Quantitative prediction of respiratory tidal volume based on the external torso volume change: a potential volumetric surrogate

Li, Guang; Arora, Naveen C; Xie, Honglan; Ning, Holly; Lu, Wei; Low, Daniel A.; Citrin, Deborah E.; Kaushal, Aradhana; Zach, Leor; Camphausen, Kevin; Miller, Robert W.

doi:10.1088/0031-9155/54/7/007

Cited by 23 publications

(53 citation statements)

References 41 publications

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“…Simple scalar surrogate signals have been derived from skin surface data by tracking a single point on the skin surface (Hughes et al, 2009), or by calculating the volumes under the skin surface (Hughes et al, 2009;Li et al, 2009;McClelland et al, 2011). It has been shown that calculating the volume under the skin surface produces a signal similar to that obtained via spirometry, but without the drift often seen in spriometry signals Hughes et al, 2009).…”

Section: Deriving Simpler Surrogate Data From High Dimensional Datamentioning

confidence: 99%

Respiratory motion models: A review

McClelland

Hawkes

Schaeffter

et al. 2013

Medical Image Analysis

342

343

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The problem of respiratory motion has proved a serious obstacle in developing techniques to acquire images or guide interventions in abdominal and thoracic organs. Motion models offer a possible solution to these problems, and as a result the field of respiratory motion modelling has become an active one over the past 15 years. A motion model can be defined as a process that takes some surrogate data as input and produces a motion estimate as output. Many techniques have been proposed in the literature, differing in the data used to form the models, the type of model employed, how this model is computed, the type of surrogate data used as input to the model in order to make motion estimates and what form this output should take. In addition, a wide range of different application areas have been proposed. In this paper we summarise the state of the art in this important field and in the process highlight the key papers that have driven its advance. The intention is that this will serve as a timely review and comparison of the different techniques proposed to date and as a basis to inform future research in this area.

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Section: Deriving Simpler Surrogate Data From High Dimensional Datamentioning

confidence: 99%

Respiratory motion models: A review

McClelland

Hawkes

Schaeffter

et al. 2013

Medical Image Analysis

342

343

View full text Add to dashboard Cite

show abstract

“…The volume‐conserving organs, such as the heart, liver, and stomach, do not change their volume with the respiratory motion, although they may deform, because non‐lung tissues are not compressible under respiratory pressure difference (3–6 mmHg) 48. Therefore, the delineated OAR volumes are expected to be constant.…”

Section: Methodsmentioning

confidence: 99%

Evaluation of automatic contour propagation in T2‐weighted 4DMRI for normal‐tissue motion assessment using internal organ‐at‐risk volume (IRV)

Zhang

Markova

García

et al. 2018

J Applied Clin Med Phys

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PurposeThe purpose of this study was to evaluate the quality of automatically propagated contours of organs at risk (OARs) based on respiratory‐correlated navigator‐triggered four‐dimensional magnetic resonance imaging (RC‐4DMRI) for calculation of internal organ‐at‐risk volume (IRV) to account for intra‐fractional OAR motion.Methods and MaterialsT2‐weighted RC‐4DMRI images were of 10 volunteers acquired and reconstructed using an internal navigator‐echo surrogate and concurrent external bellows under an IRB‐approved protocol. Four major OARs (lungs, heart, liver, and stomach) were delineated in the 10‐phase 4DMRI. Two manual‐contour sets were delineated by two clinical personnel and two automatic‐contour sets were propagated using free‐form deformable image registration. The OAR volume variation within the 10‐phase cycle was assessed and the IRV was calculated as the union of all OAR contours. The OAR contour similarity between the navigator‐triggered and bellows‐rebinned 4DMRI was compared. A total of 2400 contours were compared to the most probable ground truth with a 95% confidence level (S95) in similarity, sensitivity, and specificity using the simultaneous truth and performance level estimation (STAPLE) algorithm.ResultsVisual inspection of automatically propagated contours finds that approximately 5–10% require manual correction. The similarity, sensitivity, and specificity between manual and automatic contours are indistinguishable (P > 0.05). The Jaccard similarity indexes are 0.92 ± 0.02 (lungs), 0.89 ± 0.03 (heart), 0.92 ± 0.02 (liver), and 0.83 ± 0.04 (stomach). Volume variations within the breathing cycle are small for the heart (2.6 ± 1.5%), liver (1.2 ± 0.6%), and stomach (2.6 ± 0.8%), whereas the IRV is much larger than the OAR volume by: 20.3 ± 8.6% (heart), 24.0 ± 8.6% (liver), and 47.6 ± 20.2% (stomach). The Jaccard index is higher in navigator‐triggered than bellows‐rebinned 4DMRI by 4% (P < 0.05), due to the higher image quality of navigator‐based 4DMRI.ConclusionAutomatic and manual OAR contours from Navigator‐triggered 4DMRI are not statistically distinguishable. The navigator‐triggered 4DMRI image provides higher contour quality than bellows‐rebinned 4DMRI. The IRVs are 20–50% larger than OAR volumes and should be considered in dose estimation.

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“…The BP ( BP = ΔV thx /TV ), defined as the lung volume expansion change (AP) divided by the TV change, was used to quantify the involvement of the thorax (36, 37) and abdomen (1 – BP) in respiration. Therefore, the BP is a critical parameter that introduces directional information into the scalar spirometric TV data.…”

Section: Methodsmentioning

confidence: 99%

“…Because only motion variation caused by irregularity was calculated, the computation workload was significantly reduced (34, 35). Additionally, separating the superoinferior (SI) from anteroposterior (AP) motions using breathing patterns (36, 37) simplified RMP modeling computation. The baseline tumor motion can be obtained from 4-dimensional computed tomography (4DCT) at simulation, and the motion perturbation can be calculated using the respiratory changes in TV and BP fed by the OSI-based technique (20, 21) during treatment.…”

Section: Introductionmentioning

confidence: 99%

A Novel Respiratory Motion Perturbation Model Adaptable to Patient Breathing Irregularities

Yuan

Wei

Gaebler

et al. 2016

International Journal of Radiation Oncology*Biology*Physics

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Purpose To develop a physical, adaptive motion perturbation model to predict tumor motion using feedback from dynamic measurement of breathing conditions to compensate for breathing irregularities. Methods and Materials A novel respiratory motion perturbation (RMP) model was developed to predict tumor motion variations caused by breathing irregularities. This model contained 2 terms: the initial tumor motion trajectory, measured from 4-dimensional computed tomography (4DCT) images, and motion perturbation, calculated from breathing variations in tidal volume (TV) and breathing pattern (BP). The motion perturbation was derived from the patient-specific anatomy, tumor-specific location, and time-dependent breathing variations. Ten patients were studied, and 2 amplitude-binned 4DCT images for each patient were acquired within 2 weeks. The motion trajectories of 40 corresponding bifurcation points in both 4DCT images of each patient were obtained using deformable image registration. An in-house 4D data processing toolbox was developed to calculate the TV and BP as functions of the breathing phase. The motion was predicted from the simulation 4DCT scan to the treatment 4DCT scan, and vice versa, resulting in 800 predictions. For comparison, noncorrected motion differences and the predictions from a published 5-dimensional model were used. Results The average motion range in the superoinferior direction was 9.4 ± 4.4 mm, the average ΔTV ranged from 10 to 248 mm3 (−26% to 61%), and the ΔBP ranged from 0 to 0.2 (−71% to 333%) between the 2 4DCT scans. The mean noncorrected motion difference was 2.0 ± 2.8 mm between 2 4DCT motion trajectories. After applying the RMP model, the mean motion difference was reduced significantly to 1.2 ± 1.8 mm (P = .0018), a 40% improvement, similar to the 1.2 ± 1.8 mm (P = .72) predicted with the 5-dimensional model. Conclusions A novel physical RMP model was developed with an average accuracy of 1.2 ± 1.8 mm for interfraction motion prediction, similar to that of a published lung motion model. This physical RMP was analytically derived and is able to adapt to breathing irregularities. Further improvement of this RMP model is under investigation.

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Quantitative prediction of respiratory tidal volume based on the external torso volume change: a potential volumetric surrogate

Cited by 23 publications

References 41 publications

Respiratory motion models: A review

Respiratory motion models: A review

Evaluation of automatic contour propagation in T2‐weighted 4DMRI for normal‐tissue motion assessment using internal organ‐at‐risk volume (IRV)

A Novel Respiratory Motion Perturbation Model Adaptable to Patient Breathing Irregularities

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