Abstract

Mg-based biodegradable materials, used for medical applications, have been extensively studied in the past decades. The in vitro cytocompatibility study showed that the proliferation and viability (as assessed by quantitative MTT-assay—3-(4,5-dimethyltiazol-2-yl)-2,5-diphenyl tetrazolium bromide) were not negatively affected with time by the addition of Mn as an alloying element. In this sense, it should be put forward that the studied alloys don’t have a cytotoxic effect according to the standard ISO 10993-5, i.e., the level of the cells’ viability (cultured with the studied experimental alloys) attained both after 1 day and 5 days was over 82% (i.e., 82, 43–89, 65%). Furthermore, the fibroblastic cells showed variable morphology (evidenced by fluorescence microscopy) related to the alloy sample’s proximity (i.e., related to the variation on the Ca, Mg, and Mn ionic concentration as a result of alloy degradation). It should be mentioned that the cells presented a polygonal morphology with large cytoplasmic processes in the vicinity of the alloy’s samples, and a bipolar morphology in the remote region of the wells. Moreover, the in vitro results seem to indicate that only 0.5% Mn is sufficient to improve the chemical stability, and thus the cytocompatibility; from this point of view, it could provide some flexibility in choosing the right alloy for a specific medical application, depending on the specific parameters of each alloy, such as its mechanical properties and corrosion resistance. In order to assess the in vivo compatibility of each concentration of alloy, the pieces were implanted in four rats, in two distinct body regions, i.e., the lumbar and thigh. The body’s reaction was followed over time, 60 days, both by general clinical examinations considering macroscopic changes, and by laboratory examinations, which revealed macroscopic and microscopic changes using X-rays, CT(Computed Tomography), histology exams and SEM (Scanning Electron Microscopy). In both anatomical regions, for each of the tested alloys, deformations were observed, i.e., a local reaction of different intensities, starting the day after surgery. The release of hydrogen gas that forms during Mg alloy degradation occurred immediately after implantation in all five of the groups examined, which did not affect the normal functionality of the tissues surrounding the implants. Imaging examinations (radiological and CT) revealed the presence of the alloy and the volume of hydrogen gas in the lumbar and femoral region in varying amounts. The biodegradable alloys in the Mg-Ca-Mn system have great potential to be used in orthopedic applications.

Highlights

  • Magnesium-based biodegradable alloys have the advantage of eliminating the second surgical intervention in the human body

  • CTohneclbuisoidoengsradable Mg-0.5Ca-xMn alloy system was developed for validation in terms of biocTohmepbaitoibdieligtyraadnadblpeotMengt-i0a.l5uCsae-xinMfnutuarlleooyrtshyospteemdicwaapspldiceavtieolonps.eTdhfeobriovdaeligdraatdioanblein Mtegr-m0.5sCoaf-bxiMocnoamllpoaytisbyisltietymawndaspdoetveneltoiapleudsfeoirnthfue tiunrveesotrigthaotipoendoicf iatsppbiloiccaotmiopnast.iTbihlietybiaondde- potential use in future orthopedic applications

  • The results seem to indicate that only 0.5% Mn is enough to improve the chemical stability, and the alloys’ cytocompatibility, and in this way could provide some flexibility in choosing the right alloy for a medical application depending on the specific mechanical and corrosion resistance parameters of each alloy

Read more

Summary

Introduction

Magnesium-based biodegradable alloys have the advantage of eliminating the second surgical intervention in the human body. Several discoveries have been made involving magnesium-based alloys, but the pure magnesium alloy presents high activity in an aqueous environment, low formability [3,4], low mechanical strength and the low precipitation of solid solutions, due to its hexagonal crystalline structure [4]. These disadvantages could lead to implant mass integrity loss or the excessive release of H2, which can decrease cellular development and can appear in local cysts [5]. In order to reduce the biodegradation rate, magnesium has been alloyed with Ca, Zn, Mn, Al or rare earth elements (RE), with calcium and zinc having the highest biocompatibility [11]

Objectives
Methods
Findings
Conclusion

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.