The physiological effects of plastic ingestion

Since the onset of mass production of plastics in the 1950’s the flux of plastics to the marine environment has been a growing problem (Cole at al., 2011), such that microplastic contamination of the oceans is now one of the world’s most pressing environmental concerns (Hurley et al., 2018). Recent work highlights how such materials have been found in the full range of ocean environments from the depths of the deepest ocean trenches (Woodall et al., 2014; Fischer et al., 2015; Frid and Caswell 2017)) to coastal seas around the ice-capped poles (Waller et al., 2017; Lusher et al., 2015, Obbard et al., 2014).

Microplastic pollution is known to be interacting with organisms and entering primary levels of the marine food chain (Cole et al., 2013) causing a range of unidentified and unquantified ecological outcomes. Critically, we have little understanding of the complex biological, bio-physical and bio-chemical interactions associated with the ingestion of microplastics and how this influences their fate and the fate of marine ecosystems. Significant research is therefore needed to address some of the critical gaps in our knowledge of microplastics in the marine environment. This will be achieved by a cluster of 6 PhDs investigating the physical processes and dynamics of plastic particles from fluvial source zones, through estuarine stores to marine sinks, the ecological impacts on remote and local environments and the ecophysiological and ecotoxicological effects on individual species and ecosystems.

The cluster objectives are:
[1] To quantify ecological and biological effects of microplastics on marine ecosystems and marine invertebrate physiology (1-2; 5-6).
[2] Determine the flux, types and concentrations of micro-plastic debris exiting major riverine and estuarine systems, into the coastal and wider ocean (projects 3-4).

Summary of PhD Project
The physiological effects of plastic ingestion
Supervised by Dr Jorg D Hartege, Dr Katharina Wollenberg Valero (University of Hull) & Dr Simon Morley (British Antarctic Survey)

Understanding the physiological impacts of plastic ingestion is key to understanding the level of threat they pose to aquatic animals. Ingestion of plastics is expected to affect organism physiology through direct negative physical or chemical consequences and by reducing energy intake, which will lower physiological condition and may make them more susceptible to environmental challenge.

This project will test the impacts of plastics on energy budgets, reproduction and escape response. Key taxonomic groups (molluscs and crustaceans) will be studied across latitudinal gradients from the Southern Ocean to temperate regions. We will experimentally manipulate and monitor these animals to understand whether polar species show similar responses to tropical and temperate species.

The student may have the opportunity to undertake work at the British Antarctic Survey Rothera Research Station and BAS HQ in Cambridge.

Applicants should have a 1st class undergraduate degree or Masters level research qualification in a relevant discipline. A 2:1 may be considered, if combined with relevant experience. It is anticipated that the successful applicant will have a 1st class undergraduate degree or Masters level qualification. Additionally, experience of working in the field and knowledge of marine ecosystems would be beneficial.

To apply for these Scholarships please click on the link below:
https://www.hull.ac.uk/choose-hull/study-at-hull/admissions/postgraduate/how-to-apply.aspx

PhD students at the University of Hull follow modules for research and transferable skills development and gain a Masters level Certificate, or Diploma, in Research Training, in addition to their research degree.

Successful applicants will be informed of the award as soon as possible and by 15th March 2019 at the latest.