A European research team is developing a photonic-ultrasound-based detector that will save water companies from closure in the wake of tough new drinking-water regulations, soon to be implemented by the WHO, providing the quickest ever safety diagnosis for deadly bacteria.
New high standards being set out for achieving safe drinking-water, where zero traces of bacteria should be present in a sample of just 100 ml, state future operators should adopt vigilant and proactive monitoring of drinking-water to assure microbiological safety at all times.
Despite high compliance monitoring from water companies across Europe, deadly disease outbreaks are a common occurrence, according to the 2017 World Health Organisation (WHO) report.
Monitoring three of the most deadly bacteria - E Coli, Salmonella and Pseudomonas Aeruginosa – in drinking water can take 3 days, with results usually delivered after an exposure has occurred.
Since the concentration of contaminants can be very low, this deadly trio are often hard to detect.
The current process involves water samples being taken and sent to a remote laboratory, and with bacteria traces often so small, a period of 24 hours is needed to allow the pathogens to cultivate.
However, a Photonics PPP Horizon 2020-funded water-safety project ‘WaterSpy’ has come up with a solution: a portable laser-based, water quality analyser employed at critical points on a water distribution network that provides a reading in a matter of hours rather than days.
With its prototype ready, the WaterSpy team will take their device to be tested in two sites in Genova: the Prato Water Treatment Plant, and the entry point of the Genova water distribution network.
“Most water companies,” Alessandro Giusti, (PhD) manager within the coordinating organisation explains, “will struggle to meet these new strict laws if they simply carry on as they are right now. Current technologies for bacterial diagnosis are very slow and some of the faster ones are still not precise enough. So, new technologies, such as WaterSpy are needed.”
Using the latest photonics technology, the device - a novel laser configuration combined with new photodetectors and ultrasound particle manipulation- is suitable for inline, field measurements.
“Although the water that comes out of your tap is safe before it gets to you, water utilities, public authorities and regulators rely heavily on frequent sampling and laboratory analysis. This is both time-consuming and expensive. WaterSpy intends to speed this up, make huge savings and provide real-time critical data.”
“The speed of our device is unprecedented: a full sample analysis will take up to 6 hours to complete so comparing this to the 2-3 days it takes with existing methods, we expect results 12 times faster than the current standard. WaterSpy is relatively cheap and will adhere to incoming regulatory requirements in terms of specificity and sensitivity levels. ”
Light Sound Combination
It works by first gathering the small traces bacteria, and then detecting them with a laser.
“Unfortunately”, Giusti said, “water itself is a very strong absorber of infrared light and special techniques have to be applied.”
In the same way that sand resonates in gathered patterns on top of a ceramic tile when a sound wave is applied, ultrasound is used to congregate the bacteria in the water sample in order to enhance the detection and sensitivity.
The WaterSpy device then detects the bacteria by exploiting a measurement technique called Attenuated Total Reflection (ATR), enabling a sample to be examined directly in the liquid state.
Beams of infrared light are sent into a diamond over which the water flows. The IR light then reflects off the internal surface in contact with the water sample, before being collected by a detector as it exits the crystal.
Coordinated by CyRIC, Cyprus Research and Innovation Center Ltd the WATERSPY consortium secured a grant of €3, 049, 206.74 from the European Commission under the H2020 funding program.
Waterspy is comprised of 9 partners with participants from 7 different European countries: (Italy) Consiglio Nazionale Delle Ricerche; IREN SPA; (Switzerland) Alpes Lasers SA; (Greece) National Technical University of Athens; A.U.G Signals Hellas Technology Developments and Applications; (Austria) Technische Universitaet Wien; (Poland) Vigo Systems SA; (Germany) Friedrich-Alexander-Universitaet Erlangen Nuernberg;
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Photonics21 is the European Technology Platform (ETP) for photonics, a technology encompassing all of the products and processes around the emission, manipulation and detection of light. Photonics is integral to a wide range of industries that include the medical, healthcare, transport, manufacturing, and telecommunications sectors.
"Photonics21" was set up in December 2005 to bring the community of photonics researchers and industries together. The European Commission defined photonics as one of six European Key Enabling Technologies (KET's) in September 2009. Shortly after, the European Research & Innovation Program "Horizon 2020" invited Photonics21 to become a "Public Private Partnership" (PPP). The "Photonics 21 Association", a legal entity under Belgium law, became the private contract partner in November 2013 in a Public Private Partnership (PPP) in conjunction with the EU Commission.
Today Photonics21 represents more than 3000 personal members from across Europe and abroad. Our members are experts in the photonics industry, research organisations and universities who actively engage with us to develop a joint photonics strategy for future research and innovation in Europe.
With the global photonics market growing from €350 Billion in 2011 to €447 Billion in 2015, Photonics remains a strong industry. The European photonics industry, estimated to be worth €70 billion, has considerable global leadership positions and employs over 300,000 people directly.
With positive growth forecast, current industry trends like digitalisation, resource efficiency, individual and zero failure production will drive the photonics industry further.
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