Can metabolic control analysis be used to control epidemics?

Lead Research Organisation: University of Liverpool
Department Name: Mathematical Sciences

Abstract

Our recent mathematical modelling has shown that H5N1 avian influenza in the British poultry industry can be controlled more (cost) effectively by targeting duck and goose farms than by more general intervention strategies applied equally to all farms. Indeed, these targeted interventions were shown to mitigate the chance of large outbreaks altogether.

The present research is a feasibility study to develop a general framework for designing targeted interventions to prevent and control epidemics. It is based on recent mathematical developments in the representation of epidemics on networks which enable ideas from systems biology to be applied in this new area. These methods are particularly relevant for epidemics in livestock industries where the structure is often well described by individual farms connected by a contact network of potential infection routes. Current measures for controlling epidemics in these industries often rely on general policies of increased biosecurity, vaccination, culling or movement bans. While these approaches are demonstrably effective, more targeted applications of these methods are likely to be less intrusive to the operation of industry as well as being cheaper to implement.

Epidemics are examples of complex systems where system-wide factors such as their size, likelihood, and control are emergent behaviours resulting result from the interaction of many individual components. In addition to other many other areas, problems concerning the control of complex systems also occur in systems biology where we also wish to alter network functionality by targeted interventions to help us gain understanding and to generate medical and industrial applications. For example, these could be to maximise the generation of a particular chemical for industrial purposes (e.g. ethanol in yeast) or for medical applications (e.g. determining key interventions which will destroy a tumour cell while leaving healthy cells unharmed). That is, we want to achieve the maximum positive effect with the minimum targeted intervention.

In systems biology, a form of control theory known as Metabolic Control Analysis (MCA) is used to determine the impact of specific interventions on living (typically single-cell) organisms. This project will develop related ideas to design targeted interventions to prevent or control epidemics. The application of an MCA-like theory in this context requires some novel mathematical developments but, where possible, its development will be inspired by comparison with MCA.

Targeted intervention to control infection in livestock is clearly of significant importance, not only for the welfare of the animals but also for the economic impact on industry and the wider economy. This analysis could also identify key sites or risk factors for epidemics enabling preventative measures to be put into place such that an epidemic rarely occurs.

A more subtle benefit from this research is to establish a stronger link between the methods used in systems biology and the methods used in epidemiology. Presently these subjects evolve quite independently but have notable methodological similarities. It is expected that this research will contribute to closer links, with ideas developed and implemented in one area inspiring ideas in the other.

Planned Impact

The major societal and economic impacts of this work concern future applications to the design of targeted control strategies for controlling epidemics in livestock. In particular, this will help farmers by controlling epidemics in livestock with potentially less disruption to industry operation. Additionally, minimal a priori interventions suggested by this method could prevent major outbreaks occurring in the first place.

A targeted approach is likely to be more cost effective, saving resources in implementation and equipment. Specific, targeted interventions are also likely to win support from farmers and the public, particularly those aimed at preventing epidemics from taking hold. Its impact is therefore expected to be beneficial to policy makers.
 
Description Developed a new methodology for fragmenting networks so that they are less likely to propagate epidemics.
Investigated applying epidemic methodologies to models of evolution and showed how basic evolutionary models of structures populations could be derived.
The work has also motivated and led to new ways of looking at invasion processes which were subsequently investigated under a Leverhulme award.
Exploitation Route The methods can be used where a network is needed to be altered to make it less likely to propagate dynamics. It can also potentially be adapted to increase robustness to supporting dynamics (e.g. logistics and energy supply).
Sectors Agriculture

Food and Drink

Energy

Environment

Transport

 
Description Invasion in population dynamics
Amount £163,000 (GBP)
Funding ID RPG-2014-341 
Organisation The Leverhulme Trust 
Sector Charity/Non Profit
Country United Kingdom
Start 03/2014 
End 02/2017
 
Description University of Liverpool EPSRC Impact Acceleration Account
Amount £1,000 (GBP)
Organisation Engineering and Physical Sciences Research Council (EPSRC) 
Sector Public
Country United Kingdom
Start 09/2016 
End 12/2016
 
Description University of Liverpool Impact Acceleration Account
Amount £11,876 (GBP)
Organisation Engineering and Physical Sciences Research Council (EPSRC) 
Sector Public
Country United Kingdom
Start 03/2016 
End 01/2017