A Comparison of Peripherally Inserted Central Catheter Materials.

Background: New catheter materials for peripherally inserted central catheters (PICCs) may reduce the risk of device failure due to infectious, thrombotic, and catheter occlusion events. However, data from randomized trials comparing these catheters are lacking.

Methods: We conducted a randomized, controlled, superiority trial in three Australian tertiary hospitals.

Fungi as environmental bioindicators.

Environmental bioindicators are species or communities of animals, plants, bacteria, fungi, algae, lichens, and planktons whose existence, quantity, and nature can be used to make inferences on the quality of the environment. Bioindicators can be used to detect environmental contaminants by on-site visual inspections or through laboratory analysis. Fungi are one of the most important groups of environmental bioindicators due to their ubiquitous distribution, diverse ecological roles, remarkable biological diversity, and high sensitivity to environmental changes.

Peripherally Inserted Central catheter iNnovation to reduce Infections and Clots (the PICNIC trial): a randomised controlled trial protocol.

Introduction: Peripherally inserted central catheters (PICCs) are vital for the delivery of medical therapies, but up to 30% of PICCs are associated with complications such as deep vein thrombosis or infection. The integration of antimicrobial and hydrophobic catheter materials, and pressure-activated valves, into polyurethane PICCs are innovations designed to prevent infective and/or thrombotic complications.

Methods And Analysis: A multicentre, parallel group, superiority randomised controlled trial with two experimental arms ((1) hydrophobic PICC (with pressure-activated valve); (2) chlorhexidine gluconate-impregnated PICC (with external clamp)) and one control group ((3) conventional polyurethane PICC (with external clamp)).

Abiotic hydroxylamine nitrification involving manganese- and iron-bearing minerals.

Hydroxylamine (NHOH) undergoes biotic and abiotic transformation processes in soil, producing nitrous oxide gas (NO(g)). Little is known about the magnitude of the abiotic chemical processes in the global N cycle, and the role of abiotic nitrification is still neglected in most current nitrogen trace gas studies. The abiotic fate of NHOH in soil systems is often focused on transition metals including manganese (Mn) and iron (Fe), and empirical correlations of nitrogen residual species including nitrite (NO), nitrate (NO), and NO(g).