4,569 research outputs found
Accessing the high-l frontier under the reduced shear approximation with k-cut cosmic shear
The precision of Stage IV cosmic shear surveys will enable us to probe smaller physical scales than ever before, however, model uncertainties from baryonic physics and non-linear structure formation will become a significant concern. The k-cut method - applying a redshift-dependent-cut after making the Bernardeau-Nishimichi-Taruya transform - can reduce sensitivity to baryonic physics; allowing Stage IV surveys to include information from increasingly higher-modes. Here we address the question of whether it can also mitigate the impact of making the reduced shear approximation; which is also important in the high-κ, small-scale regime. The standard procedure for relaxing this approximation requires the repeated evaluation of the convergence bispectrum, and consequently can be prohibitively computationally expensive when included in Monte Carlo analyses. We find that the k-cut cosmic shear procedure suppresses the w_{0}w_{a} CDM cosmological parameter biases expected from the reduced shear approximation for Stage IV experiments, when-modes up to 5000 are probed. The maximum cut required for biases from the reduced shear approximation to be below the threshold of significance is at k=5.37 h Mpc^{-1}. With this cut, the predicted 1σ constraints increase, relative to the case where the correction is directly computed, by less than 10% for all parameters. This represents a significant improvement in constraints compared to the more conservative case where only-modes up to 1500 are probed [A. Blanchard, (Euclid Collaboration), arXiv:1910.09273], and no k-cut is used. We also repeat this analysis for a hypothetical, comparable kinematic weak lensing survey. The key parts of code used for this analysis are made publicly available
Mapping Spatially Varying Additive Biases in Cosmic Shear Data
In this paper we address the challenge of extracting maps of spatially varying unknown additive biases from cosmic shear data. This is done by exploiting the isotropy of the cosmic shear field, and the anisotropy of a typical additive bias field, using an autocorrelation discrepancy map; which identifies significant non-Gaussian components of the map. We test this approach using simulations and find that the autocorrelation discrepancy map produces spatially varying features that are indicative of the additive bias field both in amplitude and spatial variation. We then apply this to the Dark Energy Survey Year 1 data, and find evidence for spatially varying additive biases of at most 0.002 on large-scales. The method can be used to empirically inform modelling of the spatially varying additive bias field in any cosmological parameter inference, and can act as a validation test for cosmic shear surveys
Developing artemisinin based drug combinations for the treatment of drug resistant falciparum malaria: A review
The emergence and spread of drug resistant malaria represents a
considerable challenge to controlling malaria. To date, malaria control
has relied heavily on a comparatively small number of chemically
related drugs, belonging to either the quinoline or the antifolate
groups. Only recently have the artemisinin derivatives been used but
mostly in south east Asia. Experience has shown that resistance
eventually curtails the life-span of antimalarial drugs. Controlling
resistance is key to ensuring that the investment put into developing
new antimalarial drugs is not wasted. Current efforts focus on research
into new compounds with novel mechanisms of action, and on measures to
prevent or delay resistance when drugs are introduced. Drug discovery
and development are long, risky and costly ventures. Antimalarial drug
development has traditionally been slow but now various private and
public institutions are at work to discover and develop new compounds.
Today, the antimalarial development pipeline is looking reasonably
healthy. Most development relies on the quinoline, antifolate and
artemisinin compounds.There is a pressing need to have effective, easy
to use, affordable drugs that will last a long time. Drug combinations
that have independent modes of action are seen as a way of enhancing
efficacy while ensuring mutual protection against resistance. Most
research work has focused on the use of artesunate combined with
currently used standard drugs, namely, mefloquine, amodiaquine,
sulfadoxine/pyrimethamine, and chloroquine. There is clear evidence
that combinations improve efficacy without increasing toxicity.
However, the absolute cure rates that are achieved by combinations vary
widely and depend on the level of resistance of the standard drug. From
these studies, further work is underway to produce fixed dose
combinations that will be packaged in blister packs. This review will
summarise current antimalarial drug developments and outline recent
clinical research that aims to bring artemisinin based combinations to
those that need them most
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Multiple sclerosis susceptibility alleles in African Americans.
Multiple sclerosis (MS) is an autoimmune demyelinating disease characterized by complex genetics and multifaceted gene-environment interactions. Compared to whites, African Americans have a lower risk for developing MS, but African Americans with MS have a greater risk of disability. These differences between African Americans and whites may represent differences in genetic susceptibility and/or environmental factors. SNPs from 12 candidate genes have recently been identified and validated with MS risk in white populations. We performed a replication study using 918 cases and 656 unrelated controls to test whether these candidate genes are also associated with MS risk in African Americans. CD6, CLEC16a, EVI5, GPC5, and TYK2 contained SNPs that are associated with MS risk in the African American data set. EVI5 showed the strongest association outside the major histocompatibility complex (rs10735781, OR=1.233, 95% CI=1.06-1.43, P-value=0.006). In addition, RGS1 seems to affect age of onset whereas TNFRSF1A seems to be associated with disease progression. None of the tested variants showed results that were statistically inconsistent with the effects established in whites. The results are consistent with shared disease genetic mechanisms among individuals of European and African ancestry
Preparing for the cosmic shear data flood: Optimal data extraction and simulation requirements for stage IV dark energy experiments
Upcoming photometric lensing surveys will considerably tighten constraints on the neutrino mass and the dark energy equation of state. Nevertheless it remains an open question of how to optimally extract the information and how well the matter power spectrum must be known to obtain unbiased cosmological parameter estimates. By performing a principal component analysis (PCA), we quantify the sensitivity of 3D cosmic shear and tomography with different binning strategies to different regions of the lensing kernel and matter power spectrum, and hence the background geometry and growth of structure in the Universe. We find that a large number of equally spaced tomographic bins in redshift can extract nearly all the cosmological information without the additional computational expense of 3D cosmic shear. Meanwhile a large fraction of the information comes from small poorly understood scales in the matter power spectrum, that can lead to biases on measurements of cosmological parameters. In light of this, we define and compute a cosmology-independent measure of the bias due to imperfect knowledge of the power spectrum. For a Euclid-like survey, we find that the power spectrum must be known to an accuracy of less than 1% on scales with
k
≤
7
h
 
 
Mpc
−
1
. This requirement is not absolute since the bias depends on the magnitude of modeling errors, where they occur in
k
−
z
space, and the correlation between them, all of which are specific to any particular model. We therefore compute the bias in several of the most likely modeling scenarios and introduce a general formalism and public code, RequiSim, to compute the expected bias from any nonlinear model
Nonparametric cosmology with cosmic shear
We present a method to measure the growth of structure and the background geometry of the Universe—
with no a priori assumption about the underlying cosmological model. Using Canada-France-Hawaii
Lensing Survey (CFHTLenS) shear data, we simultaneously reconstruct the lensing amplitude, the linear
intrinsic alignment amplitude, the redshift evolving matter power spectrum, Pðk; zÞ, and the comoving
distance, rðzÞ. We find that lensing predominately constrains a single global power spectrum amplitude and
several comoving distance bins. Our approach can localize the precise scales (k-modes in the matter power
spectrum) and redshifts where lambda-cold dark matter (LCDM) fails—if any. We find that below z ¼ 0.4,
the measured comoving distance rðzÞ is higher than that expected from the Planck LCDM cosmology by
∼1.5σ, while at higher redshifts, our reconstruction is fully consistent. To validate our reconstruction, we
compare LCDM parameter constraints from the standard cosmic shear likelihood analysis to those found
by fitting to the nonparametric information and we find good agreement
Phenological tracking of a seasonal climate window in a recovering tropical island bird species
Constraints on evolutionary adaptation and range shifts mean that phenotypic plasticity, which includes physiological, developmental or behavioural responses to environmental conditions, could be an important mode of adaptation to a changing climate for many species with small insular populations. While there is evidence to suggest adaptive plasticity to climate in some island populations, little is known about this capacity in species that have experienced a severe population bottleneck. In a changing climate, plasticity in the timing of life-history events, such as in breeding phenology, is adaptive if timing is optimised in seasonal environments, although these processes are poorly understood for tropical species. Here, we quantify the effects of climate on the breeding phenology and success of the Mauritius kestrel (Falco punctatus), a tropical raptor whose extinction has been averted by conservation management. We show that the timing of egg-laying is advancing in response to warming, at rates similar to temperate bird populations. Individual females show plasticity to temperature, although there is limited variation among individual responses. We show that advances in breeding phenology are likely to be adaptive, as they track changes in a seasonal climate window of favourable conditions, defined by late winter-early spring temperatures and the onset of the summer rainy season. Our results provide a rare example of a small and bottlenecked insular population that has adjusted to recent climate change through phenotypic plasticity. Furthermore, seasonal climate windows and their dynamics may be widespread mechanisms through which tropical species are impacted by and respond to climate change
Evolutionary relationships between Rhynchosporium lolii sp. nov. and other Rhynchosporium species on grass.
Copyright: 2013 King et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are creditedThe fungal genus Rhynchosporium (causative agent of leaf blotch) contains several host-specialised species, including R. commune (colonising barley and brome-grass), R. agropyri (couch-grass), R. secalis (rye and triticale) and the more distantly related R. orthosporum (cocksfoot). This study used molecular fingerprinting, multilocus DNA sequence data, conidial morphology, host range tests and scanning electron microscopy to investigate the relationship between Rhynchosporium species on ryegrasses, both economically important forage grasses and common wild grasses in many cereal growing areas, and other plant species. Two different types of Rhynchosporium were found on ryegrasses in the UK. Firstly, there were isolates of R. commune that were pathogenic to both barley and Italian ryegrass. Secondly, there were isolates of a new species, here named R. lolii, that were pathogenic only to ryegrass species. R. lolii was most closely related to R. orthosporum, but exhibited clear molecular, morphological and host range differences. The species was estimated to have diverged from R. orthosporum ca. 5735 years before the present. The colonisation strategy of all of the different Rhynchosporium species involved extensive hyphal growth in the sub-cuticular regions of the leaves. Finally, new species-specific PCR diagnostic tests were developed that could distinguish between these five closely related Rhynchosporium species.Peer reviewedFinal Published versio
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