Your search keyword '"respiratory motion management"' showing total 92 results

1. Developing and validating a bi-polar gated respiratory motion management strategy for improved lung Stereotactic body radiotherapy (SBRT) treatment

Author

Li, Zhen, Liu, Xueli, Zhang, Libo, Zhang, Shujun, Qiu, Jianjian, Zheng, Xiangpeng, and Wu, Qiuwen

Published

2025

2. Prospective study on stereotactic body radiotherapy for small pancreatic neuroendocrine tumors: tolerance and effectiveness analysis.

Author

López Gonzalez, Mercedes, Hernando-Requejo, Ovidio, Ciervide Jurío, Raquel, Montero Luis, Ángel, Saiz Guisasola, Carmen, Sánchez Saugar, Emilio, Álvarez Rodríguez, Beatriz, Chen-Zhao, Xin, García-Aranda, Mariola, Valero Albarran, Jeannette, Alonso Gutierrez, Rosa, García Cañamaque, Lina, Prados, Susana, Quijano, Yolanda, de Vicente, Emilio, and Rubio, Carmen

Abstract

Introduction: Surgery is the standard treatment for pancreatic neuroendocrine tumors (pNETs), obtaining favorable results but associating high morbidity and mortality rates. This study assesses stereotactic body radiation therapy (SBRT) as a radical approach for small (< 2 cm) nonfunctioning pNETs. Materials and methods: From January 2017 to June 2023, 20 patients with small pNETs underwent SBRT in an IRB-approved study. Endpoints included local control, tolerance, progression-free survival, and overall survival (OS). Diagnostic assessments comprised endoscopy, CT scans, OctreScan or PET-Dotatoc, abdominal MRI, and histological confirmatory samples. Results: In a 30-month follow-up of 20 patients (median age 55.5 years), SBRT was well-tolerated with no grade > 2 toxicity. 40% showed morphological response, 55% remained stable. Metabolically, 50% achieved significant improvement. With a median OS of 41.5 months, all patients were alive without local or distant progression or need for surgical resection. Conclusion: SBRT is a feasible and well-tolerated approach for small neuroendocrine pancreatic tumors, demonstrating effective local control. Further investigations are vital for validation and extension of these findings. [ABSTRACT FROM AUTHOR]

Published

2025

3. Synchronized Contrast-Enhanced 4DCT Simulation for Target Volume Delineation in Abdominal SBRT.

Author

Faccenda, Valeria, Panizza, Denis, Niespolo, Rita Marina, Colciago, Riccardo Ray, Rossano, Giulia, De Sanctis, Lorenzo, Gandola, Davide, Ippolito, Davide, Arcangeli, Stefano, and De Ponti, Elena

Subjects

*ABDOMINAL tumors, *RADIOTHERAPY, *COMPUTED tomography, *RADIOSURGERY, *SIMULATION methods in education, *RESEARCH bias, *COMPUTERS in medicine, *CONTRAST media, *TIME

Abstract

Simple Summary: Stereotactic Body Radiotherapy (SBRT) is emerging as a promising, ablative, non-invasive alternative for treating liver and pancreatic tumors. The high conformality of SBRT, essential to minimize radiation-induced side effects on nearby gastrointestinal organs at risk while ensuring the delivery of high biologically effective doses to the tumor, makes the precise delineation of the target volume even more critical. While four-dimensional computed tomography (4DCT) remains the standard imaging modality for respiratory motion assessment, it often struggles to clearly visualize abdominal tumors due to poor contrast with the surrounding normal tissues in terms of Hounsfield Units (HUs). In this study, we report on our institutional approach to improve target volume delineation and respiratory motion management in abdominal SBRT planning by integrating 4DCT simulation with synchronized intravenous contrast injection. Background/Objectives: To present the technical aspects of contrast-enhanced 4DCT (ce4DCT) simulation for abdominal SBRT. Methods: Twenty-two patients underwent two sequential 4DCT scans: one baseline and one contrast-enhanced with personalized delay time (tdelay) calculated to capture the tumor in the desired contrast phase, based on diagnostic triple-phase CT. The internal target volume (ITV) was delineated on ten contrast phases, and a panel of three experts qualitatively evaluated tumor visibility. Aortic HU values were measured to refine the tdelay for subsequent patients. The commonly used approach of combining triple-phase CT with unenhanced 4DCT was simulated, and differences in target delineation were evaluated by volume, centroid shift, Dice and Jaccard indices, and mean distance agreement (MDA). The margins required to account for motion were calculated. Results: The ce4DCT acquisitions substantially improved tumor visibility over the entire breathing cycle in 20 patients, according to the experts' unanimous evaluation. The median contrast peak time was 54.5 s, and the washout plateau was observed at 70.3 s, with mean peak and plateau HU values of 292 ± 59 and 169 ± 25. The volumes from the commonly used procedure (ITV2) were significantly smaller than the ce4DCT volumes (ITV1) (p = 0.045). The median centroid shift was 4.7 mm. The ITV1-ITV2 overlap was 69% (Dice index), 53% (Jaccard index), and 2.89 mm (MDA), with the liver volumes showing significantly lower indices compared to the pancreatic volumes (p ≤ 0.011). The margins required to better encompass ITV1 were highly variable, with mean values ≥ 4 mm in all directions except for the left–right axis. Conclusions: The ce4DCT simulation was feasible, resulting in optimal tumor enhancement with minimal resource investment, while significantly mitigating uncertainties in SBRT planning by addressing poor visibility and respiratory motion. Triple-phase 3DCT with unenhanced 4DCT led to high variability in target delineation, making the isotropic margins ineffective. [ABSTRACT FROM AUTHOR]

Published

2024

4. Involved‐field high‐dose chemoradiotherapy with respiratory motion management for esophageal squamous cell carcinoma

Author

Masaki Matsuda, Takafumi Komiyama, Kan Marino, Shinichi Aoki, Tomoko Akita, Naoki Sano, Hidekazu Suzuki, Masahide Saito, Hikaru Nemoto, and Hiroshi Onishi

Subjects

dose escalation, esophageal carcinoma, esophageal fistula, involved‐field radiotherapy, respiratory motion management, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background We investigated the clinical outcomes of involved‐field high‐dose (≥66 Gy) chemoradiotherapy (CRT) combined with respiratory motion management for esophageal squamous cell carcinoma (ESCC). Methods Patients who underwent definitive CRT for histologically confirmed ESCC in our department between 2012 and 2018 were retrospectively analyzed. Respiratory motion management strategies included breath‐holding (63%) and mask immobilization (29%) based on individual measurements of respiratory tumor motion using radiographic fluoroscopy with endoscopically placed clip markers as landmarks. We evaluated patient characteristics, treatment efficacy, failure patterns, and toxicities. Results We enrolled 35 patients with a prescribed dose of 66–70 Gy in 33–35 fractions. The overall response rate within 6 months post‐CRT was 94.3%; the median follow‐up period for survivors was 43 months. The 2‐year overall survival (OS), progression‐free survival, and locoregional failure‐free survival rates were 51.4%, 42.9%, and 42.9%, respectively. A significant difference in OS was observed between patients with and without esophageal fistulas after CRT (p = 0.002, log‐rank test). Disease failure occurred in 16 patients (45.7%), including one (2.9%) with out‐of‐field regional nodal failure. Major grade 3 or higher toxicities included decreased white blood cell count (48.6%), neutrophil count (34.3%), and esophageal stenosis (31.4%). No grade 3 or higher cardiopulmonary toxicities were observed. Bronchial/tracheal tumor compression and a higher radiotherapy dose (70 Gy) were significantly correlated with esophageal fistulas. Conclusion Involved‐field high‐dose CRT with respiratory motion management may be a feasible treatment option for ESCC. However, a comprehensive assessment of esophageal fistula risk is required to identify suitable candidates.

Published

2024

5. Modeling of artificial intelligence-based respiratory motion prediction in MRI-guided radiotherapy: a review

Author

Xiangbin Zhang, Di Yan, Haonan Xiao, and Renming Zhong

Subjects

MRI-guided radiotherapy, Respiratory motion management, Artificial intelligence, Medical physics. Medical radiology. Nuclear medicine, R895-920, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract The advancement of precision radiotherapy techniques, such as volumetric modulated arc therapy (VMAT), stereotactic body radiotherapy (SBRT), and particle therapy, highlights the importance of radiotherapy in the treatment of cancer, while also posing challenges for respiratory motion management in thoracic and abdominal tumors. MRI-guided radiotherapy (MRIgRT) stands out as state-of-art real-time respiratory motion management approach owing to the non-ionizing radiation nature and superior soft-tissue contrast characteristic of MR imaging. In clinical practice, MR imaging often operates at a frequency of 4 Hz, resulting in approximately a 300 ms system latency of MRIgRT. This system latency decreases the accuracy of respiratory motion management in MRIgRT. Artificial intelligence (AI)-based respiratory motion prediction has recently emerged as a promising solution to address the system latency issues in MRIgRT, particularly for advanced contour prediction and volumetric prediction. However, implementing AI-based respiratory motion prediction faces several challenges including the collection of training datasets, the selection of prediction methods, and the formulation of complex contour and volumetric prediction problems. This review presents modeling approaches of AI-based respiratory motion prediction in MRIgRT, and provides recommendations for achieving consistent and generalizable results in this field.

Published

2024

6. Involved‐field high‐dose chemoradiotherapy with respiratory motion management for esophageal squamous cell carcinoma.

Author

Matsuda, Masaki, Komiyama, Takafumi, Marino, Kan, Aoki, Shinichi, Akita, Tomoko, Sano, Naoki, Suzuki, Hidekazu, Saito, Masahide, Nemoto, Hikaru, and Onishi, Hiroshi

Subjects

SQUAMOUS cell carcinoma, RESPIRATION, BREATH holding, ESOPHAGEAL tumors, CHEMORADIOTHERAPY, RETROSPECTIVE studies, ENDOSCOPIC surgery, CANCER patients, DESCRIPTIVE statistics, LOG-rank test, RADIATION doses, FLUOROSCOPY, ENDOSCOPY, OVERALL survival

Abstract

Background: We investigated the clinical outcomes of involved‐field high‐dose (≥66 Gy) chemoradiotherapy (CRT) combined with respiratory motion management for esophageal squamous cell carcinoma (ESCC). Methods: Patients who underwent definitive CRT for histologically confirmed ESCC in our department between 2012 and 2018 were retrospectively analyzed. Respiratory motion management strategies included breath‐holding (63%) and mask immobilization (29%) based on individual measurements of respiratory tumor motion using radiographic fluoroscopy with endoscopically placed clip markers as landmarks. We evaluated patient characteristics, treatment efficacy, failure patterns, and toxicities. Results: We enrolled 35 patients with a prescribed dose of 66–70 Gy in 33–35 fractions. The overall response rate within 6 months post‐CRT was 94.3%; the median follow‐up period for survivors was 43 months. The 2‐year overall survival (OS), progression‐free survival, and locoregional failure‐free survival rates were 51.4%, 42.9%, and 42.9%, respectively. A significant difference in OS was observed between patients with and without esophageal fistulas after CRT (p = 0.002, log‐rank test). Disease failure occurred in 16 patients (45.7%), including one (2.9%) with out‐of‐field regional nodal failure. Major grade 3 or higher toxicities included decreased white blood cell count (48.6%), neutrophil count (34.3%), and esophageal stenosis (31.4%). No grade 3 or higher cardiopulmonary toxicities were observed. Bronchial/tracheal tumor compression and a higher radiotherapy dose (70 Gy) were significantly correlated with esophageal fistulas. Conclusion: Involved‐field high‐dose CRT with respiratory motion management may be a feasible treatment option for ESCC. However, a comprehensive assessment of esophageal fistula risk is required to identify suitable candidates. [ABSTRACT FROM AUTHOR]

Published

2024

7. Modeling of artificial intelligence-based respiratory motion prediction in MRI-guided radiotherapy: a review.

Author

Zhang, Xiangbin, Yan, Di, Xiao, Haonan, and Zhong, Renming

Subjects

VOLUMETRIC-modulated arc therapy, ARTIFICIAL intelligence, NONIONIZING radiation, MAGNETIC resonance imaging, STEREOTACTIC radiotherapy

Abstract

The advancement of precision radiotherapy techniques, such as volumetric modulated arc therapy (VMAT), stereotactic body radiotherapy (SBRT), and particle therapy, highlights the importance of radiotherapy in the treatment of cancer, while also posing challenges for respiratory motion management in thoracic and abdominal tumors. MRI-guided radiotherapy (MRIgRT) stands out as state-of-art real-time respiratory motion management approach owing to the non-ionizing radiation nature and superior soft-tissue contrast characteristic of MR imaging. In clinical practice, MR imaging often operates at a frequency of 4 Hz, resulting in approximately a 300 ms system latency of MRIgRT. This system latency decreases the accuracy of respiratory motion management in MRIgRT. Artificial intelligence (AI)-based respiratory motion prediction has recently emerged as a promising solution to address the system latency issues in MRIgRT, particularly for advanced contour prediction and volumetric prediction. However, implementing AI-based respiratory motion prediction faces several challenges including the collection of training datasets, the selection of prediction methods, and the formulation of complex contour and volumetric prediction problems. This review presents modeling approaches of AI-based respiratory motion prediction in MRIgRT, and provides recommendations for achieving consistent and generalizable results in this field. [ABSTRACT FROM AUTHOR]

Published

2024

8. Feasibility of surface‐guidance combined with CBCT for intra‐fractional breath‐hold motion management during Ethos RT.

Author

Kim, Taeho, Laugeman, Eric, Kiser, Kendall, Schiff, Joshua, Marasini, Shanti, Price, Alex, Gach, H Michael, Knutson, Nels, Samson, Pamela, Robinson, Clifford, Hatscher, Casey, and Henke, Lauren

Subjects

CONE beam computed tomography, MOTION, IMAGE registration, MOTION analysis, OPTICAL images, STEREOTACTIC radiotherapy, ORBITS of artificial satellites, IRRADIATION

Abstract

Purpose: High‐quality CBCT and AI‐enhanced adaptive planning techniques allow CBCT‐guided stereotactic adaptive radiotherapy (CT‐STAR) to account for inter‐fractional anatomic changes. Studies of intra‐fractional respiratory motion management with a surface imaging solution for CT‐STAR have not been fully conducted. We investigated intra‐fractional motion management in breath‐hold Ethos‐based CT‐STAR and CT‐SBRT (stereotactic body non‐adaptive radiotherapy) using optical surface imaging combined with onboard CBCTs. Methods: Ten cancer patients with mobile lower lung or upper abdominal malignancies participated in an IRB‐approved clinical trial (Phase I) of optical surface image‐guided Ethos CT‐STAR/SBRT. In the clinical trial, a pre‐configured gating window (± 2 mm in AP direction) on optical surface imaging was used for manually triggering intra‐fractional CBCT acquisition and treatment beam irradiation during breath‐hold (seven patients for the end of exhalation and three patients for the end of inhalation). Two inter‐fractional CBCTs at the ends of exhalation and inhalation in each fraction were acquired to verify the primary direction and range of the tumor/imaging‐surrogate (donut‐shaped fiducial) motion. Intra‐fractional CBCTs were used to quantify the residual motion of the tumor/imaging‐surrogate within the pre‐configured breath‐hold window in the AP direction. Fifty fractions of Ethos RT were delivered under surface image‐guidance: Thirty‐two fractions with CT‐STAR (adaptive RT) and 18 fractions with CT‐SBRT (non‐adaptive RT). The residual motion of the tumor was quantified by determining variations in the tumor centroid position. The dosimetric impact on target coverage was calculated based on the residual motion. Results: We used 46 fractions for the analysis of intra‐fractional residual motion and 43 fractions for the inter‐fractional motion analysis due to study constraints. Using the image registration method, 43 pairs of inter‐fractional CBCTs and 100 intra‐fractional CBCTs attached to dose maps were analyzed. In the motion range study (image registration) from the inter‐fractional CBCTs, the primary motion (mean ± std) was 16.6 ± 9.2 mm in the SI direction (magnitude: 26.4 ± 11.3 mm) for the tumors and 15.5 ± 7.3 mm in the AP direction (magnitude: 20.4 ± 7.0 mm) for the imaging‐surrogate, respectively. The residual motion of the tumor (image registration) from intra‐fractional breath‐hold CBCTs was 2.2 ± 2.0 mm for SI, 1.4 ± 1.4 mm for RL, and 1.3 ± 1.3 mm for AP directions (magnitude: 3.5 ± 2.1 mm). The ratio of the actual dose coverage to 99%, 90%, and 50% of the target volume decreased by 0.95 ± 0.11, 0.96 ± 0.10, 0.99 ± 0.05, respectively. The mean percentage of the target volume covered by the prescribed dose decreased by 2.8 ± 4.4%. Conclusion: We demonstrated the intra‐fractional motion‐managed treatment strategy in breath‐hold Ethos CT‐STAR/SBRT using optical surface imaging and CBCT. While the controlled residual tumor motion measured at 3.5 mm exceeded the predetermined setup value of 2 mm, it is important to note that this motion still fell within the clinically acceptable range defined by the PTV margin of 5 mm. Nonetheless, additional caution is needed with intra‐fractional motion management in breath‐hold Ethos CT‐STAR/SBRT using optical surface imaging and CBCT. [ABSTRACT FROM AUTHOR]

Published

2024

9. Patient Immobilization, IGRT, Respiratory Motion Management

Author

Kumazaki, Yu, Mitsunobu, Igari, and Nagata, Yasushi, editor

Published

2023

10. Quality Assurance in SBRT

Author

Ozawa, Shuichi and Nagata, Yasushi, editor

Published

2023

11. Respiratory motion management using a single rapid MRI scan for a 0.35 T MRI‐Linac system.

Author

Chen, Sihao, Eldeniz, Cihat, Fraum, Tyler J., Ludwig, Daniel R., Gan, Weijie, Liu, Jiaming, Kamilov, Ulugbek S., Yang, Deshan, Gach, H. Michael, and An, Hongyu

Subjects

*LINEAR accelerators, *STANDARD deviations, *MAGNETIC resonance imaging, *FAST Fourier transforms, *VECTOR fields

Abstract

Background: MRI has a rapidly growing role in radiation therapy (RT) for treatment planning, real‐time image guidance, and beam gating (e.g., MRI‐Linac). Free‐breathing 4D‐MRI is desirable in respiratory motion management for therapy. Moreover, high‐quality 3D‐MRIs without motion artifacts are needed to delineate lesions. Existing MRI methods require multiple scans with lengthy acquisition times or are limited by low spatial resolution, contrast, and signal‐to‐noise ratio. Purpose: We developed a novel method to obtain motion‐resolved 4D‐MRIs and motion‐integrated 3D‐MRI reconstruction using a single rapid (35‐45 s scan on a 0.35 T MRI‐Linac. Methods: Golden‐angle radial stack‐of‐stars MRI scans were acquired from a respiratory motion phantom and 12 healthy volunteers (n = 12) on a 0.35 T MRI‐Linac. A self‐navigated method was employed to detect respiratory motion using 2000 (acquisition time = 5–7 min) and the first 200 spokes (acquisition time = 35–45 s). Multi‐coil non‐uniform fast Fourier transform (MCNUFFT), compressed sensing (CS), and deep‐learning Phase2Phase (P2P) methods were employed to reconstruct motion‐resolved 4D‐MRI using 2000 spokes (MCNUFFT2000) and 200 spokes (CS200 and P2P200). Deformable motion vector fields (MVFs) were computed from the 4D‐MRIs and used to reconstruct motion‐corrected 3D‐MRIs with the MOtion Transformation Integrated forward‐Fourier (MOTIF) method. Image quality was evaluated quantitatively using the structural similarity index measure (SSIM) and the root mean square error (RMSE), and qualitatively in a blinded radiological review. Results: Evaluation using the respiratory motion phantom experiment showed that the proposed method reversed the effects of motion blurring and restored edge sharpness. In the human study, P2P200 had smaller inaccuracy in MVFs estimation than CS200. P2P200 had significantly greater SSIMs (p < 0.0001) and smaller RMSEs (p < 0.001) than CS200 in motion‐resolved 4D‐MRI and motion‐corrected 3D‐MRI. The radiological review found that MOTIF 3D‐MRIs using MCNUFFT2000 exhibited the highest image quality (scoring > 8 out of 10), followed by P2P200 (scoring > 5 out of 10), and then motion‐uncorrected (scoring < 3 out of 10) in sharpness, contrast, and artifact‐freeness. Conclusions: We have successfully demonstrated a method for respiratory motion management for MRI‐guided RT. The method integrated self‐navigated respiratory motion detection, deep‐learning P2P 4D‐MRI reconstruction, and a motion integrated reconstruction (MOTIF) for 3D‐MRI using a single rapid MRI scan (35‐45 s) on a 0.35 T MRI‐Linac system. [ABSTRACT FROM AUTHOR]

Published

2023

12. Feasibility study of deep learning‐based markerless real‐time lung tumor tracking with orthogonal X‐ray projection images.

Author

Zhou, Dejun, Nakamura, Mitsuhiro, Mukumoto, Nobutaka, Matsuo, Yukinori, and Mizowaki, Takashi

Subjects

X-ray imaging, ORTHOGRAPHIC projection, LUNG tumors, DEEP learning, IMAGING systems, MEDIAN (Mathematics)

Abstract

Purpose: The feasibility of a deep learning‐based markerless real‐time tumor tracking (RTTT) method was retrospectively studied with orthogonal kV X‐ray images and clinical tracking records acquired during lung cancer treatment. Methods: Ten patients with lung cancer treated with marker‐implanted RTTT were included. The prescription dose was 50 Gy in four fractions, using seven‐ to nine‐port non‐coplanar static beams. This corresponds to 14–18 X‐ray tube angles for an orthogonal X‐ray imaging system rotating with the gantry. All patients underwent 10 respiratory phases four‐dimensional computed tomography. After a data augmentation approach, for each X‐ray tube angle of a patient, 2250 digitally reconstructed radiograph (DRR) images with gross tumor volume (GTV) contour labeled were obtained. These images were adopted to train the patient and X‐ray tube angle‐specific GTV contour prediction model. During the testing, the model trained with DRR images predicted GTV contour on X‐ray projection images acquired during treatment. The predicted three‐dimensional (3D) positions of the GTV were calculated based on the centroids of the contours in the orthogonal images. The 3D positions of GTV determined by the marker‐implanted RTTT during the treatment were considered as the ground truth. The 3D deviations between the prediction and the ground truth were calculated to evaluate the performance of the model. Results: The median GTV volume and motion range were 7.42 (range, 1.18–25.74) cm3 and 22 (range, 11–28) mm, respectively. In total, 8993 3D position comparisons were included. The mean calculation time was 85 ms per image. The overall median value of the 3D deviation was 2.27 (interquartile range: 1.66–2.95) mm. The probability of the 3D deviation smaller than 5 mm was 93.6%. Conclusions: The evaluation results and calculation efficiency show the proposed deep learning‐based markerless RTTT method may be feasible for patients with lung cancer. [ABSTRACT FROM AUTHOR]

Published

2023

13. Intrafraction target shift comparison using two breath-hold systems in lung stereotactic body radiotherapy

Author

Alejandro Prado, Daniel Zucca, Miguel Ángel De la Casa, Jaime Martí, Leyre Alonso, Paz García de Acilu, Juan García, Ovidio Hernando, Pedro Fernández-Letón, and Carmen Rubio

Subjects

Stereotactic Body Radiotherapy, Respiratory motion management, Deep inspiration breath-hold, Intrafraction motion estimation, Surface-guidance system, Spirometry-based system, Medical physics. Medical radiology. Nuclear medicine, R895-920, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Background and purpose: In lung Stereotactic Body Radiotherapy (SBRT) respiratory management is used to reduce target motion due to respiration. This study aimed (1) to estimate intrafraction shifts through a Cone Beam Computed Tomography (CBCT) acquired during the first treatment arc when deep inspiration breath-hold (DIBH) was performed using spirometry-based (SB) or surface-guidance (SG) systems and (2) to analyze the obtained results depending on lesion localization. Material and methods: A sample of 157 patients with 243 lesions was analyzed. A total of 860 and 410 fractions were treated using SB and SG. Averaged intrafraction shifts were estimated by the offsets obtained when registering a CBCT acquired during the first treatment arc with the planning CT. Offsets were recorded in superior-inferior (SI), left–right (LR) and anterior-posterior (AP). Significance tests were applied to account for differences in average offsets and variances between DIBH systems. Systematic and random errors were computed. Results: Average offset moduli were 2.4 ± 2.2 mm and 3.5 ± 2.6 mm for SB and SG treatments (p 0.3). However, variances were statistically smaller for SB than for SG (p

Published

2022

14. Effectiveness of 4-dimensional maximum intensity projection (4D-MIP) for respiratory motion management with uncertain interobserver delineation.

Author

Hinai S, Usui K, Obara Y, Maebayashi T, Ookubo S, Ichikawa A, Sasaki Y, and Ozawa K

Abstract

This study was conducted to evaluate the use of 4-dimensional (4D) maximum intensity projection (4D-MIP) to compensate for the disadvantages of average intensity projection (AIP), which is used to determine the internal target volume (ITV) in lung tumors. A respiratory motion phantom with a simulated tumor was imaged using 4D computed tomography (4D-CT). AIP and 4D-MIP were generated based on 10 phases of 4D-CT, followed by contouring of the ITV AIP and ITV MIP ; these were compared with the ITV contoured in 10 phases of 4D-CT (ITV 10 ). Additionally, the profile curves of the ITV AIP and ITV MIP were obtained, and the full width at half maximum (FWHM) was measured. There was no significant difference between the ITV 10 and ITV MIP ; however, the ITV AIP demonstrated a lower value. The FWHM values of the ITV AIP were smaller than those of ITV MIP owing to decreased CT values in the superior-inferior margin. 4D-MIP may contribute to improving the consistency of the ITV delineation., Competing Interests: Declaration of competing interest The authors have no conflicts of interest to declare., (Copyright © 2024 American Association of Medical Dosimetrists. Published by Elsevier Inc. All rights reserved.)

Published

2025

15. Results from the AAPM Task Group 324 respiratory motion management in radiation oncology survey.

Author

Ball, Helen J., Santanam, Lakshmi, Senan, Suresh, Tanyi, James A., van Herk, Marcel, and Keall, Paul J.

Subjects

BREAST, CANCER radiotherapy, ONCOLOGY, RADIATION, BREAST cancer, CANCER patients, VENTILATION

Abstract

Purpose: To quantify the clinical practice of respiratory motion management in radiation oncology. Methods: A respiratory motion management survey was designed and conducted based on clinician survey guidelines. The survey was administered to American Association of Physicists in Medicine (AAPM) members on 17 August 2020 and closed on 13 September 2020. Results: A total of 527 respondents completed the entire survey and 651 respondents completed part of the survey, with the partially completed surveys included in the analysis. Overall, 84% of survey respondents used deep inspiration breath hold for left‐sided breast cancer. Overall, 83% of respondents perceived respiratory motion management for thoracic and abdominal cancer radiotherapy patients to be either very important or required. Overall, 95% of respondents used respiratory motion management for thoracic and abdominal sites, with 36% of respondents using respiratory motion management for at least 90% of thoracic and abdominal patients. The majority (60%) of respondents used the internal target volume method to treat thoracic and abdominal cancer patients, with 25% using breath hold or abdominal compression and 13% using gating or tracking. Conclusions: A respiratory motion management survey has been completed by AAPM members. Respiratory motion management is generally considered very important or required and is widely used for breast, thoracic, and abdominal cancer treatments. [ABSTRACT FROM AUTHOR]

Published

2022

16. Research on motion management in stereotactic body radiotherapy for lung cancer

Author

CAO Nannan and NI Xinye

Subjects

non-small cell lung cancer, stereotactic body radiotherapy, image-guided, respiratory motion management, immobilization device, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798, Medical physics. Medical radiology. Nuclear medicine, R895-920

Abstract

Stereotactic body radiotherapy, a hypofractionated radiation therapy method with fewer fractions and a large single radiation dose, is the preferred method for treating patients with early-stage non-small cell lung cancer who are clinically unsuitable for or refuse surgery. Accuracy and repeatability requirements of the target position are, therefore, necessary. In view of this, adjuvant treatments such as image-guided and respiratory motion management technology and immobilization devices are used clinically to reduce the impact of respiratory motion. This paper summarizes the research status of these approaches and proposes future directions based on the problems existing in each technology.

Published

2023

17. Motion Management

Author

Terunuma, Toshiyuki, Tsuboi, Koji, editor, Sakae, Takeji, editor, and Gerelchuluun, Ariungerel, editor

Published

2020

18. Initial estimates of continuous positive airway pressure (CPAP) on heart volume, position and motion in patients receiving chest radiation.

Author

Weizman, Noam, Baidun, Khader, Goldstein, Adam, Amit, Uri, Saad, Akram, Lawrence, Yaacov Richard, Appel, Sarit, Orion, Itzhak, Alezra, Dror, Abrams, Ross, Symon, Zvi, and Goldstein, Jeffrey

Subjects

*CONTINUOUS positive airway pressure, *LUNGS, *HEART, *LUNG volume

Abstract

To evaluate effects of Continuous Positive Airway Pressure (CPAP) on cardiac position, volume, and motion in a cohort of patients receiving thoracic radiation therapy (RT). Patients underwent 3-dimensional (3D) and 4D-computerized tomography (CT) imaging with free-breathing (FB) and CPAP for RT planning. All scans were co-registered on the treatment planning system for contouring, identification of the center of heart volume and comparative measurements of cardiac displacement, volume and motion. Heart volume (HV) was created from 3D-CT contours. Range of heart motion was estimated by creating an internal heart volume (IHV) from 4D-CT contours. Magnitude of cardiac motion (cardiac excursion) was recorded as the difference in volume between IHV and HV. Wilcoxon signed rank test and Spearmen's rank correlation coefficient were used to assess differences between variables and correlations between lung volume and heart parameters. Results from 9 patient data sets were available for this report. Compared to FB, CPAP use was associated with caudal displacement of the HV (1 cm, p < 0.008) and IHV (1.1 cm, p < 0.008). CPAP use decreased HV 6% (p < 0.008) and IHV 13% (p < 0.008). Cardiac excursion was 49% (p < 0.01) less with CPAP than with FB. CPAP use increased mean lung volume by 30% (p < 0.008) which correlated with caudal displacement of the HV (r = 0.83, p < 0.008) and IHV (r = 0.98, p < 0.001). The use of CPAP reduced cardiac motion and volume although the reduction in volume was minimal. The increase in lung volume correlated with caudal displacement of the heart. These results suggest the mechanism for achieving dosimetric benefit was obtained by cardiac displacement and decreased lung and heart motion rather than reduction of HV. Further evaluation of CPAP as a novel technique to reduce heart exposure when offering RT is warranted. [ABSTRACT FROM AUTHOR]

Published

2022

19. Effect of patient and tumor characteristics on respiratory motion in early-stage peripheral lung cancer (Tis ~ T2bN0M0) treated with stereotactic body radiation therapy (SBRT).

Author

Mitsuhashi N, Tominaga D, Ikeda H, Shiina F, Fukaya K, and Nemoto Y

Abstract

Background: Recent advances in stereotactic body radiation therapy (SBRT) technology for early-stage peripheral lung cancer have been remarkable and are becoming a viable alternative to surgery. However, the most important problem in performing SBRT correctly is minimizing the respiratory motion of the tumor., Materials and Methods: Thirty-eight patients treated with SBRT were evaluated to clarify factors affecting respiratory motion of early-stage peripheral lung cancer in the management of restrictive breathing technique (abdominal compression) to reduce respiratory tumor motion in SBRT. We investigated age, gender, body mass index (BMI), Brinkman index (BI), forced expiratory volume in 1 second (FEV 1.0), and type of ventilatory impairment as patient factors, and T-factor, stage, tumor-bearing lung lobe, and tumor pathology as tumor factors. Respiratory motion was assessed by volume differences between clinical target volume (CTV) and internal target volume (ITV). The degree of tumor motion due to respiration was compared using the formula of (ITV-CTV)/CTV as an index., Results: In the results, univariate analyses showed that only age was a significant predictor of respiratory tumor motion (p = 0.048). In multi-variate analyses, only T factor was an independent significant predictor of respiratory tumor motion (p = 0.045), while there was a significant trend for age (p = 0.061), and tumor location (p = 0.067)., Conclusions: In late elderly patients or T1a tumor, respiratory motion in early-stage peripheral lung cancer was significantly large. However, it is not predictable by patient and tumor characteristics. Therefore, respiratory motion of the tumor should be measured in all patients in some way., Competing Interests: Conflict of interests: The authors declare no conflict of interests., (© 2024 Greater Poland Cancer Centre.)

Published

2024

20. Respiratory motion management for external radiotherapy treatment.

Author

Darréon, J., Bouilhol, G., Aillières, N., Bouscayrol, H., Simon, L., and Ayadi, M.

Subjects

*RADIOTHERAPY treatment planning, *VENTILATION monitoring, *CANCER radiotherapy, *STEREOTACTIC radiotherapy, *DOSE fractionation

Abstract

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). [ABSTRACT FROM AUTHOR]

Published

2022

21. Visually guided respiratory motion management for Ethos adaptive radiotherapy.

Author

Kim, Taeho, Ji, Zhen, Lewis, Benjamin, Laugeman, Eric, Price, Alex, Hao, Yao, Hugo, Geoffrey, Knutson, Nels, Cai, Bin, Kim, Hyun, and Henke, Lauren

Subjects

CONE beam computed tomography, MAGNETIC resonance imaging, MOTION detectors, PRESSURE sensors, AIR pressure

Abstract

Purpose: Ethos adaptive radiotherapy (ART) is emerging with AI‐enhanced adaptive planning and high‐quality cone‐beam computed tomography (CBCT). Although a respiratory motion management solution is critical for reducing motion artifacts on abdominothoracic CBCT and improving tumor motion control during beam delivery, our institutional Ethos system has not incorporated a commercial solution. Here we developed an institutional visually guided respiratory motion management system to coach patients in regular breathing or breath hold during intrafractional CBCT scans and beam delivery with Ethos ART. Methods: The institutional visual‐guidance respiratory motion management system has three components: (1) a respiratory motion detection system, (2) an in‐room display system, and (3) a respiratory motion trace management software. Each component has been developed and implemented in the clinical Ethos ART workflow. The applicability of the solution was demonstrated in installation, routine QA, and clinical workflow. Results: An air pressure sensor has been utilized to detect patient respiratory motion in real time. Either a commercial or in‐house software handled respiratory motion trace display, collection and visualization for operators, and visual guidance for patients. An extended screen and a projector on an adjustable stand were installed as the in‐room visual guidance solution for the closed‐bore ring gantry medical linear accelerator utilized by Ethos. Consistent respiratory motion traces and organ positions on intrafractional CBCTs demonstrated the clinical suitability of the proposed solution in Ethos ART. Conclusion: The study demonstrated the utilization of an institutional visually guided respiratory motion management system for Ethos ART. The proposed solution can be easily applied for Ethos ART and adapted for use with any closed bore‐type system, such as computed tomography and magnetic resonance imaging, through incorporation with appropriate respiratory motion sensors. [ABSTRACT FROM AUTHOR]

Published

2022

22. Dosimetric evaluation of deep inspiration breath hold for left-sided breast cancer: analysis of patient-specific parameters related to heart dose reduction.

Author

Yamauchi, Ryohei, Mizuno, Norifumi, Itazawa, Tomoko, Saitoh, Hidetoshi, and Kawamori, Jiro

Subjects

BREAST cancer treatment, RADIATION dosimetry, BREATH holding

Abstract

Deep inspiration breath hold (DIBH) is a common method used worldwide for reducing the radiation dose to the heart. However, few studies have reported on the relationship between dose reduction and patient-specific parameters. The aim of this study was to compare the reductions of heart dose and volume using DIBH with the dose/volume of free breathing (FB) for patients with left-sided breast cancer and to analyse patient-specific dose reduction parameters. A total of 85 Asian patients who underwent whole-breast radiotherapy after breast-conserving surgery were recruited. Treatment plans for FB and DIBH were retrospectively generated by using an automated breast planning tool with a two-field tangential intensity-modulated radiation therapy technique. The prescribed dose was 50 Gy in 25 fractions. The dosimetric parameters (e.g., mean dose and maximum dose) in heart and lung were extracted from the dose–volume histogram. The relationships between dose–volume data and patient-specific parameters, such as age, body mass index (BMI), and inspiratory volume, were analyzed. The mean heart doses for the FB and DIBH plans were 1.56 Gy and 0.75 Gy, respectively, a relative reduction of 47%. There were significant differences in all heart dosimetric parameters (p  < 0.001). For patients with a high heart dose in the FB plan, a relative reduction of the mean heart dose correlated with inspiratory volume (r  = 0.646). There was correlation between the relative reduction of mean heart dose and BMI (r  = −0.248). We recommend considering the possible feasibility of DIBH in low BMI patients because the degree of benefit from DIBH varied with BMI. [ABSTRACT FROM AUTHOR]

Published

2020

23. Evaluation of the target dose coverage of stereotactic body radiotherapy for lung cancer using helical tomotherapy: A dynamic phantom study.

Author

Saito, Masahide, Suzuki, Hidekazu, Sano, Naoki, Ashizawa, Kazunari, Yoshizawa, Kazuya, Shibata, Yuki, Ueda, Koji, Komiyama, Takafumi, Marino, Kan, Aoki, Shinichi, Saito, Ryo, Maehata, Yoshiyasu, and Onishi, Hiroshi

Abstract

To evaluate the target dose coverage for lung stereotactic body radiotherapy (SBRT) using helical tomotherapy (HT) with the internal tumor volume (ITV) margin settings adjusted according to the degree of tumor motion. Lung SBRT with HT may cause a dosimetric error when the target motion is large. Two lung SBRT plans were created using a tomotherapy planning station. Using these original plans, five plans with different ITV margins (4.0–20.0 mm for superior-inferior [SI] dimension) were generated. To evaluate the effects of respiratory motion on HT, an original dynamic motion phantom was developed. The respiratory wave of a healthy volunteer was used for dynamic motion as the typical tumor respiratory motion. Five patterns of motion amplitude that corresponded to five ITV margin sizes and three breathing cycles of 7, 14, and 28 breaths per minute were used. We evaluated the target dose change between a static delivery and a dynamic delivery with each motion pattern. The target dose difference increased as the tumor size decreased and as the tumor motion increased. Although a target dose difference of <5 % was observed at ≤10 mm of tumor motion for each condition, a maximum difference of -9.94 % ± 7.10 % was observed in cases of small tumors with 20 mm of tumor motion under slow respiration. Minimizing respiratory movement is recommended as much as possible for lung SBRT with HT, especially for cases involving small tumors. [ABSTRACT FROM AUTHOR]

Published

2020

24. The impact of audio-visual biofeedback with a patient-specific guiding waveform on respiratory motion management: Comparison of two different respiratory management systems

Author

Nakajima, Y., Kadoya, N., Kida, S., Ito, K., Kanai, T., Kishi, K., Sato, K., Dobashi, S., Takeda, K., Matsushita, H, Jingu, K., MAGJAREVIC, Ratko, Editor-in-chief, Ladyzynsk, Piotr, Series editor, Ibrahim, Fatimah, Series editor, Lacković, Igor, Series editor, Rock, Emilio Sacristan, Series editor, and Jaffray, David A., editor

Published

2015

25. Respiratory Motion Management

Author

Onishi, Hiroshi and Nagata, Yasushi, editor

Published

2015

26. New technologies for carbon-ion radiotherapy — Developments at the National Institute of Radiological Sciences, QST, Japan.

Author

Kanematsu, Nobuyuki, Furukawa, Takuji, Hara, Yousuke, Inaniwa, Taku, Iwata, Yoshiyuki, Mizushima, Kota, Mori, Shinichiro, and Shirai, Toshiyuki

Subjects

*LINEAR energy transfer, *TECHNOLOGICAL innovations, *RADIOISOTOPE brachytherapy, *RADIOTHERAPY, *CARBON nanofibers, *MEDICAL care

Abstract

The National Institute of Radiological Sciences in Japan started clinical studies of carbon-ion radiotherapy (CIRT) in 1994. Due to the high linear energy transfer (LET) of highly charged particles, carbon-ion beams show high relative biological effectiveness in cell killing, especially at the Bragg peak of dose near the beam range, which is controlled to conform to a tumor. Recent technological developments for CIRT include fast pencil-beam scanning, fluoroscopic respiratory motion management, advanced beam modeling for treatment planning, and a superconducting rotating gantry, which have contributed to accuracy, precision, and conformation of dose, operational efficiency, and patient comfort. With technological maturity, CIRT facilities are rapidly increasing in Asia and Europe. Ongoing developments include extension to multiple ion species and facility downsizing to raise the quality and availability of ion-beam therapy in medical care. [ABSTRACT FROM AUTHOR]

Published

2019

27. Optimization of motion management parameters in a synchrotron‐based spot scanning system.

Author

Johnson, Jedediah E., Herman, Michael G., and Kruse, Jon J.

Subjects

SCANNING systems, INDUSTRIAL efficiency, SYNCHROTRONS, RESPIRATORY organs, PROTON beams, THREE-dimensional modeling

Abstract

Purpose: To quantify the effects of combining layer‐based repainting and respiratory gating as a strategy to mitigate the dosimetric degradation caused by the interplay effect between a moving target and dynamic spot‐scanning proton delivery. Methods: An analytic routine modeled three‐dimensional dose distributions of pencil‐beam proton plans delivered to a moving target. Spot positions and weights were established for a single field to deliver 100 cGy to a static, 15‐cm deep, 3‐cm radius spherical clinical target volume with a 1‐cm isotropic internal target volume expansion. The interplay effect was studied by modeling proton delivery from a clinical synchrotron‐based spot scanning system and respiratory target motion, patterned from surrogate patient breathing traces. Motion both parallel and orthogonal to the beam scanning direction was investigated. Repainting was modeled using a layer‐based technique. For each of 13 patient breathing traces, the dose from 20 distinct delivery schemes (combinations of four gate window amplitudes and five repainting techniques) was computed. Delivery strategies were inter‐compared based on target coverage, dose homogeneity, high dose spillage, and delivery time. Results: Notable degradation and variability in plan quality were observed for ungated delivery. Decreasing the gate window reduced this variability and improved plan quality at the expense of longer delivery times. Dose deviations were substantially greater for motion orthogonal to the scan direction when compared with parallel motion. Repainting coupled with gating was effective at partially restoring dosimetric coverage at only a fraction of the delivery time increase associated with very small gate windows alone. Trends for orthogonal motion were similar, but more complicated, due to the increased severity of the interplay. Conclusions: Layer‐based repainting helps suppress the interplay effect from intra‐gate motion, with only a modest penalty in delivery time. The magnitude of the improvement in target coverage is strongly influenced by individual patient breathing patterns and the tumor motion trajectory. [ABSTRACT FROM AUTHOR]

Published

2019

28. A novel deformable lung phantom with programably variable external and internal correlation.

Author

Ranjbar, Maida, Sabouri, Pouya, Repetto, Carlo, and Sawant, Amit

Subjects

*LUNGS, *COMPLEX variables, *LUNG cancer, *FLUOROSCOPY, *SACROILIAC joint

Abstract

Purpose: Lung motion phantoms used to validate radiotherapy motion management strategies have fairly simplistic designs that do not adequately capture complex phenomena observed in human respiration such as external and internal deformation, variable hysteresis and variable correlation between different parts of the thoracic anatomy. These limitations make reliable evaluation of sophisticated motion management techniques quite challenging. In this work, we present the design and implementation of a programmable, externally and internally deformable lung motion phantom that allows for a reproducible change in external–internal and internal–internal correlation of embedded markers. Methods: An in‐house–designed lung module, made from natural latex foam was inserted inside the outer shell of a commercially available lung phantom (RSD, Long Beach, CA, USA). Radiopaque markers were placed on the external surface and embedded into the lung module. Two independently programmable high‐precision linear motion actuators were used to generate primarily anterior–posterior (AP) and primarily superior–inferior (SI) motion in a reproducible fashion in order to enable (a) variable correlation between the displacement of interior volume and the exterior surface, (b) independent changes in the amplitude of the AP and SI motions, and (c) variable hysteresis. The ability of the phantom to produce complex and variable motion accurately and reproducibly was evaluated by programming the two actuators with mathematical and patient‐recorded lung tumor motion traces, and recording the trajectories of various markers using kV fluoroscopy. As an example application, the phantom was used to evaluate the performance of lung motion models constructed from kV fluoroscopy and 4DCT images. Results: The phantom exhibited a high degree of reproducibility and marker motion ranges were reproducible to within 0.5 mm. Variable correlation was observed between the displacements of internal–internal and internal–external markers. The SI and AP components of motion of a specific marker had a correlation parameter that varied from −11 to 17. Monitoring a region of interest on the phantom's surface to estimate internal marker motion led to considerably lower uncertainties than when a single point was monitored. Conclusions: We successfully designed and implemented a programmable, externally and internally deformable lung motion phantom that allows for a reproducible change in external–internal and internal–internal correlation of embedded markers. [ABSTRACT FROM AUTHOR]

Published

2019

29. SBRT targets that move with respiration.

Author

Dieterich, Sonja, Green, Olga, and Booth, Jeremy

Abstract

Highlights • Summary of image guidance to localize the target in real-time for intra-fraction motion. • Discussion of state-of-the art respiratory motion management. • Approaches to real-time tracking. • Real-time tracking technologies in clinical trial and clinical use. • Clinical application of real-time MRI soft-tissue imaging for real-time adaptive treatments. Abstract The technology of treating SBRT targets that move with respiration has undergone profound changes over the last 20 years. This review article summarizes modern image guidance to localize the target in real-time to account for intra-fraction motion. The state-of-the art respiratory motion compensation techniques will be discussed, including the determination and application of appropriate margins. This includes compression, gating and breath-hold, including the use of audiovisual feedback to manage motion. Approaches to real-time tracking include the use of hybrid external-internal imaging to build a skin-to-tumor correlation, which can then be tracked with a mobile robot (CyberKnife Synchrony, clinical since 2003) as well as the use of non-ionizing electromagnetic tumor surrogate localization followed by real-time tracking with a moving MLC (in clinical trials in Europe and Australia). Lastly, the clinical application of real-time MRI soft-tissue imaging to deliver adaptive, iso-toxic treatments will be presented. [ABSTRACT FROM AUTHOR]

Published

2018

30. Stereotactic body radiotherapy for lung tumors: Dosimetric analysis and clinical outcome.

Author

Talapatra, Kaustav, Majumder, Dipanjan, Chadha, Pranav, P., Shaju, Goyle, Sandeep, B. K., Smruti, Mistry, Rajesh, Shaju, P, and Smruti, B K

Subjects

*RADIOTHERAPY, *LUNG tumors, *THERAPEUTICS, *COMPUTED tomography, *ONCOLOGY, *RADIATION measurements, *RADIOSURGERY, *TREATMENT effectiveness, *ARTHRITIS Impact Measurement Scales

Abstract

Introduction: Stereotactic body radiotherapy (SBRT) has emerged as an important modality in malignant lung tumor treatment both in early localized primary and oligometastatic setting. This study aims to present the results of lung SBRT both in terms of dosimetry and clinical outcome.Materials and Methods: Twenty-seven patients were assessed from 2012 to 2016. Both the primary and oligometastatic lung tumors were evaluated. Respiratory motion management was done employing ANZAI (Siemens, Germany) based four-dimensional computed tomography (CT). Commonly used fractionations were 60 Gy/5 fractions for peripheral tumors and 48 Gy/6 fractions for central tumors. Radiation Therapy Oncology Group toxicity criteria were used for toxicity and whole-body positron emission tomography-CT scan was done at follow-up for response evaluation.Results: Twenty-seven patients were evaluated, 18 (66.7%) patients had a primary, and 9 (33.3%) patients had metastatic lung tumors. The male-to-female ratio for the entire cohort was 2:1. The median age at diagnosis was 65.8 years. Mean planning target volume (PTV) D2cc was 54.9 ± 9.04 Gy and mean internal target volume diameter was 3.0 ± 1.07 cm. Mean V20 Gy, V10 Gy, and V5 Gy of (lungs total-PTV) and (Lung ipsilateral - PTV) were 5.4 ± 4% and 10.9 ± 7.9%, 11.7 ± 5.8% and 24.2 ± 14.0%, and 22.05 ± 12.4% and 33.2 ± 15.3%, respectively. In total 21 (84%) patients and 4 patients (16%) showed a complete and partial response, respectively. One (3%) patient developed Gr 3 radiation pneumonitis. One year local control was in 18 (81%) patients whereas 4 (14%) patients progressed and three patients did not report. A higher prescribed dose significantly correlated with 1 year tumor control (P = 0.036).Conclusion: This study infers the feasibility and a favorable outcome for lung cancer amenable to SBRT in addition to being one of the largest clinical experiences for lung stereotactic treatment in our country. [ABSTRACT FROM AUTHOR]

Published

2018

31. Results from the AAPM Task Group 324 respiratory motion management in radiation oncology survey

Author

Helen J. Ball, Lakshmi Santanam, Suresh Senan, James A. Tanyi, Marcel van Herk, Paul J. Keall, Biomedical Engineering and Physics, Radiation Oncology, and CCA - Cancer Treatment and quality of life

Subjects

Radiation, clinical survey, Radiotherapy Planning, Computer-Assisted, Radiotherapy Dosage, respiratory motion management, United States, patterns of practice, Breath Holding, Motion, Surveys and Questionnaires, Radiation Oncology, Humans, Radiology, Nuclear Medicine and imaging, Tomography, X-Ray Computed, Instrumentation

Abstract

Purpose: To quantify the clinical practice of respiratory motion management in radiation oncology. Methods: A respiratory motion management survey was designed and conducted based on clinician survey guidelines. The survey was administered to American Association of Physicists in Medicine (AAPM) members on 17 August 2020 and closed on 13 September 2020. Results: A total of 527 respondents completed the entire survey and 651 respondents completed part of the survey, with the partially completed surveys included in the analysis. Overall, 84% of survey respondents used deep inspiration breath hold for left-sided breast cancer. Overall, 83% of respondents perceived respiratory motion management for thoracic and abdominal cancer radiotherapy patients to be either very important or required. Overall, 95% of respondents used respiratory motion management for thoracic and abdominal sites, with 36% of respondents using respiratory motion management for at least 90% of thoracic and abdominal patients. The majority (60%) of respondents used the internal target volume method to treat thoracic and abdominal cancer patients, with 25% using breath hold or abdominal compression and 13% using gating or tracking. Conclusions: A respiratory motion management survey has been completed by AAPM members. Respiratory motion management is generally considered very important or required and is widely used for breast, thoracic, and abdominal cancer treatments.

Published

2022

32. Development of an Educational Workshop on the Practical Application of Respiratory Motion Management Techniques for Radiation Oncology Trainees.

Author

Ward, Kristin A, Bejarano, Tatiana, Wood, Emily, Romano, Kara D, Scarboro, Sarah B, Wijesooriya, Krishni, and Janowski, Einsley M

Subjects

*EDUCATION conferences, *MEDICAL students, *RESIDENTS (Medicine), *EDUCATIONAL planning, *IMAGE-guided radiation therapy, *SCHOOL holding power

Abstract

Respiratory motion management (RMM) is an important tool that is increasingly utilized in the era of image-guided radiation therapy. There are several different techniques available to limit tumor motion during respiration with the goal of allowing for effective dose escalation to the target, while limiting toxicity to nearby organs at risk. Selection of the appropriate RMM tool depends on the clinical scenario and requires input from the treating physician and/or residents and medical physics staff, however, there is a paucity in trainee education on the various RMM methods. The purpose of this initiative was to develop a formal didactic and hands on experience for our trainees that described the RMM tools available and the appropriate clinical scenarios in which to best implement these specific techniques. Trainees (medical and physics residents as well as medical students) participated in a two-phase educational workshop: a 45 minute didactic session followed by a hands-on demonstration of RMM modalities and pertinent software for motion evaluation. Each participant completed pre- and post-workshop surveys assessing their confidence on RMM (based on a 5-point Likert scale) and knowledge based quizzes to assess their understanding of the various RMM techniques. Participant scores were paired for statistical analysis using Wilcoxon-Rank Sum and student T-tests. This educational workshop was held annually in 2021 and 2022. There were 7 participants (5 medical and 2 physics residents) in 2021 and 9 (2 medical students, 6 medical, and 1 physics resident) that participated in 2022. For all participants, there was a significant increase in self-reported post-workshop confidence in RMM techniques (median 3.625 pre- vs 4.634 post-workshop, p=0.018 in 2021 and median 1.125 vs 3.750, p=0.008 in 2022). There was also a significant increase in the participants' scores in the post-workshop knowledge based quizzes (mean 85.71% vs 92.86%, p=0.03 in 2021 and mean 48.60% vs 87.50%, p=0.008 in 2022). In order to optimize patient care, it is essential that RO trainees understand and are able to implement RMM techniques appropriately when treating intrathoracic and abdominal cavity tumors. This initiative showed that a dedicated educational workshop on RMM techniques significantly improved RO trainee's knowledge and confidence on the use of these important tools. Future aims of this project include continuing to offers this workshop annually to trainees to assess information retention and creation of a shared resource for trainees at other institutions. [ABSTRACT FROM AUTHOR]

Published

2022

33. Evaluating performance of a user‐trained MR lung tumor autocontouring algorithm in the context of intra‐ and interobserver variations.

Author

Yip, Eugene, Yun, Jihyun, Gabos, Zsolt, Baker, Sarah, Yee, Don, Wachowicz, Keith, Rathee, Satyapal, and Fallone, B. Gino

Subjects

*LUNG tumors, *PERFORMANCE evaluation, *REAL-time programming, *CANCER radiotherapy, *MAGNETIC resonance imaging of cancer, *DIAGNOSIS

Abstract

Purpose: Real‐time tracking of lung tumors using magnetic resonance imaging (MRI) has been proposed as a potential strategy to mitigate the ill‐effects of breathing motion in radiation therapy. Several autocontouring methods have been evaluated against a “gold standard” of a single human expert user. However, contours drawn by experts have inherent intra‐ and interobserver variations. In this study, we aim to evaluate our user‐trained autocontouring algorithm with manually drawn contours from multiple expert users, and to contextualize the accuracy of these autocontours within intra‐ and interobserver variations. Methods: Six nonsmall cell lung cancer patients were recruited, with institutional ethics approval. Patients were imaged with a clinical 3 T Philips MR scanner using a dynamic 2D balanced SSFP sequence under free breathing. Three radiation oncology experts, each in two separate sessions, contoured 130 dynamic images for each patient. For autocontouring, the first 30 images were used for algorithm training, and the remaining 100 images were autocontoured and evaluated. Autocontours were compared against manual contours in terms of Dice's coefficient (DC) and Hausdorff distances (dH). Intra‐ and interobserver variations of the manual contours were also evaluated. Results: When compared with the manual contours of the expert user who trained it, the algorithm generates autocontours whose evaluation metrics (same session: DC = 0.90(0.03), dH = 3.8(1.6) mm; different session DC = 0.88(0.04), dH = 4.3(1.5) mm) are similar to or better than intraobserver variations (DC = 0.88(0.04), and dH = 4.3(1.7) mm) between two sessions. The algorithm's autocontours are also compared to the manual contours from different expert users with evaluation metrics (DC = 0.87(0.04), dH = 4.8(1.7) mm) similar to interobserver variations (DC = 0.87(0.04), dH = 4.7(1.6) mm). Conclusions: Our autocontouring algorithm delineates tumor contours (<20 ms per contour), in dynamic MRI of lung, that are comparable to multiple human experts (several seconds per contour), but at a much faster speed. At the same time, the agreement between autocontours and manual contours is comparable to the intra‐ and interobserver variations. This algorithm may be a key component of the real time tumor tracking workflow for our hybrid Linac‐MR device in the future. [ABSTRACT FROM AUTHOR]

Published

2018

34. ITV, mid-ventilation, gating or couch tracking – A comparison of respiratory motion-management techniques based on 4D dose calculations.

Author

Ehrbar, Stefanie, Jöhl, Alexander, Tartas, Adrianna, Stark, Luisa Sabrina, Riesterer, Oliver, Klöck, Stephan, Guckenberger, Matthias, and Tanadini-Lang, Stephanie

Subjects

*RESPIRATORY measurements, *TUMOR dose, *STEREOTACTIC radiotherapy, *LUNG cancer, *TREATMENT of lung tumors, *RADIOTHERAPY treatment planning

Abstract

Purpose Respiratory motion-management techniques (MMT) aim to ensure tumor dose coverage while sparing lung tissue. Dynamic treatment-couch tracking of the moving tumor is a promising new MMT and was compared to the internal-target-volume (ITV) concept, the mid-ventilation (MidV) principle and the gating approach in a planning study based on 4D dose calculations. Methods For twenty patients with lung lesions, planning target volumes (PTV) were adapted to the MMT and stereotactic body radiotherapy treatments were prepared with the 65%-isodose enclosing the PTV. For tracking, three concepts for target volume definition were considered: Including the gross tumor volume of one phase (single-phase tracking), including deformations between phases (multi-phase tracking) and additionally including tracking latencies of a couch tracking system (reliable couch tracking). The accumulated tumor and lung doses were estimated with 4D dose calculations based on 4D-CT datasets and deformable image registration. Results Single-phase tracking showed the lowest ipsilateral lung Dmean (median: 3.3 Gy), followed by multi-phase tracking, gating, reliable couch tracking, MidV and ITV concepts (3.6, 3.8, 4.1, 4.3 and 4.8 Gy). The 4D dose calculations showed the MidV and single-phase tracking overestimated the target mean dose (−2.3% and −1.3%), while it was slightly underestimated by the other MMT (<+1%). Conclusion The ITV concept ensures tumor coverage, but exposes the lung tissue to a higher dose. The MidV, gating and tracking concepts were shown to reduce the lung dose. Neglecting non-translational changes of the tumor in the target volume definition for tracking results in a slightly reduced target coverage. The slightly inferior dose coverage for MidV should be considered when applying this technique clinically. [ABSTRACT FROM AUTHOR]

Published

2017

35. Respiratory motion-resolved, self-gated 4D- MRI using rotating cartesian k-space ( ROCK).

Author

Han, Fei, Zhou, Ziwu, Cao, Minsong, Yang, Yingli, Sheng, Ke, and Hu, Peng

Subjects

*RESPIRATION, *MAGNETIC resonance imaging, *RADIOTHERAPY treatment planning, *DATA binning, *COMPRESSED sensing

Abstract

Purpose To propose and validate a respiratory motion resolved, self-gated ( SG) 4D- MRI technique to assess patient-specific breathing motion of abdominal organs for radiation treatment planning. Methods The proposed 4D- MRI technique was based on the balanced steady-state free-precession ( bSSFP) technique and 3D k-space encoding. A novel rotating cartesian k-space ( ROCK) reordering method was designed which incorporates repeatedly sampled k-space centerline as the SG motion surrogate and allows for retrospective k-space data binning into different respiratory positions based on the amplitude of the surrogate. The multiple respiratory-resolved 3D k-space data were subsequently reconstructed using a joint parallel imaging and compressed sensing method with spatial and temporal regularization. The proposed 4D- MRI technique was validated using a custom-made dynamic motion phantom and was tested in six healthy volunteers, in whom quantitative diaphragm and kidney motion measurements based on 4D- MRI images were compared with those based on 2D- CINE images. Results The 5-minute 4D- MRI scan offers high-quality volumetric images in 1.2 × 1.2 × 1.6 mm3 and eight respiratory positions, with good soft-tissue contrast. In phantom experiments with triangular motion waveform, the motion amplitude measurements based on 4D- MRI were 11.89% smaller than the ground truth, whereas a −12.5% difference was expected due to data binning effects. In healthy volunteers, the difference between the measurements based on 4D- MRI and the ones based on 2D- CINE were 6.2 ± 4.5% for the diaphragm, 8.2 ± 4.9% and 8.9 ± 5.1% for the right and left kidney. Conclusion The proposed 4D- MRI technique could provide high-resolution, high-quality, respiratory motion-resolved 4D images with good soft-tissue contrast and are free of the 'stitching' artifacts usually seen on 4D- CT and 4D- MRI based on resorting 2D- CINE. It could be used to visualize and quantify abdominal organ motion for MRI-based radiation treatment planning. [ABSTRACT FROM AUTHOR]

Published

2017

36. Respiratory motion-management in stereotactic body radiation therapy for lung cancer – A dosimetric comparison in an anthropomorphic lung phantom (LuCa).

Author

Ehrbar, Stefanie, Perrin, Rosalind, Peroni, Marta, Bernatowicz, Kinga, Parkel, Thomas, Pytko, Izabela, Klöck, Stephan, Guckenberger, Matthias, Tanadini-Lang, Stephanie, Weber, Damien Charles, and Lomax, Antony

Subjects

*LUNG cancer treatment, *STEREOTACTIC radiotherapy, *RADIATION dosimetry, *ANTHROPOMORPHISM, *VENTILATION monitoring

Abstract

Background and purpose The objective of this study was to compare the latest respiratory motion-management strategies, namely the internal-target-volume (ITV) concept, the mid-ventilation (MidV) principle, respiratory gating and dynamic couch tracking. Materials and methods An anthropomorphic, deformable and dynamic lung phantom was used for the dosimetric validation of these techniques. Stereotactic treatments were adapted to match the techniques and five distinct respiration patterns, and delivered to the phantom while radiographic film measurements were taken inside the tumor. To report on tumor coverage, these dose distributions were used to calculate mean doses ( D mean ), changes in homogeneity indices (Δ H 2 - 98 ), gamma agreement, and areas covered by the planned minimum dose ( A >Dmin ). Results All techniques achieved good tumor coverage ( A >Dmin > 99.0%) and minor changes in D mean (±3.2%). Gating and tracking strategies showed superior results in gamma agreement and Δ H 2 - 98 compared to ITV and MidV concepts, which seem to be more influenced by the interplay and the gradient effect. For lung, heart and spinal cord, significant dose differences between the four techniques were found ( p < 0.05), with lowest doses for gating and tracking strategies. Conclusion Active motion-management techniques, such as gating or tracking, showed superior tumor dose coverage and better organ dose sparing than the passive techniques based on tumor margins. [ABSTRACT FROM AUTHOR]

Published

2016

37. Characterizing spatiotemporal information loss in sparse-sampling-based dynamic MRI for monitoring respiration-induced tumor motion in radiotherapy.

Author

Arai, Tatsuya J., Nofiele, Joris, Madhuranthakam, Ananth J., Yuan, Qing, Pedrosa, Ivan, Chopra, Rajiv, and Sawant, Amit

Subjects

*SPATIOTEMPORAL processes, *TUMORS, *CANCER radiotherapy, *COMPRESSED sensing, *IMAGE reconstruction, *STANDARD deviations, *MAGNETIC resonance imaging

Abstract

Purpose: Sparse-sampling and reconstruction techniques represent an attractive strategy to achieve faster image acquisition speeds, while maintaining adequate spatial resolution and signal-to-noise ratio in rapid magnetic resonance imaging (MRI). The authors investigate the use of one such sequence, broad-use linear acquisition speed-up technique (k-t BLAST) in monitoring tumor motion for thoracic and abdominal radiotherapy and examine the potential trade-off between increased sparsification (to increase imaging speed) and the potential loss of "true" information due to greater reliance on a priori information. Methods: Lung tumor motion trajectories in the superior–inferior direction, previously recorded from ten lung cancer patients, were replayed using a motion phantom module driven by an MRI-compatible motion platform. Eppendorf test tubes filled with water which serve as fiducial markers were placed in the phantom. The modeled rigid and deformable motions were collected in a coronal image slice using balanced fast field echo in conjunction with k-t BLAST. Root mean square (RMS) error was used as a metric of spatial accuracy as measured trajectories were compared to input data. The loss of spatial information was characterized for progressively increasing acceleration factor from 1 to 16; the resultant sampling frequency was increased approximately from 2.5 to 19 Hz when the principal direction of the motion was set along frequency encoding direction. In addition to the phantom study, respiration-induced tumor motions were captured from two patients (kidney tumor and lung tumor) at 13 Hz over 49 s to demonstrate the impact of high speed motion monitoring over multiple breathing cycles. For each subject, the authors compared the tumor centroid trajectory as well as the deformable motion during free breathing. Results: In the rigid and deformable phantom studies, the RMS error of target tracking at the acquisition speed of 19 Hz was approximately 0.3–0.4 mm, which was smaller than the reconstructed pixel resolution of 0.67 mm. In the patient study, the dynamic 2D MRI enabled the monitoring of cycle-to-cycle respiratory variability present in the tumor position. It was seen that the range of centroid motion as well as the area covered due to target motion during each individual respiratory cycle was underestimated compared to the entire motion range observed over multiple breathing cycles. Conclusions: The authors' initial results demonstrate that sparse-sampling- and reconstructionbased dynamic MRI can be used to achieve adequate image acquisition speeds without significant information loss for the task of radiotherapy guidance. Such monitoring can yield spatial and temporal information superior to conventional offline and online motion capture methods used in thoracic and abdominal radiotherapy. [ABSTRACT FROM AUTHOR]

Published

2016

38. Visually guided respiratory motion management for Ethos adaptive radiotherapy

Author

Hyun Jik Kim, Eric Laugeman, Bin Cai, Benjamin C. Lewis, Zhen Ji, Taeho Kim, Nels C. Knutson, A. Price, Lauren E. Henke, Yao Hao, and Geoffrey D. Hugo

Subjects

Computer science, Ethos, respiratory motion management, law.invention, Motion, Software, law, Technical Note, Humans, Radiology, Nuclear Medicine and imaging, Computer vision, Adaptive radiotherapy, Instrumentation, Radiation, business.industry, Visually guided, Radiotherapy Planning, Computer-Assisted, Respiration, Cone-Beam Computed Tomography, Visualization, Workflow, Projector, adaptive radiotherapy, Management system, visual guidance, Artificial intelligence, Technical Notes, Particle Accelerators, business

Abstract

Purpose Ethos adaptive radiotherapy (ART) is emerging with AI‐enhanced adaptive planning and high‐quality cone‐beam computed tomography (CBCT). Although a respiratory motion management solution is critical for reducing motion artifacts on abdominothoracic CBCT and improving tumor motion control during beam delivery, our institutional Ethos system has not incorporated a commercial solution. Here we developed an institutional visually guided respiratory motion management system to coach patients in regular breathing or breath hold during intrafractional CBCT scans and beam delivery with Ethos ART. Methods The institutional visual‐guidance respiratory motion management system has three components: (1) a respiratory motion detection system, (2) an in‐room display system, and (3) a respiratory motion trace management software. Each component has been developed and implemented in the clinical Ethos ART workflow. The applicability of the solution was demonstrated in installation, routine QA, and clinical workflow. Results An air pressure sensor has been utilized to detect patient respiratory motion in real time. Either a commercial or in‐house software handled respiratory motion trace display, collection and visualization for operators, and visual guidance for patients. An extended screen and a projector on an adjustable stand were installed as the in‐room visual guidance solution for the closed‐bore ring gantry medical linear accelerator utilized by Ethos. Consistent respiratory motion traces and organ positions on intrafractional CBCTs demonstrated the clinical suitability of the proposed solution in Ethos ART. Conclusion The study demonstrated the utilization of an institutional visually guided respiratory motion management system for Ethos ART. The proposed solution can be easily applied for Ethos ART and adapted for use with any closed bore‐type system, such as computed tomography and magnetic resonance imaging, through incorporation with appropriate respiratory motion sensors.

Published

2021

39. Dosimetric evaluation of deep inspiration breath hold for left-sided breast cancer: analysis of patient-specific parameters related to heart dose reduction

Author

Tomoko Itazawa, Hidetoshi Saitoh, Jiro Kawamori, Norifumi Mizuno, and Ryohei Yamauchi

Subjects

Adult, Health, Toxicology and Mutagenesis, medicine.medical_treatment, Breast Neoplasms, Common method, respiratory motion management, deep inspiration breath hold (DIBH), Mastectomy, Segmental, Radiation Dosage, Left sided, heart dose, 030218 nuclear medicine & medical imaging, Body Mass Index, Pattern Recognition, Automated, Breath Holding, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, breast cancer, medicine, Regular Paper, Unilateral Breast Neoplasms, Humans, Radiology, Nuclear Medicine and imaging, Computer Simulation, Obesity, Radiometry, Lung, Deep inspiration breath-hold, Aged, Retrospective Studies, Radiation, business.industry, Radiotherapy Planning, Computer-Assisted, Heart, Patient specific, Middle Aged, medicine.disease, Radiation therapy, Inhalation, 030220 oncology & carcinogenesis, Dose reduction, Female, Radiotherapy, Intensity-Modulated, Nuclear medicine, business, Tomography, X-Ray Computed, Body mass index

Abstract

Deep inspiration breath hold (DIBH) is a common method used worldwide for reducing the radiation dose to the heart. However, few studies have reported on the relationship between dose reduction and patient-specific parameters. The aim of this study was to compare the reductions of heart dose and volume using DIBH with the dose/volume of free breathing (FB) for patients with left-sided breast cancer and to analyse patient-specific dose reduction parameters. A total of 85 Asian patients who underwent whole-breast radiotherapy after breast-conserving surgery were recruited. Treatment plans for FB and DIBH were retrospectively generated by using an automated breast planning tool with a two-field tangential intensity-modulated radiation therapy technique. The prescribed dose was 50 Gy in 25 fractions. The dosimetric parameters (e.g., mean dose and maximum dose) in heart and lung were extracted from the dose–volume histogram. The relationships between dose–volume data and patient-specific parameters, such as age, body mass index (BMI), and inspiratory volume, were analyzed. The mean heart doses for the FB and DIBH plans were 1.56 Gy and 0.75 Gy, respectively, a relative reduction of 47%. There were significant differences in all heart dosimetric parameters (p

Published

2020

40. Optimization of motion management parameters in a synchrotron‐based spot scanning system

Author

Jedediah E. Johnson, Michael G. Herman, and Jon J. Kruse

Subjects

Organs at Risk, Materials science, medicine.medical_treatment, Movement, respiratory motion management, 030218 nuclear medicine & medical imaging, law.invention, 03 medical and health sciences, 0302 clinical medicine, Quality (physics), Optics, law, Neoplasms, medicine, Proton Therapy, Radiation Oncology Physics, Humans, Radiology, Nuclear Medicine and imaging, Four-Dimensional Computed Tomography, Radiometry, Instrumentation, repainting, Radiation, Particle therapy, business.industry, Phantoms, Imaging, Radiotherapy Planning, Computer-Assisted, Isotropy, Radiotherapy Dosage, Radius, Amplitude, particle therapy, 030220 oncology & carcinogenesis, Parallel motion, gating, Trajectory, Breathing, interplay effect, business, Synchrotrons

Abstract

Purpose To quantify the effects of combining layer‐based repainting and respiratory gating as a strategy to mitigate the dosimetric degradation caused by the interplay effect between a moving target and dynamic spot‐scanning proton delivery. Methods An analytic routine modeled three‐dimensional dose distributions of pencil‐beam proton plans delivered to a moving target. Spot positions and weights were established for a single field to deliver 100 cGy to a static, 15‐cm deep, 3‐cm radius spherical clinical target volume with a 1‐cm isotropic internal target volume expansion. The interplay effect was studied by modeling proton delivery from a clinical synchrotron‐based spot scanning system and respiratory target motion, patterned from surrogate patient breathing traces. Motion both parallel and orthogonal to the beam scanning direction was investigated. Repainting was modeled using a layer‐based technique. For each of 13 patient breathing traces, the dose from 20 distinct delivery schemes (combinations of four gate window amplitudes and five repainting techniques) was computed. Delivery strategies were inter‐compared based on target coverage, dose homogeneity, high dose spillage, and delivery time. Results Notable degradation and variability in plan quality were observed for ungated delivery. Decreasing the gate window reduced this variability and improved plan quality at the expense of longer delivery times. Dose deviations were substantially greater for motion orthogonal to the scan direction when compared with parallel motion. Repainting coupled with gating was effective at partially restoring dosimetric coverage at only a fraction of the delivery time increase associated with very small gate windows alone. Trends for orthogonal motion were similar, but more complicated, due to the increased severity of the interplay. Conclusions Layer‐based repainting helps suppress the interplay effect from intra‐gate motion, with only a modest penalty in delivery time. The magnitude of the improvement in target coverage is strongly influenced by individual patient breathing patterns and the tumor motion trajectory.

Published

2019

41. Respiratory motion management in radiotherapeutic treatment of non-small cell lung cancer

Author

Ebhardt, Constantin

Subjects

Management der Atembewegung, respiratory motion management, nicht-kleinzelliges Lungenkarzinom, radiation therapy, Strahlentherapie, non-small cell lung cancer

Abstract

Diese Arbeit befasst sich mit dem Management der Atembewegung bei der strahlentherapeutischen Behandlung des nicht-kleinzelligen Lungenkarzinoms (NSCLC). Das Lungenkarzinom stellt bei Männern die häufigste und bei Frauen die zweithäufigste Todesursache durch Krebs dar. Ziel dieser Arbeit ist es, herauszufinden, welche Methoden bei der strahlentherapeutischen Behandlung des NSCLC eingesetzt werden, um der Atembewegung entgegenzuwirken und welche Methoden eingesetzt werden, um die Atembewegung zu überprüfen. Zudem wird untersucht, ob es Unterschiede zwischen der Stereotaxie und anderen hochkonformalen Bestrahlungstechniken hinsichtlich dieser Methoden gibt. Zur Beantwortung der Forschungsfragen wurde eine umfassende Literaturrecherche in den Datenbanken PubMed, ScienceDirect, Cochrane und SpringerLink durchgeführt. Der Suchzeitraum für die Studien wurde auf die Jahre 2016 bis 2020 beschränkt, um deren Aktualität zu gewährleisten. Die Ergebnisse der Studien zeigen, dass Ganzkörper-Fixierungsapparate, Vakuumkissen, thermoplastisches Material, abdominale Kompression und Active Breathing Control (ABC) genutzt werden, um der Atembewegung entgegenzuwirken. Anhand der verwendeten Studien kann hierbei kein Unterschied zwischen der stereotaktischen Strahlentherapie und anderen hochkonformalen Bestrahlungstechniken gefunden werden. Für die Überprüfung der Atembewegung werden in den Studien das Real-Time Positioning Management (RPM)-System und die ABC beschrieben. Zusammenfassend zeigt die vorliegende Arbeit, dass verschiedene Methoden zur Anwendung kommen können, um der Atembewegung bei der Bestrahlung entgegenzuwirken. Hinsichtlich der Überprüfung der Atembewegung wird in der Mehrheit der Studien das RPM-System verwendet. Grund hierfür könnte sein, dass die Patient*innen bei diesem System während der Bestrahlung frei atmen können und auch kein Training notwendig ist, anders als bei der ABC. This bachelor thesis deals with the respiratory motion management in the radiotherapeutic treatment of non-small cell lung cancer (NSCLC). Lung carcinoma among men is the most common and among women the second most common cause of cancer related death. The aim of this thesis is to determine which methods are used during the radiotherapeutic treatment of NSCLC to counteract the respiratory motion and which methods are used to monitor the patient´s breathing. In regard to these methods, it was investigated, if there are any differences between stereotactic treatment and other highly conformal radiation techniques. In order to answer these questions a comprehensive literature research was conducted. Several databases such as PubMed, ScienceDirect, Cochrane and SpringerLink were used. To ensure timeliness only studies, which were published between 2016 and 2020, were included in this thesis. Study findings show that, whole body fixation devices, vacuum bags, thermoplastic material, abdominal compression and active breathing control (ABC) are used to counteract the respiratory motion. The included studies show no differences between the stereotactic radiotherapy and other highly conformal radiation techniques. To monitor the patient´s breathing the usage of the real-time positioning management (RPM)-system and the ABC are described. In conclusion, this thesis shows that various methods can be used to counteract the respiratory motion during radiotherapeutic treatment. With regard to the monitoring of the patient´s breathing, most of the studies state the usage of the RPM-system. This might be due to the fact that this system enables patients to breath freely during irradiation and that there is no need for training, as there is for the ABC.

Published

2021

42. Prediction of the position of external markers using a recurrent neural network trained with unbiased online recurrent optimization for safe lung cancer radiotherapy.

Author

Pohl, Michel, Uesaka, Mitsuru, Takahashi, Hiroyuki, Demachi, Kazuyuki, and Bhusal Chhatkuli, Ritu

Subjects

*RECURRENT neural networks, *CANCER radiotherapy, *LUNG cancer, *LUNGS, *REACTION time, *ONLINE education, *ROBOT control systems

Abstract

• RNNs trained with UORO allow for accurate marker position prediction in lung radiotherapy. • UORO achieved high performance for intermediate and high look-ahead values. • Linear regression and LMS are accurate for low and medium horizons, respectively. • The signal history length and learning rate strongly impact the accuracy of UORO. • UORO and RTRL have similar prediction MAE and nRMSE but UORO is much faster. Background and Objective : During lung cancer radiotherapy, the position of infrared reflective objects on the chest can be recorded to estimate the tumor location. However, radiotherapy systems have a latency inherent to robot control limitations that impedes the radiation delivery precision. Prediction with online learning of recurrent neural networks (RNN) allows for adaptation to non-stationary respiratory signals, but classical methods such as real-time recurrent learning (RTRL) and truncated backpropagation through time are respectively slow and biased. This study investigates the capabilities of unbiased online recurrent optimization (UORO) to forecast respiratory motion and enhance safety in lung radiotherapy. Methods : We used nine observation records of the three-dimensional (3D) position of three external markers on the chest and abdomen of healthy individuals breathing during intervals from 73s to 222s. The sampling frequency was 10Hz, and the amplitudes of the recorded trajectories range from 6mm to 40mm in the superior-inferior direction. We forecast the 3D location of each marker simultaneously with a horizon value (the time interval in advance for which the prediction is made) between 0.1s and 2.0s, using an RNN trained with UORO. We compare its performance with an RNN trained with RTRL, least mean squares (LMS), and offline linear regression. We provide closed-form expressions for quantities involved in the gradient loss calculation in UORO, thereby making its implementation efficient. Training and cross-validation were performed during the first minute of each sequence. Results : On average over the horizon values considered and the nine sequences, UORO achieves the lowest root-mean-square (RMS) error and maximum error among the compared algorithms. These errors are respectively equal to 1.3mm and 8.8mm, and the prediction time per time step was lower than 2.8ms (Dell Intel core i9-9900K 3.60 GHz). Linear regression has the lowest RMS error for the horizon values 0.1s and 0.2s, followed by LMS for horizon values between 0.3s and 0.5s, and UORO for horizon values greater than 0.6s. Conclusions : UORO can accurately predict the 3D position of external markers for intermediate to high response times with an acceptable time performance. This will help limit unwanted damage to healthy tissues caused by radiotherapy. [ABSTRACT FROM AUTHOR]

Published

2022

43. Determination of prospective displacement-based gate threshold for respiratory-gated radiation delivery from retrospective phase-based gate threshold selected at 4D CT simulation.

Author

Vedam, S., Archambault, L., Starkschall, G., Mohan, R., and Beddar, S.

Subjects

*TOMOGRAPHY, *MEDICAL radiography, *RESPIRATION, *RADIATION, *SIMULATION methods & models, *DATA analysis

Abstract

Four-dimensional (4D) computed tomography (CT) imaging has found increasing importance in the localization of tumor and surrounding normal structures throughout the respiratory cycle. Based on such tumor motion information, it is possible to identify the appropriate phase interval for respiratory gated treatment planning and delivery. Such a gating phase interval is determined retrospectively based on tumor motion from internal tumor displacement. However, respiratory-gated treatment is delivered prospectively based on motion determined predominantly from an external monitor. Therefore, the simulation gate threshold determined from the retrospective phase interval selected for gating at 4D CT simulation may not correspond to the delivery gate threshold that is determined from the prospective external monitor displacement at treatment delivery. The purpose of the present work is to establish a relationship between the thresholds for respiratory gating determined at CT simulation and treatment delivery, respectively. One hundred fifty external respiratory motion traces, from 90 patients, with and without audio-visual biofeedback, are analyzed. Two respiratory phase intervals, 40%–60% and 30%–70%, are chosen for respiratory gating from the 4D CT-derived tumor motion trajectory. From residual tumor displacements within each such gating phase interval, a simulation gate threshold is defined based on (a) the average and (b) the maximum respiratory displacement within the phase interval. The duty cycle for prospective gated delivery is estimated from the proportion of external monitor displacement data points within both the selected phase interval and the simulation gate threshold. The delivery gate threshold is then determined iteratively to match the above determined duty cycle. The magnitude of the difference between such gate thresholds determined at simulation and treatment delivery is quantified in each case. Phantom motion tests yielded coincidence of simulation and delivery gate thresholds to within 0.3%. For patient data analysis, differences between simulation and delivery gate thresholds are reported as a fraction of the total respiratory motion range. For the smaller phase interval, the differences between simulation and delivery gate thresholds are 8±11% and 14±21% with and without audio-visual biofeedback, respectively, when the simulation gate threshold is determined based on the mean respiratory displacement within the 40%–60% gating phase interval. For the longer phase interval, corresponding differences are 4±7% and 8±15% with and without audio-visual biofeedback, respectively. Alternatively, when the simulation gate threshold is determined based on the maximum average respiratory displacement within the gating phase interval, greater differences between simulation and delivery gate thresholds are observed. A relationship between retrospective simulation gate threshold and prospective delivery gate threshold for respiratory gating is established and validated for regular and nonregular respiratory motion. Using this relationship, the delivery gate threshold can be reliably estimated at the time of 4D CT simulation, thereby improving the accuracy and efficiency of respiratory-gated radiation delivery. [ABSTRACT FROM AUTHOR]

Published

2007

44. Local control of stereotactic body radiotherapy with dynamic tumor tracking for lung tumors: a propensity score-matched analysis.

Author

Machitori Y, Ito K, Kito S, Nakajima Y, Saito M, and Karasawa K

Subjects

Humans, Propensity Score, Retrospective Studies, Carcinoma, Non-Small-Cell Lung diagnostic imaging, Carcinoma, Non-Small-Cell Lung radiotherapy, Carcinoma, Non-Small-Cell Lung surgery, Lung Neoplasms etiology, Lung Neoplasms radiotherapy, Lung Neoplasms surgery, Radiosurgery adverse effects

Abstract

Background: Dynamic tumor tracking (DTT) is a method of respiratory motion management in radiotherapy. It reduces the radiation field but risks delivering an insufficient radiation dose to the tumor. We investigated the local control of DTT-stereotactic body radiotherapy (SBRT) for lung tumors., Methods: Patients treated with SBRT for early-stage, non-small-cell lung cancer and lung metastases (2013-18) were retrospectively reviewed. Patients with tumor motion >1 cm were treated with DTT-SBRT (DTT group); those with tumor motion ≤1 cm were treated with static-SBRT (static group). A static planning target volume for the static-SBRT plan was also created for patients in the DTT group, and planning target volume reduction relative to the planning target volume for the DTT-SBRT plan was assessed. Patients were matched in a 1:1 ratio using a propensity score predictive of the SBRT technique., Results: Of the 245 lesions in 218 patients (median follow-up, 25.4 months), 69 were treated with DTT-SBRT and 176 with static-SBRT. The median planning target volume reduction in the DTT group was 30.3%. After propensity score matching, 124 lesions were included (62 per group). Two-year local control rates for the DTT and static groups were 94.2 and 95.9%, respectively, for all lesions (P = 0.19) and 96.3 and 94.5%, respectively, for matched lesions (P = 0.79). In univariate analysis, DTT-SBRT was not associated with local control for all lesions (hazard ratio, 2.06; P = 0.20) or matched lesions (hazard ratio, 1.22; P = 0.79). No grade 4/5 toxicities were observed., Conclusions: DTT-SBRT for lung tumors reduced the planning target volume, but not local control rates. DTT was useful for respiratory motion management., (© The Author(s) 2022. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2022

45. Comparison of visual biofeedback system with a guiding waveform and abdomen-chest motion self-control system for respiratory motion management

Author

Takaya Yamamoto, Yojiro Ishikawa, Ken Takeda, Haruo Matsushita, Takayuki Kanai, Kengo Ito, Yujiro Nakajima, Noriyuki Kadoya, Keiichi Jingu, S. Dobashi, and Kiyokazu Sato

Subjects

Adult, medicine.medical_specialty, Health, Toxicology and Mutagenesis, medicine.medical_treatment, Wavelet Analysis, respiratory motion management, Biofeedback, Motion (physics), Self-Control, 030218 nuclear medicine & medical imaging, visual biofeedback, Motion, Young Adult, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, Feedback, Sensory, Abdomen, Regular Paper, Humans, Medicine, Waveform, Radiology, Nuclear Medicine and imaging, four-dimensional CT, Expiration, Respiratory system, radiotherapy, Radiation, business.industry, Respiration, Respiratory motion, Biofeedback, Psychology, Thorax, Healthy Volunteers, breathing guidance, 030220 oncology & carcinogenesis, Breathing, Physical therapy, Abdomen+Chest, business

Abstract

Irregular breathing can influence the outcome of 4D computed tomography imaging and cause artifacts. Visual biofeedback systems associated with a patient-specific guiding waveform are known to reduce respiratory irregularities. In Japan, abdomen and chest motion self-control devices (Abches) (representing simpler visual coaching techniques without a guiding waveform) are used instead; however, no studies have compared these two systems to date. Here, we evaluate the effectiveness of respiratory coaching in reducing respiratory irregularities by comparing two respiratory management systems. We collected data from 11 healthy volunteers. Bar and wave models were used as visual biofeedback systems. Abches consisted of a respiratory indicator indicating the end of each expiration and inspiration motion. Respiratory variations were quantified as root mean squared error (RMSE) of displacement and period of breathing cycles. All coaching techniques improved respiratory variation, compared with free-breathing. Displacement RMSEs were 1.43 ± 0.84, 1.22 ± 1.13, 1.21 ± 0.86 and 0.98 ± 0.47 mm for free-breathing, Abches, bar model and wave model, respectively. Period RMSEs were 0.48 ± 0.42, 0.33 ± 0.31, 0.23 ± 0.18 and 0.17 ± 0.05 s for free-breathing, Abches, bar model and wave model, respectively. The average reduction in displacement and period RMSE compared with the wave model were 27% and 47%, respectively. For variation in both displacement and period, wave model was superior to the other techniques. Our results showed that visual biofeedback combined with a wave model could potentially provide clinical benefits in respiratory management, although all techniques were able to reduce respiratory irregularities.

Published

2016

46. Multiple Breath-hold Volumetric Modulated Arc Therapy Under Fluoroscopic Image Guidance with an Implanted Fiducial Marker: An Advanced Technique

Author

Satoshi Yoshida, Koji Nobata, Tetsuya Kawanaka, Kiyohide Kitagawa, Y Kawamori, Yoko Taima, Azusa Norishima, Katsuaki Matsutani, Tatsuya Mito, Masahiro Kawahara, Yasushi Horichi, Tsuyoshi Takanaka, and Kento Koshikawa

Subjects

medicine.diagnostic_test, business.industry, Radiography, General Engineering, Implanted Fiducial, respiratory motion management, Volumetric modulated arc therapy, fluoroscopy, 030218 nuclear medicine & medical imaging, fiducial markers, 03 medical and health sciences, 0302 clinical medicine, Beam delivery, 030220 oncology & carcinogenesis, Radiation Oncology, medicine, Fluoroscopy, Lung tumor, vmat, business, Fluoroscopic image, Fiducial marker, Nuclear medicine, breath-hold

Abstract

An advanced technique for multiple breath-hold volumetric modulated arc therapy (VMAT) has been proposed under fluoroscopic image guidance with a fiducial marker implanted close to a tumor. The marker coordinates on a digitally reconstructed radiography image at a gantry start angle, under a planned breath-hold condition, were transferred to the fluoroscopic image window. Then, a reference lateral line passing through the planned breath-hold marker position was drawn on the fluoroscopic image. Additional lateral lines were further added on both sides of the reference line with a distance of 3 mm as a tolerance limit for the breath-hold beam delivery. Subsequently, the patient was asked to breathe in slowly under fluoroscopy. Immediately after the marker position on the fluoroscopic image moved inside the tolerance range, the patient was asked to hold the breath and the VMAT beam was delivered. During the beam delivery, the breath-hold status was continuously monitored by checking if the deviation of the marker position exceeded the tolerance limit. As long as the marker stayed within the tolerance range, a segmented VMAT delivery continued for a preset period of 15 to 30 seconds depending on the breath-hold capability of each patient. As soon as each segmented delivery was completed, the beam interrupt button was pushed; subsequently, the patient was asked for free breathing. This procedure was repeated until all the segmented VMAT beams were delivered. A lung tumor case is reported here as an initial study. The proposed technique may be clinically advantageous for treating respiratory moving tumors including lung tumor, liver cancer, and other abdominal cancers.

Published

2018

47. Ten-Year Experience of Stereotactic Body Radiotherapy at a Single Institution: Impact of Technological Development on the Outcome of Patients With Early Lung Cancer

Author

Yuuki Endo, Takesumi Ozawa, Kai Mizuhata, Keiichiro Koiwai, Ayumu Fukazawa, Yasunari Fujinaga, and Hironobu Ina

Subjects

Male, survival outcome, Cancer Research, medicine.medical_specialty, Lung Neoplasms, Stereotactic body radiation therapy, Early lung cancer, Kaplan-Meier Estimate, respiratory motion management, Radiosurgery, NSCLC, lcsh:RC254-282, Outcome (game theory), Survival outcome, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Carcinoma, Non-Small-Cell Lung, Humans, Medicine, image guidance, Single institution, Image guidance, Aged, Neoplasm Staging, Aged, 80 and over, SBRT, business.industry, Disease Management, Middle Aged, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Prognosis, Tumor Burden, Treatment Outcome, Oncology, 030220 oncology & carcinogenesis, Female, Original Article, Radiology, Non small cell, business, Stereotactic body radiotherapy, Radiotherapy, Image-Guided

Abstract

Purpose: Advanced radiotherapeutic techniques and apparatus have been developed and widely applied in stereotactic body radiation therapy for early-stage non-small cell lung cancer, but their clinical benefits have not necessarily been confirmed. This study was performed to review our 10-year experience with therapy for the disease and to evaluate whether the advanced radiotherapeutic system implemented in our hospital 5 years after we began the therapy improved the clinical outcomes of patients. Materials and Methods: Patients who underwent the therapy at our hospital between April 2008 and March 2018 were retrospectively reviewed. They were divided into 2 groups treated with the conventional system or the advanced system, and the characteristics and clinical outcomes were compared between the groups. The same analyses were also performed in propensity-matched patients from the 2 groups. Results: Among the 73 patients eligible for this study, 42 were treated with the conventional system and 31 with the advanced system. All were treated as planned, and severe adverse events were rare. The local progression-free survival rate in the advanced system group was significantly higher than in the conventional system group (P = 0.025). In the propensity-matched patients, both the local progression-free survival rate and the overall survival rate were significantly higher compared in the advanced system group than the conventional system group (P = 0.089 and 0.080, respectively). Conclusion: The advanced system improved the outcomes of patients with the disease, suggesting that technological development has had a strong impact on clinical outcomes.

Published

2020

48. Technical challenges of linac-based stereotactic ablative body radiotherapy: short review for non-radiation oncologists.

Author

Mihai AM, Rock L, and Milano MT

Subjects

Humans, Quality of Life, Reproducibility of Results, Carcinoma, Non-Small-Cell Lung radiotherapy, Carcinoma, Non-Small-Cell Lung surgery, Lung Neoplasms radiotherapy, Lung Neoplasms surgery, Radiosurgery

Abstract

Stereotactic ablative radiotherapy (SABR) is a radiation technique delivering high doses of radiation in a small number of treatments, to extracranial targets. It is standard of care in patients with inoperable early stage non-small cell lung cancer, and it is increasingly used in patients with oligometastatic disease. The main advantage of SABR is a steep dose gradient, allowing delivery of high biologically effective doses to the target, while minimizing irradiation exposure of the neighboring normal tissues. This results in high rates of local control of the treated target and minimal toxicity risks, and minimal impact on the quality of life of the patients. However, it requires high precision, accuracy and reproducibility during the entire process, from simulation to treatment planning and treatment delivery. This article will focus on general principles of SABR treatment planning and delivery, with emphasis on the strategies to reduce errors related to immobilization, respiratory management and treatment verification.

Published

2021

49. Guidelines for respiratory motion management in radiation therapy

Author

Yukinori Matsuo, Munefumi Shimbo, N Tohyama, Mitsuhiro Nakamura, Masahiro Hiraoka, Masahiko Okumura, Keiichi Nakagawa, Hiroki Shirato, Teiji Nishio, Yu Kumazaki, Takaki Ariji, and Hiroshi Onishi

Subjects

Technology, medicine.medical_specialty, respiratory motion, Quality Assurance, Health Care, Movement, Health, Toxicology and Mutagenesis, medicine.medical_treatment, respiratory motion management, Patient Positioning, Medical physicist, Radiation Protection, Japan, Neoplasms, Radiation oncology, medicine, Humans, Radiology, Nuclear Medicine and imaging, Medical physics, radiotherapy, Reimbursement, Radiation, business.industry, Respiratory motion, Guideline, Radiation therapy, Radiological weapon, Radiation Oncology, Respiratory Mechanics, Radiotherapy, Conformal, Radiation protection, business, guideline

Abstract

Respiratory motion management (RMM) systems in external and stereotactic radiotherapies have been developed in the past two decades. Japanese medical service fee regulations introduced reimbursement for RMM from April 2012. Based on thorough discussions among the four academic societies concerned, these Guidelines have been developed to enable staff (radiation oncologists, radiological technologists, medical physicists, radiotherapy quality managers, radiation oncology nurses, and others) to apply RMM to radiation therapy for tumors subject to respiratory motion, safely and appropriately.

Published

2012

50. Extraction and evaluation of anatomical patient surface and associated respiratory motion with a time-of-flight (ToF) camera

Author

Wentz, Thomas, Fayad, Hadi, Clément, Jean-François, Savéan, Joël, Hatt, Mathieu, Visvikis, Dimitris, Département Image et Traitement Information (ITI), Université européenne de Bretagne - European University of Brittany (UEB)-Télécom Bretagne-Institut Mines-Télécom [Paris] (IMT), Laboratoire de Traitement de l'Information Medicale (LaTIM), Université européenne de Bretagne - European University of Brittany (UEB)-Télécom Bretagne-Centre Hospitalier Régional Universitaire de Brest (CHRU Brest)-Université de Brest (UBO)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut Mines-Télécom [Paris] (IMT), Université de Brest (UBO), and Télécom Bretagne (devenu IMT Atlantique), Ex-Bibliothèque

Subjects

ToF camera, Respiratory motion management, [SPI.SIGNAL]Engineering Sciences [physics]/Signal and Image processing, [SPI.SIGNAL] Engineering Sciences [physics]/Signal and Image processing

Abstract

International audience; Objectives: A ToF camera is a new technology which provides a real-time depth map of a scene with a sufficiently high frequency to monitor respiratory motion. As such this technology makes a good alternative to systems currently used clinically since it provides a mark-less real-time monitoring of the complete patient's surface. The objective of this work was to evaluate the accuracy measuring displacements in real-time throughout the recorded patient surface. Methods: The surface provided by the camera was modeled using B-splines, including a correction methodology associated with accurately measuring recorded surface motion information irrespective of the angle between the camera and the patient. An anatomical torso phantom moved by a linear actuator was used in the evaluation. Measurements were made under static and moving conditions (triangular motion of 10 mm in amplitude and 4 seconds as period) on the B-splines control points with or without Gaussian filtering. Accuracy of the surface motion measurements was investigated with the camera placed at different distances (from 0.6m to 1.4m) and angles (α=0° to 45°) from the surface. The repeatability of accurately measuring surface displacement information was assessed on 100 repeated measurements for each experiment. Results: At 80cm between the camera and the phantom, considering all of the surface B-spline control points, motion estimation accuracy was 1.0±0.3mm and 1.3±0.5mm for an angle α = 0° and 45° respectively. Using a 3x3 Gaussian filtering, the motion estimation accuracy improved to 0.7±0.1mm and 1.1±0.3mm for α=0° and 45° respectively. The repeatability of motion estimation throughout the model's surface ranged from 0.7±0.1mm to 1.1±0.1mm for a distance between the camera and the phantom between 60cm and 1.4m. Conclusions: A millimetric accuracy for the monitoring of a patient surface can be obtained using a ToF camera. This technology can be therefore considered for monitoring respiratory motion displacements in real-time

Published

2011