Magnesium sulphate for treating acute bronchiolitis in children up to two years of age

Background: Acute bronchiolitis is a significant burden on children, their families and healthcare facilities. It mostly affects children younger than two years of age. Treatment involves adequate hydration, humidified oxygen supplementation, and nebulisation of medications, such as salbutamol, epinephrine, and hypertonic saline. The effectiveness of magnesium sulphate for acute bronchiolitis is unclear. Objectives: To assess the effects of magnesium sulphate in acute bronchiolitis in children up to two years of age. Search methods: We searched CENTRAL, MEDLINE, Embase, LILACS, CINAHL, and two trials registries to 30 April 2020. We contacted trial authors to identify additional studies. We searched conference proceedings and reference lists of retrieved articles. Unpublished and published studies were eligible for inclusion. Selection criteria: Randomised controlled trials (RCTs) and quasi‐RCTs, comparing magnesium sulphate, alone or with another treatment, with placebo or another treatment, in children up to two years old with acute bronchiolitis. Primary outcomes were time to recovery, mortality, and adverse events. Secondary outcomes were duration of hospital stay, clinical severity score at 0 to 24 hours and 25 to 48 hours after treatment, pulmonary function test, hospital readmission within 30 days, duration of mechanical ventilation, and duration of intensive care unit stay. Data collection and analysis: We used standard methodological procedures expected by Cochrane. We used GRADE methods to assess the certainty of the evidence

Phenotypic characterisation of Saccharomyces spp. yeast for tolerance to stresses encountered during fermentation of lignocellulosic residues to produce bioethanol.

BACKGROUND: During industrial fermentation of lignocellulose residues to produce bioethanol, microorganisms are exposed to a number of factors that influence productivity. These include inhibitory compounds produced by the pre-treatment processes required to release constituent carbohydrates from biomass feed-stocks and during fermentation, exposure of the organisms to stressful conditions. In addition, for lignocellulosic bioethanol production, conversion of both pentose and hexose sugars is a pre-requisite for fermentative organisms for efficient and complete conversion. All these factors are important to maximise industrial efficiency, productivity and profit margins in order to make second-generation bioethanol an economically viable alternative to fossil fuels for future transport needs. RESULTS: The aim of the current study was to assess Saccharomyces yeasts for their capacity to tolerate osmotic, temperature and ethanol stresses and inhibitors that might typically be released during steam explosion of wheat straw. Phenotypic microarray analysis was used to measure tolerance as a function of growth and metabolic activity. Saccharomyces strains analysed in this study displayed natural variation to each stress condition common in bioethanol fermentations. In addition, many strains displayed tolerance to more than one stress, such as inhibitor tolerance combined with fermentation stresses. CONCLUSIONS: Our results suggest that this study could identify a potential candidate strain or strains for efficient second generation bioethanol production. Knowledge of the Saccharomyces spp. strains grown in these conditions will aid the development of breeding programmes in order to generate more efficient strains for industrial fermentations

The genetic basis of variation in clean lineages of Saccharomyces cerevisiae in response to stresses encountered during bioethanol fermentations.

Saccharomyces cerevisiae is the micro-organism of choice for the conversion of monomeric sugars into bioethanol. Industrial bioethanol fermentations are intrinsically stressful environments for yeast and the adaptive protective response varies between strain backgrounds. With the aim of identifying quantitative trait loci (QTL's) that regulate phenotypic variation, linkage analysis on six F1 crosses from four highly divergent clean lineages of S. cerevisiae was performed. Segregants from each cross were assessed for tolerance to a range of stresses encountered during industrial bioethanol fermentations. Tolerance levels within populations of F1 segregants to stress conditions differed and displayed transgressive variation. Linkage analysis resulted in the identification of QTL's for tolerance to weak acid and osmotic stress. We tested candidate genes within loci identified by QTL using reciprocal hemizygosity analysis to ascertain their contribution to the observed phenotypic variation; this approach validated a gene (COX20) for weak acid stress and a gene (RCK2) for osmotic stress. Hemizygous transformants with a sensitive phenotype carried a COX20 allele from a weak acid sensitive parent with an alteration in its protein coding compared with other S. cerevisiae strains. RCK2 alleles reveal peptide differences between parental strains and the importance of these changes is currently being ascertained

Tribological behavior of multiphase polymeric system

Multiphase polymeric systems have numerous applications in engineering, structural and durable goods applications. Characterization of the physical, mechanical and tribological properties is crucial for fundamental understanding of the multiphase polymeric systems. Tribological properties of multiphase polymeric systems can be determined by employing the scratch test. However, understanding the scratch behavior of multiphase polymeric systems is difficult compared to single phase polymeric systems. In-depth understanding of the damage mechanisms and localized deformation because of interaction between the matrix and micro-/nano-sized fillers is needed for that purpose. As such, relationship between the surface deformation and damages, and bulk mechanical properties in multiphase polymeric systems is not straightforward. Effects of filler/particle type, filler size, concentration, and annealing on the scratch behavior of multiphase polymeric system have been investigated in this study. A three-dimensional finite element method (FEM) modeling has been carried out to explain the mechanics behind the evolution of scratch-induced surface deformation and damage mechanisms. The results show that inclusion of hard and soft fillers with increasing filler content and filler size drastically affects the stress and strain field development during the scratching process. Additionally, particle distribution influenced by annealing shows significant effect on scratch behavior of multiphase polymeric system

Inferior vena cava thrombosis in a case of amoebic liver abscess: Is hypercomplementemia responsible for this rare entity?

Among the liver abscesses, thrombosis of the inferior vena cava (IVC) has been reported mainly in amoebic liver abscess (ALA) caused by Entamoeba histolytica (E.H). It is an unusual complication especially in paediatric age group. Association of hypercomplementemia and IVC thrombosis has not been discussed previously. Published data suggest that E.H can activate the complement system and can cause hypercomplementemia. A very few studies suggest that complement activation and hypercomplementemia are associated with thrombus formation. We describe a paediatric case of ALA complicated by IVC thrombosis extending to the right atrium and discuss the possible role of hypercomplementemia in causation of IVC thrombosis in cases of ALA

The genetic basis of variation in clean lineages of Saccharomyces cerevisiae in response to stresses encountered during bioethanol fermentations.

Saccharomyces cerevisiae is the micro-organism of choice for the conversion of monomeric sugars into bioethanol. Industrial bioethanol fermentations are intrinsically stressful environments for yeast and the adaptive protective response varies between strain backgrounds. With the aim of identifying quantitative trait loci (QTL's) that regulate phenotypic variation, linkage analysis on six F1 crosses from four highly divergent clean lineages of S. cerevisiae was performed. Segregants from each cross were assessed for tolerance to a range of stresses encountered during industrial bioethanol fermentations. Tolerance levels within populations of F1 segregants to stress conditions differed and displayed transgressive variation. Linkage analysis resulted in the identification of QTL's for tolerance to weak acid and osmotic stress. We tested candidate genes within loci identified by QTL using reciprocal hemizygosity analysis to ascertain their contribution to the observed phenotypic variation; this approach validated a gene (COX20) for weak acid stress and a gene (RCK2) for osmotic stress. Hemizygous transformants with a sensitive phenotype carried a COX20 allele from a weak acid sensitive parent with an alteration in its protein coding compared with other S. cerevisiae strains. RCK2 alleles reveal peptide differences between parental strains and the importance of these changes is currently being ascertained