Abstract:Zinc-based biodegradable metals (BMs) have been developed for biomedical implant materials. However, the cytotoxicity of Zn and its alloys has caused controversy. This work aims to investigate whether Zn and its alloys possess cytotoxic effects and the corresponding influence factors. According to the guidelines of the PRISMA statement, an electronic combined hand search was conducted to retrieve articles published in PubMed, Web of Science, and Scopus (2013.1–2023.2) following the PICOS strategy. Eighty-six e… Show more
“…Fig. 2 summarizes the mechanical strength versus the qualitative biocompatibility of the most common classes of metals that are used – or could be used – to produce biomedical cellular solids, based on various literature references [ [36] , [37] , [38] , [39] , [40] , [41] , [42] ]. The biological performance is primarily influenced by potential cytotoxicity and ion release, and secondarily by the alloys ability to promote osseointegration.…”
Section: Advantages Of Metallic Cellular Solidsmentioning
“…Fig. 2 summarizes the mechanical strength versus the qualitative biocompatibility of the most common classes of metals that are used – or could be used – to produce biomedical cellular solids, based on various literature references [ [36] , [37] , [38] , [39] , [40] , [41] , [42] ]. The biological performance is primarily influenced by potential cytotoxicity and ion release, and secondarily by the alloys ability to promote osseointegration.…”
Section: Advantages Of Metallic Cellular Solidsmentioning
“…In contrast, biodegradable implants can degrade and be absorbed post implantation while maintaining their mechanical integrity during the critical period before complete healing is achieved [3][4][5][6]. In many cases, the use of a temporary biodegradable implant is sufficient as there is no need for the presence of the implant after the recovery of the tissue [6][7][8][9][10][11]. The desired time for the biodegradable implant to remain in the body until complete dissolution varies, depending on the function of the implant and the tissue to which it is attached.…”
The present study aims to evaluate the effect of up to 3 wt.% Nd on pure Zn in terms of physical properties and in vitro analysis. The use of Nd as an alloying element is due to its relatively adequate biocompatibility and its potential capability to reinforce metals with a hexagonal close-packed (HCP) crystal structure, such as Mg and Zn. The microstructural assessment was executed using X-ray diffraction analysis, along with optical and scanning electron microscopy. The mechanical properties were evaluated by hardness and tensile strength testing. The corrosion performance in simulated physiological environments was examined by means of immersion tests, potentiodynamic polarization, and impedance spectroscopy using phosphate-buffered saline (PBS) solution. Cytotoxicity assessment was carried out by indirect cell viability analysis according to the ISO 10993-5/12 standard using Mus musculus 4T1 cells, which are known to be very sensitive to toxic environments. The obtained results clearly highlighted the reinforcing effect of Nd in Zn-base alloys, mainly due to the formation of a secondary phase: NdZn5. This strengthening effect was acquired without impairing the inherent ductility and corrosion performance of the tested alloys. The cytotoxicity assessment indicated that the addition of Nd has a strong favorable effect on cell viability, which stimulates the inherent anti-inflammatory characteristics of Zn.
“… 1–5 However, the complex intricacies of biomedicine pose a challenge for single-component organic and inorganic materials in terms of their biological functionality while ensuring biocompatibility, 6 as well as tackling concerns like cell or tissue toxicity. 7–9 Figure 1 Schematic diagram of the application of MOF materials in different fields. Adapted from Cao, Y., Fu, M., Fan, S., Gao, C., Ma, Z., & Hou, D. Hydrophobic MOF/PDMS-Based QCM Sensors for VOCs Identification and Quantitative Detection in High-Humidity Environments.…”
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