‘Ethical’, but Gender-Biased?

The migration of healthcare professionals from developing to developed countries, often aided by recruitment agencies, is a phenomenon of great international concern, as reflected in the construction of numerous ethical recruitment codes, which aim to govern the process. In an attempt to provide an overview of the situation, dealing specifically with the migration of nurses, as well as a critical and gender sensitive analysis of the codes, this paper follows three broad steps: first, it reviews the literature dedicated to the migration of nurses from developing to developed countries, adding a gendered account to more conventional push-pull explanations; second, it delineates the positive and negative effects that nurse migration has at the stakeholders levels of the individual, institutional, national and international level, paying particular attention to the role of gender; and third, it reviews and compares numerous codes for the ethical recruitment of nurses, highlighting the gendered rationale and consequences they may have. In showing that nurse migration is a gendered phenomenon, the paper questions whether the codes, written in gender neutral language, will come to bear unintended consequences that will effectively work to uphold gender stereotypes and inequalities.

Vesicle motion during sustained exocytosis in chromaffin cells

Chromaffin cells release catecholamines by exocytosis, a process that includes vesicle docking, priming and fusion. Although all these steps have been intensively studied, some aspects of their mechanisms, particularly those regarding vesicle transport to the active sites situated at the membrane, are still unclear. In this work, we show that it is possible to extract information on vesicle motion in Chromaffin cells from the combination of Langevin simulations and amperometric measurements. We developed a numerical model based on Langevin simulations of vesicle motion towards the cell membrane and on the statistical analysis of vesicle arrival times. We also performed amperometric experiments in bovine-adrenal Chromaffin cells under Ba2+ stimulation to capture neurotransmitter releases during sustained exocytosis. In the sustained phase, each amperometric peak can be related to a single release from a new vesicle arriving at the active site. The amperometric signal can then be mapped into a spike-series of release events. We normalized the spike-series resulting from the current peaks using a time-rescaling transformation, thus making signals coming from different cells comparable. We discuss why the obtained spike-series may contain information about the motion of all vesicles leading to release of catecholamines. We show that the release statistics in our experiments considerably deviate from Poisson processes. Moreover, the interspike-time probability is reasonably well described by two-parameter gamma distributions. In order to interpret this result we computed the vesicles’ arrival statistics from our Langevin simulations. As expected, assuming purely diffusive vesicle motion we obtain Poisson statistics. However, if we assume that all vesicles are guided toward the membrane by an attractive harmonic potential, simulations also lead to gamma distributions of the interspike-time probability, in remarkably good agreement with experiment. We also show that including the fusion-time statistics in our model does not produce any significant changes on the results. These findings indicate that the motion of the whole ensemble of vesicles towards the membrane is directed and reflected in the amperometric signals. Our results confirm the conclusions of previous imaging studies performed on single vesicles that vesicles’ motion underneath plasma membranes is not purely random, but biased towards the membrane.