB and Anisotropic Analytic Algorithm dose calculation in advanced non-small-cell lung cancer treatments. , 2012, International journal of radiation oncology, biology, physics.

[39]  Xavier Geets,et al.  Helical tomotherapy for SIB and hypo-fractionated treatments in lung carcinomas: a 4D Monte Carlo treatment planning study. , 2012, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[40]  M. Schell,et al.  Stereotactic body radiation therapy: the report of AAPM Task Group 101. , 2010, Medical physics.

[41]  E. Hoffman,et al.  Mass preserving nonrigid registration of CT lung images using cubic B-spline. , 2009, Medical physics.

[42]  Ross Berbeco,et al.  Management of the interplay effect when using dynamic MLC sequences to treat moving targets. , 2008, Medical physics.

[43]  Josien P. W. Pluim,et al.  Evaluation of Optimization Methods for Nonrigid Medical Image Registration Using Mutual Information and B-Splines , 2007, IEEE Transactions on Image Processing.

[44]  M. Staring,et al.  A rigidity penalty term for nonrigid registration. , 2007, Medical physics.

[45]  Steve B. Jiang,et al.  The management of respiratory motion in radiation oncology report of AAPM Task Group 76a). , 2006, Medical physics.

[46]  S. Riederer,et al.  Respiratory Motion of the Heart: Kinematics and the Implications for the Spatial Resolution in Coronary Imaging , 1995, Magnetic resonance in medicine.

[47]  S. Senan,et al.  Dosimetric impact of interplay effect on RapidArc lung stereotactic treatment delivery. , 2011, International journal of radiation oncology, biology, physics.

[48]  Max A. Viergever,et al.  elastix: A Toolbox for Intensity-Based Medical Image Registration , 2010, IEEE Transactions on Medical Imaging.

[49]  Marjan A Admiraal,et al.  Dose calculations accounting for breathing motion in stereotactic lung radiotherapy based on 4D-CT and the internal target volume. , 2008, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.