Verhalten metallischer Konstruktionswerkstoffe unter thermomechanischer Belastung - experimentelle Charakterisierung und modellmäßige Beschreibung /

Bauer, Valerij.

January 2007

Universiẗat, Diss.--Siegen, 2006.

Wave propagation in infinite domains : with applications to structure interaction /

Lehmann, Lutz.

January 2007

Techn. Univ., Habil.-Schr.--Braunschweig, 2006.

Prozess-Gefüge-Eigenschaften : Korrelation für langfaserverstärktes Aluminium /

Rosefort, Marcel.

January 2007

Techn. Hochsch., Diss.--Aachen, 2006.

Hedgehog signaling regulates mechanical tension along the anteroposterior compartment boundary in the developing Drosophila wing

Rudolf, Katrin

11 August 2014

The interplay between biochemical signals and mechanical processes during animal development is key for the formation of tissues and organs with distinct shapes and functions. An important step during the formation of many tissues is the formation of compartment boundaries which separate cells of different fates and functions. Compartment boundaries are lineage restrictions that are characterized by a straight morphology. Biochemical signaling across compartment boundaries induce the expression of morphogens in the cells along the boundaries. These morphogens then act at long-range to direct growth and patterning of the whole tissue. Compartment boundaries stabilize the position of morphogens and thereby contribute to proper tissue development. The straight morphology of compartment boundaries is challenged by cell rearrangements caused by cell division and tissue reshaping. Physical mechanisms are therefore required to maintain the straight morphology of compartment boundaries. The anteroposterior (A/P) compartment boundary in the developing Drosophila melanogaster wing is established by biochemical signals. Furthermore, mechanical processes are required to maintain the straight shape of the A/P boundary. Recent studies show that mechanical tension mediated by actomyosin motor proteins is increased along the A/P boundary. However, it was not understood how biochemical signals interact with mechanical processes to maintain the A/P boundary. Here I provide the first evidence that Hedgehog signaling regulates mechanical tension along the A/P boundary. I was able to show that differences in Hedgehog (Hh) signal transduction activity between the anterior and posterior compartments are necessary and sufficient to maintain the straight shape of the A/P boundary, which is crucial for patterning and growth of the adult wing. Moreover, differences in Hh signal transduction activity are necessary and sufficient for the increase in mechanical tension along the A/P boundary. In addition, differences in Hh signal transduction activity are sufficient to generate smooth borders and to increase mechanical tension along ectopic interfaces. Furthermore, the differential expression of the transmembrane protein Capricious is sufficient to increase mechanical tension along ectopic interfaces. It was previously suggested that mechanical tension is generated by an actomyosin-cable through which the increase in mechanical tension is transmitted between the junctions along the A/P boundary. Here I show that mechanical tension is generated locally at each cell bond and not transmitted between junctions by an actomyosin cable. My results provide new insights for our understanding of the interplay between biochemical signals and mechanical processes during animal development.

Kompartimentsgrenze

Hedgehog Signalweg

mechanische Spannung

compartment boundary

Hedgehog signaling

mechanical tension

ddc:570

rvk:WD 5100

Research on the mechanical properties of the sand cast magnesium alloy AZ91

Erchov, Serguei

10 July 2009

In dieser Arbeit wurden die mechanischen Eigenschaften der Magnesiumsandgusslegierung AZ91 in Abhängigkeit von den Prozessparametern untersucht. Es wurde gezeigt, dass durch die Anwendung von Filtration, Kornfeinung und Wärmebehandlung das Niveau der mechanischen Eigenschaften des Sandgusses dem des Druckgusses angepasst werden kann. In dieser Arbeit wurde außerdem der Einfluss der Prozessparameter auf die Spannungsrelaxations- und Dämpfungseigenschaften untersucht.

Magnesiumsandguss

Magnesiumlegierung

Magnesium

Sandguss

AZ91

Mechanische Eigenschaften

Innere Reibung

Spannungsrelaxation

Dämpfung

ddc:600

rvk:UQ 7000

Do cells contribute to tendon and ligament biomechanics?

Hammer, Niels, Huster, Daniel, Schmidt, Peter, Fritsch, Sebastian, Wagner, Martin Franz-Xaver, Hädrich, Carsten, Koch, Holger, Boldt, Andreas, Sichting, Freddy

18 August 2014

Introduction: Acellular scaffolds are increasingly used for the surgical repair of tendon injury and ligament tears. Despite this increased use, very little data exist directly comparing acellular scaffolds and their native counterparts. Such a comparison would help establish the effectiveness of the acellularization procedure of human tissues. Furthermore, such a comparison would help estimate the influence of cells in ligament and tendon stability and give insight into the effects of acellularization on collagen. Material and Methods: Eighteen human iliotibial tract samples were obtained from nine body donors. Nine samples were acellularized with sodium dodecyl sulphate (SDS), while nine counterparts from the same donors remained in the native condition. The ends of all samples were plastinated to minimize material slippage. Their water content was adjusted to 69%, using the osmotic stress technique to exclude water content-related alterations of the mechanical properties. Uniaxial tensile testing was performed to obtain the elastic modulus, ultimate stress and maximum strain. The effectiveness of the acellularization procedure was histologically verified by means of a DNA assay. Results: The histology samples showed a complete removal of the cells, an extensive, yet incomplete removal of the DNA content and alterations to the extracellular collagen. Tensile properties of the tract samples such as elastic modulus and ultimate stress were unaffected by acellularization with the exception of maximum strain. Discussion: The data indicate that cells influence the mechanical properties of ligaments and tendons in vitro to a negligible extent. Moreover, acellularization with SDS alters material properties to a minor extent, indicating that this method provides a biomechanical match in ligament and tendon reconstruction. However, the given protocol insufficiently removes DNA. This may increase the potential for transplant rejection when acellular tract scaffolds are used in soft tissue repair. Further research will help optimize the SDS-protocol for clinical application.

Sehne

Band

Kollagen

mechanische Eigenschaften

tendon

ligament

collagen

mechanical properties

ddc:610

Force Distribution in Macromolecules / Kraftverteilung in Makromolekülen

Stacklies, Wolfram

05 August 2010

All living organisms utilize thousands of molecular building blocks to perform mechanical tasks. These building blocks are mostly proteins, and their mechanical properties define the way they can be utilized by the cell. The spectrum ranges from rope like structures that give hold and stability to our bodies to microscopic engines helping us to perform or sense mechanical work. An increasing number of biological processes are revealed to be driven by force and well-directed distribution of strain is the very base of many of these mechanisms. We need to be able to observe the distribution of strain within bio-molecules if we want to gain detailed insight into the function of these highly complex nano-machines. Only by theoretical understanding and prediction of mechanical processes on the molecular level will we be able to rationally tailor proteins to mimic specific biological functions. This thesis aims at understanding the molecular mechanics of a wide range of biological molecules, such as the muscle protein titin or silk fibers. We introduce Force Distribution Analysis (FDA), a new approach to directly study the forces driving molecular processes, instead of indirectly observing them by means of coordinate changes.

Force distribution

molecular dynamics

mechanical resistance

protein

Kraftverteilung

mechanische widerstandsfähigkeit

protein

ddc:000

Jet milling from a particle perspective predicting particle fracture based on mechanical material properties /

Vegt, Onno Martinus de,

January 2007

Proefschr. Rijksuniversiteit Groningen. / Met lit. opg.-Met samenvatting in het Nederlands.

Grain refinement of cold rolled low carbon steels by rapid transformation annealing (RTA) /

Lesch, Christian Manfred.

January 2006

Techn. Hochsch., Diss., 2006--Aachen.

Experimentelle Untersuchungen zur Diffusion von Wasserstoff und Deuterium in Nb0.8Mo0.2 und Hafnium

Leu, Boris.

Unknown Date

Techn. Universiẗat, Diss., 2006--Darmstadt.