Observed

Odour Based Selective Recognition of Veterinary Diseases 

Funding: NWA-ORC
Project duration:

Many (veterinary) conditions and infections are accompanied by the emission of Volatile Organic Compounds (VOCs) in a specific composition, as confirmed by veterinarians who can smell the wide-spread presence of disease in a stable. Detection of this VOC mixture in very low concentrations (ppb) in an early stage of a health disruption, or when only few animals are affected, makes applying interventions possible to prevent the spread of diseases among animals. Tools to predict or prevent diseases are a breakthrough innovation, addressing socio-economic demands for sustainable animal production, without antibiotics and minimal environmental impact. The challenge is therefore, to have healthy livestock production chains under conditions that prevent development of disease and health problems without systematic use of antibiotics and with minimal influence on food safety. Currently, no sensing device exist that have sufficient sensitivity and selectivity and can enable this in an economic way. 

To this end, the realization of a versatile, cheap, small, low-power and yet very sensitive system that can identify odours is needed. Existing sensor systems, such as e-nose equipment make use of insufficiently sensitive macroscopic metal-oxide sensing elements that require high power and take up large volumes. Therefore, the applicants have taken up the challenge to develop a smart, low-cost and low-power, very sensitive VOC detection system based on electronic nose principles for early veterinary disease detection. Such a system would consist of a sensor platform, based on micro- or nanotechnology for making it sufficiently sensitive and scalable, coated with affinity layers. Because the affinity layers cannot be made 100% specific for a given VOC, the readout of n sensor array, each coated with a different layer, will have to be processed to yield a fingerprint of the composition of the mixture. Such a development requires solving numerous scientific as well as technical challenges. 

In the project various aspects will be studied: the relation between emission of VOCs and a specific health disruption, the edvelopment of sensor platforms, capture layers for the specific volatile species, and the data processing schemes require for pattern recognition, as well as studies into the most effective ways to apply the technology and obtain a major societal impact. 

Currently involved scientific partners: Saxion University of Applied Sciences, Utrecht University, Wageningen University & Research, Delft University of Technology, University of Twente, Fontys University of Applied Sciences, Radboud University, The Hague University of Applied Sciences. 

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