Your search keyword '"Arbeiter Daniela"' showing total 6 results

1. The influence of PEGDA’s molecular weight on its mechanical properties in the context of biomedical applications

Author

Rekowska Natalia, Arbeiter Daniela, Seitz Hermann, Mau Robert, Riess Alexander, Eickner Thomas, Grabow Niels, and Teske Michael

Subjects

poly(ethylene glycol) diacrylate (pegda), mechanical properties, photopolymerizable biomaterials, Medicine

Abstract

Hydrogels are 3D polymeric networks, which exhibit properties such as softness, viscoelasticity and their ability to absorb large amounts of water. These characteristics make them exceptionally suitable in biomedicine as e.g. tissue scaffolds, drug delivery systems, wound dressings or contact lenses. One of these hydrogels is the biocompatible, hydrophilic and photopolymerizable poly(ethylene glycol) diacrylate (PEGDA). It is used in different biomedical applications due to its tunable mechanical characteristics. In our study, the mechanical properties of different PEGDA hydrogel compositions with variyng molecular masses and contents of water/methanol, were investigated. Different compositions containing 20 m%, 30 m% or 40 m% of PEGDA4K(4,000 g/mol), PEGDA10K(10,000 g/mol) or PEGDA20K(20,000 g/mol) in ultrapure water/methanol (1:2) were produced. Dumbbell-shaped samples were prepared in molds via photopolymerization in a UV chamber. Lithium phenyl-2,4,6-trimethylbenzoylphosphinate (LAP) was used as photoinitiator (0.5% w/w). The mechanical testing was performed using a uniaxial testing system. The obtained results showed averagely 78% higher tensile strength (σmax) values for 30 m% and 40 m% samples in comparison with 20 m% samples for all of the tested polymers. PEGDA20K30 m% samples showed the highest σmax among all of the samples with 12.8 MPa. All of the PEGDA20K samples exhibited the highest elongation at break (εB) values (up to 958%), whereas the lowest values were found for PEGDA4K(up to 105%). The obtained stress-strain curves for most of the samples were typical for deformable, amorphous polymers with a deformation upon reaching a critical stress point. The PEGDA materials showed variable mechanical characteristics according to changing molecular mass or polymer concentration. These promising results showed that it should be possible to compose scaffolds with desired mechanical stability according to the needed application.

Published

2022

2. Dry vs. wet testing: quasi-static tensile experiment setup for polymer based biomaterials

Author

Arbeiter Daniela, Oschatz Stefan, Lebahn Kerstin, Illner Sabine, and Grabow Niels

Subjects

mechanical properties, thermoplastic polyurethanes, dry and wet testing setup., Medicine

Abstract

Polymer materials can be manufactured with high reproducibility and do offer the potential for chemical modification. This enables matrix property modification and fine-tuning of several material characteristics, such as tissue-implant interaction, inflammatory potential or susceptibility to biofilm formation. Whereas manufacturing protocols are crucial for the resulting material properties, also the evaluation in terms of performance and safety has to be considered. Regarding this, both, temperature and composition of test medium may affect the physicochemical properties of implant materials. The present study addresses the influence of test medium compared to dry test conditions, each at two different temperatures, on the mechanical properties of elastomeric film and nonwoven materials.

Published

2021

3. Thermomechanical properties of PEGDA and its co-polymers

Author

Rekowska Natalia, Arbeiter Daniela, Konasch Jan, Riess Alexander, Mau Robert, Eickner Thomas, Seitz Hermann, Grabow Niels, and Teske Michael

Subjects

drug delivery system, poly(ethylene glycol) diacrylate (pegda), 1,3-butanediol diacrylate, pentaerythritol triacrylate, photopolymerisation, glass transition temperature, mechanical properties, Medicine

Abstract

Current research activities focus on personalized, comfortable and safe products for systemic or local drug application in patients. Poly(ethylene glycol) diacrylate is in particular interest as a drug delivery material, as it shows appropriate biological properties such as hydrophilicity and low toxicity. Additionally, as an easily photopolymerizable compound it can be also utilized for the production of scaffolds with the use of different techniques such as stereolithography. Even though it is often used as a biomaterial or as a copolymer in many photopolymer systems for drug delivery, thermomechanical analysis and basic understanding are rare.

Published

2018

4. Method for the improvement of mechanical properties of biodegradable polymeric scaffolds

Author

Schümann Kerstin, Arbeiter Daniela, Grabow Niels, and Schmitz Klaus-Peter

Subjects

biodegradable stents, polymer, thermomechanical treatment, mechanical properties, Medicine

Abstract

At present, a main focus in the field of stent technologies is on the development of biodegradable polymeric stents. Due to inferior material characteristics of polymers compared to permanent metals stents require thicker stents struts to accomplish adequate mechanical properties. Therefore, a thermo-mechanical treatment of polymeric stents was tested, which showed a positive effect on mechanical stent characteristics.

Published

2019

5. Influence of Drug Incorporation on the Physico-Chemical Properties of Poly(l-Lactide) Implant Coating Matrices—A Systematic Study

Author

Arbeiter, Daniela, Reske, Thomas, Teske, Michael, Bajer, Dalibor, Senz, Volkmar, Schmitz, Klaus-Peter, Grabow, Niels, and Oschatz, Stefan

Subjects

thermal properties, dexamethasone, poly-l-lactide, mechanical properties, Article, drug-eluting stent (DES), lcsh:QD241-441, paclitaxel, sirolimus, lcsh:Organic chemistry, l<%2Fspan>-lactide%22">poly-l-lactide, surface morphology, drug delivery coatings, cyclosporine A

Abstract

Local drug delivery has become indispensable in biomedical engineering with stents being ideal carrier platforms. While local drug release is superior to systemic administration in many fields, the incorporation of drugs into polymers may influence the physico-chemical properties of said matrix. This is of particular relevance as minimally invasive implantation is frequently accompanied by mechanical stresses on the implant and coating. Thus, drug incorporation into polymers may result in a susceptibility to potentially life-threatening implant failure. We investigated spray-coated poly-l-lactide (PLLA)/drug blends using thermal measurements (DSC) and tensile tests to determine the influence of selected drugs, namely sirolimus, paclitaxel, dexamethasone, and cyclosporine A, on the physico-chemical properties of the polymer. For all drugs and PLLA/drug ratios, an increase in tensile strength was observed. As for sirolimus and dexamethasone, PLLA/drug mixed phase systems were identified by shifted drug melting peaks at 200 &deg, C and 240 &deg, C, respectively, whereas paclitaxel and dexamethasone led to cold crystallization. Cyclosporine A did not affect matrix thermal properties. Altogether, our data provide a contribution towards an understanding of the complex interaction between PLLA and different drugs. Our results hold implications regarding the necessity of target-oriented thermal treatment to ensure the shelf life and performance of stent coatings.

Published

2021

6. Mechanical behavior of in vivo degraded second generation resorbable magnesium scaffolds (RMS).

Author

Brandt-Wunderlich, Christoph, Ruppelt, Philipp, Zumstein, Philine, Schmidt, Wolfram, Arbeiter, Daniela, Schmitz, Klaus-Peter, and Grabow, Niels

Subjects

MAGNESIUM alloys, MAGNESIUM, CORONARY disease, CORONARY arteries, FRACTURE mechanics

Abstract

Abstract Resorbable magnesium scaffolds are used for the treatment of atherosclerotic coronary vascular disease and furthermore, for vascular restoration therapy. Recently, the first-in-man clinical studies with Magmaris showed promising results regarding the target lesion failure as well as vasomotion properties after 12 and 24 month. The consistency of in vivo degraded magnesium alloys in a cardiovascular environment is qualitatively described in literature, but only little has been disclosed about the actual change in mechanical properties and the behavior of the magnesium alloy degradation products. In the present study, uncoated magnesium scaffolds 3.0 × 20 mm were implanted in coronary arteries of two healthy Goetinnger mini-swine. The scaffolds were explanted to evaluate the mechanical properties of the degraded magnesium scaffolds after 180 days in vivo. Ex vivo sample preparation and test conditions were adapted to a customized compression test setup which was developed to investigate the micro-scale scaffold fragments (width 225 ± 75 µm, thickness 150 µm). As reference bare undegraded magnesium scaffold fragments were tested. Mechanical parameters relating to force as a function of displacement were determined for both sample groups. The undegraded samples showed no fracturing at the maximum applied force of 8 N, whereas the in vivo degraded test samples showed forces of 0.411 ± 0.197 N at the first fracturing and a maximum force of 0.956 ± 0.525 N. The deformation work, calculated as area beneath the force-displacement curve, of the in vivo degraded test samples was reduced by approximately 87–88% compared to the undegraded samples (5.20 mN mm and 40.79 mN mm, both at 7.5% deformation). The indication for a complete loss of structural integrity through a reduction of mechanical properties after a certain degradation time increases the chance to restore vascular function and physiological vasomotion in the stented vessel compartment. [ABSTRACT FROM AUTHOR]

Published

2019