Department of Nuclear Medicine, Union Hospital, Tongji Medical College, Huazhong University of Science and Technology, Wuhan 430022, China.
Molecular Imaging Program at Stanford, Bio-X Program, and Department of Radiology, Canary Center at Stanford for Cancer Early Detection, Stanford University, California 94305-5344, USA.
J Mater Chem B. 2021 Nov 17;9(44):9116-9122. doi: 10.1039/d1tb01640g.
Featuring simultaneous multicolor imaging for multiple targets, a synergistic strategy has become promising for fluorescence imaging applications. Visible and first near infrared (NIR-I, 700-900 nm) fluorophores have been explored for multicolor imaging to achieve good multi-target capacity, but they are largely hampered by the narrow imaging bands available (400-900 nm, bandwidth 500 nm), the broad emission spectra of many fluorophores, shallow tissue penetration and scattering loss. With attractive characteristic emission peaks in the second NIR window (NIR-II, 1000-1700 nm), a narrow emission spectrum, and deeper tissue penetration capability, rare-earth doped nanoparticles (RENPs) have been considered by us to be outstanding candidates for multicolor bioimaging. Herein, two RENPs, NaYF:Yb20Er2@NaYF and NaYF:Nd5@NaYF, were prepared and modified with polyethylene glycol (PEG) to explore simultaneous imaging in the NIR-IIb (1530 nm, under 980 nm laser excitation) and the NIR-II (1060 nm, under 808 nm laser excitation) windows. The PEGylated-RENPs (RENPs@PEG) were able to simultaneously visualize the circulatory system, trace the lymphatic system, and evaluate the skeletal system. Our study demonstrates that RENPs have high synergistic imaging capability in multifunctional biomedical applications using their NIR-II fluorescence. Importantly, the two RENPs@PEG are complementary to each other for higher temporal resolution in NaYF:Nd5@NaYF@PEG and higher spatial resolution in NaYF:Yb20Er2@NaYF@PEG, which may provide more comprehensive and accurate imaging diagnosis. In conclusion, RENPs are highly promising nanomaterials for multicolor imaging in the NIR-II window.
针对多靶点的同时多色成像,协同策略已成为荧光成像应用的有前途的方法。已经探索了可见和近红外一区(NIR-I,700-900nm)荧光团用于多色成像以实现良好的多靶点容量,但是它们受到可用的窄成像带宽(400-900nm,带宽500nm)、许多荧光团的宽发射光谱、浅组织穿透和散射损耗的极大限制。具有在第二近红外窗口(NIR-II,1000-1700nm)中吸引人的特征发射峰、窄的发射光谱和更深的组织穿透能力,稀土掺杂纳米粒子(RENPs)已被我们认为是多色生物成像的杰出候选者。在此,制备了两种 RENPs,NaYF:Yb20Er2@NaYF 和 NaYF:Nd5@NaYF,并进行了聚乙二醇(PEG)修饰以探索在 NIR-IIb(980nm 激光激发下的 1530nm)和 NIR-II(808nm 激光激发下的 1060nm)窗口中的同时成像。PEG 化的 RENPs(RENPs@PEG)能够同时可视化循环系统、追踪淋巴系统和评估骨骼系统。我们的研究表明,RENPs 具有在多功能生物医学应用中使用其近红外-II 荧光的高协同成像能力。重要的是,两种 RENPs@PEG 在 NaYF:Nd5@NaYF@PEG 中具有更高的时间分辨率和在 NaYF:Yb20Er2@NaYF@PEG 中具有更高的空间分辨率是互补的,这可能提供更全面和准确的成像诊断。总之,RENPs 是近红外-II 窗口中多色成像的很有前途的纳米材料。
