ATWARM Advanced Technologies for Water Resource Management Marie Curie Initial Training Network Next Generation Autonomous Analytical Platforms for Remote.

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Presentation transcript:

ATWARM Advanced Technologies for Water Resource Management Marie Curie Initial Training Network Next Generation Autonomous Analytical Platforms for Remote Environmental Monitoring Generation of Fully Functioning Biomimetic Analytical Platforms for Water Quality M. Czugala, F. Benito-Lopez and D. Diamond CLARITY: Centre for Sensor Web Technologies, National Centre for Sensor Research, Dublin City University, Dublin 9, IRELAND Project Objectives: Conferences M. Czugala, R. Gorkin, C. Rovira-Borras, J. Ducree, D. Diamond, F. Benito-Lopez, Microfluidic system with a wireless paired detector diode device as an optical sensor for water quality monitoring, Conference on Analytical Sciences Ireland 2011, February 21-22, 2011, Dublin, Ireland. Submitted (POSTER). R. Gorkin, M. Czugala, C. Rovira-Borras, J. Ducree, D. Diamond, F. Benito-Lopez, A Wireless Paired Emitter Detector Diode Device as Optical Sensor for Lab-On-A-Disc Applications, The 16th International Conference on Solid-State Sensors, Actuators and Microsystems (Transducers-2011), June 5-9, 2011, Beijing, China. (POSTER). ANTICIPATED CONFERENCES: M. Czugala, R. Gorkin, T. Phelan, J. Ducree, D. Diamond, F. Benito-Lopez, Novel Optical Sensing System Based on Wireless Paired Emitter Detector Diode Device for Lab- on-a-Disc Water Quality Analysis, The 15th International Conference on Miniaturized Systems for Chemistry and Life Sciences (MicroTAS), October 2-6, 2011, Seattle, USA. (ORAL) Wireless Paired Emitter Diode Device as Optical Sensor for Lab-on-a-Disc Water Analysis - Introduction Figure 5. Water pH analysis using a commercially available pH- meter and the PEDD lab-on-a- disc device. Figure 6: a) Turbidity measurements using a UV-VIS spectrometer (transmittance) and b) two channels with river samples; one contents solids in the upper chamber (left) while the other is clean (right). Fig 1. The schematic of circuit used in the system. Integration of actuators into a microfluidic platform: - biomimetic structures with detectors - fluidic manifolds - integral reagent addition and calibration standards - integral electronics - communications and power generation/storage Demonstration of fully functioning analytical platform. Fig 2. a) Prototype of the PEDD centrifugal micro-fluidic system, b) channel consisting of three chambers. [1] Fig 3. Calibration curve of the sensing area of the microfluidic device using pH buffer solutions. (n=70, error represents the average of light intensity values during data collection). Fig 4. Images of a channel of the CD-chip during centrifugation at 1500 rpm. A) the upper chamber is filled with sample, then the disc is spun and all the liquid is transferred to the sensing area (B-D). Solid contents are accumulated in the first chamber (>85µm diameter) (B-D) and at the bottom of the channel (<85µm diameter). Results [ 1] Czugala M. et. al., NOVEL OPTICAL SENSING SYSTEM BASED ON WIRELESS PAIRED EMITTER DETECTOR DEVICE FOR LAB ON A DISC WATER QUALITY ANALYSIS, MicroTAS 2011 Conference, October 2-6, 2011, Seattle, USA. a)b) a)b)