Prevalence and predictors of yogic breathing and meditation use - A nationally representative survey of US adult yoga practitioners.

Introduction Yoga practice in common usage is often confined to the physical aspects of the comprehensive practice. The purpose of this study was to examine the use of two additional aspects of yoga as part of yoga practice, i.e. yogic breathing and meditation (YoBaM). Prevalence and predictors of YoBaM use among yoga practitioners in the US general population were analyzed. Method Cross-sectional data from the 2012 and 2017 National Health Interview Survey (NHIS) (N = 61,267) was used. 12-month prevalence of yoga use and YoBaM use among yoga practitioners were analyzed descriptively for the two cohorts respectively. Logistic regression analyses were used to analyze sociodemographic and health-related predictors of YoBaM use among yoga practitioners. Results 12-month prevalence of yoga use and YoBaM use were 8.9 % and 4.8 % respectively in 2012. In 2017, 13.3 % had practiced yoga in the past 12 months and 7.0 % had used YoBaM. Yoga practitioners aged between 50 and 64 compared to being 29 or younger, females, Hispanics and those experiencing mild to severe forms of psychological distress were more likely to use YoBaM as part of their yoga practice. Yoga practitioners living in the Midwest or in a relationship were less likely to use YoBaM. Conclusion In recent years, the number of yoga practitioners in the US general population has considerably increased and YoBaM use is common among yoga practitioners. YoBaM use seems to be associated with age, gender, ethnicity, region, marital status and psychological distress dimensions

Light transmission assisted by Brewster-Zennek modes in chromium films carrying a subwavelength hole array

This work confirms that not only surface plasmons but many other kinds of electromagnetic eigenmodes should be considered in explaining the values of the transmittivity through a slab bearing a two-dimensional periodic corrugation. Specifically, the role of Brewster-Zennek modes appearing in metallic films exhibiting regions of weak positive dielectric constant. It is proposed that these modes play a significant role in the light transmission in a thin chromium film perforated with normal cylindrical holes, for appropriate lattice parameters.Comment: 5 pages, 4 figures. Published versio

The Effects of Interfacial Properties on the Mechanical Behavior of Layered Aluminum Matrix Composites

Al/SiC-composites are not only ajfected by inelastic deformation processes in the metallic matrix but also by debonding occurring at the fiber-matrix-interface. Therefore a viscoplastic material law including damage evolution and growth, as well as a cohesive zone model for the interface, are integrated into a finite element technique. By this the influence of interfacial characteristics on the stress-strain behavior of a laminated Al/SiC-composite is ezramined

Coat/tether interactions-exception or rule?

Coat complexes are important for cargo selection and vesicle formation. Recent evidence suggests that they may also be involved in vesicle targeting. Tethering factors, which form an initial bridge between vesicles and the target membrane, may bind to coat complexes. In this review, we ask whether these coat/tether interactions share some common mechanisms, or whether they are special adaptations to the needs of very specific transport steps. We compare recent findings in two multisubunit tethering complexes, the Dsl1 complex and the HOPS complex, and put them into context with the TRAPP I complex as a prominent example for coat/tether interactions. We explore where coat/tether interactions are found, compare their function and structure, and comment on a possible evolution from a common ancestor of coats and tethers

Capturing regional differences in flood vulnerability improves flood loss estimation

Flood vulnerability is quantified by loss models which are developed using either empirical or synthetic approaches. In reality, processes influencing flood risk are stochastic and loss predictions bear significant uncertainty, especially due to differences in vulnerability across exposed objects and regions. However, many state-of-the-art flood loss models are deterministic, i.e., they do not account for data and model uncertainty. The Bayesian Data-Driven Synthetic (BDDS) model was one of the first approaches that used empirical data to reduce the prediction errors at object-level and enhance the reliability of synthetic flood loss models. However, the BDDS model does not account for regional differences in vulnerability which may result in over-/under-estimation of losses in some regions. In order to overcome this limitation, this study introduces a hierarchical parameterization of the BDDS model which enhances synthetic flood loss model predictions by quantifying regional differences in vulnerability. The hierarchical parameterization makes optimal use of the process information contained in the overall data set for the various regional applications, so that it is particularly suitable for cases in which only a small amount of empirical data is available. The implementation and performance of the hierarchical parametrization is demonstrated with the Multi-Colored Manual (MCM) loss functions and empirical damage dataset from the UK consisting of residential buildings from the regions Appleby, Carlisle, Kendal and Cockermouth that suffered losses during the 2015 flood event. The developed model improves prediction accuracy of flood loss compared to MCM by reducing the absolute error and bias by at least 23 and 90%, respectively. The model reliability in terms of hit rate (i.e., the probability that the observed value lies in the 90% high density interval of predictions) is 88% for residential buildings from the same regions used for calibration and 73% for residential buildings from new regions. The approach is of high practical relevance for all regions where only limited amounts of empirical flood loss data is available

Effect of Uniaxial Tensile Loading on the Stiffness of Two-Dimensional Woven SiC/SiC - Modeling and Numerical Simulation

The behavior of two-dimensional woven SiC/SiC ceramic matrix composites (CMC) is studied by numerical simulations based on the finite element method (FEM). Starting point of the investigations is amicromechanical model regarding a three-dimensional unit cell. Damage as well as fracture of the singlecomponents - fiber bundles and inter yarn matrix - are regarded from a statistical point of view usingWeibull distribution. Statements of the behavior of the whole composite are possible by building up amacrostructure. The purpose of the current study is set on the stifiness reduction of the 2Dw compositesubjected to tensile loading in one of the fiber directions. Because of the strong anisotropy of the dam-age a tensor approach is used considering the terms of the elasticity matrix, which are determined forincreasing load. Regarding the elasticity matrix the behavior of the composite for any loading situationcan be predicted after an arbitrary preloading in one of the fiber direction

A Characterisation of the Weylian Structure of Space-Time by Means of Low Velocity Tests

The compatibility axiom in Ehlers, Pirani and Schild's (EPS) constructive axiomatics of the space-time geometry that uses light rays and freely falling particles with high velocity, is replaced by several constructions with low velocity particles only. For that purpose we describe in a space-time with a conformal structure and an arbitrary path structure the radial acceleration, a Coriolis acceleration and the zig-zag construction. Each of these quantities give effects whose requirement to vanish can be taken as alternative version of the compatibility axiom of EPS. The procedural advantage lies in the fact, that one can make null-experiments and that one only needs low velocity particles to test the compatibility axiom. We show in addition that Perlick's standard clock can exist in a Weyl space only.Comment: to appear in Gen.Rel.Gra

Crystal structure of a murine α-class glutathione S-transferase involved in cellular defense against oxidative stress

Glutathione S-transferases (GSTs) are ubiquitous multifunctional enzymes which play a key role in cellular detoxification. The enzymes protect the cells against toxicants by conjugating them to glutathione. Recently, a novel subgroup of α-class GSTs has been identified with altered substrate specificity which is particularly important for cellular defense against oxidative stress. Here, we report the crystal structure of murine GSTA4-4, which is the first structure of a prototypical member of this subgroup. The structure was solved by molecular replacement and refined to 2.9 Å resolution. It resembles the structure of other members of the GST superfamily, but reveals a distinct substrate binding site.

Potential Energy Surface for H_2 Dissociation over Pd(100)

The potential energy surface (PES) of dissociative adsorption of H_2 on Pd(100) is investigated using density functional theory and the full-potential linear augmented plane wave (FP-LAPW) method. Several dissociation pathways are identified which have a vanishing energy barrier. A pronounced dependence of the potential energy on ``cartwheel'' rotations of the molecular axis is found. The calculated PES shows no indication of the presence of a precursor state in front of the surface. Both results indicate that steering effects determine the observed decrease of the sticking coefficient at low energies of the H_2 molecules. We show that the topology of the PES is related to the dependence of the covalent H(s)-Pd(d) interactions on the orientation of the H_2 molecule.Comment: RevTeX, 8 pages, 5 figures in uufiles forma