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Erschienen in:

2018 | OriginalPaper | Buchkapitel

Development of BioMg^® 250 Bioabsorbable Implant Alloy

verfasst von : R. Decker, S. LeBeau, D. LaCroix, S. Makiheni, J. Allison

Erschienen in: Magnesium Technology 2018

Verlag: Springer International Publishing

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Abstract

The alloy development of bioabsorbable BioMg^® 250 is described in terms of design of mechanical properties, biocorrosion rate and biocompatibility. The basic mechanistic role of microalloyig elements Zn, Ca and Mn is discussed as related to microstructures. In vitro corrosion and in vivo animal studies are reported. Finally, we list potential orthopedic applications in bone fixation devices fabricated from BioMg 250.

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Vorheriges Kapitel Investigations on Microstructure and Mechanical Properties of Non-flammable Mg–Al–Zn–Ca–Y Alloys

Nächstes Kapitel The Electrolytic Production of Magnesium from MgO

Xin, X., Hu, T., Chu, P., (2011), In Vitro studies of biomedical magnesium alloys in a simulated physiological environment: a review, Acta Biomatrialia, 7, p. 1452.

Staiger, M., Pietak, A., Huadmai, J., Dias,G., (2006), Magnesium and its alloys as orthopedic materials: a review, Biomaterials, 27, p. 1728.

Hartwig, A., (2001), Role of magnesium in genomic stability, Mutat Res/Fund Mol Mech Mutagen, 457, p. 13.

Wolf, F., Cittadini, A., (2003), Chemistry and biochemistry of magnesium, Mol Aspects Med, 24, p. 3.

Vormann, J., (2003), Magnesium: nutrition and metabolism, Mol Aspects Med, 24, p. 27.

Decker, R., LeBeau, S., Young, S., Patent WO201414145672AI, September 18, 2014.

Yasi, J., Hector, L., Trinkle, D., (2010), First-principles for solid-solution strengthening of Magnesium: From geometry and chemistry to properties, Acta Materialia, 58, p. 5704.

Saal, J., Wolverton, C., (2014), Thermodynamic stability of Mg-based ternary long-period stacking ordered structures, Acta Materialia, 68, p. 325.

Oh-ishi, K., Watanabe, R., Mendis, C., Hono, K., (2009), Age-hardening response of Mg-0.3 at% Ca alloys with different Zn contents, Materials Science and Engineering A, 526, p. 177.

10.

Zeng, Z., Zhu, Y., Xu, S., Bian, M., Davies, C., Birbilis, N. Nie, J., (2016), Texture evolution during static recrystallization of cold-rolled magnesium alloys, Acta Materialia, 105, p. 479.

11.

Yuasa, M., Hayashi, M., Mabuchi, M., Chino, Y., (2014), Improve plastic anisotropy of Mg–Zn–Ca alloys exhibiting high-stretch formability—a first principles study, Acta Materialia, 65, p. 207.

12.

Zeng, Z., Xu, S., Bian, M., Davies, C., Birbilis, N. Nie, J., (2016) Effects of Dilute Additions of Zn and Ca on Ductility of Magnesium Alloys, Materials and Science & Engineering A, 674, p. 459.

13.

Hase, T., Ohhtagaki, T., Yamaguchi, M., Ikeo, N., (2016), Effect of aluminum or zinc solute addition on enhancing impact toughness in Mg–Ca alloys, Acta Materialia, 104, p. 283.

14.

Yoshizawa S, Brown A, Barchowsky A, Sfeir C. (2014), Magnesium ion stimulation of bone marrow stromal cells enhances osteogenic activity, simulating the effect of magnesium alloy degradation. Acta Biomaterialia, 10(6), p. 2834.

15.

Cheng, P., Han, P., Zhao, C., Zhang, S., Wu, H., Ni, J., Peng, J., Zhang, Y., Liu, J., Xu, H., Liu, S., Zhang, X., Zheng, Y., (2016), High Purity magnesium interference screws promote fibrocartilaginous entheses regeneration in the anterior cruciate ligament reconstruction rabbit model via accumulation of BMP-2 and VEGF, Biomaterials, 81, p. 14.

16.

Witte, F., Kaese, V., Haferkamp, H., Switzer, E., Meyer-Lindenberg, A., Wirth, C., (2005), In vivo corrosion of four magnesium alloys and the associated bone response, Biomaterials, 26, p. 3557.

17.

Castellani, C., Lindtner, R., Hausbrandt, P., Tschegg, E., Stanzl-Tschegg, S., Zanoni, G., Beck, S., Weinberg, A., (2011), Bone-implant interface strength and osseointegration: Biodegradable magnesium alloy versus standard titanium control, Acta Biomaterialia, 7, p. 432.

18.

Dewei-Zhao, M., et al., (2016), Vascularized bone grafting fixed by biodegradable magnesium screw for treating osteonecrosis of the femoral head, Biomaterials, 81, p. 84.

19.

Yu, Y., et al., Multifunctions of dual Zn/Mg ion-implanted titanium on osteogenesis, angiogenesis and bacterial inhibition for dental implants, Acta Biomaterialia, article in press, 2016.11.067.

20.

Zheng, Y., Magnesium Alloys as Degradable Biomaterials, CRC Press (2016), ISBN-13: 978-1-4665-9804-1.

21.

Kallyanashis, P., Lee, B., Abueva, C., Kim, B., Jun Choi, J., Bae, S., Byong Taek Lee, B., (2017) In vivo evaluation of injectable calcium phosphate cement composed of Zn‐and Si‐incorporated β‐tricalcium phosphate and monocalcium phosphate monohydrate for a critical sized defect of the rabbit femoral condyle, J. Biomedical Materials Research B. Applied Biomaterials, 105, p. 260.

22.

Fielding, G., Bandyopadhyay, A., Bose, S., (2012), Effects of silica and zinc oxide doping on mechanical and biological properties of 3-D printed tricalcium phosphate tissue engineering scaffolds, Dental Materials, 2012, 28, p. 113.

23.

Moreno-Eutimio, M., Nieto-Velazquez, N., Espinosa-Monroy, L., Torres-Ramos, Y., Montoya-Estrada, A., Cueto, J.,,Hicks, J., Acosta-Altamirano, G., (2014), Potent Anti-Inflammatory Activity of Carbohydrate Polymer with Oxide of Zinc, Biomed Res Int, 2014, p. 8.

24.

Molokwu, C., Li, Y., (Fall 2006), Zinc Homeostasis and Bone Density, Ohio Research and Clinical Review, 15, p. 7.

25.

Chou, A., et al, Implant Dentistry, 2007, 16, p. 89.

26.

Yang, F., et al, Oral Surg Oral Med Oral Pathol Oral Radiol, 2012, 113, p. 313.

27.

Ghorbani, F., Kaffashi, B., Shokrollahi, P., Seyedjafari, E., Ardeshirlylajima, A., (2015), PCL/chitisan/Zn-doped nHA electrospun nanocomposite scaffold promotes adipose derived stem cells adhesion and proliferation, Carbohydr Polym,118, p. 133.

Titel: Development of BioMg® 250 Bioabsorbable Implant Alloy
verfasst von: R. Decker
S. LeBeau
D. LaCroix
S. Makiheni
J. Allison
Verlag: Springer International Publishing
Buch: Magnesium Technology 2018
Print ISBN: 978-3-319-72331-0

Electronic ISBN: 978-3-319-72332-7

Copyright-Jahr: 2018
DOI: https://doi.org/10.1007/978-3-319-72332-7_18

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