化学
纳米技术
透视图(图形)
生物传感器
工程伦理学
生化工程
化学传感器
计算生物学
生物相容性材料
光学传感
作者
Navid Rabiee,Hossein Daneshgar,Payam Arghavani,Mohammad Edrisi,Mohammad Rabiee,Mohammad Akrami‐Hasan‐Kohal,Sidi A. Bencherif
标识
DOI:10.1016/j.ccr.2025.217160
摘要
Triplet-state materials have become valuable tools in bioimaging and biosensing due to their unique photophysical properties. These materials are characterized by long-lived emission lifetimes, high signal-to-noise ratios, and sensitivity to changes in their microenvironment. In this review, we examine over 500 publications and critically compare 287 highly cited studies to evaluate the current landscape of organic, inorganic, and hybrid triplet-state materials. We explain the design principles and emission mechanisms of organic systems, including thermally activated delayed fluorescence emitters and metal-organic complexes, and contrast these with inorganic counterparts, such as transition metal-doped nanomaterials and lanthanide-based probes, known for their photostability and sharp emission profiles. The review also discusses hybrid materials that combine features from both domains to address limitations and enhance biomedical applications. Key areas of focus include emerging red and near-infrared triplet emitters, surface engineering for biocompatibility and targeting, and multimodal imaging integration. We address challenges such as oxygen quenching, biological safety, and targeted in vivo delivery. By presenting a comparative framework supported by quantitative and qualitative data, this work is intended to offer a valuable resource for researchers working toward the development of next-generation triplet-state materials for high-resolution bioimaging, real-time diagnostics, and theranostic applications. • Reviewed 500+ studies, comparing 287 key papers on triplet-state materials for biomedical imaging and sensing. • Explored organic, inorganic, and hybrid emitters with long lifetimes and high signal-to-noise ratios. • Highlighted red/NIR emitters and surface engineering for improved targeting and biocompatibility. • Discussed strategies to overcome oxygen quenching and enhance in vivo delivery. • Provided a quantitative framework for developing next-gen materials for imaging, diagnostics, and theranostics.
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