Toward Tailoring the Degradation Rate of Magnesium-Based Biomaterials for Various Medical Applications: Assessing Corrosion, Cytocompatibility and Immunological Effects

Philip Hartjen; Nils Wegner; Parimah Ahmadi; Levi Matthies; Ola Nada; Sandra Fuest; Ming Yan; Christian Knipfer; Martin Gosau; Frank Walther; Ralf Smeets

doi:10.3390/ijms22020971

Toward Tailoring the Degradation Rate of Magnesium-Based Biomaterials for Various Medical Applications: Assessing Corrosion, Cytocompatibility and Immunological Effects

Standard

Toward Tailoring the Degradation Rate of Magnesium-Based Biomaterials for Various Medical Applications: Assessing Corrosion, Cytocompatibility and Immunological Effects. / Hartjen, Philip; Wegner, Nils; Ahmadi, Parimah; Matthies, Levi; Nada, Ola; Fuest, Sandra; Yan, Ming; Knipfer, Christian ; Gosau, Martin; Walther, Frank; Smeets, Ralf.

in: INT J MOL SCI, Jahrgang 22, Nr. 2, 19.01.2021, S. 971.

Publikationen: SCORING: Beitrag in Fachzeitschrift/Zeitung › SCORING: Zeitschriftenaufsatz › Forschung › Begutachtung

Harvard

Hartjen, P, Wegner, N, Ahmadi, P, Matthies, L, Nada, O, Fuest, S, Yan, M, Knipfer, C , Gosau, M, Walther, F & Smeets, R 2021, 'Toward Tailoring the Degradation Rate of Magnesium-Based Biomaterials for Various Medical Applications: Assessing Corrosion, Cytocompatibility and Immunological Effects', INT J MOL SCI, Jg. 22, Nr. 2, S. 971. https://doi.org/10.3390/ijms22020971

APA

Hartjen, P., Wegner, N., Ahmadi, P., Matthies, L., Nada, O., Fuest, S., Yan, M., Knipfer, C., Gosau, M., Walther, F., & Smeets, R. (2021). Toward Tailoring the Degradation Rate of Magnesium-Based Biomaterials for Various Medical Applications: Assessing Corrosion, Cytocompatibility and Immunological Effects. INT J MOL SCI, 22(2), 971. https://doi.org/10.3390/ijms22020971

Vancouver

Hartjen P, Wegner N, Ahmadi P, Matthies L, Nada O, Fuest S et al. Toward Tailoring the Degradation Rate of Magnesium-Based Biomaterials for Various Medical Applications: Assessing Corrosion, Cytocompatibility and Immunological Effects. INT J MOL SCI. 2021 Jan 19;22(2):971. https://doi.org/10.3390/ijms22020971

Bibtex

@article{769a364fda854eb49586d855db8cdbd8,

title = "Toward Tailoring the Degradation Rate of Magnesium-Based Biomaterials for Various Medical Applications: Assessing Corrosion, Cytocompatibility and Immunological Effects",

abstract = "Magnesium (Mg)-based biomaterials hold considerable promise for applications in regenerative medicine. However, the degradation of Mg needs to be reduced to control toxicity caused by its rapid natural corrosion. In the process of developing new Mg alloys with various surface modifications, an efficient assessment of the relevant properties is essential. In the present study, a WE43 Mg alloy with a plasma electrolytic oxidation (PEO)-generated surface was investigated. Surface microstructure, hydrogen gas evolution in immersion tests and cytocompatibility were assessed. In addition, a novel in vitro immunological test using primary human lymphocytes was introduced. On PEO-treated WE43, a larger number of pores and microcracks, as well as increased roughness, were observed compared to untreated WE43. Hydrogen gas evolution after two weeks was reduced by 40.7% through PEO treatment, indicating a significantly reduced corrosion rate. In contrast to untreated WE43, PEO-treated WE43 exhibited excellent cytocompatibility. After incubation for three days, untreated WE43 killed over 90% of lymphocytes while more than 80% of the cells were still vital after incubation with the PEO-treated WE43. PEO-treated WE43 slightly stimulated the activation, proliferation and toxin (perforin and granzyme B) expression of CD8+ T cells. This study demonstrates that the combined assessment of corrosion, cytocompatibility and immunological effects on primary human lymphocytes provide a comprehensive and effective procedure for characterizing Mg variants with tailorable degradation and other features. PEO-treated WE43 is a promising candidate for further development as a degradable biomaterial.",

author = "Philip Hartjen and Nils Wegner and Parimah Ahmadi and Levi Matthies and Ola Nada and Sandra Fuest and Ming Yan and Christian Knipfer and Martin Gosau and Frank Walther and Ralf Smeets",

year = "2021",

month = jan,

day = "19",

doi = "10.3390/ijms22020971",

language = "English",

volume = "22",

pages = "971",

journal = "INT J MOL SCI",

issn = "1661-6596",

publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

number = "2",

}

RIS

TY - JOUR

T1 - Toward Tailoring the Degradation Rate of Magnesium-Based Biomaterials for Various Medical Applications: Assessing Corrosion, Cytocompatibility and Immunological Effects

AU - Hartjen, Philip

AU - Wegner, Nils

AU - Ahmadi, Parimah

AU - Matthies, Levi

AU - Nada, Ola

AU - Fuest, Sandra

AU - Yan, Ming

AU - Knipfer, Christian

AU - Gosau, Martin

AU - Walther, Frank

AU - Smeets, Ralf

PY - 2021/1/19

Y1 - 2021/1/19

N2 - Magnesium (Mg)-based biomaterials hold considerable promise for applications in regenerative medicine. However, the degradation of Mg needs to be reduced to control toxicity caused by its rapid natural corrosion. In the process of developing new Mg alloys with various surface modifications, an efficient assessment of the relevant properties is essential. In the present study, a WE43 Mg alloy with a plasma electrolytic oxidation (PEO)-generated surface was investigated. Surface microstructure, hydrogen gas evolution in immersion tests and cytocompatibility were assessed. In addition, a novel in vitro immunological test using primary human lymphocytes was introduced. On PEO-treated WE43, a larger number of pores and microcracks, as well as increased roughness, were observed compared to untreated WE43. Hydrogen gas evolution after two weeks was reduced by 40.7% through PEO treatment, indicating a significantly reduced corrosion rate. In contrast to untreated WE43, PEO-treated WE43 exhibited excellent cytocompatibility. After incubation for three days, untreated WE43 killed over 90% of lymphocytes while more than 80% of the cells were still vital after incubation with the PEO-treated WE43. PEO-treated WE43 slightly stimulated the activation, proliferation and toxin (perforin and granzyme B) expression of CD8+ T cells. This study demonstrates that the combined assessment of corrosion, cytocompatibility and immunological effects on primary human lymphocytes provide a comprehensive and effective procedure for characterizing Mg variants with tailorable degradation and other features. PEO-treated WE43 is a promising candidate for further development as a degradable biomaterial.

AB - Magnesium (Mg)-based biomaterials hold considerable promise for applications in regenerative medicine. However, the degradation of Mg needs to be reduced to control toxicity caused by its rapid natural corrosion. In the process of developing new Mg alloys with various surface modifications, an efficient assessment of the relevant properties is essential. In the present study, a WE43 Mg alloy with a plasma electrolytic oxidation (PEO)-generated surface was investigated. Surface microstructure, hydrogen gas evolution in immersion tests and cytocompatibility were assessed. In addition, a novel in vitro immunological test using primary human lymphocytes was introduced. On PEO-treated WE43, a larger number of pores and microcracks, as well as increased roughness, were observed compared to untreated WE43. Hydrogen gas evolution after two weeks was reduced by 40.7% through PEO treatment, indicating a significantly reduced corrosion rate. In contrast to untreated WE43, PEO-treated WE43 exhibited excellent cytocompatibility. After incubation for three days, untreated WE43 killed over 90% of lymphocytes while more than 80% of the cells were still vital after incubation with the PEO-treated WE43. PEO-treated WE43 slightly stimulated the activation, proliferation and toxin (perforin and granzyme B) expression of CD8+ T cells. This study demonstrates that the combined assessment of corrosion, cytocompatibility and immunological effects on primary human lymphocytes provide a comprehensive and effective procedure for characterizing Mg variants with tailorable degradation and other features. PEO-treated WE43 is a promising candidate for further development as a degradable biomaterial.

U2 - 10.3390/ijms22020971

DO - 10.3390/ijms22020971

M3 - SCORING: Journal article

C2 - 33478090

VL - 22

SP - 971

JO - INT J MOL SCI

JF - INT J MOL SCI

SN - 1661-6596

IS - 2

ER -