Electrophoretic Deposition of Nanohydroxyapatite on Homogenized Magnesium Based Alloy for Biomedical Applications

IF 0.5 Q4 ENGINEERING, BIOMEDICAL Journal of Biomimetics, Biomaterials and Biomedical Engineering Pub Date : 2023-07-31 DOI:10.4028/p-CU9Y6h
T. O. Sadiq, I. Sudin, Ahmed Alsakkaf, J. Idris, N. A. Fadil
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Abstract

Magnesium (Mg) alloys are promising biodegradable implant materials. If successful, they do not require second surgical operation for their removal. However, the focus of this study is to address the limitation of fast degradation rate (DR) which hinders the clinical application of Mg alloys. The bio-corrosion rate of any intermetallic alloy is related to its beta (β) phase volume fraction. Thus, homogenization heat treatment (HHT) was carried out to reduce the β phase. The influence of β phase and the hydroxyapatite powders (HAp) was employed to slow down the initial DR of Mg AZ91 alloy. Samples were cut from Mg grade AZ91 alloy ingot in 10mm x 10mm x 3mm dimension. The samples were prepared and divided into two; the first part was classified as as-received sample (sample a) while the second one was processed for HHT. HHT was carried out at 410°C/10h, cooled inside the furnace and named as homogenized sample (sample b). The HAp was synthesized using a simple wet chemical precipitation technique (SWCPT) and deposited on sample b via electrophoretic deposition (EPD) at different voltages with different deposition times. The HAp, uncoated and coated samples were characterized. Potentiodynamic polarization (PP) and immersion tests were carried out in stimulated body fluid (SBF) to estimate the DR and in vitro bioactivity of Mg AZ91 respectively. The results revealed a significant drop in DR from sample a (1.421 mm per year) to coated sample h (3.73 x 10-4 mm per year). Keywords: Magnesium alloy, biodegradable implants, beta phase, homogenization heat treatment, hydroxyapatite, electrophoretic deposition.
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电泳沉积纳米羟基磷灰石在均匀化镁基合金上的生物医学应用
镁合金是一种很有前途的生物可降解植入材料。如果成功,他们不需要第二次手术切除。然而,本研究的重点是解决快速降解率(DR)的限制,这阻碍了镁合金的临床应用。金属间合金的生物腐蚀速率与其β (β)相体积分数有关。因此,采用均质热处理(HHT)来减少β相。采用β相和羟基磷灰石粉末(HAp)的影响来减缓Mg AZ91合金的初始DR。样品由Mg级AZ91合金铸锭切割,尺寸为10mm × 10mm × 3mm。样品被制备并分成两份;第一部分归类为收到样品(样品a),第二部分处理为HHT。HHT在410°C/10h下进行,在炉内冷却并命名为均质样品(样品b)。采用简单湿化学沉淀法(SWCPT)合成HAp,并在不同电压和不同沉积时间下通过电泳沉积(EPD)沉积在样品b上。对HAp、未包覆和包覆样品进行了表征。采用动电位极化法(PP)和浸泡法(SBF)分别测定Mg AZ91的DR和体外生物活性。结果显示,从样品a(每年1.421 mm)到涂层样品h(每年3.73 x 10-4 mm), DR显著下降。关键词:镁合金,可生物降解植入物,β相,均质热处理,羟基磷灰石,电泳沉积。
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CiteScore
1.40
自引率
14.30%
发文量
73
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