Trials / Active Not Recruiting

Active Not RecruitingNCT07305103

Defining Dosimetric Reference Levels in Computed Tomography Spectral Scanning

Summary

Spectral computed tomography or dual-energy CT imaging can overcome the limitations of conventional CT in differentiating between two materials with equivalent total attenuation. It can generate several types of images, such as virtual monochromatic images, which improve the contrast-to-noise ratio for low energy levels and reduce artifacts for high energy levels. It also allows for quantitative image analysis and thus better characterization of lesions and tissues through material mapping (e.g., iodinated contrast agent mapping). This technique is increasingly used in routine clinical practice thanks to improvements in image flow management and technological advances. It also involves exposing patients to ionizing radiation, as with conventional CT but, unlike conventional CT scans, for which dosimetric reference levels (RLs) are defined for the most common examinations in France (RL decree dated 2019), there are currently no dosimetric reference levels for examinations performed using this technique. Yet RLs are an important and effective tools for optimizing patient exposure to ionizing radiation. Several articles were published between 2012 and 2017 when the first dual-energy scanners arrived in clinics. However, the results presented in these studies are now far removed from recent practices, as they do not take into account the latest technological developments used in dual-energy scanners, which reduce X-ray doses. The main objective of the study is to define dosimetric reference levels for the most commonly performed spectral computed tomography examinations in France.

Detailed description

Spectral computed tomography (CT) (or dual-energy CT) imaging can overcome the limitations of conventional CT in differentiating between two materials with equivalent total attenuation. It can generate several types of images, such as virtual monochromatic images, which improve the contrast-to-noise ratio for low energy levels and reduce artifacts for high energy levels. It also allows for quantitative image analysis and thus better characterization of lesions and tissues through material mapping (e.g., iodinated contrast agent mapping). This technique is increasingly used in routine clinical practice thanks to improvements in image flow management and technological advances. It also involves exposing patients to ionizing radiation, as with conventional CT. However, unlike conventional CT scans, for which dosimetric reference levels (RLs) are defined for the most common examinations in France (RL decree dated 2019), there are currently no dosimetric reference levels for examinations performed using this technique. Yet the RL is an important and effective tool in optimizing patient exposure to ionizing radiation. In fact, a number of articles were published between 2012 and 2017, when the first dual-energy scanners arrived in clinics. However, the results presented in these studies are now far removed from recent practices, as they do not take into account the latest technological developments used in dual-energy scanners, which reduce X-ray doses. The main objective of the study is to define dosimetric reference levels for the most frequently performed spectral computed tomography examinations in France: 1. Chest CT for pulmonary embolism 2. Chest CT for other indications 3. Coronary CT with contrast injection and retrospective gating 4. Coronary CT with contrast injection and prospective gating 5. Cranial CT with contrast injection 6. Supra-aortic trunk CT 7. Neck and ear,nose and throat sphere CT with contrast injection 8. Oncological abdomen-pelvis CT scan 9. Abdomen-pelvis CT scan to check for kidney stones 10. Abdomen-pelvis CT scan for non-oncological purposes and to check for kidney stones 11. Oncological chest-abdomen-pelvis CT scan 12. Non-oncological chest-abdomen-pelvis CT scan 13. Oncological chest-abdomen CT scan 14. Non-oncological chest-abdomen CT scan 15. Lower limb angiography 16. Cervical spine CT scan 17. Thoracic spine CT scan 18. Lumbar spine CT scan 19. Pelvis CT scan, 20. Extremities CT scan The secondary objectives of the study are to evaluate, for each examination performed: 1. the impact of the spectral acquisition/detection technique on the dose delivered to patients. 2. the impact of patients' BMI on the dose delivered to patients. 3. the impact of reconstruction algorithms on the dose delivered to patients.

Conditions

• Medical Imaging

Interventions

Timeline

Start date

2025-09-01

Primary completion

2025-12-31

Completion

2026-06-30

First posted

2025-12-26

Last updated

2025-12-26

Locations

1 site across 1 country: France

Source: ClinicalTrials.gov record NCT07305103. Inclusion in this directory is not an endorsement.