Abstract
A compact, portable and improved blood flow measurement system for an extracorporeal circuit having a rotating permanent magnetic excitation scheme is described in this paper. The system consists of a set of permanent magnets rotating near blood or any conductive fluid to create high-intensity alternating magnetic field in it and inducing a sinusoidal varying voltage across the column of fluid. The induced voltage signal is acquired, conditioned and processed to determine its flow rate. Performance analysis shows that a sensitivity of more than 250 mV/lpm can be obtained, which is more than five times higher than conventional flow measurement systems. Choice of rotating permanent magnet instead of an electromagnetic core generates alternate magnetic field of smooth sinusoidal nature which in turn reduces switching and interference noises. These results in reduction in complex electronic circuitry required for processing the signal to a great extent and enable the flow measuring device to be much less costlier, portable and light weight. The signal remains steady even with changes in environmental conditions and has an accuracy of greater than 95 %. This paper also describes the construction details of the prototype, the factors affecting sensitivity and detailed performance analysis at various operating conditions.
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References
Barnes CW (1960) A new method for obtaining flow signals from the electromagnetic flow meter. Naturwissenschaften 47(3):56–57
Donati S (2004) Electro-optical instrumentation: sensing and measuring with lasers. Pearson Education, New York
Gill RW (1985) Measurement of blood flow by ultrasound: accuracy and sources of error. Ultrasound Med Biol 11(4):625–641
Hartley CJ, Cole JS (1974) An ultrasonic pulsed Doppler system for measuring blood flow in small vessels. J Appl Physiol 37(4):626–629
Hickman R, Crosier JH, Smith P, Immelman EJ, Terblanche J (1975) Problems with an electromagnetic blood flowmeter. S Afr Med J 49:261–264
Koelink MH, De Mul FFM, Weijers AL, Greve J, Graaff R, Dassel ACM, Aarnoudse JG (1994) Fiber-coupled self-mixing diode-laser Doppler velocimeter: technical aspects and flow velocity profile disturbances in water and blood flows. Appl Opt 33(24):5628–5641
Kolin A (1936) An electromagnetic flowmeter. Principle of the method and its application to bloodflow measurements. Exp Biol Med 35(1):53–56
Lund-Johansen P (1990) The dye dilution method for measurement of cardiac output. Eur Heart J 11(suppl I):6–12
Nair SS, Nagesh DS (2015) Design of electromagnetic probe having reduced base line drift for blood flow measurement. IETE J Res 61(3) [Epub ahead of print]
Norgia M, Pesatori A, Rovati L (2010) Low-cost optical flowmeter with analog front-end electronics for blood extracorporeal circulators. IEEE Trans Instrum Meas 59(5):1233–1239
Pesatori A, Norgia M, Rovati L (2009) Optical flowmeter for blood extracorporeal circulators. In: Instrumentation and Measurement Technology Conference. IEEE, pp. 1759–1762
Renal Research Institute (2012) Effect of sodium concentration of priming and rinsing fluids on inter dialytic weight gain and blood pressure in hemo dialysis patients: a prospective pilot study, NCT01168947
Rhode KS, Lambrou T, Hawkes DJ, Seifalian AM (2005) Novel approaches to the measurement of arterial blood flow from dynamic digital X-ray images. IEEE Trans Med Imaging 24(4):500–513
Spencer MP, Denison AB (1959) The square-wave electromagnetic flowmeter: theory of operation and design of magnetic probes for clinical and experimental applications. IRE Trans Med Electron 4:220–228
Vatner SF, Franklin DEAN, VanCitters RL (1970) Simultaneous comparison and calibration of the Doppler and electromagnetic flowmeters. J Appl Physiol 29(6):907–910
Webster JG (ed) (1999) Chapter V, Mechanical variables measurement-fluids, the measurement, instrumentation, and sensors: handbook. IEEE press, New York, pp 28.64–28.77. ISBN 0-8493-8347-1
Wyatt DG (1961) Problems in the measurement of blood flow by magnetic induction. Phys Med Biol 5(4):369
Wyatt DG (1961) Zero error in induction flowmeters employing a permanent magnet. Phys Med Biol 5(4):449
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Nair, S.S., Vinodkumar, V., Sreedevi, V. et al. Rotating permanent magnet excitation for blood flow measurement. Med Biol Eng Comput 53, 1187–1199 (2015). https://doi.org/10.1007/s11517-015-1310-y
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DOI: https://doi.org/10.1007/s11517-015-1310-y