Polarization state studies in second harmonic generation signals to trace atherosclerosis lesions

We have performed multi-photon image reconstructions as well as polarization state analyses inside an artery wall affected by atherosclerosis to investigate the changes in collagen structure. Mice, either healthy or affected by spontaneous atherosclerosis, have been used for this purpose. A two-photon imaging system has been used to investigate atherosclerotic lesions in the ascending aorta of mice. Second harmonic imaging has been performed alternatively on healthy samples and on affected region. The reconstructed images show that the spatial distribution of the collagen network seems disorganized by the disease. The polarization state studies reveal however that the apparent disorganization of the collagen is related to its spatially diffuse distribution and that the internal structure of the collagen fibers is not affected by the disease. In addition, a theoretical simulation of the second harmonic polarization states shows that they are consistent with the known 3D structure of the collagen network

Magnetism of CoPd self-organized alloy clusters on Au(111)

Magnetic properties of gold-encapsulated CoxPd1-x self-organized nano-clusters on Au(111) are analyzed by x-ray magnetic circular dichroism for x = 0.5, 0.7, and 1.0. The clusters are superparamagnetic with a blocking temperature decreasing with increasing Pd concentration, due to a reduction of the out-of-plane anisotropy strength. No magnetic moment is detected on Pd in these clusters, within the detection limit, contrary to thick CoPd films. Both reduction of anisotropy and vanishing Pd moment are attributed to strain. (C) 2013 AIP Publishing LLC

Caracterização da dinâmica da complexação do receptor tipo Toll 4 humano a MD-2

Os receptores tipo Toll desempenham um importante papel na resposta imune inata, reconhecendo tanto padrões moleculares associados a patógenos (PAMPs), quanto padrões moleculares associados a danos (DAMPs), liberados sob condições de injúria ou estresse celular. O receptor tipo Toll 4 humano (hTLR4), associado ao seu co-receptor, o fator de diferenciação mielóide 2 (MD-2), forma um heterodímero caracterizado como responsável pelo reconhecimento de lipopolissacarídeos bacterianos (LPS), derivados de bactérias Gram-negativas. Nestes casos, sabe-se que o MD-2 reconhece LPS e promove a dimerização do complexo hTLR4 - MD-2 - LPS, promovendo a sinalização intracelular. Já foi reportada a ausência da associação hTLR4 a MD-2, no reconhecimento de outros ligantes por hTLR4, e, nesses casos, pouco é conhecido a respeito das mudanças estruturais e conformacionais sofridas por este receptor. No presente estudo, empregando a técnica de simulação por dinâmica molecular, foram exploradas as propriedades dinâmicas do complexo de reconhecimento de LPS, hTLR4 - MD-2, bem como investigou-se as implicações da presença do co-receptor para a biologia estrutural do hTLR4. Os resultados mostram que o receptor apresenta um movimento do tipo pinça, o qual leva a um estado final mais aberto da estrutura em forma de ferradura. Ademais, a estabilidade desta estrutura parece ser influenciada pela presença do co-receptor, MD-2.Toll-like receptors (TLRs) play an important role in innate immunity recognizing pathogen-associated molecular patterns (PAMPs), as also damageassociated molecular patterns (DAMPs), released after cellular injury or stress. Human Toll-Like Receptor 4 (hTLR4) and its co-receptor, myeloid differentiation factor 2 (MD-2), as a heterodimer, is a well-known complex of Gram-negative bacteria lipopolysaccharide (LPS) recognition. In this process, MD-2 recognizes LPS and promotes the dimerization of the complex hTLR4 - MD-2 - LPS, initiating an intracellular immune signaling. Moreover, it has been reported that hTLR4 can also act in the absence of MD-2, in the case of other ligands recognition, and, in these cases, little is known about the structural and conformational changes that hTLR4 structure underwent. In the current study, employing molecular dynamics simulations, we had explored the dynamical properties of the hTLR4 - MD-2 complex and investigated the implications of the co-receptor complexation to the structural biology of hTR4. We observed that the receptor showed a tweezers-like movement, leading to a more oppened final state of its horseshoe-shaped structure. Additionally, the stability of this structure seems to be influenced by the presence of the co-receptor, MD-2

Breakdown of the electron-spin motion upon reflection at metal-organic or metal-carbon interfaces

Spin-polarized electron scattering experiments on different metal-organic and metal-carbon interfaces are performed. A completely unexpected behavior of the spin-motion angles as well as of related quantities as a function of the organic layer or carbon coverage is observed. In fact, by deposition of organic molecules or carbon onto ferromagnetic as well as nonmagnetic metal surfaces in the submonolayer thickness range, the electron reflection amplitude, i.e., both the reflectivity and the reflection phase, become spin independent. Our findings show that this behavior is a very general phenomenon which is independent of the electron energy and the choice of the metal as well as of the organic molecules and thus does not depend on the choice of the specific interface

Highly spin-polarized carbon-based spinterfaces

We deploy topographical and spectroscopic techniques to show that a strongly spin-polarized interface arises between ferromagnetic cobalt and an amorphous carbon layer. Scanning tunneling microscopy and spectroscopy show how a semiconducting carbon film with a low band gap of about 0.4 eV is formed atop the metallic interface. To understand how the cobalt/carbon interface is formed, we used X-ray photoemission spectroscopy to study the hybridization state of carbon. We find that the semiconducting layer consists mainly of sp(2)-bonded carbon atoms with a sp(2)-to-sp(3) ratio between 1.4 and 1.8. The spin-polarized properties of the cobalt/carbon interface are studied by spin-resolved photoemission spectroscopy. We observe interface states close to the Fermi energy that are not exclusive to cobalt. These electronic states reveal a high degree of spin polarization at room temperature. (C) 2015 Elsevier Ltd. All rights reserved