Optimising use of 4D-CT phase information for radiomics analysis in lung cancer patients treated with stereotactic body radiotherapy

Davey, A.; Herk, Marcel van; Faivre-Finn, Corinne; Brown, Sean; McWilliam, A.

doi:10.1088/1361-6560/abfa34

Cited by 8 publications

(32 citation statements)

References 56 publications

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“…The counterintuitive result of Region 1 is explained by considering the mean EQD2 dose inside each of the regions identified by the dose parameter (Supplementary Figure 13). In region 1, the median value is 55 Gy with range 74-92 Gy, which is significantly higher than 9 Gy (17)(18)(19)(20)(21)(22)(23)(24)(25)(26)(27)(28)(29)(30)(31)(32) in R2 and 14 Gy (22)(23)(24)(25)(26)(27)(28)(29)(30)(31)(32)(33)(34)(35)(36)(37)(38)(39)(40)(41) in R3. Considering the difference in dose scales, a large SD in this region would not lead to underdosage of microscopic disease.…”

Section: Confounding Investigationmentioning

confidence: 87%

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Radial Data Mining to Identify Density–Dose Interactions That Predict Distant Failure Following SABR

et al. 2022

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PurposeLower dose outside the planned treatment area in lung stereotactic radiotherapy has been linked to increased risk of distant metastasis (DM) possibly due to underdosage of microscopic disease (MDE). Independently, tumour density on pretreatment computed tomography (CT) has been linked to risk of MDE. No studies have investigated the interaction between imaging biomarkers and incidental dose. The interaction would showcase whether the impact of dose on outcome is dependent on imaging and, hence, if imaging could inform which patients require dose escalation outside the gross tumour volume (GTV). We propose an image-based data mining methodology to investigate density–dose interactions radially from the GTV to predict DM with no a priori assumption on location.MethodsDose and density were quantified in 1-mm annuli around the GTV for 199 patients with early-stage lung cancer treated with 60 Gy in 5 fractions. Each annulus was summarised by three density and three dose parameters. For parameter combinations, Cox regressions were performed including a dose–density interaction in independent annuli. Heatmaps were created that described improvement in DM prediction due to the interaction. Regions of significant improvement were identified and studied in overall outcome models.ResultsDose–density interactions were identified that significantly improved prediction for over 50% of bootstrap resamples. Dose and density parameters were not significant when the interaction was omitted. Tumour density variance and high peritumour density were associated with DM for patients with more cold spots (less than 30-Gy EQD2) and non-uniform dose about 3 cm outside of the GTV. Associations identified were independent of the mean GTV dose.ConclusionsPatients with high tumour variance and peritumour density have increased risk of DM if there is a low and non-uniform dose outside the GTV. The dose regions are independent of tumour dose, suggesting that incidental dose may play an important role in controlling occult disease. Understanding such interactions is key to identifying patients who will benefit from dose-escalation. The methodology presented allowed spatial dose–density interactions to be studied at the exploratory stage for the first time. This could accelerate the clinical implementation of imaging biomarkers by demonstrating the impact of incidental dose for tumours of varying characteristics in routine data.

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Section: Confounding Investigationmentioning

confidence: 87%

“…Planning four-dimensional CT (4D-CT) scans [described in Davey et al. ( 18 )] and 3D dose distributions were available for all patients. Patients received a dose of 54 Gy in 3 fractions, or 60 Gy in 5 or 8 fractions, with further planning details included in Supplementary Material , Section 1.…”

Section: Methodsmentioning

confidence: 99%

Radial Data Mining to Identify Density–Dose Interactions That Predict Distant Failure Following SABR

et al. 2022

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“…Previous work has shown that tumor motion can alter the radiomic feature space in discrete ways 21,22,27 . However, whether motion-associated variations are deterministic, capturing true changes in tumor composition, or stochastic, representing "noise" to be dampened remained unknown.…”

Section: Discussionmentioning

confidence: 99%

“…Although the documented instability in the classical radiomic feature space created by tumor motion has been established 21,22,27 , it remains unclear if these variations are clinically meaningful. Moreover, motion-related variations in some radiomic features may not be relevant to DL models.…”

Section: Discussionmentioning

confidence: 99%

“…In addition to these potential sources of variation, tumor motion has been shown to impact radiomic feature stability. Lung tumors, in particular, can have significant motion during respiration 20 and radiomic features extracted from free breathing (FB) computed tomography (CT) 21 or four-dimensional (4D) CT scans can be affected by motion 22 . Tumor motion could be mitigated with active breathing control (breath hold) and use of abdominal compression techniques 12 .…”

Section: Introductionmentioning

confidence: 99%

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Robust image-based risk predictions from the deep learning of lung tumors in motion

Bajaj

Teo

Randall

et al. 2021

Preprint

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Deep learning (DL) models that use medical images to predict clinical outcomes are poised for clinical translation. For tumors that reside in organs that move, however, the impact of motion (i.e. degenerated object appearance or blur) on DL model accuracy remains unclear. Here we examine the impact of tumor motion on an image-based DL framework that predicts local failure risk for patients with lung cancer receiving stereotactic body radiotherapy. We show that an image-based DL risk score derived from a series of four-dimensional CT images varies in a deterministic, sinusoidal trajectory in phase with the respiratory cycle. Critically, the mean of the scores derived from time series of images and the score obtained from free breathing scans (average tumor position) were highly associated (Pearson r = 0.99). These results indicate that deep learning models of tumors in motion can be robust to fluctuations in object appearance due to movement.

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Vulnerabilities of radiomic features to respiratory motion on four‐dimensional computed tomography‐based average intensity projection images: A phantom study

Adachi

Nagasawa

Nakamura

et al. 2022

J Applied Clin Med Phys

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Purpose To evaluate the influence of respiratory motion on the robustness of radiomic features on four‐dimensional computed tomography (4DCT)‐based average intensity projection (AIP) images by employing an anthropomorphic chest phantom. Methods Three spherical objects (φ30 mm), namely, acrylic (100 Hounsfield unit [HU], homogeneous), rubber (−140 HU, homogeneous), and cork (−630 HU, heterogeneous), were moved with motion amplitudes of 0, 1, 2.5, 4, 6, 8, and 10 mm in the phantom, and 4DCT scans were repeated at four different locations. Thereafter, the AIP images were generated considering the average of the 10 respiratory phases of the 4DCT images. Further, the targets were manually delineated on the AIP images in the lung window setting. A total of 851 radiomic features, including 107 unfiltered features and 744 wavelet filter‐based features, were extracted from the region of interest for each material. The feature robustness among the different target motion amplitude (ε) was evaluated by normalizing the feature variability of the target motion relative to the variability of data from 573 patients with early‐stage non‐small cell lung cancer. The features with absolute ε values ≤0.5 were considered highly robust to target motions. Results The percentage of robust unfiltered and wavelet filter‐based features with a motion amplitude of 1 mm was greater than 83.2% and 93.4%, respectively; however, the percentage decreased by more than 24.3% and 17.6%, respectively, for motion amplitudes greater than 2.5 mm. The movement of cork had a small effect on the feature robustness compared to that of acrylic and rubber, regardless of the target motion amplitudes. Conclusions Our phantom study demonstrated that target motion amplitudes ≤1 mm led to the robustness of radiomic features on the 4DCT‐based AIP images of thoracic regions. The frequency components and directions of the wavelet filters may be essential factors in 4DCT‐based radiomic analysis.

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Optimising use of 4D-CT phase information for radiomics analysis in lung cancer patients treated with stereotactic body radiotherapy

Cited by 8 publications

References 56 publications

Radial Data Mining to Identify Density–Dose Interactions That Predict Distant Failure Following SABR

Radial Data Mining to Identify Density–Dose Interactions That Predict Distant Failure Following SABR

Robust image-based risk predictions from the deep learning of lung tumors in motion

Vulnerabilities of radiomic features to respiratory motion on four‐dimensional computed tomography‐based average intensity projection images: A phantom study

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