Your search keyword '"Andreas H. Teuschl"' showing total 4 results

1. Repopulation of an auricular cartilage scaffold, AuriScaff, perforated with an enzyme combination

Author

Christoph Schneider, G.V.M. van Osch, Xavier Monforte, Susanne Wolbank, Bernhard Rieder, Severin Mühleder, Heinz Redl, Andreas H. Teuschl, B. Schädl, Sylvia Nürnberger, Claudia Keibl, Wolfgang Holnthoner, Claudia Gahleitner, and Otorhinolaryngology and Head and Neck Surgery

Subjects

Male, Scaffold, Compressive Strength, 0206 medical engineering, Biomedical Engineering, 02 engineering and technology, Matrix (biology), Biochemistry, Biomaterials, Prosthesis Implantation, Chondrocytes, Tissue engineering, medicine, Animals, Humans, Molecular Biology, Collagen Type II, Cellular Senescence, Glycosaminoglycans, Decellularization, Tissue Scaffolds, Chemistry, Hyaline cartilage, Regeneration (biology), Cartilage, Cell Differentiation, General Medicine, DNA, Middle Aged, 021001 nanoscience & nanotechnology, Chondrogenesis, 020601 biomedical engineering, medicine.anatomical_structure, Cattle, Female, Ear Cartilage, 0210 nano-technology, Biotechnology, Biomedical engineering

Abstract

Biomaterials currently in use for articular cartilage regeneration do not mimic the composition or architecture of hyaline cartilage, leading to the formation of repair tissue with inferior characteristics. In this study we demonstrate the use of “AuriScaff”, an enzymatically perforated bovine auricular cartilage scaffold, as a novel biomaterial for repopulation with regenerative cells and for the formation of high-quality hyaline cartilage. AuriScaff features a traversing channel network, generated by selective depletion of elastic fibers, enabling uniform repopulation with therapeutic cells. The complex collagen type II matrix is left intact, as observed by immunohistochemistry, SEM and TEM. The compressive modulus is diminished, but three times higher than in the clinically used collagen type I/III scaffold that served as control. Seeding tests with human articular chondrocytes (hAC) alone and in co-culture with human adipose-derived stromal/stem cells (ASC) confirmed that the network enabled cell migration throughout the scaffold. It also guides collagen alignment along the channels and, due to the generally traverse channel alignment, newly deposited cartilage matrix corresponds with the orientation of collagen within articular cartilage. In an osteochondral plug model, AuriScaff filled the complete defect with compact collagen type II matrix and enabled chondrogenic differentiation inside the channels. Using adult articular chondrocytes from bovine origin (bAC), filling of even deep defects with high-quality hyaline-like cartilage was achieved after 6 weeks in vivo. With its composition and spatial organization, AuriScaff provides an optimal chondrogenic environment for therapeutic cells to treat cartilage defects and is expected to improve long-term outcome by channel-guided repopulation followed by matrix deposition and alignment. Statement of Significance After two decades of tissue engineering for cartilage regeneration, there is still no optimal strategy available to overcome problems such as inconsistent clinical outcome, early and late graft failures. Especially large defects are dependent on biomaterials and their scaffolding, guiding and protective function. Considering the currently used biomaterials, structure and mechanical properties appear to be insufficient to fulfill this task. The novel scaffold developed within this study is the first approach enabling the use of dense cartilage matrix, repopulate it via channels and provide the cells with a compact collagen type II environment. Due to its density, it also provides better mechanical properties than materials currently used in clinics. We therefore think, that the auricular cartilage scaffold (AuriScaff) has a high potential to improve future cartilage regeneration approaches.

Published

2018

2. Decellularized human placenta chorion matrix as a favorable source of small-diameter vascular grafts

Author

Heinz Redl, Andreas H. Teuschl, Petra Aigner, Xavier Monforte, Karl H. Schneider, Wolfgang Holnthoner, Dominik Rünzler, and Sylvia Nürnberger

Subjects

Materials science, Biocompatibility, 0206 medical engineering, Biomedical Engineering, 02 engineering and technology, Matrix (biology), Biochemistry, Umbilical vein, Biomaterials, Tissue engineering, Blood vessel prosthesis, Placenta, Human Umbilical Vein Endothelial Cells, medicine, Humans, Molecular Biology, Vascular tissue, Decellularization, Tissue Scaffolds, Chorion, General Medicine, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Blood Vessel Prosthesis, Extracellular Matrix, medicine.anatomical_structure, Female, 0210 nano-technology, Biotechnology, Biomedical engineering

Abstract

Biomaterials based on decellularized tissues are increasingly attracting attention as functional alternatives to other natural or synthetic materials. However, a source of non-cadaver human allograft material would be favorable. Here we establish a decellularization method of vascular tissue from cryopreserved human placenta chorionic plate starting with an initial freeze–thaw step followed by a series of chemical treatments applied with a custom-made perfusion system. This novel pulsatile perfusion set-up enabled us to successfully decellularize the vascular tissue with lower concentrations of chemicals and shorter exposure times compared to a non-perfusion process. The decellularization procedure described here lead to the preservation of the native extracellular matrix architecture and the removal of cells. Quantitative analysis revealed no significant changes in collagen content and a retained glycosaminoglycan content of approximately 29%. In strain-to-failure tests, the decellularized grafts showed similar mechanical behavior compared to native controls. In addition, the mechanical values for ultimate tensile strength and stiffness were in an acceptable range for in vivo applications. Furthermore, biocompatibility of the decellularized tissue and its recellularizationability to serve as an adequate substratum for upcoming recellularization strategies using primary human umbilical vein endothelial cells (HUVECs) was demonstrated. HUVECs cultured on the decellularized placenta vessel matrix performed endothelialization and maintained phenotypical characteristics and cell specific expression patterns. Overall, the decellularized human placenta vessels can be a versatile tool for experimental studies on vascularization and as potent graft material for future in vivo applications. Statement of significance In the US alone more than 1 million vascular grafts are needed in clinical practice every year. Despite severe disadvantages, such as donor site morbidity, autologous grafting from the patient’s own arteries or veins is regarded as the gold standard for vascular tissue repair. Besides, strategies based on synthetic or natural materials have shown limited success. Tissue engineering approaches based on decellularized tissues are regarded as a promising alternative to clinically used treatments to overcome the observed limitations. However, a source for supply of non-cadaver human allograft material would be favorable. Here, we established a decellularization method of vascular tissue from the human placenta chorionic plate, a suitable human tissue source of consistent quality. The decellularized human placenta vessels can be a potent graft material for future in vivo applications and furthermore might be a versatile tool for experimental studies on vascularization.

Published

2016

3. Enhanced cell adhesion on silk fibroin via lectin surface modification

Author

Andreas H. Teuschl, Dominik Rünzler, Lukas Neutsch, Xavier Monforte, Franz Gabor, Heinz Redl, and Martijn van Griensven

Subjects

Stromal cell, Materials science, Lectins/chemistry, Surface Properties, Cells, Biomedical Engineering, Silk, Fibroin, Biochemistry, Biomaterials, Tissue engineering, Lectins, Cell Adhesion, Humans, Cell adhesion, Molecular Biology, Cells, Cultured, Cultured, Cell Differentiation, General Medicine, Adhesion, In vitro, Wheat germ agglutinin, Cell biology, Surface modification, Fibroins, Biotechnology, Biomedical engineering

Abstract

Various tissue engineering (TE) approaches are based on silk fibroin (SF) as scaffold material because of its superior mechanical and biological properties compared to other materials. The translation of one-step TE approaches to clinical application has generally failed so far due to the requirement of a prolonged cell seeding step before implantation. Here, we propose that the plant lectin WGA (wheat germ agglutinin), covalently bound to SF, will mediate cell adhesion in a time frame acceptable to be part of a one-step surgical intervention. After the establishment of a modification protocol utilizing carbodiimide chemistry, we examined the attachment of cells, with a special focus on adipose-derived stromal cells (ASC), on WGA-SF compared to pure native SF. After a limited time frame of 20min the attachment of ASCs to WGA-SF showed an increase of about 17-fold, as compared to pure native SF. The lectin-mediated cell adhesion further showed an enhanced resistance to trypsin (as a protease model) and to applied fluid shear stress (mechanical stability). Moreover, we could demonstrate that the adhesion of ASCs on the WGA-SF does not negatively influence proliferation or differentiation potential into the osteogenic lineage. To test for in vitro immune response, the proliferation of peripheral blood mononuclear cells in contact with the WGA-SF was determined, showing no alterations compared to plain SF. All these findings suggest that the WGA modification of SF offers important benefits for translation of SF scaffolds into clinical applications.

Published

2014

4. A novel bioreactor for the generation of highly aligned 3D skeletal muscle-like constructs through orientation of fibrin via application of static strain

Author

Andreas H. Teuschl, Babette Maleiner, Josef Kollmitzer, Heinz Redl, Johanna Pruller, Susanne Wolbank, Philipp Heher, Dominik Rünzler, Xavier Monforte, and Christiane Fuchs

Subjects

Materials science, Biomedical Engineering, Muscle Proteins, MyoD, Biochemistry, Cell Line, Biomaterials, Mice, Bioreactors, Tissue engineering, medicine, Myocyte, Animals, Mechanotransduction, Muscle, Skeletal, Molecular Biology, Myogenin, Fibrin, Myogenesis, Skeletal muscle, Hydrogels, General Medicine, Antigens, Differentiation, Cell biology, Extracellular Matrix, medicine.anatomical_structure, Fibrin scaffold, Stress, Mechanical, Biotechnology, Biomedical engineering

Abstract

The generation of functional biomimetic skeletal muscle constructs is still one of the fundamental challenges in skeletal muscle tissue engineering. With the notion that structure strongly dictates functional capabilities, a myriad of cell types, scaffold materials and stimulation strategies have been combined. To further optimize muscle engineered constructs, we have developed a novel bioreactor system (MagneTissue) for rapid engineering of skeletal muscle-like constructs with the aim to resemble native muscle in terms of structure, gene expression profile and maturity. Myoblasts embedded in fibrin, a natural hydrogel that serves as extracellular matrix, are subjected to mechanical stimulation via magnetic force transmission. We identify static mechanical strain as a trigger for cellular alignment concomitant with the orientation of the scaffold into highly organized fibrin fibrils. This ultimately yields myotubes with a more mature phenotype in terms of sarcomeric patterning, diameter and length. On the molecular level, a faster progression of the myogenic gene expression program is evident as myogenic determination markers MyoD and Myogenin as well as the Ca2+ dependent contractile structural marker TnnT1 are significantly upregulated when strain is applied. The major advantage of the MagneTissue bioreactor system is that the generated tension is not exclusively relying on the strain generated by the cells themselves in response to scaffold anchoring but its ability to subject the constructs to individually adjustable strain protocols. In future work, this will allow applying mechanical stimulation with different strain regimes in the maturation process of tissue engineered constructs and elucidating the role of mechanotransduction in myogenesis. Statement of Significance Mechanical stimulation of tissue engineered skeletal muscle constructs is a promising approach to increase tissue functionality. We have developed a novel bioreactor-based 3D culture system, giving the user the possibility to apply different strain regimes like static, cyclic or ramp strain to myogenic precursor cells embedded in a fibrin scaffold. Application of static mechanical strain leads to alignment of fibrin fibrils along the axis of strain and concomitantly to highly aligned myotube formation. Additionally, the pattern of myogenic gene expression follows the temporal progression observed in vivo with a more thorough induction of the myogenic program when static strain is applied. Ultimately, the strain protocol used in this study results in a higher degree of muscle maturity demonstrated by enhanced sarcomeric patterning and increased myotube diameter and length. The introduced bioreactor system enables new possibilities in muscle tissue engineering as longer cultivation periods and different strain applications will yield tissue engineered muscle-like constructs with improved characteristics in regard to functionality and biomimicry.

Published

2015