Respiratory Adaptive Computed Tomography: Feasibility Study on Real-Time Gated 4DCT for Lung Cancer Radiotherapy

Not Applicable

Recruiting

• Conditions: Lung Cancer
• Interventions: Diagnostic Test: Real-time Gated 4DCT; Diagnostic Test: Conventional 4DCT

• Registration Number: NCT05030207
• Lead Sponsor: University of Sydney

Brief Summary

This study does not involve a therapeutic intervention as standard radiation therapy treatment will be prescribed. This study involves one additional 4DCT scan (i.e. the Real-Time Gated 4DCT scan) acquired immediately before or following the conventional 4DCT scan. This will take place on the day of the patient's treatment simulation, as per the current standard of care. The scanning sequence (i.e. conventional first versus gated first) will be randomised.

The Real-Time Gated 4DCT is anticipated to take longer than the conventional 4DCT scan, due to its gated (beam-pause) nature. However, upper limits for timing will be implemented in the software, and the scan aborted for highly erratic breathing traces that would not benefit from a Real-Time Gated 4DCT scan.

Detailed Description

Four-dimensional computed tomography (4DCT) is considered the standard of care for modern high-precision stereotactic ablative body radiotherapy (SABR) techniques. Clinical 4DCT works by acquiring CT slices and breathing data synchronously as the patient moves through the rotating X-ray imager. The CT slices are sorted into 5-10 'phase images' (mid-exhale, peak-exhale, mid-inhale, peak-inhale, etc.) and stitched together to form a 3D+breathing induced tumour/organ motion or '4D' representation of the breathing anatomy. Current best practice in radiation therapy is for clinicians to perform manual delineation or 'contouring' of lung tumours on one or more 4DCT phase images to ensure proper coverage by the treatment beam despite breathing motion. In the presence of irregular breathing, mismatches arise between CT slices that are in the same breathing phase but imaged at different couch positions. As a result, the images produced suffer from various kinds of discontinuities including truncation, duplication or overlap. Yamamoto found that irregular breathing caused at least one error \>4mm in 90% (45 out of 50) abdominal and thoracic patient scans. The main consequence of 4DCT image errors is that they can introduce tumour volume and position uncertainties as large as 30% between different 4D phase bins or different observers.

This can potentially reduce the likelihood of tumour control by up to one-third and lead to unnecessary irradiation of healthy lung tissue, contributing to major dose-limiting side effects like radiation pneumonitis, which is symptomatic in up to 30% of patients and fatal in 2%. The proposed solution is Real-Time Gated 4DCT using prospective regularity gating, which will be implemented for the first time on lung cancer patients.

The Real-Time Gated 4DCT method detects and then pauses the CT beam during irregular breathing events. We will analyse the patient's breathing pattern to prospectively gate acquisition in real-time. Real-time gated 4DCT ensures that the X-ray imager is switched on only when the breathing is regular; the scan gets paused otherwise. The benefits for the patient of gating a 4DCT scan have been demonstrated in previous studies:

* a reduction of breathing motion errors by 50%

* a reduction of imaging dose. Delineation of tumours and organs in CT scans is the first step in a lung cancer patient's radiation therapy journey. Accurate delineation is pivotal to patient outcomes because errors propagate throughout treatment and can lead to radiation dose missing parts of the tumour or unnecessarily irradiating healthy tissue or organs. Unfortunately, the most important imaging modality used for the delineation of lung cancers, 4DCT, is error prone. Radiation Oncologists (ROs) are faced with an enormous challenge and are required to delineate tumours when 90% of clinical scans suffer severe imaging errors. These errors obfuscate the true tumour position/shape and reduce the chance of tumour control by up to one third.

The main culprit for imaging errors is irregular breathing: i.e. natural breathing variations, which are heightened for lung cancer patients but not accounted for by clinical scanners. A solution to this problem was proposed, which is to gate the CT scanner (i.e. pausing the beam) whenever a breathing condition occurs that is likely to produce an imaging artefact.

Research Question The primary endpoint is that the number of image artifacts using the Real-time gated scan will produce fewer artefacts than the conventional scan.

Secondary endpoints involve examining image quality and the impact on treatment planning with the benefits to the patient being:

1. Consistent/predictable image quality: Consistent image quality will assist radiation oncologists in identifying tumour and organ interfaces and therefore reduce delineation errors.

2. Improvements in treatment plans: More accurate delineation will lead to improved treatment plans and therefore improved patient outcomes.

This clinical trial is a first-in-humans pilot feasibility study and the aim is therefore to prove feasibility of Real-Time Gated 4DCT, with the aim of leading to an efficacy trial. As such, patient scans will be acquired across a broad range of patient breathing conditions to optimise the Real-Time Gated technique and to plan a larger, hypothesis-driven phase II clinical trial to follow. Automatic cut-offs for these erratic breathing traces will be built into the Real-Time Gated 4DCT software.

Rationale for Current Study In-silico studies suggest that the Real-Time Gated 4DCT approach, can reduce imaging errors by up to 50% whilst also reducing imaging dose by \>20%. It has been estimated that the current rate of artifacts using conventional 4DCT is at least 60% and possibly up to 95%. A reduction to at most 35% (25% of images with fewer artifacts) would be clinically worthwhile.

Study Timeline

• Study First Submitted: 2021-06-24
• Study First Submitted QC: 2021-08-29
• Study First Posted: 2021-09-01
• Study Start: 2024-05-15
• Status Verified: 2025-04
• Last Update Submitted: 2025-04-01
• Last Update Posted: 2025-04-04
• Primary Completion: 2025-12
• Study Completion: 2025-12

Recruitment & Eligibility

• Status: RECRUITING
• Sex: All
• Target Recruitment: 30

Inclusion Criteria

• 18 years or older
• Have the ability to give informed consent
• A diagnosis of lung cancer with an indication for radiation therapy
• Radiation therapy treatment involving the acquisition of a 4DCT scan for treatment planning

Exclusion Criteria

• Pregnant women
• Patients <18 years
• Patients who in the opinion of the treating physician could not tolerate the extra time on the CT couch for an extra scan

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: SINGLE_GROUP

Arm && Interventions

Group	Intervention	Description
Real-Time Gated 4DCT and Conventional 4DCT	Conventional 4DCT	During the simulation (radiotherapy planning) session, the participant will undergo both the experimental 'Real-Time Gated 4DCT' and standard 'Conventional 4DCT'.
Real-Time Gated 4DCT and Conventional 4DCT	Real-time Gated 4DCT	During the simulation (radiotherapy planning) session, the participant will undergo both the experimental 'Real-Time Gated 4DCT' and standard 'Conventional 4DCT'.

Primary Outcome Measures

Name	Time	Method
The feasibility of using Real-Time Gated 4DCT instead of Conventional 4DCT for planning radiotherapy for lung cancer.	30 minutes	A change in the anticipated rate of image artifacts in images acquired from Conventional of 60% to 35% or less in images acquired from Real-Time Gated 4DCT.

Secondary Outcome Measures

Name	Time	Method
Patient tolerance to the experimental scan (Real-Time Gated 4DCT)	1 minute at end of planning session	The radiation therapist conducting the radiation therapy study scan will complete a survey consisting of two yes/no questions after the planning session to assess patient tolerance (1. whether the patient finishes the scan without getting off the couch. 2. If the patient voiced any complaints during the scan and seem uncomfortable.)
clinician confidence in acquiring a Real-Time Gated 4DCT scan	5 minutes at end of planning session	The radiation therapist conducting the radiation therapy study scan will complete an in-house survey of 10 questions after the treatment session to evaluate their experience with REACT software and its usability.
Effect on Real-Time Gated 4DCT image quality of patient characteristics: breathing type, breathing period, BMI, tumour location, breathing amplitude, breathing regularity, pulmonary function, ECOG status.	40 minutes, prior to and during the planning session	Correlation between image quality (the number of artifacts greater than 4mm in the images acquired from Real-Time Gated 4DCT) and participant characteristics known to affect image quality in conventional scans: Breathing period ( seconds) and breathing amplitude will be measured using the Varian real-time position management system; body mass index (weight(kg) x height(m)2); tumour location;, breathing regularity (root mean square error (RMSE) of 6 breaths/min was obtained), pulmonary function, Performance status (Eastern Cooperative Oncology Group (ECOG) performance scale).
Difference in scanning time between Real-Time Gated 4DCT compared with Conventional 4DCT for planning of radiotherapy for lung cancer	30 minutes	Time in minutes from start to end of scan.
clinician confidence in delineation on a Real-Time Gated 4DCT scan	5-10 minutes, following delineation of standard care and study scans.	The radiation oncologist performing the delineation on the radiation therapy planning scan images and study scan images will complete an in-house survey of 10 questions to evaluate his experience with REACT and his confidence with using REACT for delineation.
Quality of treatment plan using images acquired during Real-Time Gated 4DCT compared with images acquired during Conventional 4DCT	1 week	Contouring and planning using the Real-Time Gated 4DCT image set to develop a treatment plan of prescribed radiation therapy. Treatment plans will be assessed using the 3%/3mm and 2%/2mm gamma pass index.

Trial Locations

Locations (1)

Blacktown Hospital; 🇦🇺 Blacktown, New South Wales, Australia