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Electrochemical sensor for monitoring levels of oxygen and nitrogen reactive species to benefit ageing research

ReferenceBB/K013807/1
Principal Investigator / Supervisor Professor Bhavik Patel
Co-Investigators /
Co-Supervisors		 Professor Richard Faragher, Dr Mark Yeoman
Institution University of Brighton
DepartmentSch of Pharmacy & Biomolecular Sciences
Funding typeResearch
Value (£) 94,436
StatusCompleted
TypeResearch Grant
Start date 23/09/2013
End date 22/09/2014
Duration12 months

Abstract

This proposal is aimed at developing a radical new approach for the fabrication of carbon based microelectrodes. Such electrodes can be made, where the electrode size can be modified to any specific size, and also allows for the means to create rigid or flexible devices based on the application. This will be used alongside a novel microelectrode array (MEA) that will be fabricated using boron-doped diamond. Both the microelectrodes and MEA will be modified to allow for dynamic detection of various reactive oxygen and nitrogen species (ROS/RNS). ROS/RNS were chosen as the analyte to modify this sensor as they have been implicated in the ageing process. These sensors will be aimed initially towards bioscience researchers focusing on understanding the process of ageing. The MEA and microelectrode will be assessed on two specific applications. The ROS/RNS microelectrode will be from both division competent and senescent cells, whilst the MEA will be used to simultaneously record levels of various ROS/RNS from anatomical regions of an isolated neurone. Most important, the working of the sensor will be disseminated to researchers working on ageing through a hands-on workshop, which will provide scientists will information on how the microelectrode works and the level of information they can obtain from this.

Summary

This proposal is focused on the development of a novel microelectrode that can be tailored for any specific chemical post biological and chemical modification. These microelectrodes will be made using carbon nanotube composite material, which allows the means to have a varied electrode area. These sensors can be made using two different strategies, where they can be held in either glass capillaries or plastic pipettes, allowing for sensors to be rigid or flexible. This is a rapid improvement compared to conventionally made carbon based electrodes. These sensors will be modified for the detection of various reactive oxygen and nitrogen species (ROS/RNS). These chemicals are of specific interest as they play key biological roles. They have been implicated in the ageing process and are the basis of many theories associated with the ageing process. At present, only total ROS/RNS have been detected with current technology, as the fluorescent dyes that are used offer poor specificity. This device will be made to benefit researchers working on ageing and is anticipated to increase the impact of these studies. Measurements will be made using microelectrode arrays, which will be fabricated using boron-doped diamond. These microelectrode arrays will be modified for detection of ROS/RNS. Our microelectrodes are advantageous as they allow simultaneous measurements of ROS/RNS over various locations. The ROS/RNS microelectrode and MEAs will be tested on two applications associated with ageing. The first will be to characterise the changes in ROS/RNS levels over various regions of old and young isolated neurones. The second application will be to look at ROS/RNS changes in cell lines that enter senescence. Measurements will be carried out in comparison with fluorescent dyes. Finally to allow access to this new sensor technology for bioscience researchers, we will host a workshop that will allow scientist to learn about how the sensor functions and how it can be utilised for monitoring ROS/RNS levels from biological samples. Overall this new sensing strategy will provide impact to studies associated with ageing, but with the main electrode having the ability to be modified for any specific analyte, the long-term benefits can be for various sectors and fields of importance. It is envisioned that this microelectrode can be tailored for detection of key analytes for major priority areas such as food security, understanding animal physiology and healthy ageing.

Impact Summary

We anticipate that the results of this work will have important impact for several groups including the public health sector, commercial sector and the third sector. We will engage in a range of activities to maximise the impact of our research in these groups in the following ways: The Public Health Sector: The developed device will have limited impact to the public health sector for the duration of the proposal. However the device will be aimed initially toward a major area of research, which is the ageing population. In the short to medium term, the device will provide impact on ageing research studies and thus will provide vital insight on the ageing process. It is anticipated in the long-term that these studies will yield new knowledge that can direct better pharmacological interventions. These developments will have a great impact on the public healthcare service, as the ageing population is anticipated to have a great economic impact on the healthcare service. The Commercial Private Sector: The sensor developed in the proposed study encompasses new strategies for the fabrication of microelectrodes. Thus the device itself and components of the device may need to be protected. Intellectual property (IP) arising from this project will be protected and exploited by the University of Brighton Business Development and Enterprise Department. The University is well networked with industry and has a history of cooperation with the Pharmaceutical and Biotech Industries. We will be working closely with partners from these sectors to maximise the economic and social impact of this project. Initially in the short term we will provide a range of sensors for bioscience researchers who have already expressed an interest in our work. This device will be made available for scientists not only working in ageing research but for researchers with an interest in monitoring analytes in a wide range of disciplines. Other sensors have been developed within the group for a gastrointestinal researcher, so we have a trac record for providing electrochemical devices for bioscience researchers. To increase the outreach of our device, we will work alongside industrial links, which have a track record for the robust production of the sensor devices. Third Sector: We will endeavour to disseminate our work within relevant third sector organisations (Age UK). RGF is on the Board of Governors for the local Age UK group, and thus will be able to disseminate our findings. General Public. The PI and CoIs have already been actively engaged in presenting research to the public and will continue to do so with regards to the findings from the proposed project. MSY has previously given public lectures to Age (UK), and his work has been widely publicised via both the local (Argus) and national press (e.g. Times Higher Supplement). His recent work has also been published on both national (South Today) and international (Normandy) television. In addition MSY and BAP have compiled a short film on their research, which is available through YouTube and the University of Brighton's website. BAP is an active STEM Ambassador and would use this role to highlight the proposed research.
Committee Research Committee A (Animal disease, health and welfare)
Research TopicsTechnology and Methods Development
Research PriorityX – Research Priority information not available
Research Initiative Tools and Resources Development Fund (TRDF) [2006-2015]
Funding SchemeX – not Funded via a specific Funding Scheme
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