Discursive Overlap and Conflictive Fragmentation of Risk and Security in the Geopolitics of Energy

As it touches all aspects of human activity and society in general, energy has become an object of discourse. Two main discourses have formed on the use of energy: risk discourse and security discourse. While environmental changes and oil depletion continue, a new application for the term security has appeared: energy security. This concept can be interpreted within the terms of risk discourse, which is oriented towards rational consensus and decision making, or as an exercise of power, sovereignty and hegemony. The boundaries between interpretations are often unclear. Thus, in an institutional framework that has fragmented principles, norms and rules, opposing discourses will overlap. Political agents and institutions deploy strategies based on these discourses. With this overlapping of discourses, the performative powers of different institutions clash, thus creating conflictive fragmentation in a governance architecture. The purpose of this investigation is to analyze the use of, replication of, and ambiguities surrounding the concept of energy security, so as to understand how and why these discourses overlap and the profound consequences that this overlap may have for present and future energy use, environmental negotiations, and political climate

Development of an antimicrobial and antioxidant hydrogel/nano-electrospun wound dressing

A nanocomposite based on an antibiotic-loaded hydrogel into a nano-electrospun fibre with antimicrobial and antioxidant capacities is investigated. The material is composed of nanofibres of enzymatic PCL grafted with poly(gallic acid) (PGAL), a recently developed enzyme-mediated hydrophilic polymer that features a multiradical and polyanionic nature in a helicoidal secondary structure. An extensive experimental–theoretical study on the molecular structure and morphological characterizations for this nanocomposite are discussed. The hydrogel network is formed by sodium carboxymethylcellulose (CMC) loaded with the broad-spectrum antibiotic clindamycin. This nano electrospun biomaterial inhibits a strain of Staphylococcus aureus, which is the main cause of nosocomial infections. The SPTT assay demonstrates that PGAL side chains also improve the release rates for this bactericide owing to the crosslinking to the CMC hydrogel matrix. The absence of hemolytic activity and the viability of epithelial cells demonstrates that this nanocomposite has no cytotoxicity.Postprint (published version