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Multi-channel Cell Counter Utilizing The Aperture Impedance Technique Aaron Lee & Dr. Ash M. Parameswaran Simon Fraser University School of Engineering Sciences Burnaby, B.C. Canada V5A 1S6 Email: cleek@sfu.ca This work is sponsored by Brain Insights, California Overview Introduction
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Multi-channel Cell Counter Utilizing The Aperture Impedance Technique Aaron Lee & Dr. Ash M. Parameswaran Simon Fraser University School of Engineering Sciences Burnaby, B.C. Canada V5A 1S6 Email: cleek@sfu.ca This work is sponsored by Brain Insights, California
Overview • Introduction • Centralized approach • Clinical facts • Techniques of cell counting • Electrical and physical relationships • Disposable unit design • Conclusion
Thesis Concentration Construction, modeling and testing of the disposable unit and the electronics
Introduction • Most people have blood test at some point in their lives • Blood is the vital fluid of our body and the quality of blood is an indication of health • Measured in number of cells per cubic millimeter of blood
Centralized approach • Most blood cell counting today is done by sending the blood samples to a centralized laboratory • Very complex system and required skilled personnel to operate • Long turn-around time • Patient has to visit another time
18 cell sizes result and histograms Dimensions: 37x47x38(cm) Weight: 18 kg net Power: AC No portable blood counter in the market Commercial blood cell counter
Our challenges • Shortens the turn around time • Reduce the cost so clinics can afford to own the blood cell counter • Miniaturize the testing equipment • Maintain or improve accuracy
Cell count techniques • Electrical • Optical
Electrical Counting • Gain in precision and reproducibility • Lower coefficient of variation and complete a large number of determinations quickly • Cost of the electrical cell-counting equipments ($2500 to over $50,000) • Samples has to be diluted before the count
Constant Current Source Vacuum Pump Electrodes 9% NaCl Electrolyte Aperture Tube with Aperture Cell Direction of Flow Container Impedance Principle • Constant current • Insulated chambers • Vacuum pump • Isotonic electrolytes • More on next slide
Aperture size is 50-100um “Aperture size: 80 µm for commercial unit” Measure changes in electrical resistance Change in impedance is proportional to individual volume Accurately counts and sizes cells Impedance Principle (Cont’d)
Capacitance Principle • Similar idea as the impedance method • Measured in the function of the change in capacitance • However, pulse amplitude generated is not proportional the cell size
Outlet Light Source Beam Aperture Photodiode Darkfield stop disk Inlet Darkfield Optical Principle (Cont’d)
Darkfield Optical Principle (Cont’d) • The pulse generated by the system is not proportional to the size of the cell • Optical detection is sensitive to size of the dark field stop disk, and the optical magnification • An offset of the parameters will greatly affect the amplitude of the signal
Electrical and physical relationships • The pulse height-cell volume relationship can be calculated by using the Maxwell equation:
Resistivity of electrolyte • 0.9% NaCl used as the electrolyte • Conductivity of aqueous solutions are usually expressed in Siemens Conductivity (S/cm) = Molarity (mol/L) x ion conductance (SL/cm/eq) x 1 eq/mol • Resistance of the 0.9% NaCl solution is calculated to be 51 Ω/cm
Coincidence correction • When a particle is in the aperture, and while the detecting electronics are still busy processing data, the system cannot simultaneously measure another cell
Design requirements • Cell sizes that we are measuring vary from 2 μm to 20 μm in diameter • Aperture size of 50-100 μm in diameter will be used • Design of a disposable unit and electronics that can be put in a portable cell counter
Disposable unit (1st design) Aperture To Vacuum
Image of the aperture film under microscope Drilled by laser and measured under electronic microscope ~60um
Conclusion • Theory of multi-channel cell counter utilizing the aperture impedance technique have been discussed • Highest resolution available in the industry for particle counting and size distribution • Color or refractive index does not affect results • More design on the disposable unit will be performed and more testing will be done
References • [1] Basic Principles in Biology by Y.K.To, Hung Fung Book Co. • [2] Haematology, R.B. Thompson • [3] Kubitschek HE: Counting and sizing micro-organisms with the Coulter counter, in Methods in Microbiology, ed DW Ribbons and JR Norris. London: Academic Press, 1969 • [4] Coulter WH: High speed automatic blood cell counter and cell size analyzer. Presented at the National Electronics Conference, Chicago, October 1956 • [5] Hayes TL: The scanning electron microscope: principles and applications in biology and medicine. Adv Biol Med Phys 12:85, 1968 • [6] Brightfield and darkfield: http://www.wsu.edu/~omoto/papers/Fig1.html • [7] Mansberg HP: Optical techniques of particle counting, in Advances in Automated Analysis, Vol 1. Technicon International Congress. New York: Mediad, 1969 • [8] Hematology; principles and practice. Edited by Charles E. Mengel, Emil Frei, III [and] Ralph Nachman. • [9] http://www.principalhealthnews.com/topic/topic100587682 • [10] http://www.utmem.edu/physpharm/.010.html • [11] Brecher G et al: Evaluation of an electronic red cell counter. Am J Clin Pathol 16:1439, 1956 • [12] Ionic reactions and equilibria. New York : Macmillan, [1967] • [13] http://www.colby.edu/chemistry/CH141B/CH141B.Lab/CH141L4condFall2002.pdf • [14] Practical guide to modern hematology analysers, warren Groner, Elkin Simson, john wiley and sons ltd, 1995