Utility of Photon Counting CT in Transcatheter Structural Heart Disease Interventions

Abstract

Photon counting Computed Tomography (PCCT) is an innovative technology that utilizes a semiconductor detector and assigns x-ray photons to specific energy bins. PCCT features include ultra high-resolution, multi-energy binning, higher signal of iodine, lower artifacts, lower noise, and geometric radiation dose efficiency. These advantages may be highly beneficial in pre- and post-procedural assessment of transcatheter structural heart disease (SHD) interventions. Ultra-high resolution improves visualization of device structure and subtle findings such as hypoattenuated leaflet thickening, small vegetations and paravalvular leaks. High resolution also improves the evaluation of heavily calcified and stented coronary arteries, which are prevalent in high-risk transcatheter aortic valve replacement (TAVR) population. Visualization of heavily calcified coronary arteries and access vessels can also be improved by using multienergy calcium separation or high-energy virtual monoenergetic images (VMIs). PCCT allows use of low dose of iodinated contrast in severe renal dysfunction, due to inherent higher contrast-to-noise ratio of iodine, availability of a high-pitch helical mode and low-energy VMIs. High-energy VMIs can decrease artifacts including calcium blooming, beam hardening and metallic artifacts. Iodine maps enable quantification of extracellular volume without need for a non-contrast scan, facilitating the identification of cardiomyopathies like cardiac amyloidosis. Moreover, calcium score can be obtained from virtual non contrast (VNC) images derived from CT angiographic images. Additionally, VNC and iodine maps can characterize incidentally encountered lesions such as thrombus. In this article, we review the utility of PCCT in transcatheter SHD interventions.