University of Erlangen-Nuremberg

About: University of Erlangen-Nuremberg is a education organization based out in Erlangen, Bayern, Germany. It is known for research contribution in the topics: Population & Immune system. The organization has 42405 authors who have published 85600 publications receiving 2663922 citations.

Carbon nanotubes—electronic/electrochemical properties and application for nanoelectronics and photonics

Abstract: The fundamental chemical, redox, electrochemical, photoelectrochemical, optical and optoelectronic features of carbon nanotubes are surveyed with particular emphasis on the most relevant applications as electron donor/electron acceptor or as electron conductor/hole conductor materials, in solutions and in the solid state. Methods that aim at p- and n-doping as a means to favor hole or electron injection/transport are covered as well (critical review, 208 references).

Progress in enzyme immobilization in ordered mesoporous materials and related applications

Abstract: A short time after the discovery of ordered mesoporous materials, which possess unique features such as high specific surface area and pore volume, highly uniform pore distribution and tunable pore size, these materials have been prospected as promising carriers for enzyme immobilization. The immobilization of enzymes in ordered mesoporous materials has been studied for almost two decades. With the development of tailored ordered mesoporous materials and advances in enzyme technology, this field attracted increasing interest due to its quickly expanded functions and applications. This review focuses on the relation between the progress in ordered mesoporous materials and its corresponding contribution to enzyme immobilization as well as the applications of these materials in biocatalysis. The potential trends in the future development of this field are also pointed out.

TiO2 nanotube surfaces: 15 nm--an optimal length scale of surface topography for cell adhesion and differentiation.

Abstract: Studies of biomimetic surfaces in medicine and biomaterial fields have explored extensively how the micrometer-scale topography of a surface controls cell behavior, but only recently has the nanoscale environment received attention as a critical factor for cell behavior. Several investigations of cell interactions have been performed using surface protrusion topographies at the nanoscale; such topographies are typically based on polymer demixing, ordered gold cluster arrays, or islands of adhesive ligands at distinct length scales. Recent work has indicated that the fabrication of ordered TiO2 nanotube layers with controlled diameters can be achieved by anodization of titanium in adequate electrolytes. Such surfaces can almost ideally be used as nanoscale spacing models for size-dependent cellular response. This is particularly important as these studies are carried out on titanium surfaces—a material used for clinical titanium implantations for the purpose of bone, joint, or tooth replacements. Therefore, principles elucidated from this work can guide implant surface modifications toward an optimized surface geometry and profile to best fit and cell interactions for adequate bone growth.

Distinct fibroblast subsets drive inflammation and damage in arthritis.

Abstract: The identification of lymphocyte subsets with non-overlapping effector functions has been pivotal to the development of targeted therapies in immune-mediated inflammatory diseases (IMIDs)1,2. However, it remains unclear whether fibroblast subclasses with non-overlapping functions also exist and are responsible for the wide variety of tissue-driven processes observed in IMIDs, such as inflammation and damage3-5. Here we identify and describe the biology of distinct subsets of fibroblasts responsible for mediating either inflammation or tissue damage in arthritis. We show that deletion of fibroblast activation protein-α (FAPα)+ fibroblasts suppressed both inflammation and bone erosions in mouse models of resolving and persistent arthritis. Single-cell transcriptional analysis identified two distinct fibroblast subsets within the FAPα+ population: FAPα+THY1+ immune effector fibroblasts located in the synovial sub-lining, and FAPα+THY1- destructive fibroblasts restricted to the synovial lining layer. When adoptively transferred into the joint, FAPα+THY1- fibroblasts selectively mediate bone and cartilage damage with little effect on inflammation, whereas transfer of FAPα+ THY1+ fibroblasts resulted in a more severe and persistent inflammatory arthritis, with minimal effect on bone and cartilage. Our findings describing anatomically discrete, functionally distinct fibroblast subsets with non-overlapping functions have important implications for cell-based therapies aimed at modulating inflammation and tissue damage.

SLM peak-power reduction without explicit side information

Abstract: Selected mapping (SLM) peak-power reduction is distortionless as it selects the actual transmit signal from a set of alternative signals, which all represent the same information. The specific signal generation information needs to be transmitted and carefully protected against bit errors. Here, me propose an extension of SLM, which employs scrambling and refrains from the use of explicit side information in the receiver. Some additional complexity and nearly vanishing redundancy is introduced to achieve markedly improved transmit signal statistics. Even though SLM is applicable with any modulation, we concentrate on orthogonal frequency-division multiplexing (OFDM) in this letter.