Analyse initialer Adhäsionsmechanismen von humanen Osteoblasten in Abhängigkeit physiko-chemischer Oberflächencharakteristika definiert mikrostrukturierter Titanoberflächen

Die Qualität von Zell-Biomaterial-Interaktionen wird von den physiko-chemischen Eigenschaften des Biomaterials bestimmt und ist entscheidend für den klinischen Erfolg von Implantaten. Die Analyse der Zellphysiologie von humanen Osteoblasten auf definiert mikrostrukturierten Titanoberflächen zeigt einen starken Zusammenhang zwischen topographischen Oberflächeneigenschaften und diversen Zellfunktionen. Das Auffinden solcher Zusammenhänge leistet einen wichtigen Beitrag zur Aufklärung von Zell-Biomaterial-Interaktionen und somit zur zukünftigen Optimierung von Implantatoberflächen

Development of a biodegradable microstent for minimally invasive treatment of Fallopian tube occlusions

Obstructions of the Fallopian tube represent one of the most common reasons for an unfulfilled desire to have children. Microstent technology opens up new therapeutic possibilities to restore the natural lumen of the Fallopian tube within a single treatment. Within the current work we developed a self-expandable biodegradable microstent for gynecological applications. Based on a novel microstent design, prototypes were manufactured from poly-L-lactide tubing by means of fs-laser cutting. Microstent prototypes were characterized morphologically by means of scanning electron microscopy and biaxial laser scanning. As manufactured, a microstents outside diameter of about 2.3 mm and a strut thickness/width of about 114 µm/103 µm was measured. Mechanical characterization of microstents included bending as well as crimping and release behavior. After crimping to a minimum diameter of 0.8 mm and consecutive release, a microstent recovery to a diameter of 1.8 mm was found. Therefore, proof-of-concept for the self-expandable microstent could be successfully provided. © 2020 by Walter de Gruyter Berlin/Boston 2020

Safety evaluation of resveratrol as an active compound for drug-eluting cardiovascular implants

Resveratrol is a member of stilbenoids with promising anti-atherosclerotic properties. This hallmark makes it an extremely interesting candidate for local drug delivery to damaged tissue adjacent to the implant in order to reduce implant-related complications. For the regulatory approval drug-eluting medical devices have to be thoroughly tested for safety, efficacy and interactions with the surrounding tissue, including tests for sensitization among others. Studies for sensitization help to estimate the risk for an allergic reaction upon prolonged exposure to a chemical compound. Due to increased social and regulatory demand for replacement of animal experiments by in vitro approaches a number of reliable predictive non-animal tests have been developed. Here, we assessed the skin sensitization potential of resveratrol by the direct peptide reactivity assay (DPRA), one of the first non-animal tests adopted by the OECD

Cell adhesion and viability of human endothelial cells on electrospun polymer scaffolds

The usage of electrospun polymer scaffolds is a promising approach for artificial heart valve design. This study aims at the evaluation of biological performance of nanofibrous polymer scaffolds poly(L-lactide) PLLA L210, PLLA L214 and polyamide-6 fabricated by electrospinning via analyzing viability, adhesion and morphology of human umbilical vein endothelial cells (EA.hy926). Nanofibrous surface topography was shown to influence cell phenotype and cell viability according to the observation of diminished cell spreading accompanied with reduced cell viability on nonwovens. Among those, highest biocompatibility was assessed for PLLA L214, although being generally low when compared to the planar control surface. Electrospinning was demonstrated as an innovative technique for the fabrication of advanced biomaterials aiming at guided cellular behavior as well as the design of novel implant platforms. A better understanding of cell–biomaterial interactions is desired to further improve implant development

Application of 3R principles in small animal GLP testing of biomaterials

On the protection of animals used for scientific purposes, the EU Parliament adopted Directive 2010/63/EU. The essential factor is the 3R principle: Replacement, Reduction and Refinement. In 2013, the third amendment to the German Animal Welfare Act was revised and adapted to the European Directive. The majority of animals in science are used in basic research, as well as in translational and applied research. In medical research, animal experimentation is conducted to clarify previously unknown life processes and basic biological relationships, in order to improve diagnostics and treatment of human diseases. Before an animal experiment can be performed, it must be reported to and approved by the responsible authorities. The planned research project must be justified scientifically, and it must be demonstrated that the personnel and spatial/ technical prerequisites are in place to successfully complete the project. If all conditions are met, the approval can be granted, but may be subject to conditions. The guiding principle of essentiality also affects the procedure of the experiments: The number of animals used and the pain, suffering and damage caused to these animals must be limited to what is absolutely necessary. In this context, the 3R principle has to be applied. To obtain reliable results, it is essential that the laboratory animals are in normal physiological conditions and free of pain and fear. Scientific interest and animal welfare are therefore not in opposition, but rather mutually dependent. In our GLP (Good Laboratory Practice) laboratory we test new drug release systems for different biomedical applications in rabbits after careful selection of the animal model. Stress during animal experiments must be avoided as far as possible. Providing pain-killers and ensuring the best possible husbandry and care conditions are crucial for the animal’s wellbeing and absence of pain and anxiety. In the present work we report our different experience in a GLPcertified biomaterial test laboratory

Actinomycin D for fibrosis management in ophthalmic implant surgery

Implants that feature a drug delivery system loaded with antifibrotic active drugs provide a promising approach to address postoperative complications caused by fibrosis. This study is intended to clarify whether Actinomycin D has an impact specifically on components of the extracellular matrix (ECM) and its formation in human primary fibroblasts of the Tenon capsule (hTF). Furthermore, the suitability of this agent in poly(N-vinylpyrrolidone)- poly(methylmethacrylate)(PVP-co-PMMA) as a drug delivery model is evaluated in drug incorporation and release studies. RT-qPCR revealed a significant downregulation of the fibrotic marker genes ACTA2, COL1A1 and FN1 in cells stimulated with TGF- β1 and additionally treated with Actinomycin D. However, these findings could only be confirmed on α- SMA protein level. collagen I and Fibronectin synthesis stayed unaffected. The diffusion based incorporation of Actinomycin D into the polymer model proved to be very effective. The release of the agent was retarded with a slightly prolonged kinetic. These findings make Actinomycin D a promising antifibrotic agent in ophthalmic implant surgery

Promising biocompatible hydrogels of crosslinked polyelectrolytes for biomedical applications

For the development of intelligent implant systems hydrogels (HG) from crosslinked ionic liquids feature a high potential to be utilised as a drug depot. Biocompatibility of the HGs is one key prerequisite for biomedical applications. HGs were polymerised from a variety of different ionic monomers based on methacrylate, methacrylamide, styrene or vinyl imidazolium derivatives in aqueous solution. N,N'-methylenebisacrylamide was used as crosslinker. CellQuanti-Blue™ Cell Viability Assay Kit was implemented to proof viability of L929 mouse fibroblasts. The predominant part of the HG eluates generated only a marginal reduction of less than 15% cell viability at 100% eluate concentration. This underlines the excellent suitability of these HGs for biomedical applications and revealed some promising candidates for the development of drug depots for implants

Mutual influence of incorporated drugs in a dual drug delivery coating for cardiovascular applications

For a long-term efficient drug-eluting stent for vascular applications, the development of drug-loaded coating, combining the effective inhibition of smooth muscle cell proliferation while promoting the re-endothelialization, is a promising concept. However the mostly required simultaneous incorporation of drugs can influence decisively the stability, efficacy and release of the respective drug. Therefore, the mutual influence of a dual local drug delivery coatings based on poly(L-lactide-co-ε-caprolactone) (PLLA-co-CL) containing vascular endothelial growth factor (VEGF165) coupled to the surface and an embedded drug, such as fluorescein diacetate (FDAc) instead of Paclitaxel (PTX) on the in vitro drug release was investigated. Surprisingly, for the investigated coating the immobilized VEGF loading was enhanced and the release profile was accelerated by FDAc incorporation. Even a manifold increase for the in vitro released amounts of VEGF was detected. In contrast, the immobilization of VEGF seems to have a negligible influence on the in vitro FDAc release profiles

Accelerated Endothelialization of Nanofibrous Scaffolds for Biomimetic Cardiovascular Implants

Nanofiber nonwovens are highly promising to serve as biomimetic scaffolds for pioneering cardiac implants such as drug-eluting stent systems or heart valve prosthetics. For successful implant integration, rapid and homogeneous endothelialization is of utmost importance as it forms a hemocompatible surface. This study aims at physicochemical and biological evaluation of various electrospun polymer scaffolds, made of FDA approved medical-grade plastics. Human endothelial cells (EA.hy926) were examined for cell attachment, morphology, viability, as well as actin and PECAM 1 expression. The appraisal of the untreated poly-L-lactide (PLLA L210), poly-ε-caprolactone (PCL) and polyamide-6 (PA-6) nonwovens shows that the hydrophilicity (water contact angle > 80°) and surface free energy (<60 mN/m) is mostly insufficient for rapid cell colonization. Therefore, modification of the surface tension of nonpolar polymer scaffolds by plasma energy was initiated, leading to more than 60% increased wettability and improved colonization. Additionally, NH3-plasma surface functionalization resulted in a more physiological localization of cell–cell contact markers, promoting endothelialization on all polymeric surfaces, while fiber diameter remained unaltered. Our data indicates that hydrophobic nonwovens are often insufficient to mimic the native extracellular matrix but also that they can be easily adapted by targeted post-processing steps such as plasma treatment. The results achieved increase the understanding of cell–implant interactions of nanostructured polymer-based biomaterial surfaces in blood contact while also advocating for plasma technology to increase the surface energy of nonpolar biostable, as well as biodegradable polymer scaffolds. Thus, we highlight the potential of plasma-activated electrospun polymer scaffolds for the development of advanced cardiac implants