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. 2018 Apr 2;13(4):e0193927.
doi: 10.1371/journal.pone.0193927. eCollection 2018.

Development and properties of duplex MgF2/PCL coatings on biodegradable magnesium alloy for biomedical applications

Preeti Makkar  1 Hoe Jin Kang  2 Andrew R Padalhin  1 Ihho Park  3 Byoung-Gi Moon  4 Byong Taek Lee  1   2
Affiliations

Development and properties of duplex MgF2/PCL coatings on biodegradable magnesium alloy for biomedical applications

Preeti Makkar et al. PLoS One. .

Abstract

The present work addresses the performance of polycaprolactone (PCL) coating on fluoride treated (MgF2) biodegradable ZK60 magnesium alloy (Mg) for biomedical application. MgF2 conversion layer was first produced by immersing Mg alloy substrate in hydrofluoric acid solution. The outer PCL coating was then prepared using dip coating technique. Morphology, elements profile, phase structure, roughness, mechanical properties, invitro corrosion, and biocompatibility of duplex MgF2/PCL coating were then characterized and compared to those of fluoride coated and uncoated Mg samples. The invivo degradation behavior and biocompatibility of duplex MgF2/PCL coating with respect to ZK60 Mg alloy were also studied using rabbit model for 2 weeks. SEM and TEM analysis showed that the duplex coating was uniform and comprised of porous PCL film (~3.3 μm) as upper layer with compact MgF2 (~2.2 μm) as inner layer. No significant change in microhardness was found on duplex coating compared with uncoated ZK60 Mg alloy. The duplex coating showed improved invitro corrosion resistance than single layered MgF2 or uncoated alloy samples. The duplex coating also resulted in better cell viability, cell adhesion, and cell proliferation compared to fluoride coated or uncoated alloy. Preliminary invivo studies indicated that duplex MgF2/PCL coating reduced the degradation rate of ZK60 Mg alloy and exhibited good biocompatibility. These results suggested that duplex MgF2/PCL coating on magnesium alloy might have great potential for orthopedic applications.

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Conflict of interest statement

Competing Interests: IP is currently employed by Sk Innovation Global Technology. Sk Innovation Global Technology does not derive benefits from the publication of this work, and had no role in the funding of the work or other dimensions of participation other than paying the salary of the author. There are no patents, products in development or marketed products to declare. This does not alter our adherence to PLOS ONE policies on sharing data and materials.

Figures

Fig 1
Fig 1. Optical micrograph of as-received ZK60 Mg alloy.
Fig 2
Fig 2. SEM images of (a) ZK60 Mg alloy, (b) MgF2 and (c) duplex MgF2/PCL coatings along with EDX (d-f).
Fig 3
Fig 3. Dark field TEM image showing cross-section of duplex MgF2/PCL coatings along with corresponding SAD patterns and mapping profile.
Fig 4
Fig 4. ZK60 Mg alloy, MgF2, and MgF2/PCL coatings (a) XRD, and (b) XPS analysis.
Fig 5
Fig 5. ZK60 Mg alloy, MgF2 and MgF2/PCL coatings (a) AFM, and (b) Wettability studies.
Fig 6
Fig 6. (a) Adhesion strength of MgF2, PCL and MgF2/PCL coatings, and (b) Hardness studies of ZK60 Mg alloy and duplex MgF2/PCL coatings.
Fig 7
Fig 7
(a) pH change, (b) Volume of hydrogen released, (c) Weight loss as a function of immersion time in PBS solution for 14 days for ZK60 Mg alloy, MgF2, and MgF2/PCL coating samples. (d) Schematic illustration of the degradation mechanism of MgF2/PCL coated alloy after immersion in PBS solution.
Fig 8
Fig 8. SEM images of ZK60 Mg alloy, MgF2, and MgF2/PCL coatings.
(a) After immersion in PBS solution for 14 days along with EDS; (b) After washing of corroded products.
Fig 9
Fig 9. Confocal images of adhesion and attachment of MC3T3-E1 cells after 4 hr seeding on MgF2 and MgF2/PCL coatings.
Phalloidin, Vinculin and nucleus were labelled with green, red and blue respectively.
Fig 10
Fig 10
(a) Cytotoxicity of MgF2 and duplex MgF2/PCL against MC3T3-E1 cells. MTT assay was performed using indirect assay after 1day incubation with increasing extract concentrations. (b) Cell proliferation behaviour of MgF2 and MgF2/PCL coating after incubation of 1, 3, and 5 days.
Fig 11
Fig 11. Control (defect), ZK60 Mg alloy and duplex MgF2/PCL coating (a) Photographs at the time of implantation and extraction, (b) Degradation rate and Bone volume at the interface, (c) 3-D MicroCT scans of the implanted zone and (d) Histological analysis after 2 weeks implantation.
See this image and copyright information in PMC

References

    1. Alvarez K, Nakajima H. Metallic scaffolds for bone regeneration. Materials. 2009;2 (3):790–832.
    1. Manivasagam G, Dhinasekaran D, Rajamanickam A. Biomedical Implants: Corrosion and its Prevention-A Review. Recent Patents on Corrosion Science. 2010.
    1. Seal CK, Vince K, Hodgson M, editors. Biodegradable surgical implants based on magnesium alloys–a review of current research. IOP conference series: materials science and engineering; 2009: IOP Publishing.
    1. Witte F, Kaese V, Haferkamp H, Switzer E, Meyer-Lindenberg A, Wirth C, et al. In vivo corrosion of four magnesium alloys and the associated bone response. Biomaterials. 2005;26(17):3557–63. doi: 10.1016/j.biomaterials.2004.09.049 - DOI - PubMed
    1. Li J, Cao P, Zhang X, Zhang S, He Y. In vitro degradation and cell attachment of a PLGA coated biodegradable Mg–6Zn based alloy. Journal of Materials Science. 2010;45(22):6038–45.

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