Your search keyword '"Breiter, Roman"' showing total 19 results

1. Towards rare earth element recovery from wastewaters: biosorption using phototrophic organisms

Author

Heilmann, Marcus, Breiter, Roman, and Becker, Anna Maria

Published

2021

2. Cartilage regeneration using decellularized cartilage matrix: Long-term comparison of subcutaneous and intranasal placement in a rabbit model

Author

von Bomhard, Achim, Elsaesser, Alexander, Riepl, Ricarda, Pippich, Katharina, Faust, Joseph, Schwarz, Silke, Koerber, Ludwig, Breiter, Roman, and Rotter, Nicole

Published

2019

3. Laser surface modification of decellularized extracellular cartilage matrix for cartilage tissue engineering

Author

Goldberg-Bockhorn, Eva, Schwarz, Silke, Subedi, Rachana, Elsässer, Alexander, Riepl, Ricarda, Walther, Paul, Körber, Ludwig, Breiter, Roman, Stock, Karl, and Rotter, Nicole

Published

2017

4. A compositional analysis of native and decellularized porcine nasal septum cartilage.

Author

Tluczynski, Katharina and Breiter, Roman

Subjects

*NASAL septum, *CARTILAGE, *INDIVIDUAL differences, *COLLAGEN, *REGRESSION analysis

Abstract

Objectives: Decellularization of porcine septum cartilage is necessary for its application as xenogenic replacement material. The aim of this study was to investigate spatial differences of structure and composition in the whole native and decellularized porcine nasal septum. Subsequently, the results shall be compared with studies of human nasal septum. Methods: Ten porcine nasal septa were divided into six regions from caudal to cephalic and four regions from dorsal to ventral to create a grid of 24 approximately equal segments. All segments of five septal cartilages were decellularized separately by a wet chemical multistep procedure. The segments were analyzed to determine quantitative amounts of total collagen, chondrocytes, and sulfated glycosaminoglycans (sGAG). Results: The distribution of cell number showed no significant differences between the individual regions. For the distribution of collagen and sGAG, no significant differences could be identified from caudal to cephalic, both in native and decellularized tissue. From dorsal to ventral, native and decellularized nasal septum showed significant differences between individual regions. In native septum, linear regression analysis indicated a decreasing collagen and an increasing sGAG content from dorsal to ventral. After decellularization, an increasing collagen and a decreasing sGAG content was detected. Conclusion: The results of this study showed slightly but significant differences in the distribution of collagen and sGAG from dorsal to ventral. From caudal to cephalic, no differences could be observed. Compared to human, nasal septum differences in cell, collagen, and sGAG content were detected. Despite this, human and porcine nasal septum showed similar distributions and a consistently inverse linearity of collagen and sGAG content. Nevertheless, the midcaudal and midcephalic regions showed the highest porosity and a high stability and thus offer the best conditions for the revitalization of porcine tissue by human cells. [ABSTRACT FROM AUTHOR]

Published

2022

5. Modelling the Competitive Sorption Process of Multiple Solutes During their Transport in Porous Media

Author

Salaices Avila, Manuel Alejandro and Breiter, Roman

Published

2009

6. Estimating the PDMS-Coated, SPME-Fibre/Water- and Fibre/Gas-Partition Coefficients of Chlorinated Ethenes by Headspace-SPME

Author

Avila, Manuel Alejandro Salaices and Breiter, Roman

Published

2007

7. Modulation of the inflammatory response to decellularized collagen matrix for cartilage regeneration.

Author

Gvaramia, David, Kern, Johann, Jakob, Yvonne, Tritschler, Hanna, Brenner, Rolf E., Breiter, Roman, Kzhyshkowska, Julia, and Rotter, Nicole

Abstract

Decellularized extracellular matrices (DECM) are among the most common types of materials used in tissue engineering due to their cell instructive properties, biodegradability, and accessibility. Particularly in cartilage, a natural collagen type II matrix can be a promising means to provide the necessary cues and support for chondrogenic stem and progenitor cells (CSPCs). However, efficient remodeling of the transplanted DECM is largely dependent on the host immune response, with macrophages playing the central role in orchestrating both inflammatory and regenerative processes. Here we assessed the reaction of human primary macrophages to the cartilage DECM. Our findings show that the xenogeneic collagen matrix can elicit a mixed response in human macrophages, whereby the inflammatory response (M1) and the activation of remodeling (M2) type of macrophages are both present. Additionally, we demonstrate the inhibitory effect of macrophage response on the migratory capacity of human CSPCs. We further show that the inflammatory reaction of macrophages to the cartilage DECM, as well as the resulting inhibitory effects on CSPC migration, can be attenuated by interleukin‐4 (IL‐4). Finally, we demonstrate that IL‐4 can effectively bind the matrix, thereby modulating macrophage response by reducing the inflammatory reaction and inducing the M2 phenotype. [ABSTRACT FROM AUTHOR]

Published

2022

8. Screening for unicellular algae as possible bioassay organisms for monitoring marine water samples

Author

Millán de Kuhn, Rosmary, Streb, Christine, Breiter, Roman, Richter, Peter, Neeße, Thomas, and Häder, Donat-Peter

Published

2006

9. In situ regeneration of nasal septal defects using acellular cartilage enhanced with platelet-derived growth factor.

Author

Huber, Lena, Gvaramia, David, Kern, Johann, Jakob, Yvonne, Zoellner, Frank G., Hirsch, Daniela, Breiter, Roman, Brenner, Rolf E., and Rotter, Nicole

Subjects

PLATELET-derived growth factor, CARTILAGE regeneration, CARTILAGE, AUTOGRAFTS, NASAL septum, MAGNETIC resonance imaging, AUTOTRANSPLANTATION, BONE regeneration

Abstract

Nasal septum defects can currently only be reconstructed using autologous cartilage grafts. In this study, we examine the reconstruction of septal cartilage defects in a rabbit model using porcine decellularized nasal septal cartilage (DNSC) functionalized with recombinant platelet-derived growth factor-BB (PDFG-BB). The supportive function of the transplanted DNSC was estimated by the degree of septum deviation and shrinkage using magnetic resonance imaging (MRI). The biocompatibility of the transplanted scaffolds was evaluated by histology according to international standards. A study group with an autologous septal transplant was used as a reference. In situ regeneration of cartilage defects was assessed by histological evaluation 4 and 16 weeks following DNSC transplantation. A study group with non-functionalized DNSC was introduced for estimation of the effects of PDFG-BB functionalization. DNSC scaffolds provided sufficient structural support to the nasal septum, with no significant shrinkage or septal deviations as evaluated by the MRI. Biocompatibility analysis after 4 weeks revealed an increased inflammatory reaction of the surrounding tissue in response to DNSC as compared to the autologous transplants. The inflammatory reaction was, however, significantly attenuated after 16 weeks in the PDGF-BB group whereas only a slight improvement of the biocompatibility score was observed in the untreated group. In situ regeneration of septal cartilage, as evidenced by the degradation of the DNSC matrix and production of neocartilage, was observed in both experimental groups after 16 weeks but was more pronounced in the PDFG-BB group. Overall, DNSC provided structural support to the nasal septum and stimulated in situ regeneration of the cartilage tissue. Furthermore, PDFG-BB augmented the regenerative potential of DNSC and enhanced the healing process, as demonstrated by reduced inflammation after 16 weeks. [ABSTRACT FROM AUTHOR]

Published

2022

10. Laser surface modification of decellularized extracellular cartilage matrix for cartilage tissue engineering.

Author

Goldberg-Bockhorn, Eva, Schwarz, Silke, Subedi, Rachana, Elsässer, Alexander, Riepl, Ricarda, Walther, Paul, Körber, Ludwig, Breiter, Roman, Stock, Karl, and Rotter, Nicole

Subjects

CARTILAGE, TISSUE engineering, CELL motility, TISSUE scaffolds, MEDICAL lasers, IMMUNOHISTOCHEMISTRY, PROTEIN metabolism, ANIMALS, CARTILAGE cells, CELL culture, CELL death, COLLAGEN, CULTURE media (Biology), EXTRACELLULAR space, LASERS, SWINE, SURFACE properties, METABOLISM, PHYSIOLOGICAL effects of radiation

Abstract

The implantation of autologous cartilage as the gold standard operative procedure for the reconstruction of cartilage defects in the head and neck region unfortunately implicates a variety of negative effects at the donor site. Tissue-engineered cartilage appears to be a promising alternative. However, due to the complex requirements, the optimal material is yet to be determined. As demonstrated previously, decellularized porcine cartilage (DECM) might be a good option to engineer vital cartilage. As the dense structure of DECM limits cellular infiltration, we investigated surface modifications of the scaffolds by carbon dioxide (CO2) and Er:YAG laser application to facilitate the migration of chondrocytes inside the scaffold. After laser treatment, the scaffolds were seeded with human nasal septal chondrocytes and analyzed with respect to cell migration and formation of new extracellular matrix proteins. Histology, immunohistochemistry, SEM, and TEM examination revealed an increase of the scaffolds' surface area with proliferation of cell numbers on the scaffolds for both laser types. The lack of cytotoxic effects was demonstrated by standard cytotoxicity testing. However, a thermal denaturation area seemed to hinder the migration of the chondrocytes inside the scaffolds, even more so after CO2 laser treatment. Therefore, the Er:YAG laser seemed to be better suitable. Further modifications of the laser adjustments or the use of alternative laser systems might be advantageous for surface enlargement and to facilitate migration of chondrocytes into the scaffold in one step. [ABSTRACT FROM AUTHOR]

Published

2018

11. Reconstruction of nasal septal defects in rabbits using PDGF-BB-loaded decellularized cartilage scaffolds.

Author

Huber, Lena, Kern, Johann, Gvaramia, David, Jakob, Yvonne, Körber, Ludwig, Breiter, Roman, and Rotter, Nicole

Published

2022

12. Acoustic Properties of Collagenous Matrices of Xenogenic Origin for Tympanic Membrane Reconstruction.

Author

Schwarz, David, Pazen, David, Gosz, Kamill, Schwarz, Silke, Nünning, Maike, Gostian, Antoniu-Oreste, Koerber, Ludwig, Breiter, Roman, Rotter, Nicole, and Beutner, Dirk

Published

2016

13. Processed xenogenic cartilage as innovative biomatrix for cartilage tissue engineering: effects on chondrocyte differentiation and function.

Author

Schwarz, Silke, Elsaesser, Alexander F., Koerber, Ludwig, Goldberg‐Bockhorn, Eva, Seitz, Andreas M., Bermueller, Christian, Dürselen, Lutz, Ignatius, Anita, Breiter, Roman, and Rotter, Nicole

Published

2015

14. Competitive sorption of cis-DCE and TCE in silica gel as a model porous mineral solid

Author

Avila, Manuel Alejandro Salaices and Breiter, Roman

Subjects

*TRICHLOROETHYLENE, *DICHLOROETHYLENE, *ADSORPTION (Chemistry), *SILICA gel, *ABSORPTION, *EFFECT of temperature on chemical kinetics, *THERMODYNAMICS, *GIBBS' free energy

Abstract

The competitive sorption of 1,2-cis-dichloroethene (cis-DCE) and trichloroethene (TCE) was investigated by means of column experiments using a model porous mineral solid represented by silica gel. The experimental isotherms were obtained by employing a chromatographic method. The competitive sorption isotherms were modelled with the extended Freundlich and extended Langmuir isotherms, using the parameters from single-solute experiments. The breakthrough curves were modelled with the advection–dispersion transport equation coupled with the lumped pore diffusion model. The best results were obtained when the extended Freundlich isotherm was employed. The competitive sorption was revealed with the presence of an overshoot in the breakthrough curve of cis-DCE and a decrease in the degree of sorption of cis-DCE (20%) and TCE (12%). A linear dependency of the overshoot with an increase in the concentration of cis-DCE at a fixed concentration of TCE was observed, between 16% and 20%, and at least at concentrations <6mgL−1 in the liquid phase. The displaced molecules of cis-DCE by TCE were accumulated through the column causing its overshoot; thus short columns may hinder its observation. Thermodynamic analysis shows an exothermic adsorption process of −34 to −41kJmol−1, which is enhanced by sorption in micropores. The Gibbs free energy is positive for cis-DCE in the multi-component case, due to its displacement by TCE. [Copyright &y& Elsevier]

Published

2008

15. Development of a simple, accurate SPME-based method for assay of VOCs in column breakthrough experiments

Author

Salaices Avila, Manuel Alejandro, Breiter, Roman, and Mott, Henry

Subjects

*SOLID phase extraction, *GAS chromatography, *TRICHLOROETHYLENE, *SOILS

Abstract

Abstract: Solid-phase microextraction (SPME) with gas chromatography is to be used for assay of effluent liquid samples from soil column experiments associated with VOC fate/transport studies. One goal of the fate/transport studies is to develop accurate, highly reproducible column breakthrough curves for 1,2-cis-dichloroethylene (cis-DCE) and trichloroethylene (TCE) to better understand interactions with selected natural solid phases. For SPME, the influences of the sample equilibration time, extraction temperature and the ratio of volume of sample bottle to that of the liquid sample (V T/V w) are the critical factors that could influence accuracy and precision of the measured results. Equilibrium between the gas phase and liquid phase was attained after 200min of equilibration time. The temperature must be carefully controlled due to variation of both the Henry’s constant (K h) and the fibre/gas phase distribution coefficient (K fg). K h decreases with decreasing temperature while K fg increases. Low V T/V w yields better sensitivity but results in analyte losses and negative bias of the resultant assay. High V T/V w ratio yields reduced sensitivity but analyte losses were found to be minimal, leading to better accuracy and reproducibility. A fast SPME method was achieved, 5min for SPME extraction and 3.10min for GC analysis. A linear calibration function in the gas phase was developed to analyse the breakthrough curve data, linear between a range of 0.9–236μgl−1, and a detection limit lower than 5μgl−1. [Copyright &y& Elsevier]

Published

2007

16. Delayed fluorescence, steady state fluorescence, photosystem II quantum yield as endpoints for toxicity evaluation of Cu2+ and Ag+.

Author

Strauch, Sebastian M., Richter, Peter R., Haag, Ferdinand W.M., Krüger, Marcus, Krüger, Julia, Azizullah, Azizullah, Breiter, Roman, and Lebert, Michael

Subjects

*EFFECT of metals on plants, *PHOTOSYSTEMS, *EUGLENA gracilis, *DELAYED fluorescence, *IMAGE analysis

Abstract

The effect of copper and silver ions on photosynthetic parameters of the flagellate Euglena gracilis was determined. The photosystem II quantum yield (Y (PSII) ) and steady state fluorescence (F t ) were measured with a PAM-fluorometer, while delayed fluorescence (DF) was determined by means of a sensitive single-photon camera attached to an image analysis device, which counted the relative number of photons released from the algae in darkness after previous light-stimulation. We found that after 3 h of incubation photosynthesis was affected only in the presence of relatively high concentrations of the used noble metals. The obtained EC 50 values for Cu 2+ were 505.8 mg L −1 (Y (PSII) ), 286.5 mg L −1 (DF), and 491.0 mg L −1 (F t ). The EC 50 values for silver ions were 51.9 mg L −1 (Y (PSII) ), 51.8 mg L −1 (DF) (values for F t not determinable). Photosynthesis is far less sensitive against toxic noble metals compared to motility parameters as reported in earlier studies, in part because the organelles of photosynthesis, the chloroplasts, are well protected from external substances within the cell, while flagella, reaching into the surrounding of the cell, are more easily influenced. As chloroplasts are easily accessible by means of non-invasive methods e.g. PAM- fluorometry, they are probably interesting model systems in order to detect effects of substances deep inside the cell. Influence on the chloroplasts is a measure that a germicide entered the cells, diffused through the cytoplasm and the membranous systems and reached compartmentalized enzyme complexes. [ABSTRACT FROM AUTHOR]

Published

2016

17. Transplantation of Chemically Processed Decellularized Meniscal Allografts.

Author

Gelse K, Körber L, Schöne M, Raum K, Koch P, Pachowsky M, Welsch G, and Breiter R

Abstract

Objective The aim of this study was to evaluate the chondroprotective effect of chemically decellularized meniscal allografts transplanted into the knee joints of adult merino sheep. Methods Lateral sheep meniscal allografts were chemically processed by a multistep method to yield acellular, sterile grafts. The grafts were transplanted into the knee joints of sheep that were treated by lateral meniscectomy. Joints treated by meniscectomy only and untreated joints served as controls. The joints were analyzed morphologically 6 and 26 weeks after surgery by the macroscopical and histological OARSI (Osteoarthritis Research Society International) score. Additionally, the meniscal grafts were biomechanically tested by cyclic indentation. Results Lateral meniscectomy was associated with significant degenerative changes of the articular cartilage of the lateral joint compartment. Transplanted lateral meniscal allografts retained their integrity during the observation period without inducing significant synovitis or foreign body reactions. Cellular repopulation of the grafts was only present on the surface and the periphery of the lateral meniscus, but was still completely lacking in the center of the grafts at week 26. Transplantation of processed meniscal allografts could not prevent degenerative changes of the articular cartilage in the lateral joint compartment. Compared with healthy menisci, the processed grafts were characterized by a significantly reduced dynamic modulus, which did not improve during the observation period of 26 weeks in vivo. Conclusion Chemically decellularized meniscal allografts proved their biocompatibility and durability without inducing immunogenic reactions. However, insufficient recellularization and inferior stiffness of the grafts hampered chondroprotective effects on the articular cartilage.

Published

2017

18. In vitro cytotoxicity and in vivo effects of a decellularized xenogeneic collagen scaffold in nasal cartilage repair.

Author

Elsaesser AF, Bermueller C, Schwarz S, Koerber L, Breiter R, and Rotter N

Subjects

Animals, Cell Death drug effects, Extracellular Matrix metabolism, Immunohistochemistry, Implants, Experimental, Male, Models, Animal, Nasal Cartilages drug effects, Nasal Cartilages surgery, Rats, Inbred Lew, Sus scrofa, Collagen pharmacology, Nasal Cartilages pathology, Tissue Scaffolds chemistry, Transplantation, Heterologous, Wound Healing drug effects

Abstract

Tissue engineering is considered a promising future option for nasal cartilage repair. However, until now, an optimal material has not been identified for this specific purpose. Therefore, the aim of this study was to analyze a recently developed decellularized collagen matrix, which has promising material properties for septal cartilage repair. A tetrazolium dye based cytotoxicity assay using rat nasal septum chondrocytes was performed to examine the cytotoxic effects of decellularized cartilage matrices. Unseeded scaffolds as well as scaffolds seeded with chondrocytes were implanted in nasal septum defects in Lewis rats to investigate the cellular and humoral inflammatory responses in the surrounding tissue as well as the effect on the formation of nasal septum perforations. Samples were analyzed histochemically and immunohistochemically after 1, 4, and 12 weeks. Although cells for the cytotoxicity assay were cultured under serum-free conditions for 24 h to increase sensitivity, no cytotoxic effects were detected. Histological and immunohistochemical evidence displayed that the implanted scaffolds induced minor macrophage and lymphocyte infiltration and were well integrated at the contact site to native cartilage and between the mucosal membranes. The biocompatibility index revealed only slightly irritating effects during the study period. Septal perforations were prevented efficiently. In summary, our results provide evidence that decellularized xenogeneic collagen scaffolds are suitable for cartilage tissue engineering. The scaffolds were integrated well into septal cartilage defects without causing a strong inflammatory reaction and prevented the development of nasal septum perforations. Therefore, we envision the possibility to use them in nasal cartilage repair in the future.

Published

2014

19. Decellularized cartilage matrix as a novel biomatrix for cartilage tissue-engineering applications.

Author

Schwarz S, Koerber L, Elsaesser AF, Goldberg-Bockhorn E, Seitz AM, Dürselen L, Ignatius A, Walther P, Breiter R, and Rotter N

Subjects

Acetylglucosamine metabolism, Adolescent, Adult, Aged, Animals, Biomechanical Phenomena drug effects, Cell Adhesion drug effects, Cell Death drug effects, Cell Shape drug effects, Chondrocytes cytology, Chondrocytes drug effects, Chondrocytes ultrastructure, Collagen chemistry, Collagen ultrastructure, Elastic Modulus drug effects, Extracellular Matrix drug effects, Glycosaminoglycans metabolism, Humans, Menisci, Tibial cytology, Mice, Middle Aged, Porosity, Protein Denaturation drug effects, Sus scrofa, Young Adult, Biocompatible Materials pharmacology, Cartilage physiology, Extracellular Matrix metabolism, Tissue Engineering methods, Tissue Scaffolds chemistry

Abstract

Damage of cartilage structures in the head and neck region as well as in orthopedic sites are frequently caused by trauma, tumor resection, or congenital defects. Despite a high demand in many clinical fields, until today, no adequate cartilage replacement matrix is available for these fields of application. Materials that are clinically applied for joint cartilage repair still need optimization due to difficult intraoperative handling and risk of early mechanical damage. We have developed and applied a novel chemical process to completely decellularize and sterilize human and porcine cartilage tissues (meniscus cartilage and nasal septum) to generate a new type of bioimplant matrix. To characterize this matrix and to determine the effect of the decellularization process, the content of denatured collagen (w(D)) and the content of glycosaminoglycans (GAGs) (w(G)) were determined. Possible cytotoxic effects and cellular compatibility of the matrix in vitro have been examined by seeding processed cartilage biomatrices with human primary chondrocytes as well as murine fibroblasts (L929). Vitality and state of metabolism of cells were measured using MTS assays. Both cell types adhered to scaffold surfaces and proliferated. No areas of growth inhibition or cytotoxic effects were detected. New synthesis of cartilage-specific extracellular matrix was observed. By histological staining, electron microscopy, and μCT analysis, an increase of matrix porosity, complete cell elimination, and high GAG removal were demonstrated. Being from natural-origin, processed xenogenic and allogeneic cartilage biomatrices are highly versatile with regard to shape, size, and biomechanics, making them promising candidates for various biomedical applications.

Published

2012