3,677 research outputs found
Cytokines and depression in cancer patients and caregivers.
Objective:A better understanding of the biobehavioral mechanisms underlying depression in cancer is required to translate biomarker findings into clinical interventions. We tested for associations between cytokines and the somatic and psychological symptoms of depression in cancer patients and their healthy caregivers. Patients and methods:The GRID Hamilton Rating Scale for Depression (Ham-D) was administered to 61 cancer patients of mixed type and stage, 26 primary caregivers and 38 healthy controls. Concurrently, blood was drawn for multiplexed plasma assays of 15 cytokines. Multiple linear regression, adjusted for biobehavioral variables, identified cytokine associations with the psychological (Ham-Dep) and somatic (Ham-Som) subfactors of the Ham-D. Results:The Ham-Dep scores of cancer patients were similar to their caregivers, but their Ham-Som scores were significantly higher (twofold, p=0.016). Ham-Som was positively associated with IL-1ra (coefficient: 1.27, pâ€0.001) in cancer patients, and negatively associated with IL-2 (coefficient: -0.68, p=0.018) in caregivers. Ham-Dep was negatively associated with IL-4 (coefficient: -0.67, p=0.004) in cancer patients and negatively associated with IL-17 (coefficient: -1.81, p=0.002) in caregivers. Conclusion:The differential severity of somatic symptoms of depression in cancer patients and caregivers and the unique cytokine associations identified with each group suggests the potential for targeted interventions based on phenomenology and biology. The clinical implication is that depressive symptoms in cancer patients can arise from biological stressors, which is an important message to help destigmatize the development of depression in cancer patients
Electroweak Measurements Using Heavy Quarks Identified in Annihilation
Since 1989, the Large Electron Positron collider at CERN has been used to study elec- troweak physics to an unprecedented precision. The data have acted as spectacular confirmation of the Standard Model as the best description of electroweak interac- tions at scales of - 100 GeV. However, in 1995, a possible anomaly appeared in the LEP measurement of Rb = (Z-adbb) which was more than three standard devia- ( Z-*hadrons) tions above the Standard Model prediction. This effect could not be accounted for by minor adjustment of model parameters, in particular the mass of the top quark which had recently been directly measured at the Fermilab Tevatron. In order to investigate whether the deviation could be an indication of physics beyond the Standard Model we present new precise measurements of both Rb and the forward-backward asymme- try of b quark production, AbFB , using -63 pb - 1 of data at the Z peak recorded by the L3 detector during 1994-95. The results are: Rb = 0.2146 ± 0.0017(stat) + 0.00 3 3 (sys) - 0.139 (R, - 0.171) AbFB = 9.33 ± 1.40(stat) ± 0.65(sys) ± 0.10(QCD)% This value for Rb agrees with the Standard Model to within one standard deviation. AFB leads to a value for the effective weak mixing angle for b-quarks sin 2 eff - 0.2333 ± 0.0025(stat) ± 0.0012(sys) which is consistent with values obtained using different decay modes of the Z and from neutrino physics, supporting flavour universality. We thus observe no deviation from the Standard Model and, from the Rb measurement, limit the effects of new physics to < 1.7% in b decay
Theoretical studies of the kinetics of mechanical unfolding of cross-linked polymer chains and their implications for single molecule pulling experiments
We have used kinetic Monte Carlo simulations to study the kinetics of
unfolding of cross-linked polymer chains under mechanical loading. As the ends
of a chain are pulled apart, the force transmitted by each crosslink increases
until it ruptures. The stochastic crosslink rupture process is assumed to be
governed by first order kinetics with a rate that depends exponentially on the
transmitted force. We have performed random searches to identify optimal
crosslink configurations whose unfolding requires a large applied force
(measure of strength) and/or large dissipated energy (measure of toughness). We
found that such optimal chains always involve cross-links arranged to form
parallel strands. The location of those optimal strands generally depends on
the loading rate. Optimal chains with a small number of cross-links were found
to be almost as strong and tough as optimal chains with a large number of
cross-links. Furthermore, optimality of chains with a small number of
cross-links can be easily destroyed by adding cross-links at random. The
present findings are relevant for the interpretation of single molecule force
probe spectroscopy studies of the mechanical unfolding of load-bearing
proteins, whose native topology often involves parallel strand arrangements
similar to the optimal configurations identified in the study
Digilego for Peripartum Depression: A Novel Patient-Facing Digital Health Instantiation
Digital health technologies offer unique opportunities to improve health outcomes for mental health conditions such as peripartum depression (PPD), a disorder that affects approximately 10-15% of women in the U.S. every year. In this paper, we present the adaption of a digital technology development framework, Digilego, in the context of PPD. Methods include mapping of the Behavior Intervention Technology (BIT) model and the Patient Engagement Framework (PEF) to translate patient needs captured through focus groups. This informs formative development and implementation of digital health features for optimal patient engagement in PPD screening and management. Results show an array ofPPD-specific Digilego blocks ( My Diary , Mom Talk , My Care , Library , How am I doing today? ). Initial evaluation results from comparative market analysis indicate that our proposed platform offers advantageous technology aspects. Limitations and future work in areas of interdisciplinary care coordination and patient engagement optimization are discussed
On Properties of the Isoscalar Giant Dipole Resonance
Main properties (strength function, energy-dependent transition density,
branching ratios for direct nucleon decay) of the isoscalar giant dipole
resonance in several medium-heavy mass spherical nuclei are described within a
continuum-RPA approach, taking into account the smearing effect. All model
parameters used in the calculations are taken from independent data.
Calculation results are compared with available experimental data.Comment: 12 pages, 2 figure
Lateral current density fronts in asymmetric double-barrier resonant-tunneling structures
We present a theoretical analysis and numerical simulations of lateral
current density fronts in bistable resonant-tunneling diodes with Z-shaped
current-voltage characteristics. The bistability is due to the charge
accumulation in the quantum well of the double-barrier structure. We focus on
asymmetric structures in the regime of sequential incoherent tunneling and
study the dependence of the bistability range, the front velocity and the front
width on the structure parameters. We propose a sectional design of a structure
that is suitable for experimental observation of front propagation and discuss
potential problems of such measurements in view of our theoretical findings. We
point out the possibility to use sectional resonant-tunneling structures as
controllable three-terminal switches.Comment: to appear in J.Appl.Phy
Nuclear matrix elements for neutrinoless double-beta decay and double-electron capture
A new generation of neutrinoless double beta decay experiments with improved
sensitivity is currently under design and construction. They will probe
inverted hierarchy region of the neutrino mass pattern. There is also a revived
interest to the resonant neutrinoless double-electron capture, which has also a
potential to probe lepton number conservation and to investigate the neutrino
nature and mass scale. The primary concern are the nuclear matrix elements.
Clearly, the accuracy of the determination of the effective Majorana neutrino
mass from the measured 0\nu\beta\beta-decay half-life is mainly determined by
our knowledge of the nuclear matrix elements. We review recent progress
achieved in the calculation of 0\nu\beta\beta and 0\nu ECEC nuclear matrix
elements within the quasiparticle random phase approximation. A considered
self-consistent approach allow to derive the pairing, residual interactions and
the two-nucleon short-range correlations from the same modern realistic
nucleon-nucleon potentials. The effect of nuclear deformation is taken into
account. A possibility to evaluate 0\nu\beta\beta-decay matrix elements
phenomenologically is discussed.Comment: 24 pages; 80 references. arXiv admin note: substantial text overlap
with arXiv:1101.214
Uncertainties in the --decay nuclear matrix elements
The nuclear matrix elements of the neutrinoless double beta decay
() of most nuclei with known -decay rates are
systematically evaluated using the Quasiparticle Random Phase Approximation
(QRPA) and Renormalized QRPA (RQRPA). The experimental -decay
rate is used to adjust the most relevant parameter, the strength of the
particle-particle interaction. With such procedure the values become
essentially independent on single-particle basis size, the axial vector
quenching factor, etc. Theoretical arguments in favor of the adopted way of
determining the interaction parameters are presented. It is suggested that most
of the spread among the published 's can be ascribed to the choices
of implicit and explicit parameters, inherent to the QRPA method.Comment: 9 pages, 1 figure. Contribution to MEDEX'05, Corfu, Greece, September
26 - 29, 2005. A short version of nucl-th/0503063, to be published in Czech.
J. Phy
Short-range correlations and neutrinoless double beta decay
In this work we report on the effects of short-range correlations upon the
matrix elements of neutrinoless double beta decay. We focus on the calculation
of the matrix elements of the neutrino-mass mode of neutrinoless double beta
decays of 48Ca and 76Ge. The nuclear-structure components of the calculation,
that is the participant nuclear wave functions, have been calculated in the
shell-model scheme for 48Ca and in the proton-neutron quasiparticle
random-phase approximation (pnQRPA) scheme for 76Ge. We compare the traditional
approach of using the Jastrow correlation function with the more complete
scheme of the unitary correlation operator method (UCOM). Our results indicate
that the Jastrow method vastly exaggerates the effects of short-range
correlations on the neutrinoless double beta decay nuclear matrix elements.Comment: 12 pages, 3 figures, to appear in Physics Letters B (2007
Evaluation of the mean intensity of the P-odd mixing of nuclear compound states
A temperature version of the shell-optical-model approach for describing the
low-energy compound-to-compound transitions induced by external single-particle
fields is given. The approach is applied to evaluate the mean intensity of the
P-odd mixing of nuclear compound states. Unified description for the mixing and
electromagnetic transitions allows one to evaluate the mean intensity without
the use of free parameters. The valence-mechanism contribution to the mentioned
intensity is also evaluated. Calculation results are compared with the data
deduced from cross sections of relevant neutron-induced reactions.Comment: LaTeX, 10 page
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