Respiratory effort correction strategies to improve the reproducibility of lung expansion measurements

Du, Kaifang; Reinhardt, Joseph M.; Christensen, Gary E.; Ding, Kai; Bayouth, John E.

doi:10.1118/1.4829519

Cited by 33 publications

(48 citation statements)

References 34 publications

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“…Specific efforts are being made to reduce the impact of imaging artifacts, uncertainties in the deformable image registration(35), means of normalizing the ventilation values(36), and the actual calculation of the ventilation values(37). This study also examines the initial ventilation maps calculated from pre-treatment 4DCT scans.…”

Section: Discussionmentioning

confidence: 99%

Evaluating Which Dose-Function Metrics Are Most Critical for Functional-Guided Radiation Therapy

Faught

Yamamoto

Castillo

et al. 2017

International Journal of Radiation Oncology*Biology*Physics

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Purpose 4DCT-ventilation imaging is increasingly being used to calculate lung ventilation and implement functional-guided radiotherapy in clinical trials. There has been little exhaustive work evaluating which dose-function metrics should be used for treatment planning and plan evaluation. The purpose of our study was to evaluate which dose-function metrics best predict for radiation pneumonitis (RP). Methods and Materials Seventy lung cancer patients with 4DCT imaging and pneumonitis grading were used. Pre-treatment 4DCTs of each patient were used to calculate ventilation images. We evaluated 3 types of dose function metrics that combined that patient’s 4DCT-ventilation image and treatment planning dose distribution: 1) structure-based approaches 2) image-based approaches using the dose-function histogram (DFH) and 3) non-linear weighting schemes. Log-likelihood methods were used to generate normal tissue complication probability (NTCP) models predicting grade 3+ pneumonitis for all dose-function schemes. The area under the curve (AUC) was used to assess the predictive power of the models. All techniques were compared to NTCP models based on traditional, total lung dose metrics. Results The most predictive models were structure-based approaches that focused on the volume of functional lung receiving ≥20Gy (AUC=0.70). Probability of grade 3+ RP of 20% and 10% correspond to V20Gy to the functional sub-volumes of 26.8% and 9.3%, respectively. Imaging-based analysis with the DFH and non-linear weighted ventilation values yielded AUCs of 0.66 and 0.67, respectively, when evaluating the percentage of functionality receiving ≥20Gy. All dose-function metrics outperformed the traditional dose metrics (mean lung dose, AUC=0.55). Conclusion A full range of dose-function metrics and functional thresholds were examined. The calculated AUC values for the most predictive functional models occupied a narrow range (0.66–0.70) and all demonstrated notable improvements over AUC from traditional lung dose metrics (0.55). Identifying the combinations most predictive of grade 3+ RP provides valuable data to inform the functional-guided radiotherapy process.

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Section: Discussionmentioning

confidence: 99%

Evaluating Which Dose-Function Metrics Are Most Critical for Functional-Guided Radiation Therapy

Faught

Yamamoto

Castillo

et al. 2017

International Journal of Radiation Oncology*Biology*Physics

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“…The calculation techniques for 4DCT-ventgilation are still being optimized including methods to deal with 4DCT imaging artifacts, deformable image registration uncertainties [27], various methods of normalization [28], and the calculation techniques themselves [5]. In addition, there could be second order effects on the dose-function metrics because the dose was calculated on the free-breathing CT while the 4DCT-ventilation was calculated on the exhale phase of the 4DCT.…”

Section: Discussionmentioning

confidence: 99%

Regional Lung Function Profiles of Stage I and III Lung Cancer Patients: An Evaluation for Functional Avoidance Radiation Therapy

Vinogradskiy

Schubert

Diot

et al. 2016

International Journal of Radiation Oncology*Biology*Physics

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Purpose 4DCT-ventilation is an exciting imaging modality that uses 4DCT data to calculate lung function maps. The development of clinical trials is underway to use 4DCT-ventilation imaging to preferentially spare functional lung in patients undergoing radiotherapy. The purpose of this work was to generate data to aide with clinical trial design by retrospectively characterizing dosimetric and functional profiles for patients with different stages of lung cancer disease Methods and Materials A total of 118 lung cancer patients (36% stage I and 64% stage III) from 2 institutions were used for the study. A 4DCT-ventilation map was calculated using the patient’s 4DCT imaging, deformable image registration, and a density-change based algorithm. In order to assess each patient’s spatial ventilation profile both quantitative and qualitative metrics were developed including an observer-based defect observation and metrics based on the ventilation in each lung third. For each patient we used the clinical doses to calculate weighted mean lung doses (fMLD) and metrics that assessed the interplay between the spatial location of the dose and high-functioning lung. Results Both qualitative and quantitative metrics revealed a significant difference in functional profiles between the 2 stage groups (p<0.01). We determined that 65% of stage III and 28% of stage I patients had ventilation defects. Average fMLD was 19.6 Gy and 5.4 Gy for stage III and I patients respectively with both groups containing patients with large spatial overlap between dose and high-function regions. Conclusion Our 118 patient retrospective study found that 65% stage III patients have regionally variant ventilation profiles that are suitable for functional avoidance. Our results suggest that regardless of disease stage, it is possible to have unique spatial interplay between dose and high-functional lung highlighting the importance of evaluating the function of each patient and developing a personalized functional avoidance treatment approach.

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“…Efforts are being made to address imaging artifacts, deformable image registration uncertainties(43), normalization techniques(44), and the means of calculating ventilation(28). Work is still being done to comprehensively validate 4DCT-ventilation and evaluate the reproducibility.…”

Section: Discussionmentioning

confidence: 99%

Evaluating the Toxicity Reduction With Computed Tomographic Ventilation Functional Avoidance Radiation Therapy

Faught

Miyasaka

Kadoya

et al. 2017

International Journal of Radiation Oncology*Biology*Physics

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Summary A retrospective study of 70 lung cancer patients with 4DCT images was performed to estimate the toxicity reduction achieved when using CT-ventilation functional avoidance radiotherapy in place of traditional radiotherapy. Normal tissue complication probability (NTCP) models were developed from clinically used plans based on dose to functional lung. Thirty patients were re-planned using functional avoidance techniques and RTOG 0617 constraints, and the reduction in lung toxicity was assessed using the NTCP models. Purpose CT-ventilation imaging is a new modality that uses 4DCT information to calculate lung ventilation. While retrospective studies have reported on the reduction in dose to functional lung, no work has been published in which the dosimetric improvements have been translated to a reduction in the probability of pulmonary toxicity. Our work estimates the reduction in toxicity for CT-ventilation based functional avoidance planning. Methods and Materials Seventy previously treated lung cancer patients with 4DCT imaging were used for the study. CT-ventilation maps were calculated using the 4DCT, deformable image registration, and a density-change-based algorithm. Pneumonitis was graded based on imaging and clinical presentation. Maximum-likelihood methods were used to generate normal tissue complication probability (NTCP) models predicting grade 2 or higher (2+) and grade 3+ pneumonitis as a function of dose (V5Gy, V10Gy, V20Gy, V30Gy, and mean dose) to functional lung. For thirty patients a functional plan was generated with the goal of reducing dose to the functional lung while meeting RTOG 0617 constraints. The NTCP models were applied to the functional plans and the clinically-used plans to calculate toxicity reduction. Results Using functional avoidance planning, absolute reductions in grade 2+ NTCP of 6.3%, 7.8% and 4.8% were achieved based on the mean fV20Gy, fV30Gy, and fMLD metrics, respectively. Absolute grade 3+ NTCP reductions of 3.6%, 4.8%, and 2.4% were achieved with fV20Gy, fV30Gy, and fMLD. Maximum absolute reductions of 52.3% and 16.4% were seen for grade 2+ and grade 3+ pneumonitis for individual patients. Conclusion Our study quantifies the possible toxicity reduction from CT-ventilation-based functional avoidance planning. Reductions in grades 2+ and 3+ pneumonitis were 7.1% and 4.7% based on mean dose-function metrics with reductions as high as 52.3% for individual patients. Our work provides seminal data for determining the potential toxicity benefit from incorporating CT-ventilation into thoracic treatment planning.

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Respiratory effort correction strategies to improve the reproducibility of lung expansion measurements

Cited by 33 publications

References 34 publications

Evaluating Which Dose-Function Metrics Are Most Critical for Functional-Guided Radiation Therapy

Evaluating Which Dose-Function Metrics Are Most Critical for Functional-Guided Radiation Therapy

Regional Lung Function Profiles of Stage I and III Lung Cancer Patients: An Evaluation for Functional Avoidance Radiation Therapy

Evaluating the Toxicity Reduction With Computed Tomographic Ventilation Functional Avoidance Radiation Therapy

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