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Principles of Biomedical Systems & Devices

Principles of Biomedical Systems & Devices. 0909.504.04 / 0909.402.02. WEEK 10: Flow & Volume of Blood. Measurement of Flow & Volume of Blood. A measurement of paramount importance: concentration of O 2 and other nutrients in cells  Very difficult to measure

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Principles of Biomedical Systems & Devices

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  1. Principles of Biomedical Systems & Devices 0909.504.04 / 0909.402.02 WEEK 10: Flow & Volume of Blood

  2. Measurement of Flow & Volume of Blood • A measurement of paramount importance: concentration of O2 and other nutrients in cells  Very difficult to measure • Second-class measurement: blood flow and changes in blood volume  correlate well with concentration • Third-class measurement: blood pressure  correlates well with blood flow • Fourth class measurement: ECG  correlates adequately with blood pressure • How to make blood flow / volume measurements? Standard flow meters, such as turbine flow meters, obviously cannot be used! • Indicator-dilution method: cont./rapid injection, dye dilution, thermodilution • Electromagnetic flowmeters • Ultrasonic flowmeters / Doppler flowmeters • Plethysmography: Chamber / electric impedance / photoplethysmography

  3. Indicator Dilution with Continuous Injection • Measures flow / cardiac output averaged over several heart beats • Fick’s technique: the amount of a substance (O2) taken up by an organ / whole body per unit time is equal to the arterial level of O2 minus the venous level of O2 times the blood flow  Change in [] due to continuously added indicator m to volume V Consumption of O2 (mL/min) Blood flow, liters/min(cardiac output) Arterial and venousconcentration of O2 (mL/L of blood)

  4. Fick’s technique • How is dm/dt (O2 consumption) measured? • Where and how would we measure Ca and Cv? (Exercise)

  5. Indicator Dilution with Rapid Injection • A known amount of a substance, such as a dye or radioactive isotope, is injected into the venous blood and the arterial concentration of the indicator is measured through a serious of measurements until the indicator has completely passed through given volume. • The cardiac output (blood flow) is amount of indicator injected, divided by average concentration in arterial blood.

  6. Indicator – Dilution Curve After the bolus is injected at time A, there is a transportation delay before the concentration begins rising at time B. After the peak is passed, the curve enters an exponential decay region between C and D, which would continue decaying alone the dotted curve to t1 if there were no recirculation. However, recirculation causes a second peak at E before the indicator becomes thoroughly mixed in the blood at F. The dashed curve indicates the rapid recirculation that occurs when there is a hole between the left and right sides of the heart.

  7. An Example

  8. Dye Dilution • In dye-dilution, a commonly used dye is indocyanine green (cardiogreen), which satisfies the following • Inert • Safe • Measurable though spectrometry • Economical • Absorption peak is 805 nm, a wavelength at which absorption of blood is independent of oxygenation • 50%of the dye is excreted by the kidneys in 10 minutes, so repeat measurements is possible

  9. Thermodilution • The indicator is cold – saline, injected into the right atrium using a catheter • Temperature change in the blood is measured in the pulmonary artery using a thermistor • The temperature change is inversely proportional to the amount of blood flowing through the pulmonary artery

  10. Measuring Cardiac Output Several methods of measuring cardiac output In the Fick method, the indicator is O2; consumption is measured by a spirometer. The arterial-venous concentration difference is measure by drawing simples through catheters placed in an artery and in the pulmonary artery. In the dye-dilution method, dye is injected into the pulmonary artery and samples are taken from an artery. In the thermodilution method, cold saline is injected into the right atrium and temperature is measured in the pulmonary artery.

  11. Electromagnetic Flowmeters • Based on Faraday’s law of induction that a conductor that moves through a uniform magnetic field, or a stationary conductor placed in a varying magnetic field generates emf on the conductor: When blood flows in the vessel with velocity u and passes through the magnetic field B, the induced emf emeasured at the electrodes is. For uniform B and uniform velocity profile u, the induced emf is e=BLu. Flow can be obtained by multiplying the blood velocity uwith the vessel cross section A.

  12. ElectromagneticFlowmeter Probes • Comes in 1 mm increments for 1 ~ 24 mm diameter blood vessels • Individual probes cost $500 each • Made to fit snuggly to the vessel during diastole • Only used with arteries, not veins, as collapsed veins during diastole lose contact with the electrodes • Needless to say, this is an INVASIVE measurement!!! • A major advantage is that it can measure instantaneous blood flow, not just average flow

  13. Ultrasonic Flowmeters • Based on the principle of measuring the time it takes for an acoustic wave launched from a transducer to bounce off red blood cells and reflect back to the receiver. • All UT transducers, whether used for flowmeter or other applications, invariably consists of a piezoelectric material, which generates an acoustic (mechanical) wave when excited by an electrical force (the converse is also true) • UT transducers are typically used with a gel that fills the air gaps between the transducer and the object examined

  14. Near / Far Fields • Due to finite diameters, UT transducers produce diffraction patterns, just like an aperture does in optics. • This creates near and far fields of the UT transducer, in which the acoustic wave exhibit different properties • The near field extends about dnf=D2/4λ, where D is the transducer diameter and λ is the wavelength. During this region, the beam is mostly cylindrical (with little spreading), however with nonuniform intensity. • In the far field, the beam diverges with an angle sinθ=1.2 λ/D, but the intensity uniformly attenuates proportional to the square of the distance from the transducer Higher frequencies and larger transducers should be used for nearfield operation. Typical operating frequency is 2 ~ 10 MHz.

  15. UT Flowmeters Zero-crossingdetector / LPF Determine direction High acoustic impedance material

  16. Transit time flowmeters Effective velocity of sound in blood: velocity of sound (c) +velocity of flow of blood averaged along the path of the ultrasound (û) û=1.33ū for laminar flow, û=1.07ū for turbulent flowū: velocity of blood averaged over the cross sectional area, this is differentthan û because the UT path is along a single line not over an averaged of cross sectional area Transit time in up/down stream direction: Difference between upstream and downstream directions

  17. Transit Time Flowmeters The quantity ∆T is typically very small and very difficult to measure, particularly in the presence of noise. Therefore phase detection techniques are usually employed rather then measuring actual timing.

  18. Doppler Flowmeters • The Doppler effect describes the change in the frequency of a received signal , with respect to that of the transmitted signal, when it is bounced off of a moving object. • Doppler frequency shift Source signal frequency Speed of blood flow (~150 cm/s) Angle between UT beamand flow of blood Speed of sound in blood (~1500 m/s)

  19. Doppler Flowmeters

  20. Problems Associated withDoppler Flowmeters • There are two major issues with Doppler flowmeters • Unlike what the equations may suggest, obtaining direction information is not easy due to very small changes in frequency shift that when not in baseband, removing the carrier signal without affecting the shift frequency becomes very difficult • Also unlike what the equation may suggest, the Doppler shift is not a single frequency, but rather a band of frequencies because • Not all cells are moving at the same velocity (velocity profile is not uniform) • A cell remains within the UT beam for a very short period of time; the obtained signal needs to be gated, creating side lobes in the frequency shift • Acoustic energy traveling within the beam, but at an angle from the bam axis create an effective ∆θ, causing variations in Doppler shift • Tumbling and collision of cells cause various Doppler shifts

  21. Directional Doppler • Directional Doppler borrows the quadrature phase detector technique from radar in determining the speed and direction of an aircraft. • Two carrier signals at 90º phase shift are used instead of a single carrier. The +/- phase difference between these carriers after the signal is bounced off of the blood cells indicate the direction, whereas the change in frequency indicate the flowrate

  22. Directional Doppler (a) Quadrature-phase detector. Sine and cosine signals at the carrier frequency are summed with the RF output before detection. The output C from the cosine channel then leads (or lags) the output S from the sine channel if the flow is away from (or toward) the transducer. (b) Logic circuits route one-shot pulses through the top (or bottom) AND gate when the flow is away from (or toward) the transducer. The differential amplifier provides bi-directional output pulses that are then filtered.

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