skin color monitor sarah offutt, rachel mosher, victoria vasys bme 301 march 7, 2008
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Skin Color Monitor
Sarah Offutt, Rachel Mosher, Victoria Vasys
BME 301March 7, 2008
Client:John Webster, Ph.D
Department of Biomedical Engineering
Advisor:Brenda M. Ogle, Ph.D., M.S.
Dept. of Biomedical Engineering
Overview Problem Statement Background
Physiology of Hot Flashes Existing Devices
Design Components Housing Design Clear Plate Circuit
Future Work Questions
Problem StatementThe goal is to design a device to monitor
skin color changes during hot flashes, which could be used to provide the objective measurement needed for therapeutic drug testing for menopausal women.
Physiology of Hot Flashes Decreased estrogen levels confuse
hypothalamus- body is “too hot” Due to menopause, medications
Heart pumps faster, blood vessels dilate, blood flow to periphery increases Skin flushes red
85% of women experience hot flashes during menopause Sweating, sleep loss, interruption of daily
activities
Existing Devices Temperature Sensors Skin conductance measurements Skin-color-change detectors We aim to merge the two technologies in
order to best detect hot flashes Longer lasting Easier use
Last Semester Blue LED and Phototransistor Would like to improve on
Specular Reflection elimination Smaller Larger color differentiation
PDS Summary Measurements taken every 10 seconds 6 x 6 x 1 cm 50 g Battery life to last for overnight reading Comfortable and discreet
Housing Design
Needs: Aesthetics Durability Space for circuitry Comfort
3 options Box Flat Box Dome
Housing Design MatrixCRITERIA WEIGHT Box Flat Box Dome
Aesthetics 25 0.1 (2.5) 0.4 (10) 0.5 (12.5)
Durability 25 0.37 (9.25) 0.33 (8.25) 0.3 (7.5)
Space for LEDs and Circuitry 25 0.33 (8.25) 0.33 (8.25) 0.33 (8.25)
Comfort 15 0.2 (3) 0.35 (5.25) 0.45 (6.75)
Machinability 5 0.5 (2.5) 0.4 (2) 0.1 (0.5)
Cost 5 0.2 (1) 0.4 (2) 0.4 (2)
TOTAL 100 26.5 35.75 37.5
Clear Plate Skin kept flat Even pressure Needs to be:
Transparent Lightweight Safe
3 options NOA61 Acrylic Glass
Clear Plate Design Matrix
CRITERIA WEIGHT NOA61 Acrylic Glass
Safety 35 0 0.7 (24.5) 0.3 (10.5)
Weight 25 0.3 (7.5) 0.5 (12.5) 0.2 (5)
Cost 15 0.1 (1.5) 0.4 (6) 0.5 (7.5)
Refractive Index 15 0.3 (4.5) 0.3 (4.5) 0.6 (9)
Machinability 10 0.2 (2) 0.5 (5) 0.3 (3)
TOTAL 100 15.5 47 35.5
Circuit 3 options
Original Design Parallel Branch Design Op-Amp Design
Want circuit that will detect the smallest amount of change
Will make biggest difference in quality of project
Circuit Design 1 and 2 Circuit 1—Original
Few circuit parts Low cost Easy to construct Lowest voltage output
Circuit 2—Parallel Few circuit parts Low cost Easy to construct 0-5V output range
Circuit Design 3 Op-amp
More circuit parts Increased cost Harder to construct Offset resistor Ranges -5 to 5V
Circuit Design Matrix
CRITERIA WEIGHT Old Circuit Parallel Branch Circuit Op-Amp Circuit
Differentiation 50 0.1 (2.5) 0.2 (5) 0.7 (17.5)
Ease 20 0.4 (10) 0.4 (10) 0.2 (5)
Size 20 0.4 (10) 0.4 (8) 0.2 (4)
Cost 10 0.4 (4) 0.4 (4) 0.2 (2)
TOTAL 100 26.5 27 28.5
Final Design Blue LED Phototransistor Dome housing design Acrylic Plate Op-amp Circuit
Current Work Specular reflection eliminated Tested different colors of “skin” Compared different colors of LEDs Phototransistor compared with photocell Housing will be made soon
Future Work Design Circuit
Finding skin color output range Setting offset Testing skin color values with exercise
Making Independent Print Circuit -5 to 5V source Recording device
Implement Housing Design
References Carpenter, J. S., Azzouz, F., Monahan, P. O., Storniolo, A. M. &
Ridner, S. H. (2005). Is sternal skin conductance monitoring a valid measure of hot flash intensity or distress? Menopause, 12(5), 512-9.
Raskin, B. (1987). Hot Flashes. New York: St. Martin’s Press. Singh, M. & Simpkins, J. W. (Eds.). (2005). The future of hormone
therapy : what basic science and clinical studies teach us. New York: New York Academy of Science.
Wearable hot flash monitor (WHFM). Metis Design Corporation. Retrieved February 17, 2008 from http://www.metisdesign.com/biosensors.htm.
Webster, J. G., Bahr, D. E., Shults, M. C., Grady, D. G. & Macer, J. (2006). A miniature sternal skin-attached hot flash recorder. International Federation for Medical and Biological Engineering, 14, 577-580.
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