Rational design of functional materials guided by single particle chemiluminescence imaging

化学发光 动力学 合理设计 表征(材料科学) 粒子(生态学) 材料科学 粒径 磁粉成像 纳米技术 化学 纳米颗粒 磁性纳米粒子 物理化学 物理 地质学 海洋学 量子力学
作者
Weijun Kong,Qi Li,Wei Wang,Xiaoning Zhao,Shenlong Jiang,Tianhua Zheng,Qun Zhang,Wen Shen,Hua Cui
出处
期刊:Chemical Science [Royal Society of Chemistry]
卷期号:10 (21): 5444-5451 被引量:22
标识
DOI:10.1039/c9sc00954j
摘要

Chemiluminescence (CL) functionalized materials have found tremendous value in developing CL assays for clinical assays and point-of-care tests. To date, the design and optimization of these materials have mainly relied on conventional trial-and-error procedures in which the ensemble performance is evaluated using conditional experiments. Here we have built an optical microscope to acquire the CL emission from single magnetic-polymer hybrid microbeads functionalized with luminol analogues, and to access the CL kinetics of each individual particle. It was incidentally found that a minor subpopulation of microbeads exhibited intense and delayed CL emission while the majority showed transient and weak emission. Structural characterization of the very same individual particles uncovered that the amorphous multi-core microstructures were responsible for the enhanced encapsulation efficiency and optimized CL reaction kinetics. Guided by this knowledge stemming from single particle CL imaging, the synthesis procedure was rationally optimized to enrich the portion of microbeads with better CL performance, which was validated by both single particle imaging and the significantly improved analytical performance at the ensemble level. The present work not only demonstrates the CL imaging and CL kinetics curve of single microbeads for the first time, but also sets a clear example showing the capability of single particle studies to investigate the structure-activity relationship in a bottom-up manner and to help the rational design of ensemble materials with improved performance.

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