Among all types of cancer, lung cancer remains one of the deadliest, accounting for 4.4% of all deaths in the European Union and nearly one fifth (19.8%) of all cancer-related deaths in 2022 [1]. One key reason is that most patients are diagnosed far too late. This reality highlights the life-saving potential of early detection: when lung cancer is identified at an early stage, treatment is more effective and survival rates improve significantly.
Advances in imaging technologies continue to expand what is possible in early detection. Photon-counting CT systems, for example, offer higher spatial resolution, improved contrast-to-noise ratios, and enhanced visualization of even the smallest pulmonary nodules — while keeping radiation doses remarkably low. These capabilities make them a game changer for modern lung cancer screening programs.
However, advanced technology alone is not sufficient. Across Europe, screening is performed using a wide range of CT systems, ranging from conventional energy-integrating detector scanners (EID) to next-generation photon-counting CT models (PCCT). Ensuring consistent image quality and diagnostic reliability across this heterogeneous landscape requires standardized, reliable quality control. Multinational initiatives such as the SOLACE project are therefore working towards the harmonization of low-dose screening protocols and the integration of quality assurance as a standard part of clinical practice.
Against this background, standardized tools and robust quality assurance are essential to improve outcomes for a disease that remains one of the leading causes of cancer-related mortality worldwide.