生物矿化
纳米技术
DNA
矿化(土壤科学)
表面改性
材料科学
纳米结构
DNA纳米技术
结晶
微观结构
钙
化学
化学工程
生物化学
有机化学
冶金
氮气
工程类
物理化学
作者
Shanshan Wu,Meizhou Zhang,Jie Song,Stefan A. L. Weber,Xiaoguo Liu,Chunhai Fan,Yuzhou Wu
出处
期刊:ACS Nano
[American Chemical Society]
日期:2020-12-17
卷期号:15 (1): 1555-1565
被引量:62
标识
DOI:10.1021/acsnano.0c08998
摘要
Calcium phosphate (Ca-P) is the most abundant biomineral in hard tissues with diverse microstructures, which in nature ensure a broad range of functionalities with virtually similar and simple chemical compositions. Artificial fabrication of rationally designed Ca-P materials with arbitrary microstructures is a long-standing challenge for inorganic chemists. Although DNA nanotechnology has been elegantly used to modulate the nanofabrication of inorganic materials because of its programmability, encoding customized Ca-P mineralization with high structural precision remains unachievable because of fast affinity-driven crystal growth. Herein, this long-standing ambition has been skillfully fulfilled by taking advantage of crystallization via a particle attachment (CPA) process. The derived hybrid materials not only well inherited the structural details encoded by the DNA template but also exhibited significantly enhanced mechanical strength, even after heating. Moreover, this method preserved preinstalled synthetic functionalities on the DNA surface, allowing for downstream site-specific modification.
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