Post on 29-Mar-2015
Multi-channel Cell Counter Utilizing The Aperture Impedance
Technique
Aaron Lee & Dr. Ash M. Parameswaran
Simon Fraser UniversitySchool of Engineering SciencesBurnaby, B.C. Canada V5A 1S6
Email: cleek@sfu.ca
This work is sponsored by Brain Insights, California
Overview
1. Introduction
2. Centralized approach
3. Clinical facts
4. Techniques of cell counting
5. Electrical and physical relationships
6. Disposable unit design
7. 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 timePatient has to visit another time
Commercial blood cell counter
18 cell sizes result and histograms
Dimensions: 37x47x38(cm)
Weight: 18 kg net Power: AC No portable blood
counter in the market
Our challenges
Shortens the turn around timeReduce the cost so clinics can afford to
own the blood cell counterMiniaturize the testing equipmentMaintain or improve accuracy
Blood cell type Sizes(um)
Normal Ranges (per mm3)
-- -- Male Female
Red blood cell 6-10 4.5-6.5 M 3.9-5.6 M
White blood cell 10-20 4.5-11 k 4.5-11k
Platelets 2-4 150-350 k 150-350 k
Blood cell sizes and their normal ranges
Diseases of the Blood
Cell Type Increase count Decrease count
WBC Infectious diseases Inflammatory disease Severe emotional Physical stress Tissue damage
Bone marrow failure Presence of toxic substance Disease of the liver/spleen Radiation
RBC Renal tumor Iron overload in organs
Anemia Chronic inflammation
Platelet Renal disease Infection or inflammation
Anemia Bone marrow failure Uremia Liver disease
Cell count techniques
ElectricalOptical
Electrical Counting
Gain in precision and reproducibility Lower coefficient of variation and complete
a large number of determinations quicklyCost of the electrical cell-counting
equipments ($2500 to over $50,000) Samples has to be diluted before the
count
Impedance Principle Constant current Insulated chambers Vacuum pump Isotonic electrolytes More on next slide
Container
ApertureTube with ApertureCell
9% NaCl Electrolyte
Vacuum PumpConstant
Current Source
Electrodes
Direction of Flow
Impedance Principle (Cont’d)
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
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
Darkfield Optical Principle (Cont’d)
Inlet
Outlet
Darkfield stop disk
Light SourceBeam
AperturePhotodiode
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:
22 )(
A
iVVoltage
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
Activity
RateCountRawratecountCorrected
1
____
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
Cell counter handheld unit
Disposable unit (1st design)
To Vacuum
Aperture
Disposable unit (1st design)
Images of Disposable unit (1st design)
Image of the aperture film under microscope
~60um
Drilled by laser and measured under electronic microscope
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
Questions