Author: Jonathan Cole

  Low dose Angiography (LDA) systems rely on significant recursive filtration (aka temporal averaging) to maintain image quality. The use of this type of processing is specific to the imaging application (cardiac, neuro, vascular…) and can be varied by the system vendor. In situations of rapid motion, such processing can have a detrimental effect on images obtained, producing temporal ghosting. LDA enables the use of lower kV and mAs resulting in lower patient and staff doses. It also allows manufacturers to overcome output limitations when using smaller focal spots. While the benefits are clear very little work has been carried out in relation to the drawbacks of this approach. This work aims to examine the impact of recursive filtration on moving targets in LDA systems. Common test objects such as the Leeds Test Objects do not allow for the dynamic assessment of Image ghosting. In this study, a modified NEMA Cardiology Phantom and an in-house linear motion phantom were used...

Presentation to come   Background Fluoroscopically-guided procedures are among the most irradiating medical interventions using ionising radiation. As such, a fair amount of pressure is put on reducing patient dose, either by adapting the protocols implemented in the units, or by heavy technical upgrades allowing for online image processing and subsequent patient exposure reduction. The downside is a potential loss in image information content, leading to either longer procedure times or, worse, increased volumes of injected contrast medium. To our knowledge, there is no existing quantity able to properly assess the visibility of moving structures in fluoroscopic images. This work proposes a new method to measure image quality using a clinically relevant detection task in dynamic conditions. Methods Our test object consists of a 3 mm thick and 250 mm wide PMMA square plate, with a 1 mm deep groove along one of the diagonals. The groove is used to straighten a 0.014” thick coronary guidewire. The plate is attached to a dedicated motion...

  Purpose To provide a protocol optimization software helping radiologist to tailor image quality (IQ) in Interventional Radiology (IR) thanks to an anthropomorphic images atlas. Method and materials For the four most representative anatomic areas of our clinical practice (liver, pelvis, lung, spleen), five reference protocols were set-up in our interventional radiology system (Innova IGS 540, GE Healthcare, Buc, France) with different IQ/dose preferences from low dose to high Image Quality (IQ). These preferences were defined by adjusting the Automatic Dose Rate and Image Quality (ADRIQ) strategy, the detail level and the rotation speed for 3DA sequences. For these 20 protocols, 3D angiography images were acquired on an anthropomorphic phantom (PBU-60, Kyoto Kagaku). All acquired images were qualitatively validated by a senior radiologist. These images were implemented in a home-made software (ProtoEnhanceIR) in order to optimize protocols by displaying the anthropomorphic images and associated Peak Skin Dose (PSD). The radiologist has the ability to select the most suitable protocols in regard...