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Development of a Wearable, Wireless, NIR* Imaging Device Rowan University Biosensors Lab Linda M. Head PhD, Faculty Director Rane Pierson BSECE, MS Student.

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Presentation on theme: "Development of a Wearable, Wireless, NIR* Imaging Device Rowan University Biosensors Lab Linda M. Head PhD, Faculty Director Rane Pierson BSECE, MS Student."— Presentation transcript:

1 Development of a Wearable, Wireless, NIR* Imaging Device Rowan University Biosensors Lab Linda M. Head PhD, Faculty Director Rane Pierson BSECE, MS Student Undergraduate Students: Jessica Donovan, Andrew Flanyak, Michael McDonald *Near InfraRed

2 OUTLINE A.Uses of fNIR B.Our goals C.Progress to date D.Future work E.Acknowledgements F.References 11/17/08 New Jersey Technology Council Mid Atlantic Imaging Symposium 2

3 APPLICATIONS OF NIR SENSING & IMAGING TECHNIQUES 11/17/08 New Jersey Technology Council Mid Atlantic Imaging Symposium 3 Figure 1: Hb and HbO 2 absorption spectra [1] 1.Absorption of radiation by Hb and HbO 2 exceeds absorption by H 2 O at NIR wavelengths. [1] 2.Medical applications for near-infrared have proliferated into areas of blood analyte monitoring and imaging of materials including tissue. [2,3] 3.Specific applications include: a)Oximetry – measurement of O 2 levels in the blood (e.g. pulse oximetry) [4] b)Non-invasive assessment of brain function [5] c)In-vivo muscle metabolism measurement [6]

4 GOALS FOR ROWAN NIR IMAGING PROJECT Integrated electronics Custom package Reconfigurable FPGA-based control and data processing Wireless portability 11/17/08 New Jersey Technology Council Mid Atlantic Imaging Symposium 4 Figure 2: Modular Concept Drawing Fully modular and programmable NIR sensor.

5 STATE OF THE PROJECT: INTEGRATED ELECTRONICS Prototype component- based version of control system completed. – λ designation – Sampling rate – Noise suppression – Data storage & transmission Spartan3 development board prototype. 11/17/08 New Jersey Technology Council Mid Atlantic Imaging Symposium 5 Figure 3: Component-Based Board layout

6 STATE OF THE PROJECT: SENSOR NIR LED with 4 programmable settings: – dark – 730 nm – 805 nm – 850 nm OPT101 Photodiode detector Customizable package with embedded flexible circuit http://www.youtube.com/watch?v=j5SYnL0bh50 11/17/08 New Jersey Technology Council Mid Atlantic Imaging Symposium 6 Figure 5: Version1, Molded Rubber Sensor Assembly Figure 4: EPITEX NIR LED Specifications

7 STATE OF THE PROJECT: WIRELESS SOLUTION Goal is a single chip solution that can be embedded in the individual sensor modules – Single unit/multiple sensor – custom design – Multiple unit/multiple sensor – modular design Wireless network solutions required Development board in use for design prototypes 11/17/08 New Jersey Technology Council Mid Atlantic Imaging Symposium 7 Figure 6: Radiotronix RK-Wi232-DTS-R [7]

8 FUTURE PLANS 11/17/08 New Jersey Technology Council Mid Atlantic Imaging Symposium 8 Jr/Sr “Clinic” Thesis Project Product Development Sensor Package Wireless Network Project Planning FPGA Solutions Phantom Production Prototype ProductionTesting/Verification Funding Proposals Data Analysis Solution Conference Presentations

9 ACKNOWLEDGEMENTS Initial project conceived in collaboration with the Functional Optical Brain Imaging group at Drexel University. Funding provided by Rowan Dean’s Research Fund, Electrical & Computer Engineering program. Dr Sachin Shetty for conversations on wireless networks. Drs. Ramachandran and Tang for allowing undergraduates to miss class today! 11/17/08 New Jersey Technology Council Mid Atlantic Imaging Symposium 9

10 REFERENCES 1.http://www.biop.dk/Research/Main_research_tweezers.htmhttp://www.biop.dk/Research/Main_research_tweezers.htm 2.http://www.spectroscopynow.com/coi/cda/detail.cda&id=1881&type=EducationFeature&c hId=2&page=1#Refshttp://www.spectroscopynow.com/coi/cda/detail.cda&id=1881&type=EducationFeature&c hId=2&page=1#Refs 3.E. Ciurczak and J. Drennen, Near-Infrared Spectroscopy in Pharmaceutical and Medical Applications, Marcel-Dekker, Inc. New York, 2002. 4.Yoshiya I, Shimada Y, Tanaka K. Spectrophotometric monitoring of arterial oxygen in the fingertip. Med Biol Eng Comput 1980;18:27-32 5.Wolf M, et al. Progress of near infrared spectroscopy and imaging instrumentation for brain and muscle clinical applications. J. Biomed. Opt. 2007; 12, 062104. Review 6.Yuanqing Lin,a) Gwen Lech, Shoko Nioka, Xavier Intes, and Britton Chance, Noninvasive, low-noise, fast imaging of blood volume and deoxygenation changes in muscles using light- emitting diode continuous-wave imager. Review of Scientific Instruments, Vol. 73, No. 8, August 2002. 7.http://www.radiotronix.com/products/proddb.asp?ProdID=12http://www.radiotronix.com/products/proddb.asp?ProdID=12 11/17/08 New Jersey Technology Council Mid Atlantic Imaging Symposium 10

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