Optical molecular imaging in cancer research: current impact and future prospect

Abstract

Abstract Cancer has long been a major threat to human health. Recent advancements in molecular imaging have revolutionized cancer research by enabling early and precise disease localization, essential for effective management. In particular, optical molecular imaging is an invaluable cancer detection tool in preoperative planning, intraoperative guidance, and postoperative monitoring owing to its noninvasive nature, rapid turnover, safety, and ease of use. The tumor microenvironment and cells within it express distinct biomarkers. Optical imaging technology leverages these markers to differentiate tumor tissues from surrounding tissues and capture real-time images with high resolution. Nevertheless, a robust understanding of these cancer-related molecules and their dynamic changes is crucial for effectively managing cancer. Recent advancements in optical molecular imaging technologies offer novel approaches for cancer investigation in research and practice. This review investigates the modern optical molecular imaging techniques employed in both preclinical and clinical research, including bioluminescence, fluorescence, chemiluminescence, photoacoustic imaging, and Raman spectroscopy. We explore the current paradigm of optical molecular imaging modalities, their current status in preclinical cancer research and clinical applications, and future perspectives in the fields of cancer research and treatment.