A latent growth curve model to estimate electronic screen use patterns amongst adolescents aged 10 to 17 years

Background: High quality, longitudinal data describing young people's screen use across a number of distinct forms of screen activity is missing from the literature. This study tracked multiple screen use activities (passive screen use, gaming, social networking, web searching) amongst 10- to 17-year-old adolescents across 24 months. Methods: This study tracked the screen use of 1948 Australian students in Grade 5 (n = 636), Grade 7 (n = 672), and Grade 9 (n = 640) for 24 months. At approximately six-month intervals, students reported their total screen time as well as time spent on social networking, passive screen use, gaming, and web use. Patterns of screen use were determined using latent growth curve modelling. Results: In the Grades 7 and 9 cohorts, girls generally reported more screen use than boys (by approximately one hour a day), though all cohorts of boys reported more gaming. The different forms of screen use were remarkably stable, though specific cohorts showed change for certain forms of screen activity. Conclusion: These results highlight the diverse nature of adolescent screen use and emphasise the need to consider both grade and sex in future research and policy

Green Synthesis of Carbon Nanoparticles (CNPs) from Biomass for Biomedical Applications

In this review, we summarize recent work on the “green synthesis” of carbon nanoparticles (CNPs) and their application with a focus on biomedical applications. Recent developments in the green synthesis of carbon nanoparticles, from renewable precursors and their application for environmental, energy-storage and medicinal applications are discussed. CNPs, especially carbon nanotubes (CNTs), carbon quantum dots (CQDs) and graphene, have demonstrated utility as high-density energy storage media, environmental remediation materials and in biomedical applications. Conventional fabrication of CNPs can entail the use of toxic catalysts; therefore, we discuss low-toxicity manufacturing as well as sustainable and environmentally friendly methodology with a focus on utilizing readily available biomass as the precursor for generating CNPs

Polysaccharides from New Zealand Native Plants: A Review of Their Structure, Properties, and Potential Applications

Water-soluble, non-starch polysaccharides from plants are used commercially in a wide range of food and non-food applications. The increasing range of applications for natural polysaccharides means that there is growing demand for plant-derived polysaccharides with different functionalities. The geographical isolation of New Zealand and its unique flora presents opportunities to discover new polysaccharides with novel properties for a range of applications. This review brings together data published since the year 2000 on the composition and structure of exudate gums, mucilages, and storage polysaccharides extracted from New Zealand endemic land plants. The structures and properties of these polysaccharides are compared with the structures of similar polysaccharides from other plants. The current commercial use of these polysaccharides is reviewed and their potential for further exploitation discussed

Retention of the structure and function of heparan sulfate biomaterials after gamma irradiation

Heparan sulfate (HS) is a highly heterogeneous polysaccharide implicated in many important biological processes. Our previous work has demonstrated that a particular affinity-selected HS (referred to henceforth as “HS3”) is capable of enhancing the osteogenic effects of bone morphogenetic protein 2 (BMP2). Here, we gamma-irradiated HS with 26 kGy of ionizing radiation to determine how this affected the structure, composition, and function. Initial structural studies were performed on a commercial preparation of HS as a proof-of-concept. Gamma irradiation of this HS preparation did not significantly alter its structure or composition compared to nonirradiated material, as demonstrated by proton nuclear magnetic resonance spectroscopy, molecular weight analysis using size exclusion chromatography, and disaccharide compositional analysis. When HS3 was gamma irradiated, no significant effect on binding affinity toward BMP2 was observed, based on competitive surface plasmon resonance and differential scanning fluorimetry assays. Furthermore, irradiation did not significantly affect HS3's ability to synergistically enhance the osteogenic effects of BMP2 in vitro; as measured by the relative abundance of osteogenic transcripts in transdifferentiating C2C12 murine myoblasts. Additionally, no significant differences were observed in the levels of alkaline phosphatase (ALP) or calcium deposition in C2C12s treated with BMP2, together with the irradiated, or nonirradiated HS3. Irradiation of HS3 incorporated into collagen type I sponges did not affect its ability to enhance BMP2-mediated ALP expression in C2C12 cells. Our data confirm that gamma irradiation is a cost-effective and viable solution for the sterilization of HS species that allows the retention of its structure and biological function. The work suggests an effective way to incorporate clinically compatible HS species into orthotic implants, scaffolds, and other medical devices for use in the treatment of a range of diseases and disorders.ASTAR (Agency for Sci., Tech. and Research, S’pore

Cellulose as a Source of Water Dispersible Renewable Film-Forming Materials

Cellulose is found to be a good source of waterborne film-forming materials when modified with the correct type and level of functional groups. The modification of cellulose to incorporate high levels of levulinic functionality and other C₂–C₆ alkyl esters is reported for the first time. The levulinyl-functionalized cellulose is readily modified to produce oxime or acylhydrazone derivatives, which is particularly useful to fine-tune the physical characteristics of the cellulose ester. This includes the glass transition temperature of the cellulose esters, their ability to produce fine uniform colloidal particles in aqueous media and ultimately provide the principle film-forming component of an architectural coating. The process has been demonstrated at the 500 g level suggesting ready scalability. Lewis acids and Lewis acid-assisted Brønsted acids are employed for the first time in such chemistry, and together with sulfur-based Brønsted acids are all found to be effective catalysts for the esterification of cellulose to produce mixed ester systems. The Lewis acid catalysts demonstrate exceptional activity and produce high molecular weight cellulose derivatives

Neptune long-lived atmospheric features in 2013–2015 from small (28-cm) to large (10-m) telescopes

International audienc