338 research outputs found

    A Spatial Analysis of Rift Valley Fever Virus Seropositivity in Domestic Ruminants in Tanzania

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    Rift Valley fever (RVF) is an acute arthropod-borne viral zoonotic disease primarily occurring in Africa. Since RVF-like disease was reported in Tanzania in 1930, outbreaks of the disease have been reported mainly from the eastern ecosystem of the Great Rift Valley. This cross-sectional study was carried out to describe the variation in RVF virus (RVFV) seropositivity in domestic ruminants between selected villages in the eastern and western Rift Valley ecosystems in Tanzania, and identify potential risk factors. Three study villages were purposively selected from each of the two Rift Valley ecosystems. Serum samples from randomly selected domestic ruminants (n = 1,435) were tested for the presence of specific immunoglobulin G (IgG) and M (IgM), using RVF enzyme-linked immunosorbent assay methods. Mixed effects logistic regression modelling was used to investigate the association between potential risk factors and RVFV seropositivity. The overall RVFV seroprevalence (n = 1,435) in domestic ruminants was 25.8% and species specific seroprevalence was 29.7%, 27.7% and 22.0% in sheep (n = 148), cattle (n = 756) and goats (n = 531), respectively. The odds of seropositivity were significantly higher in animals sampled from the villages in the eastern than those in the western Rift Valley ecosystem (OR = 1.88, CI: 1.41, 2.51; p<0.001), in animals sampled from villages with soils of good than those with soils of poor water holding capacity (OR = 1.97; 95% CI: 1.58, 3.02; p< 0.001), and in animals which had been introduced than in animals born within the herd (OR = 5.08, CI: 2.74, 9.44; p< 0.001). Compared with animals aged 1-2 years, those aged 3 and 4-5 years had 3.40 (CI: 2.49, 4.64; p< 0.001) and 3.31 (CI: 2.27, 4.82, p< 0.001) times the odds of seropositivity. The findings confirm exposure to RVFV in all the study villages, but with a higher prevalence in the study villages from the eastern Rift Valley ecosystem

    Chemical specificity in REDOX-responsive materials:the diverse effects of different Reactive Oxygen Species (ROS) on polysulfide nanoparticles

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    REDOX responsive (nano)materials typically exhibit chemical changes in response to the presence and concentration of oxidants/reductants. Due to the complexity of biological environments, it is critical to ascertain whether the chemical response may depend on the chemical details of the stimulus, in addition to its REDOX potential, and whether chemically different responses can determine a different overall performance of the material. Here, we have used oxidation-sensitive materials, although these considerations can be extended also to reducible ones. In particular, we have used poly(propylene sulfide) (PPS) nanoparticles coated with a PEGylated emulsifier (Pluronic F127); inter alia, we here present also an improved preparative method. The nanoparticles were exposed to two Reactive Oxygen Species (ROS) typically encountered in inflammatory reactions, hydrogen peroxide (H2O2) and hypochlorite (ClO−); their response was evaluated with a variety of techniques, including diffusion NMR spectroscopy that allowed to separately characterize the chemically different colloidal species produced. The two oxidants triggered a different chemical response: H2O2 converted sulfides to sulfoxides, while ClO− partially oxidized them further to sulfones. The different chemistry correlated to a different material response: H2O2 increased the polarity of the nanoparticles, causing them to swell in water and to release the surface PEGylated emulsifier; the uncoated oxidized particles still exhibited very low toxicity. On the contrary, ClO− rapidly converted the nanoparticles into water-soluble, depolymerized fragments with a significantly higher toxicity. The take-home message is that it is more correct to discuss ‘smart’ materials in terms of an environmentally specific response to (REDOX) stimuli. Far from being a problem, this could open the way to more sophisticated and precisely targeted applications

    Increase of SERS Signal Upon Heating or Exposure to a High-Intensity Laser Field: Benzenethiol on an AgFON Substrate

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    The surface-enhanced Raman scattering (SERS) signal from an AgFON plasmonic substrate, recoated with benzenethiol, was observed to increase by about 100% upon heating for 3.5 min at 100C and 1.5 min at 125C. The signal intensity was found to increase further by about 80% upon a 10 sec exposure to a high-intensity (3.2 kW/cm^2) 785-nm cw laser, corresponding to 40 mW in a 40+/-5-um diameter spot. The observed increase in the SERS signal may be understood by considering the presence of benzenethiol molecules in an intermediate or 'precursor' state in addition to conventionally ordered molecules forming a self-assembled monolayer. The increase in the SERS signal arises from the conversion of the molecules in the precursor state to the chemisorbed state due to thermal and photo-thermal effects.Comment: 9 pages, 4 figures; J. Phys. Chem. C, accepte

    Rhodium nanoparticles for ultraviolet plasmonics

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    The nonoxidizing catalytic noble metal rhodium is introduced for ultraviolet plasmonics. Planar tripods of 8 nm Rh nanoparticles, synthesized by a modified polyol reduction method, have a calculated local surface plasmon resonance near 330 nm. By attaching p-aminothiophenol, local field-enhanced Raman spectra and accelerated photodamage were observed under near-resonant ultraviolet illumination, while charge transfer simultaneously increased fluorescence for up to 13 min. The combined local field enhancement and charge transfer demonstrate essential steps toward plasmonically enhanced ultraviolet photocatalysis.This work has been supported by NSF-ECCS-12-32239. This work was partially supported by the Army’s In-house Laboratory Innovative Research program. Financial support from USAITCA (project no. W911NF-13-1-0245) and MICINN (Spanish Ministry of Science and Innovation, project no. FIS2013- 45854-P) is also acknowledged

    Raman Spectroscopy and Regenerative Medicine: A Review

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    The field of regenerative medicine spans a wide area of the biomedical landscape—from single cell culture in laboratories to human whole-organ transplantation. To ensure that research is transferrable from bench to bedside, it is critical that we are able to assess regenerative processes in cells, tissues, organs and patients at a biochemical level. Regeneration relies on a large number of biological factors, which can be perturbed using conventional bioanalytical techniques. A versatile, non-invasive, non-destructive technique for biochemical analysis would be invaluable for the study of regeneration; and Raman spectroscopy is a potential solution. Raman spectroscopy is an analytical method by which chemical data are obtained through the inelastic scattering of light. Since its discovery in the 1920s, physicists and chemists have used Raman scattering to investigate the chemical composition of a vast range of both liquid and solid materials. However, only in the last two decades has this form of spectroscopy been employed in biomedical research. Particularly relevant to regenerative medicine are recent studies illustrating its ability to characterise and discriminate between healthy and disease states in cells, tissue biopsies and in patients. This review will briefly outline the principles behind Raman spectroscopy and its variants, describe key examples of its applications to biomedicine, and consider areas of regenerative medicine that would benefit from this non-invasive bioanalytical tool

    Evolution, pollination biology, and biogeography of the grape relative Leea (Leeaceae, vitales):

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    Leea D. Royen ex L. is the sole member of the tropical family Leeaceae, which is closely related to the economically important grape family, Vitaceae. Both comprise the order Vitales. In spite of its affinity with the grape family, Leea's molecular systematics has remained unexplored. This study presents the first phylogeny (chapter 1) of Leeaceae using molecular markers to provide an evolutionary framework to understand its taxonomy, morphological evolution (chapter 2), ecology (chapter 3), and biogeography (chapter 4). Ridsdale (1974, 1976) estimated that there are 34 Leea species inhabiting the tropics of Africa and Asia. DNA sequences for the internal transcribed spacer (ITS) and the 5S non-transcribed spacer (NTS) were extracted and amplified from leaf material of 22 species, representing the morphological and geographical diversity of Leea. The ITS secondary structure for the type species, L. aequata L., facilitated homology assessments in ITS sequence alignments, while 5S-NTS data helped resolve terminal relationships. The concatenated matrix was used to estimate the phylogeny and divergence times and generate the topology for ancestral area reconstructions. Area optimization was also performed on the Vitales topology estimated from previously published sequences to locate the geographic origin of Leeaceae, but either an out-of-Asia (i.e. Indochina) or out-of-India origin was inferred possible. The molecular phylogeny recovered four major clades, with the Indian/Indochinese L. asiatica (L.) Ridsdale (clade I) diverging 65.5 mya from the rest of the family. Its primitive trait of free stamens supports its position as the earliest-diverging clade. Clades II, III, and IV form a monophyletic group that had evolved in the Eocene (50.8 mya) in Indochina and/or West Malesia and exhibit the derived feature of fused stamens. Clade II, the spine-bearing species, is sister to Clade III, whose species have large flowers. Clade IV, which is unique in having multi-pinnate leaves and small stipules, evolved by the end of the Oligocene (25.6 mya) and comprise the polyphyletic 'species' (sensu Ridsdale) L. guineensis G. Don and L. indica (Burm. f.) Merr. nested among other morphologically discernible species. The radiation of Leea species mostly occurred in the Neogene (1.8-23.0 mya) during a time of dynamic geological and environmental changes in Southeast Asia. Africa and Australia were also colonized by Neogene dispersals of Asian Leea. Current species circumscriptions of L. guineensis and L. indica underestimate the genetic diversity of the genus and need to be revised. An updated checklist of 47 species reflecting clades recovered by the molecular phylogeny is presented including resurrected and putative new species. Field studies of three sympatric Philippine Leea morphospecies have revealed that habit and ecology must be considered in species circumscriptions.Ph.D.Includes bibliographical references (p. 95-107)by Jeanmaire E. Molin
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