Preparation, Biocompatibility, and In Vitro Bioactivity of High-Entropy Bio-Piezoelectric Ceramics
Huaizhang Gu, Yuanxun Li, Yunfei Kai, Xiaojuan Shang

TL;DR
Researchers developed new high-entropy piezoelectric ceramics with good biocompatibility and bioactivity for potential use in bone repair.
Contribution
The study introduces novel high-entropy bio-piezoelectric ceramics with enhanced biocompatibility and bioactivity.
Findings
Both ceramics exhibited perovskite structures and good piezoelectric properties (d33 ≥ 78 pC/N).
In vitro tests showed high cell growth rates (>80%) when co-cultured with murine fibroblasts L929.
Electrically charged surfaces of BNZST enhanced cell proliferation compared to non-polarized or unpolarized ceramics.
Abstract
A high-entropy strategy has emerged as a promising approach to enhance the functional properties of piezoelectric ceramics for biomedical applications. For this reason, we have designed two novel high-entropy ceramics, (Bi1/2Na1/2)(Zr1/3Sn1/3Ti1/3)O3(BNZST) and (Bi1/2Na1/2)(Zr1/4Sn1/4Hf1/4Ti1/4)O3(BNZSHT), which were synthesized via a two-step solid-state reaction. The phase structure, surface morphology, biocompatibility, and in vitro bioactivity were assessed. The results showed both ceramics adopted perovskite structures. BNZST and BNZSHT ceramics had relatively even crystallite sizes and element distribution, as well as achieving piezoelectric (d33 ≥ 78 pC/N) properties. In vitro tests confirmed a high relative cell growth rate (RSG, >80%) after co-culturing BNZST or BNZSHT ceramic with murine fibroblasts L929 for more than 3 days. In particular, the surface with electric charge…
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Taxonomy
TopicsFerroelectric and Piezoelectric Materials · Bone Tissue Engineering Materials · Shape Memory Alloy Transformations
