Bose Sivakumar, Surendhiran Duraiarasan, Chun Byung-Soo, Arthanari Srinivasan, Tran Van Nam, Lee Huseung, Kang Hyun Wook
Marine-integrated Biomedical Technology Center, The National Key Research Institutes in Universities, Pukyong National University (PKNU), Busan 48513, Republic of Korea.
Institute of Food Science, PKNU, Busan 48513, Republic of Korea.
Colloids Surf B Biointerfaces. 2022 Nov;219:112807. doi: 10.1016/j.colsurfb.2022.112807. Epub 2022 Aug 28.
Bacterial infection is a major complication associated with bioimplant materials, including titanium (Ti) based orthopedic joints and dental implants. Thus, the fabrication of Ti surfaces with antibacterial activity is highly important. Black phosphorus (BP) is a recently discovered promising two-dimensional semiconductor for various biomedical applications due to its tunable bandgap and physicochemical properties. The present study aimed to synthesize zinc oxide (ZnO) laden BP nanohybrids (NH) and their coatings on a Ti bioimplant surface for improving the antibacterial activities against pathogenic bacteria with and without near-infrared (NIR) light irradiation. Nanohybrids were produced with the slightly oxidized BP NF and electrostatically laden ZnO NP. The produced BP-ZnO NH was a NIR active nanomaterial (up to ∼1000 nm), demonstrating a photothermal effect against bacterial infection and showing improved activity by damaging the cell membrane towards S. aureus in comparison to E. coli. Ti surface coated with BP-ZnO NH embedded chitosan (CS) demonstrated better antibacterial activity than BP NF, especially with NIR light treatment. Additionally, the produced BP nanoflakes and BP-ZnO NH, and their coatings over the Ti surface were found to be toxic at a negligible level. Electrochemical studies revealed the high corrosion resistance of the Ti surface coated with the synthesized antibacterial agents without altering its characteristic passive behavior. Owing to the interactions between the charged groups between chitosan and cell surfaces, a slight increase in antibacterial activities was noticed. Chitosan-based coating matrix embedded with nanoagents has adhered well over the Ti surface due to its inherent film-forming and high adhesion properties.
细菌感染是与生物植入材料相关的主要并发症,包括钛(Ti)基骨科关节和牙科植入物。因此,制备具有抗菌活性的Ti表面非常重要。黑磷(BP)是一种最近发现的有前途的二维半导体,因其可调节的带隙和物理化学性质而适用于各种生物医学应用。本研究旨在合成负载氧化锌(ZnO)的BP纳米杂化物(NH)及其在Ti生物植入物表面的涂层,以提高对有或没有近红外(NIR)光照射的病原菌的抗菌活性。纳米杂化物是由轻度氧化的BP纳米片(NF)和静电负载的ZnO纳米颗粒(NP)制备而成。所制备的BP-ZnO NH是一种近红外活性纳米材料(波长可达~1000nm),对细菌感染具有光热效应,与大肠杆菌相比,对金黄色葡萄球菌的细胞膜具有更强的破坏作用,从而表现出更高的活性。涂有BP-ZnO NH并嵌入壳聚糖(CS)的Ti表面显示出比BP NF更好的抗菌活性,尤其是在近红外光处理下。此外,所制备的BP纳米片和BP-ZnO NH及其在Ti表面的涂层在可忽略不计的水平上被发现具有毒性。电化学研究表明,涂有合成抗菌剂的Ti表面具有高耐腐蚀性,且不改变其特征性的钝化行为。由于壳聚糖与细胞表面之间带电基团的相互作用,抗菌活性略有增加。由于其固有的成膜和高粘附性能,嵌入纳米剂的壳聚糖基涂层基质在Ti表面上粘附良好。
