Home > Research > Publications & Outputs > Biocompatibility testing of aluminium and zirco...

Research

Electronic data

View graph of relations

Biocompatibility testing of aluminium and zirconium based hybrid organic-inorganic materials

Research output: Contribution to conference - Without ISBN/ISSN Posterpeer-review

Published

Standard

Biocompatibility testing of aluminium and zirconium based hybrid organic-inorganic materials. / Balciunas, Evaldas; Baldock, Sara; Hardy, John et al.
2016. Poster session presented at Laboratory Animals in Research, Vilnius, Lithuania.

Research output: Contribution to conference - Without ISBN/ISSN Posterpeer-review

Harvard

Balciunas, E, Baldock, S, Hardy, J & Baltriukiene, D 2016, 'Biocompatibility testing of aluminium and zirconium based hybrid organic-inorganic materials', Laboratory Animals in Research, Vilnius, Lithuania, 24/11/16 - 25/11/16.

APA

Balciunas, E., Baldock, S., Hardy, J., & Baltriukiene, D. (2016). Biocompatibility testing of aluminium and zirconium based hybrid organic-inorganic materials. Poster session presented at Laboratory Animals in Research, Vilnius, Lithuania.

Vancouver

Balciunas E, Baldock S, Hardy J, Baltriukiene D. Biocompatibility testing of aluminium and zirconium based hybrid organic-inorganic materials. 2016. Poster session presented at Laboratory Animals in Research, Vilnius, Lithuania.

Author

Balciunas, Evaldas ; Baldock, Sara ; Hardy, John et al. / Biocompatibility testing of aluminium and zirconium based hybrid organic-inorganic materials. Poster session presented at Laboratory Animals in Research, Vilnius, Lithuania.

Bibtex

@conference{9342d0327a7a4116afc11719ef9810f7,
title = "Biocompatibility testing of aluminium and zirconium based hybrid organic-inorganic materials",
abstract = "Introduction: Tissue engineering is a field based on the idea that the majority of human tissues and organs can be replaced by autologous artificial tissues, composed of cells and scaffolds [1]. There are many scaffold fabrication techniques, but one of the most promising ones is laser multiphoton polymerisation [2]. A wide range of materials can be structured via this technique, but hybrid organic-inorganic materials are among the most widely investigated due to their high structuring quality and ease of workflow [3]. Here, we present an aluminium-based hybrid organic-inorganic material that is relatively simple to prepare, tune and structure in 3D. We investigate its biocompatibility by comparing it to a hybrid organic-inorganic material based on zirconium and a commercially available OrmoComp (Micro Resist Technology GmbH).[1] L. G. Cima et al,1991. DOI: 10.1115/1.2891228[2] S. Maruo et al, 1997. DOI: 10.1364/OL.22.000132[3] M. Farsari et al, 2010. DOI: 10.1088/2040-8978/12/12/124001[4] M. Mailnauskas et al, 2012. DOI: 10.1007/s00339-012-6965-8",
author = "Evaldas Balciunas and Sara Baldock and John Hardy and Daiva Baltriukiene",
year = "2016",
month = nov,
day = "24",
language = "English",
note = "Laboratory Animals in Research ; Conference date: 24-11-2016 Through 25-11-2016",

}

RIS

TY - CONF

T1 - Biocompatibility testing of aluminium and zirconium based hybrid organic-inorganic materials

AU - Balciunas, Evaldas

AU - Baldock, Sara

AU - Hardy, John

AU - Baltriukiene, Daiva

PY - 2016/11/24

Y1 - 2016/11/24

N2 - Introduction: Tissue engineering is a field based on the idea that the majority of human tissues and organs can be replaced by autologous artificial tissues, composed of cells and scaffolds [1]. There are many scaffold fabrication techniques, but one of the most promising ones is laser multiphoton polymerisation [2]. A wide range of materials can be structured via this technique, but hybrid organic-inorganic materials are among the most widely investigated due to their high structuring quality and ease of workflow [3]. Here, we present an aluminium-based hybrid organic-inorganic material that is relatively simple to prepare, tune and structure in 3D. We investigate its biocompatibility by comparing it to a hybrid organic-inorganic material based on zirconium and a commercially available OrmoComp (Micro Resist Technology GmbH).[1] L. G. Cima et al,1991. DOI: 10.1115/1.2891228[2] S. Maruo et al, 1997. DOI: 10.1364/OL.22.000132[3] M. Farsari et al, 2010. DOI: 10.1088/2040-8978/12/12/124001[4] M. Mailnauskas et al, 2012. DOI: 10.1007/s00339-012-6965-8

AB - Introduction: Tissue engineering is a field based on the idea that the majority of human tissues and organs can be replaced by autologous artificial tissues, composed of cells and scaffolds [1]. There are many scaffold fabrication techniques, but one of the most promising ones is laser multiphoton polymerisation [2]. A wide range of materials can be structured via this technique, but hybrid organic-inorganic materials are among the most widely investigated due to their high structuring quality and ease of workflow [3]. Here, we present an aluminium-based hybrid organic-inorganic material that is relatively simple to prepare, tune and structure in 3D. We investigate its biocompatibility by comparing it to a hybrid organic-inorganic material based on zirconium and a commercially available OrmoComp (Micro Resist Technology GmbH).[1] L. G. Cima et al,1991. DOI: 10.1115/1.2891228[2] S. Maruo et al, 1997. DOI: 10.1364/OL.22.000132[3] M. Farsari et al, 2010. DOI: 10.1088/2040-8978/12/12/124001[4] M. Mailnauskas et al, 2012. DOI: 10.1007/s00339-012-6965-8

M3 - Poster

T2 - Laboratory Animals in Research

Y2 - 24 November 2016 through 25 November 2016

ER -