Ross Jaggers invited to participate in the Stonewall Young Leaders Programme

Ross Jaggers, a second year PhD student in the research group of prof.dr.ir. Stefan Bon (BonLab) in the Department of Chemistry at the University of Warwick, has been invited to attend the Stonewall Young Leaders Programme in London this coming September. The programme, sponsored by Bank of America Merrill Lynch, explores how sexual orientation and gender identity relates to the workplace and career aspirations, as well as inspiring participants to think about their impact on others as young LGBT leaders and role models.

Ross Jaggers

Ross Jaggers

 

For more information on Stonewall, the UK’s leading LGBT rights charity, visit www.stonewall.org.uk.

 

Control of vesicle membrane permeability with catalytic particles

Control of vesicle membrane permeability with catalytic particles

The ability to control membrane permeability in vesicles allows for regulated transport of matter across the vesicular wall. Vesicles can be seen as microscopic sacs containing a compartmentalized volume of liquid dispersed in a bulk liquid environment. Compartmentalization of small and finite volumes of liquid and consecutive the emergence of membrane bioenergetics are identified as being of key importance in the evolution of cells, and hence the origin of life. Nature has devised sophisticated strategies to accomplish control of transmembrane transport, including endo- and exocytosis as well as the incorporation of transmembrane proteins into cell membranes. A variety of synthetic approaches have been explored by scientists in order to accomplish such control in manmade systems. Examples include hybrid systems whereby transmembrane proteins were incorporated as part of synthetic vesicles, and the use of responsive macromolecular building blocks to regulate membrane porosity upon an external trigger in polymer vesicles, also referred to as polymersomes.

A Mechanistic Insight into the Synthesis of Silica-Based “Matchstick” Colloids

A Mechanistic Insight into the Synthesis of Silica-Based “Matchstick” Colloids

In the field of colloid science the ability to fabricate particles with a defined shape, other than a sphere, has gained attention. The reason is that anisotropy in shape and/or chemical composition can lead to interesting physical properties when these particles are dispersed in a liquid, or when they form part of a product formulation. We report an insight into the synthesis of silica-based “matchstick”-shaped colloidal particles, which are of interest in the area of self-propulsion on small length scales. The generation of aqueous emulsion droplets dispersed in an n-pentanol-rich continuous phase and their use as reaction centers allows for the fabrication of siliceous microparticles that exhibit anisotropy in both particle morphology, that is, a “matchstick” shape, and chemistry, that is, a transition-metal oxide-enriched head. We provide a series of kinetic studies to gain a mechanistic understanding and unravel the particle formation and growth processes. Additionally, we demonstrate the ability to select the aspect ratio of the “matchstick” particle in a straightforward manner.

The paper is recently published in Langmuir. DOI:10.1021/acs.langmuir.5b02645