Your search keyword '"Arbeiter Daniela"' showing total 2 results

1. Fiber composite materials via coaxial, dual or blend electrospinning

Author

Illner Sabine, Sühr Michelle, Fiedler Nicklas, Arbeiter Daniela, Götz Andreas, Schmitz Klaus-Peter, and Grabow Niels

Subjects

core-sheath, technology, industry, and agriculture, Biomedical Engineering, Medicine, scaffold, nanofiber, nonwoven

Abstract

Electrospinning (ES) is a suitable and cost effective method to mimic the chemical composition, morphology, and functional surface of natural tissues, for example of the nervous, dermal, vascular, and musculoskeletal systems. This technique is a versatile tool to obtain tailored fibrous scaffolds from various polymer materials. By varying the diameter, porosity, orientation, layering, surface structuring, mechanical properties and biodegradability of the fibers the properties can be adapted for specific applications ranging from implantable medical devices to wound repair and protective clothing. Especially the combination of different polymer types offers a high potential. In this study electrospun two-component nonwoven structures of thermoplastic copolyester elastomer (TPC-ET) and bioresorbable polylactide (PLLA) were fabricated, using different ES setups. A comparative evaluation in terms of porosity, thermal and mechanical properties as well as required fabrication effort, was performed. Nonwovens made from polymer blends and coaxial spun core-sheath fibers showed similar tensile strength, which was higher than dual electrospun fabrics. Porosity was found to be in the range of 80 - 90%. By modifying the polymer solution and process parameters multicomponent nonwoven structures with tailored properties and drug release profiles can be manufactured.

Published

2021

2. Definition of test parameters for dynamic mechanical testing of polymeric implant materials

Author

Fiedler Nicklas, Arbeiter Daniela, Oschatz Stefan, Grabow Niels, and Lebahn Kerstin

Subjects

dynamic mechanical analysis, biomedical applications, polymer characterization, Biomedical Engineering, Medicine, time-temperaturesuperposition, fatigue test

Abstract

The selection of appropriate test conditions is of critical importance in mechanical testing of biomaterials. In particular the definition of dynamic test conditions is requiring high efforts. In this work, a thermoplastic semicrystalline polymer was characterized regarding mechanical properties by dynamic mechanical analysis (DMA). Timetemperature- superposition (TTS) of dynamic mechanical data provides an efficient method for the experimental design of follow-up studies. Our focus was to provide test conditions for cyclic tests, which correspond to viscoelastic materials. The results show, that the test temperature for dynamic mechanical fatigue tests, as an indicator of mechanical modification for viscoelastic materials, should necessarily remain below the onset temperatures of storage modulus and loss modulus. Moreover, changes in material characteristics due to varying frequencies should be considered when constructing a master curve for the evaluation of test frequencies. Therefore, TTS is particularly beneficial for the rapid determination of test parameters for accelerated material examination.

Published

2021