WO2009022330A2 - Dynamically variable filter - Google Patents
Dynamically variable filter Download PDFInfo
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- WO2009022330A2 WO2009022330A2 PCT/IL2008/001105 IL2008001105W WO2009022330A2 WO 2009022330 A2 WO2009022330 A2 WO 2009022330A2 IL 2008001105 W IL2008001105 W IL 2008001105W WO 2009022330 A2 WO2009022330 A2 WO 2009022330A2
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/02—Detecting, measuring or recording pulse, heart rate, blood pressure or blood flow; Combined pulse/heart-rate/blood pressure determination; Evaluating a cardiovascular condition not otherwise provided for, e.g. using combinations of techniques provided for in this group with electrocardiography or electroauscultation; Heart catheters for measuring blood pressure
- A61B5/02028—Determining haemodynamic parameters not otherwise provided for, e.g. cardiac contractility or left ventricular ejection fraction
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/02—Detecting, measuring or recording pulse, heart rate, blood pressure or blood flow; Combined pulse/heart-rate/blood pressure determination; Evaluating a cardiovascular condition not otherwise provided for, e.g. using combinations of techniques provided for in this group with electrocardiography or electroauscultation; Heart catheters for measuring blood pressure
- A61B5/026—Measuring blood flow
- A61B5/029—Measuring or recording blood output from the heart, e.g. minute volume
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/02—Detecting, measuring or recording pulse, heart rate, blood pressure or blood flow; Combined pulse/heart-rate/blood pressure determination; Evaluating a cardiovascular condition not otherwise provided for, e.g. using combinations of techniques provided for in this group with electrocardiography or electroauscultation; Heart catheters for measuring blood pressure
- A61B5/026—Measuring blood flow
- A61B5/0295—Measuring blood flow using plethysmography, i.e. measuring the variations in the volume of a body part as modified by the circulation of blood therethrough, e.g. impedance plethysmography
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/05—Detecting, measuring or recording for diagnosis by means of electric currents or magnetic fields; Measuring using microwaves or radio waves
- A61B5/053—Measuring electrical impedance or conductance of a portion of the body
- A61B5/0535—Impedance plethysmography
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/48—Other medical applications
- A61B5/4869—Determining body composition
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/72—Signal processing specially adapted for physiological signals or for diagnostic purposes
- A61B5/7235—Details of waveform analysis
- A61B5/725—Details of waveform analysis using specific filters therefor, e.g. Kalman or adaptive filters
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/74—Details of notification to user or communication with user or patient ; user input means
- A61B5/742—Details of notification to user or communication with user or patient ; user input means using visual displays
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/05—Detecting, measuring or recording for diagnosis by means of electric currents or magnetic fields; Measuring using microwaves or radio waves
- A61B5/053—Measuring electrical impedance or conductance of a portion of the body
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/05—Detecting, measuring or recording for diagnosis by means of electric currents or magnetic fields; Measuring using microwaves or radio waves
- A61B5/053—Measuring electrical impedance or conductance of a portion of the body
- A61B5/0537—Measuring body composition by impedance, e.g. tissue hydration or fat content
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/72—Signal processing specially adapted for physiological signals or for diagnostic purposes
- A61B5/7235—Details of waveform analysis
- A61B5/7239—Details of waveform analysis using differentiation including higher order derivatives
Definitions
- the present invention relates to processing of electrical signals, and more particularly to the filtering of a signal pertaining to at least one electrical property of an organ of a subject.
- heart diseases may be caused by (i) a failure in the autonomic nerve system where the impulses from the central nervous system control to the heart muscle fail to provide a regular heart rate and/or (ii) an insufficient strength of the heart muscle itself where even though the patient has a regular heart rate, its force of contraction is insufficient. Either way, the amount of blood or the rate at which the blood is supplied by a diseased heart is abnormal and it is appreciated that an assessment of the state of a patient's circulation is of utmost importance.
- Cardiac output is the volume of blood pumped by the heart during a time interval, which is typically taken to be a minute. Cardiac output is the product of heart rate (HR) and the amount of blood which is pumped with each heartbeat, also known as the stroke volume (SV). For example, the stroke volume at rest in the standing position averages between 60 and 80 ml of blood in most adults. Thus, at a resting heart rate of 80 beats per minute the resting cardiac output varies between 4.8 and 6.4 L per min.
- a common clinical problem is that of hypotension (low blood pressure); this may occur because the cardiac output is low and/or because of low systemic vascular resistance. This problem can occur in a wide range of patients, especially those in intensive care or postoperative high dependency units. In these high risk patients, more detailed monitoring is typically established including measuring central venous pressure via a central venous catheter and continuous display of arterial blood pressure via a peripheral arterial catheter.
- cardiac output can be used for calculating the systemic vascular resistance.
- the measurement of cardiac output is useful both for establishing a patient's initial cardiovascular state and for monitoring the response to various therapeutic interventions such as transfusion, infusion of inotropic drugs, infusion of vasoactive drugs (to increase or reduce systemic vascular resistance) or altering heart rate either pharmacologically or by adjusting pacing rate.
- 6,485,431 in which the compliance of the arterial system is determined from measured arterial pressure and used for calculating the cardiac output as the product of the mean arterial pressure and compliance divided by a time constant.
- catheter based methods such as thermodilution (see, e.g., U.S. Patent No. 4,153,048).
- thoracic electrical bioimpedance A non-invasive method, known as thoracic electrical bioimpedance, was first disclosed in U.S. Patent No. 3,340,867 and has recently begun to attract medical and industrial attention [U.S. Patent Nos. 3,340,867, 4,450,527, 4,852,580, 4,870,578, 4,953,556, 5,178,154, 5,309,917, 5,316,004, 5,505,209, 5,529,072, 5,503,157, 5,469,859, 5,423,326, 5,685,316, 6,485,431, 6,496,732 and 6,511,438; U.S. Patent Application No. 20020193689].
- the thoracic electrical bioimpedance method has the advantages of providing continuous cardiac output measurement at no risk to the patient.
- the present invention there is provided a method of processing a signal pertaining to at least one electrical property of an organ of a subject.
- the method comprises determining a physiological condition of the subject, selecting a frequency band, filtering the signal according to the frequency band, and dynamically adapting the frequency band in response to a change in the physiological condition, thereby processing the signal.
- a filtering device comprising a first input unit for receiving an input pertaining to at least one electrical property of an organ of a subject, a second input unit for receiving data pertaining to a physiological condition of the subject, and a filtering unit configured for filtering the input signal according to a frequency band which is dynamically adapted in response to a change in the physiological condition.
- a system for monitoring cardiac output comprising the filtering device.
- a system for predicting at least one of: a body cell mass, a fat free mass and total body water of a subject comprising the filtering device.
- a system for determining hematocrit of blood in a body part of a subject comprising the filtering device.
- a system for monitoring hydration status of a subject comprising the filtering device.
- a system for discriminating tissue comprising the filtering device.
- a system for calculating the circumference of a body segment comprising the filtering device.
- a method of monitoring at least one electrical property of an organ of a subject comprises: sensing an input radiofrequency signal from the organ, processing the input radiofrequency signal to provide a processed input signal, filtering the input signals using a dynamically variable filter to provide a filtered signal, and using the filtered signal for monitoring the at least one electrical property of the organ.
- apparatus for monitoring at least one electrical property of an organ of a subject comprises an input unit for receiving an input radiofrequency signal sensed from the organ; a signal processing unit for processing the input radiofrequency signal to provide processed input signal; a filtering unit configured for filtering the input signal using dynamically variable filter to thereby provide a filtered signal; and a monitoring unit for monitoring the at least one electrical property of the organ based on the filtered signal.
- a system for monitoring at least one electrical property of an organ of a subject there is provided.
- the system comprises a radiofrequency generator for generating an output radiofrequency signal and a plurality of electrodes, designed to be connectable to the skin of the subject, and configured for transmitting the output radiofrequency signal to the organ and sensing an input radiofrequency signal from the organ.
- the system further comprises a monitoring apparatus, e.g., the apparatus described herein.
- the dynamically variable filter is adapted in response to a change in a physiological condition of the subject.
- the filter is typically a band pass filter characterized by a frequency band defined by, e.g., a lower frequency bound and an upper frequency bound.
- the physiological condition is a heart rate of the subject.
- At least one of a lower bound of the frequency band and an upper bound of the frequency band parameter is a linear function of the heart rate.
- the heart rate is determined from an ECG signal received from the subject.
- the upper frequency bound is determined using an iterative process.
- the iterative process is based on a comparison between a value of a physiological parameter as extracted from the filtered input signal and a value of the physiological parameter as extracted from a reference signal.
- the reference signal comprises the ECG signal.
- the physiological parameter is a ventricular ejection time (VET).
- each iteration of the iterative process comprises: if the comparison meets a predetermined criterion, then updating the upper frequency bound by calculating an average between a low threshold for the upper bound and a high threshold for the upper bound.
- the thresholds can be predetermined or they can be set in a previous iteration of the iterative process.
- the physiological is terminated if a value of the VET as extracted from the filtered input signal is higher than a value of the VET as extracted from the reference signal.
- the VET is averaged over a plurality of heart beats. According to some embodiments of the present invention the VET is extracted from an average heart beat morphology of the subject.
- an initial value of the upper frequency bound in the iterative process is a linear function of the heart rate.
- the linear function is Fu(HR).
- the radiofrequency signal is filtered using an analog filter.
- At least one quantity is calculated using the electrical property.
- the quantity can be a stroke volume, a cardiac output, a brain intra luminal blood volume, a blood flow and the like.
- the blood flow comprises at least one of: an external carotid blood flow rate, an internal carotid blood flow rate, an ulnar blood flow rate, a radial blood flow rate, a brachial blood flow rate, a common iliac blood flow rate, an external iliac blood flow rate, a posterior tibial blood flow rate, an anterior tibial blood flow rate, a peroneal blood flow rate, a lateral plantar blood flow rate, a medial plantar blood flow rate and a deep plantar blood flow rate.
- a phase shift of the input radiofrequency signal relative to an output radiofrequency signal transmitted to the organ is determined.
- the phase shift can be used for calculating the quantity or quantities.
- the amplitude modulation of the input radiofrequency signal is reduced or eliminated so as to provide signals of substantially constant envelope.
- a phase modulation of the input radiofrequency signal is maintained while reducing or eliminating the amplitude modulation.
- the input radiofrequency signal and the output radiofrequency signal are mixed so as to provide a mixed radiofrequency signal.
- the mixed radiofrequency signal comprises a radiofrequency sum and a radiofrequency difference.
- the input radiofrequency signal is indicative of impedance the organ.
- the input radiofrequency signal is indicative of hemodynamic reactance of the organ.
- selected steps of the invention could be implemented as a chip or a circuit.
- selected steps of the invention could be implemented as a plurality of software instructions being executed by a computer using any suitable operating system.
- selected steps of the method and system of the invention could be described as being performed by a data processor, such as a computing platform for executing a plurality of instructions.
- FIG. 1 is a schematic illustration of a filtering device, according to various exemplary embodiments of the present invention
- FIGs. 2a-b show a representative example of dynamically varying frequency bounds, employed according to embodiments of the present invention
- FIG. 2c show a representative example of a dynamically varying frequency band, employed according to embodiments of the present invention.
- FIG. 3a is a flowchart diagram of a method suitable for processing an input signal, according to various exemplary embodiments of the present invention
- FIG. 3b is a flowchart diagram of an iterative process for selecting a frequency bound, according to various exemplary embodiments of the present invention
- FIG. 3 c is a schematic illustration of a procedure for extracting ventricular ejection time from an ECG signal
- FIG. 3d is a schematic illustration of a procedure for extracting ventricular ejection time from a derivative of a filtered signal according to various exemplary embodiments of the present invention
- FIGs. 3e-f are schematic illustrations of beat morphology characterization procedures, according to various exemplary embodiments of the present invention.
- FIG. 4 is a schematic illustration of apparatus for monitoring one or more electrical properties of an organ of a subject, according to various exemplary embodiments of the present invention
- FIG. 5 is a schematic illustration of a signal processing unit, according to various exemplary embodiments of the present invention.
- FIG. 6 is a block diagram of electronic circuitry, according to various exemplary embodiments of the present invention
- FIG. 7 is a schematic illustration of a system for monitoring at least one electrical property of an organ of a subject, according to a preferred embodiment of the present invention
- FIGs. 8a-e are schematic illustrations showing perspective (Figure 8a), front (Figure 8b), rear ( Figure 8c), side ( Figure 8d) and top (Figure 8e) views of a sticker which can be used for transmitting and sensing the radiofrequency signal, according to one embodiment of the present invention
- FIG. 8f is a schematic illustration of a package of several stickers according to an embodiment of the present invention
- FIGs. 9a-d are schematic illustrations of various electronic circuitries, according to exemplary embodiments of the present invention.
- FIGs. lOa-10-e, l la-l le, 12a-12e, 13a-13e, 14a- 14e, 15a-15e, 16a-16g and 17a- 17g show snapshots of the display of a prototype system, manufactured and configured according to various exemplary embodiments of the present invention
- FIGs. 18a- 18b, 19a- 19b and 20a-20b are plots of cardiac output as calculated from a signal filtered according to various exemplary embodiments of the present invention.
- the present embodiments comprise a method, device apparatus and system which can be used for processing a signal. Specifically, but not exclusively, the present embodiments can be used for processing a radiofrequency signal sensed from an organ of a subject and for monitoring one or more electrical properties of an organ, e.g., for the purpose of determining one or more quantities which are related to electrical properties. Thus, for example, exemplary embodiments of the present invention can be used for calculating stroke volume, cardiac output, brain intra luminal blood volume and/or blood flow.
- Embodiments of the present invention can also be used for discriminating tissue and/or determining at least one of: body cell mass, fat free mass, total body water, hematocrit of blood, hydration status and circumference of a body segment.
- body cell mass body cell mass
- fat free mass total body water
- hematocrit of blood hydration status and circumference of a body segment.
- Computer programs implementing the method according to embodiments of the present invention can commonly be distributed to users on a distribution medium such as, but not limited to, a floppy disk, CD-ROM and flash memory cards. From the distribution medium, the computer programs can be copied to a hard disk or a similar intermediate storage medium. The computer programs can be run by loading the computer instructions either from their distribution medium or their intermediate storage medium into the execution memory of the computer, configuring the computer to act in accordance with the method of this invention. All these operations are well-known to those skilled in the art of computer systems.
- a typical system for monitoring electrical properties of a body section such as a bioimpedance system, includes a tetrapolar array of circumferential band electrodes connected to the subject at the base of the neck and surrounding the circumference of the lower chest, at the level of the xiphoid process.
- a voltage proportional to the thoracic electrical impedance (or reciprocally proportional to the admittance) is measured between the inner cervical and thoracic band electrodes.
- the portion of the cardiac synchronous impedance change, temporally concordant with the stroke volume, is ascribed solely and uniquely to volume changes of the aorta during expansion and contraction over the heart cycle.
- a typical printed circuit board of such system comprises one or more band pass filters, a half-wave rectification circuit and one or more low pass filters.
- the present Inventor discovered techniques for reducing the noise associated with conventional systems. As demonstrated in the Examples section that follows, the present Inventor succeeded in reducing noise introduced due to patient agitation or other physiological phenomena like breathing. The present Inventor discovered techniques for separating and differentiating between a cardiovascular bioreactance signal and a respiratory bioreactance signal, where the latter is typically much larger than the former. The present Inventor has realized that the noise level is proportional to the bandwidth of the band pass filter and that a considerable portion of the noise passes the band pass filter hence being folded into the half-wave rectification circuit
- the present Inventor also discovered techniques for reducing or eliminating AM noise hence significantly improving the ability to provide accurate measurement.
- Figure 1 illustrates a filtering device 10, according to various exemplary embodiments of the present invention.
- Device 10 comprises a first input unit 12 which receives an input signal 16 pertaining to one or more electrical properties of an organ of a subject.
- signal 16 can relate to the hemodynamic reactance of the organ.
- hemodynamic reactance refers to the imaginary part of the impedance. Techniques for extracting the imaginary part from the total impedance are known in the art. Typically, such extraction is performed at hardware level but the use of algorithm at a software level is not excluded from the scope of the present invention.
- Signal 16 can be provided, for example, by processing a radiofrequency signal sensed from the organ, as further detailed hereinunder.
- device 10 further comprises a second input unit 14 which receives data 18 pertaining to a physiological condition of the subject.
- the physiological condition is preferably, but not obligatorily, the heart rate of the subject, and the data pertaining to the physiological condition can be analog data or digital data, as desired. While the embodiments below are described with a particular emphasis to physiological condition which is a heart rate, it is to be understood that more detailed reference to the heart rate is not to be interpreted as limiting the scope of the invention in any way.
- the physiological condition is a ventilation rate of the subject, a repetition rate of a particular muscle unit and/or one or more characteristics of an action potential sensed electromyography.
- Device 10 further comprises a filtering unit 20 which filters the input signal 16 to provide a filtered signal 22.
- the filtering is according to a frequency band which is dynamically adapted in response to a change in the physiological condition of the subject. It was found by the Inventor of the present invention that the dynamical adaptation of the frequency band to the physiological condition of the subject can significantly reduce the influence of unrelated signals on the measured or monitoring of electrical properties of the body section.
- the adaptation of the frequency band to the physiological condition can be according to any adaptation scheme known in the art.
- one or more parameters of the frequency band e.g., lower bound, upper bound, bandwidth, central frequency
- Such parameter can be, for example, the number of heart beats per minute.
- bpm beats per minute
- the lower bound of the frequency band varies linearly such that at a heart rate of about 60 the lower bound is about 0.9 Hz bpm and at a heart rate of about 180 bpm the lower bound is about 2.7 Hz.
- the term "about” or “approximately” refers to ⁇ 10 %.
- the upper bound equals Fu(HR) at all times, while in other embodiments, the upper bound is set using an iterative process.
- the lower bound equals F L (HR) at all times while in other embodiments the lower bound is set by an iterative process.
- a dynamically varying band pass filter (BPF) characterized by a dynamically varying upper frequency bound and a dynamically varying lower frequency bound, according to some embodiments of the present invention is illustrated in Figure 2c.
- BPF band pass filter
- Figure 2c depicts a BPF in which the lower bound is about 0.9 Hz and the upper bound is about 6 Hz.
- Figure 3 a is a flowchart diagram of a method suitable for processing an input signal, according to various exemplary embodiments of the present invention.
- the method can be executed by activating filtering device 10 or using any other filtering device supplemented by appropriate circuitry.
- Selected steps of the method can be embodied in many forms.
- the selected steps can be embodied in on a tangible medium such as a computer for performing the selected steps.
- the selected steps can be embodied on a computer readable medium, comprising computer readable instructions for carrying out the selected steps.
- the selected steps can also be embodied in electronic device having digital computer capabilities arranged to run the computer program on the tangible medium or execute the instruction on a computer readable medium.
- the method begins at step 30 and continues to step 31 in which the physiological condition of the subject is determined.
- the physiological condition can be, as stated, a heart rate and it can be determined using any procedure known in the art, such as, but not limited to, analysis of an electrocardiogram (ECG) signal or the like.
- ECG electrocardiogram
- the method continues to step 32 in which a frequency band is selected based on the physiological condition of the subject, and proceeds to step 33 in which the input signal is filtered according to frequency band.
- the method loops back to step 31 so as to dynamically adapt the frequency band in response to a change in the physiological condition.
- the selection of frequency band can be according to any adaptation scheme, including, without limitation, the use of one or more linear functions ⁇ e.g., the functions Fu and F L ) as further detailed hereinabove, and/or an iterative process as further detailed hereinbelow.
- the method ends at step 34.
- the iterative process can, in some embodiments, based a comparison between a value of a physiological parameter as extracted or calculated from the filtered input signal and a value of the same physiological parameter as extracted or calculated from a reference signal, for example, an ECG signal.
- physiological parameter refers to any variable parameter which is measurable or calculable and is representative of a physiological activity, particularly, but not necessarily, activity of the heart.
- the physiological parameter is other than the heart rate per se.
- the physiological parameter can be a time-related parameter, amplitude-related parameters or combination thereof.
- the filter signal and the reference signal are expressed in terms of amplitude as a function of the time.
- time-related parameters are typically calculated using abscissa values of the signals and amplitude-related parameters are is typically calculated using ordinate values of the signals.
- time-related physiological parameters suitable for the present embodiments include, without limitation, systolic time, diastolic time, pre-ejection period and ejection time.
- a representative example of amplitude-related physiological parameter suitable for the present embodiments includes, without limitation, cardiac contractility, maximal amplitude above zero during a single beat, maximal peak-to-peak amplitude during a single beat, and RMS level during a single beat.
- various slopes parameters such as, but not limited to, the average slope between two points over the signal.
- the physiological parameter is a ventricular ejection time (VET). While the embodiments below are described with a particular emphasis to VET as the physiological parameter, it is to be understood that more detailed reference to VET is not to be interpreted as limiting the scope of the invention in any way.
- the present inventors discovered that a significant amount of the biological information for a particular subject can be obtained from a frequency range between
- the advantage of the comparison between two different techniques for extracting or calculating the same physiological parameter is that it allows to substantially optimize the upper frequency bound of the of the band pass filter.
- the comparison in each iteration of the iterative process, the comparison is repeated. If the comparison meets a predetermined criterion, the upper frequency bound is updated by calculating an average between a low threshold for the upper bound and a high threshold for the upper bound.
- the lower frequency bound can be a constant bound, e.g., a constant frequency which is from about 0.9 Hz to about 2.7 Hz) 5 or it can be dynamic, e.g., F L (HR), HR being the heart rate of the subject before or during the respective iteration.
- the low and high thresholds for the upper bound can be set in more than one way.
- the low and high thresholds are predetermined (namely they determined ⁇ priori before the iterative process), in some embodiments, the thresholds are set in a previous iteration of iterative process, in some embodiments one of the thresholds is predetermined and the other threshold is set in a previous iteration of iterative process. In any event, the first iteration is based on two thresholds which are determined ⁇ priori before the iterative process.
- the first threshold can be about Fu(40), which in various exemplary embodiments of the invention is about 5.5 Hz
- the second threshold can be the calculated value of Fu(HR), HR being the heart rate of the subject before or during the respective iteration.
- the predetermined criterion used during the iterations can be, for example, that the results of the two calculations are similar (e.g., within about 40 % or 30 % or 25 % of each other).
- the predetermined criterion can also relate to the direction of difference between the two calculations.
- the upper bound is updated if the value of the parameter as calculated based on the reference signal is higher than value of the parameter as calculated based on the filtered signal, and for amplitude-related parameters the upper bound is updated if the value of parameter as calculated based on the reference signal is lower than the value of the parameter as calculated based on the filtered signal.
- the upper bound is typically updated if the value of the parameter as calculated based on the reference signal is higher than the value of the parameter as calculated based on the filtered signal.
- a Boolean combination between the above criteria can also be used as a criterion.
- an AND Boolean combination can be employed in which case the upper frequency bound can be updated if the results of the two calculations are similar and the calculation according to the filtered signal indicates an abnormal physiological condition while the calculation according to the reference signal indicates a normal physiological condition.
- Figure 3 b is a flowchart diagram of an iterative process for selecting the upper frequency bound, according to various exemplary embodiments of the present invention. The description is for a physiological parameter which is VET, but, as stated, it is not intended to limit the scope of the present invention to this type of physiological parameter.
- the iterative process begins at 60 and continues to 61 in which the upper frequency bound is set to the value of Fu(HR), HR being the heart rate of the subject before the initiation of the iterative process.
- the heart rate can be inputted or it can be determined by the process, e.g. , from the ECG signal.
- the process continues to 62 in which initial values are assigned to two frequency thresholds.
- the frequency thresholds are denoted in Figure 3b by Tl and T2.
- the initial value of Tl is Fu(40) and the initial value of T2 is the initial upper frequency bound.
- VET is calculated separately from the filtered input signal (63) and from a reference signal (64), e.g., ECG.
- the VET as calculated from the input signal is denoted in Figure 3 b VETl and the VET as calculated from the ECG signal is denoted in Figure 3b VET2.
- the filtered signal from which VETl is calculated is preferably obtained by filtering the input signal using a band pass filter defined between the upper and lower frequency bounds as initially set at 61.
- VETl is recalculated but from a signal which is filtered using an updated band pass filter.
- the lower bound of the updated band pass filter can be the initial lower bound or it can be updated based on the heart rate of the subject immediately before the filtration of the input signal (e.g., according to F L described above).
- the upper bound of the updated band pass filter is preferably the updated upper bound.
- the process continues to 68 in which the VET2 is also recalculated from the reference signal. Alternatively, the value of VET2 from 64 can be used.
- the process then continues to decision 69 in which the process determines whether or not a predetermined termination criterion is met. If the predetermined termination criterion is met, the iterative process continues to 73 where it is terminated, otherwise the process continues to decision 70 in which VETl and VET2 are compared. If the deviation between VETl and VET2 is lower than a predetermined threshold ⁇ and VETl is lower than VET2, the process continues to 71 at which the value of the upper bound is assigned to T2, otherwise the process continues to 72 at which the value of the upper bound is assigned to Tl.
- the threshold ⁇ employed at decision 70 is typically expressed as a fraction of VET2 or a fraction of (VET2-VET1)/VET2.
- the termination criterion employed at decision 69 can be for example, a maximal number of iterations.
- the process counts the number of iterations and compares them to a predetermined iteration number threshold. If the number of iterations exceeds iteration number threshold the process determines that the termination condition is met and continues to end 73.
- the value of the predetermined iteration number threshold is from about 3 iterations to about 10 iterations, e.g., 5 or 6 iterations.
- the VET (either VETl or VET2) can be calculated over a single heart beat, or, more preferably, it can be averaged over two or more heart beats.
- the advantage of using an averaging procedure rather than using a single beat is that it attenuates random disturbances which may be present in the signal during the iterative process. Nevertheless, extraction of the VET from a single beat is not excluded from the scope of the present invention.
- the calculation of VET can be performed by characterizing the morphology of the beat, identifying two or more identifiable points on the beat and measuring the time between the identified points.
- Figure 3 c illustrates a procedure for extracting VET2 when the reference signal is an ECG signal. Shown in Figure 3c is a typical morphology of a single beat of an ECG signal as a function of the time. VET2 can be defined as the time period (difference between the abscissa values) between the R peak and the T peak of the ECG signal.
- the value of VETl is preferably extracted from the first derivative of the filtered signal.
- the procedure is illustrated in Figure 3d, which illustrates a typical morphology of a single beat of the hemodynamic reactance N and its first derivative dN, as a function of the time.
- dN has two zeroes O 1 and O 2 over the beat, with a point of local maximum M 1 between the zeroes and a point of local minimum M 2 after the second zero.
- VETl is defined as the time period (difference between the abscissa values) between the first zero O 1 and the first minimum M 2 after the second zero O 2 .
- the beat morphology of the filtered signal can be characterized by identifying identifiable points on the reference signal and using the time associated with these points (abscissa values) for defining anchor points on the filtered signal.
- a single beat of dN (first derivative of the hemodynamic reactance ⁇ ) is defined between two anchor endpoints: a first (left) endpoint has the abscissa value of the Q peak of the ECG signal, and a second (right) endpoint has the abscissa value of the R peak of the next ECG signal.
- a single beat of dN has a width which equals the following sum of five successive intervals over the ECG: QR + RS + ST + TQ + QR.
- a single beat of dN is defined using three anchor points: the two anchor endpoints as described in Figure 3e and an intermediate anchor point which has the abscissa value of the global maximum A of the hemodynamic reactance ⁇ between the two endpoints.
- the calculation can be done in more than one way.
- the same morphology characterization is employed for a plurality of beats over a predetermined interval of the respective signal, so as to provide one local VET for each beat.
- the VET can be defined as the average of all local VETs.
- Any averaging procedure can be employed, include, without limitation, arithmetic mean, weighted average, geometric mean, harmonic mean, RMS and the like.
- the morphologies of the beats are averaged over an ensemble of beats in the filtered signal, to provide an average beat morphology, and the VET is be determined by identifying two or more identifiable points on the average beat morphology and measuring the time between the identified points.
- the morphology can be characterized as described above and all the morphologies can be averaged, e.g., point by point.
- the morphologies can also be averaged in segments. This embodiments is particularly useful when a single beat is defined using more than two anchor points in which case each segment over the beats (between two successive anchor points) can be averaged, e.g., point-by-point.
- the average beat morphology can then be obtained by stitching the averaged segments.
- the beat is defined using two intermediate anchor points and an intermediate point.
- each beat has a left segment (from the abscissa value of Q to the abscissa value of A) and a right segment (from the abscissa value of A to the abscissa value of R).
- the left segments of all beats in the ensemble can be averaged to provide a left segment average
- the right segments of all beats in the ensemble can be averaged to provide a right segment average.
- the average beat morphology can be obtained by stitching the left segment average to the right segment average.
- the time scale of the beats in the ensemble is adjusted so as to fit all the beats in the ensemble to a single time scale.
- the result of this average is a single beat morphology from which VETl can be extracted as described above.
- the average morphology typically has the shape illustrated in Figure 3d.
- VETl can then be extracted as the time period between O 1 and O 2 .
- the first derivative of the signal can be calculated before or after averaging.
- the averaging procedure described above is performed with respect to the derivative of the signal.
- the averaging procedure described above is performed with respect to the signal and the obtained average is then differentiated. Calculation of the first derivative after averaging is preferred from the standpoint of noise reduction.
- the predetermined time period over which an averaging procedure is performed to extract the VET typically extends over about 10 heart beats.
- a particular advantage of the device and method of the present embodiments is that they can be implemented in many systems designed for measuring or monitoring electrical properties of body sections, thereby improving their performance, e.g., by increasing their signal to noise ratio at least for situations in which the amount of noise is high.
- Representative examples of such systems include, without limitation, a system for monitoring blood flow, cardiac output and/or stroke volume, which can be similar to or based on the systems disclosed in U.S. Published Application No. 2006020033 and International Patent Publication No. WO2006/087696, the contents of which are hereby incorporated by reference; a system for predicting body cell mass, fat free mass and/or total body water of a subject, which can be similar to or based on the system disclosed in U.S. Patent No.
- FIG. 4 is a schematic illustration of apparatus 40 for monitoring one or more electrical properties of an organ of a subject 121, according to various exemplary embodiments of the present invention.
- Apparatus 40 comprises an input unit 42 for receiving an input radiofrequency signal sensed from the organ.
- the input radiofrequency signal typically comprises a radiofrequency signal related to the electrical properties of the organ (e.g., bioimpedance which may generally relate to the impedance and/or hemodynamic reactance of the organ).
- the signal is sensed from one or more sensing locations 48 on the organ of subject 121 and is originated from an output radiofrequency signal 124 generated by a radiofrequency generator 122.
- the input radiofrequency signal can include one or more noise components, which may be introduced into the signal due to various reasons, e.g., subject agitation or breathing. In various exemplary embodiments of the invention apparatus 40 is capable of reducing or eliminating these noise components.
- Apparatus 40 further comprises a signal processing unit 44 which processes the input radiofrequency signal.
- the processing may include, for example, mixing, demodulation, determination of phase shift, analog filtering, sampling and any combination thereof.
- Signal processing unit 44 may or may not be in communication with radiofrequency generator 122, as desired.
- a representative example of signal processing unit 44 is provided hereinunder with reference to Figure 5.
- Apparatus 40 further comprises a filtering unit 46 which filters the processed input signal. Unit 46 preferably performs the filtration operation in the frequency domain.
- a series of samples of the processed radiofrequency signal is transformed, e.g., by a Fast Fourier Transform (FFT), to provide a spectral decomposition of the signal in the frequency domain.
- FFT Fast Fourier Transform
- the transformation to the frequency domain can be done by a data processor. Algorithms for performing such transformations are known to those skilled in the art of signal processing.
- unit 46 The obtained spectral decomposition of the signal is filtered by unit 46 which typically eliminates one or more of the frequencies in the spectrum, depending on the upper and lower frequency bounds of the filter employed by unit 46.
- Unit 46 preferably employs a dynamically variable filter.
- unit 46 can comprise filtering device 10 as described above.
- the signal is transmitted to a monitoring unit 52 which monitors the electrical property or properties of the organ based on filtered signal.
- Unit 52 can monitor the electrical property by recording it and/or transmitting it to an external device, such as a display device and/or a computer.
- the dynamically variable filter can be adapted in response to a change in the physiological condition of the subject, as further detailed hereinabove.
- Apparatus 40 is optionally and preferably designed for determining a phase shift ⁇ of signal 126 relative to signal 124. This can be done using a phase shift determinator 50 (not shown, see Figure 5) which can operate according to any known technique for determining a phase shift.
- the phase shift can be determined for any frequency component of the spectrum of radiofrequency signals received from the organ. For example, in one embodiment, the phase shift is determined from the base frequency component, in another embodiment the phase shift is determined from the second frequency component, and so on. Alternatively the phase shift can be determined using several frequency components, e.g., using an appropriate averaging algorithm.
- phase shift of the input signal, as received from the organ, relative to the output signal as generated by generator 122 is indicative of the blood flow in the organ.
- the blood flow is determined using the phase shift (A ⁇ ).
- the advantage of using A ⁇ for determining the blood flow is that the relation between the blood flow and A ⁇ depends on fewer measurement-dependent quantities as compared to prior art determination techniques in which the impedance is used. Specifically, it was found by the Inventor of the present invention that there is a linear relationship between A ⁇ and the blood flow, with a proportion coefficient comprising the systolic ejection time, T.
- apparatus 40 comprises a data processor 142, configured for calculating at least one quantity using the filtered signal.
- Data processor 142 can also be employed by unit 46 for performing the transformation to the frequency domain and/or eliminating the frequency components according to the dynamically variable frequency bounds.
- processor 142 calculates blood- volume related quantities, such as, but not limited to, a stroke volume, a cardiac output and a brain intra luminal blood volume.
- monitoring unit 46 can monitor the quantity calculated by processor 142.
- processor 142 can calculate the quantity based on the phase shift.
- Figure 5 schematically illustrates signal processing unit 44, according to various exemplary embodiments of the present invention.
- Unit 44 preferably comprises a mixer 128, electrically communicating with generator 122, for mixing signal 124 and signal 126, so as to provide a mixed radiofrequency signal.
- Signals 124 and 126 may be inputted into mixer 128 through more than one channel, depending on optional analog processing procedures (e.g., amplification) which may be performed prior to the mixing.
- Mixer 128 may be any known radiofrequency mixer, such as, but not limited to, double-balanced radiofrequency mixer and unbalanced radiofrequency mixer.
- the mixed radiofrequency signal is composed of a plurality of radiofrequency signals, which may be, in one embodiment, a radiofrequency sum and a radiofrequency difference.
- a sum and a difference may be achieved, e.g., by selecting mixer 128 such that signal 124 and signal 126 are multiplied thereby. Since a multiplication between two frequencies is equivalent to a frequency sum and a frequency difference, mixer 128 outputs a signal which is composed of the desired radiofrequency sum and radiofrequency difference.
- the advantage in the production of a radiofrequency sum and a radiofrequency difference is that whereas the radiofrequency sum includes both the signal, which is indicative of the electrical property, and a considerable amount of electrical noise, the radiofrequency difference is approximately noise-free.
- unit 44 further comprises a phase shift determinator 50 for determining the phase shift of the input signal relative to the output signal.
- Phase shift determinator 50 can determine the phase shift according to any technique known in the art.
- the phase shift can be determined from the radiofrequency difference outputted from mixer 128.
- processing unit 44 further comprises electronic circuitry 132, which filters out a portion of the signal such that a remaining portion of the signal is characterized by a substantially increased signal- to-noise ratio.
- Circuitry 132 is better illustrated in Figure 6.
- circuitry 132 comprises a low pass filter 134 to filter out the high frequency content of the signal.
- Low pass filter 134 is particularly useful in the embodiment in which mixer 128 outputs a sum and a difference, in which case low pass filter 134 filters out the radiofrequency sum and leaves the approximately noise-free radiofrequency difference.
- Low pass filter 134 may be designed and constructed in accordance with the radiofrequency difference of a particular system which employs apparatus 40.
- a judicious design of filter 134 substantially reduces the noise content of the remaining portion.
- a substantial amount of the noise of the received signal is folded into the remaining signal, which is thus characterized by a bandwidth of about 2 kilohertz. It has been found by the inventor of the present invention that by including output radiofrequency signal 124 and by mixing it with input radiofrequency signal 126, the noise in the resulting signal is characterized by a bandwidth that is at least one order of magnitude below the noise bandwidth of conventional systems.
- mixer 128 and circuitry 132 are designed and constructed for increasing the signal-to-noise ratio by at least 20 dB, more preferably by 25 dB, most preferably by 30 dB.
- Circuitry 132 preferably comprises an analog amplification circuit 136 for amplifying the remaining portion of the signal.
- the construction and design of analog amplification circuit 136 is not limited, provided circuit 136 is capable of amplifying the signal.
- a non limiting example of amplification circuit 136 is further detailed herein below in the Examples section that follows.
- circuitry 132 further comprises a digitizer 138 for digitizing the signal.
- the digitization of the signal is useful for further digital processing of the digitized signal, e.g., by a microprocessor.
- circuitry comprises a differentiator 140 (either a digital differentiator or an analog differentiator) for performing at least one time-differentiation of the measured impedance to obtain a respective derivative (e.g., a first derivative, a second derivative, etc.) of the electrical property.
- Differentiator 140 may comprise any known electronic functionality (e.g., a chip) that is capable of performing analog or digital differentiation. Time-derivatives are useful, for example, when the electrical property is bioimpedance and the apparatus is employed in a system for measuring stroke volume or cardiac output, as further detailed hereinafter.
- signal processing unit 44 comprises an envelope elimination unit 135 which reduces or, more preferably, eliminates amplitude modulation of signal 126.
- unit 135 maintains the phase modulation of signal 126.
- the output of unit 135 thus represents the phase (or frequency) modulation of signal 126.
- Unit 135 can employ, for example, a limiter amplifier which amplifies signal 126 and limits its amplitude such that the amplitude modulation is removed.
- the advantage of the removal of the amplitude modulation is that it allows a better determination of the phase shift A ⁇ between the input and output signals, as further detailed hereinabove.
- System 120 preferably comprises a radiofrequency generator 122, for generating an output radiofrequency signal.
- Generator 122 may be embodied as any radiofrequency generator, such as, but not limited to, radiofrequency generator 112 of system 110.
- System 120 further comprises a plurality of electrodes 125, which are connected to the skin of subject 121. Electrodes 125 transmit output radiofrequency signal 124, generated by generator 122 and sense input radiofrequency signal 126 originated from the organ of subject 121.
- System 120 preferably comprises any of the components of apparatus 40 described above.
- system 120 further comprises a detector 129 for detecting a voltage drop on a portion of the body of subject 121 defined by the positions of electrodes 125.
- detector 129 preferably generates a signal which is indicative of impedance of the respective portion of the body.
- the stroke volume can be calculated using (dX/d ⁇ max , as further detailed hereinabove. Knowing the stroke volume, the cardiac output is calculated by multiplying the stroke volume by the heart rate of the subject. More preferably, detector 129 generates a signal which is indicative of a hemodynamic reactance, X.
- system 120 may further comprise a pacemaker 144.
- the data processor (not shown, see Figure 4) is preferably programmed to electronically control pacemaker 144 in accordance with the calculated quantity.
- the data processor calculates the cardiac output and sends signals to pacemaker 144 which controls, substantially in real-time, the heart rate of subject 121, so as to improve the cardiac output.
- system 120 may also comprise a cardiac assist device 148, preferably constructed and design for increasing the cardiac output.
- Cardiac assist devices are known in the art and typically comprise a reinforcing member which restricts an expansion of a portion of the heart tissue, so that the cardiac output is increased.
- the data processor is preferably programmed to electronically control device 148 in accordance with the calculated cardiac output, so that both the determination and the improvement of the cardiac output are automatically performed by system 120.
- system 120 comprises a drug administrating device 146.
- Device 146 serves for administrating drugs to subject 121.
- the data processor is preferably programmed to electronically control device 146, in accordance with the value of the calculated quantity. For example, if the calculated quantity is the brain intra luminal blood volume, then, depending on the value of the blood volume, the data processor sends signal to device 146 and thereby controls the amount and/or type of medications administered to subject 121.
- any number of electrodes of system 125 or connection configurations of electrodes 125 to subject 121 are not excluded from the present invention.
- Any type of electrode, in any combination may be used, for measuring blood flow in any artery of the body, such as, but not limited to, the external carotid artery, the internal carotid artery, the ulnar artery, the radial artery, the brachial artery, the common iliac artery, the external iliac artery, the posterior tibial artery, the anterior tibial artery, the peroneal artery, the lateral plantar artery, the medial plantar artery and the deep plantar artery.
- system 120 When system 120 is used together with other systems it is desired to minimize the area occupied by electrodes 125 so as not to interfere the operation of the other systems. For example, in intensive care units, the subjects are oftentimes connected to
- ECG leads, arterial line, central venous line, brain stem evoked response equipment, chest tubes, GI tube, intravenous and the like.
- Figures 8a-e are schematic illustrations showing perspective (Figure 8a), front ( Figure 8b), rear ( Figure 8c), side ( Figure 8d) and top ( Figure 8e) views of a sticker 141 which can be used for transmitting and sensing the radiofrequency signal, according to one embodiment of the present invention.
- the sticker comprises electrical contacts 145 being as fixed and predetermined distance therebetween, thus reducing any the effect of variable inter-electrode distance on the measurement. Two such contacts 145a and 145b are shown in Figure 8b, but any number of contacts can be employed, with the provision that there are at least two contacts.
- the sticker can be connected to system 120 via a connector 143. Connector 143 is optionally foldable to facilitate packaging and storage of sticker 141.
- connector 143 includes two conductive members 149a and 149b devoid of electrical communication therebetween.
- Each of electrical contacts 145a and 145b is in electrical communication with one conductive member of connector 143 via a different internal conducting line 147a and 147b.
- sticker can be connected to system 120 using a single line, because connector 143 interfaces communication for both contacts.
- Figure 8f is a schematic illustration of a package of several stickers (four such stickers are shown in the exemplary illustration of Figure 8f), where each sticker can be similar to sticker 141 described above. Also shown in Figure 8f are exemplary dimensions and distances of the package and the individual stickers.
- the output radiofrequency signal is preferably from about 10 KHz to about 200 KHz in frequency and from about 1OmV to about 20OmV in magnitude; the input radiofrequency signal is preferably about 75 KHz in frequency and about 2OmV in magnitude; a typical impedance which can be measured by the present embodiments is from about 5 Ohms to about 75 Ohms; the resulting signal-to-noise ratio of the present embodiments is at least 4OdB; low pass filter 134 is preferably characterized by a cutoff frequency of about 35Hz and digitizer 138 preferably samples the signal at a rate of about 500-1000 samples per second.
- the prototype system includes:
- a double balanced mixer purchased from Mini-Circuits, used for providing a radiofrequency sum and a radiofrequency difference, as detailed above.
- the prototype system further includes electronic circuitry formed in a printed circuit board.
- electronic circuitry formed in a printed circuit board.
- Several electronic circuitries were designed and manufactured, so as to investigate the correlation between the qualities of the results, the design of the electronic circuitry and the number of electrodes.
- the various electronic circuitries are schematically illustrated in Figures 9a-d.
- Figure 9a shows a block diagram of electronic circuitry to be used with three electrodes.
- the electrodes leads are designated in Figure 9a by E 1 , E 2 and Ij, where the output radiofrequency signal, generated by the radiofrequency generator (designated
- OSC is outputted through E 1 and E 2 and the input radiofrequency signal, as measured of the body is inputted through I 1 .
- the input signal is channeled through a differential amplifier G 1 , a band pass filter BPF and a differential amplifier G 2 .
- the input signal is channeled through a differential amplifier G 3 , a band pass filter BPF and an envelope elimination unit EEU.
- the EEU eliminates the amplitude modulation from the input signal.
- Both input and output signals are mixed by mixer DMB, to form, as stated, a frequency sum and a frequency difference.
- a low pass filter LPF filters out the frequency sum and the resulting signal (carrying the frequency difference) is further amplified by additional differential amplifiers G 5 , G 6 and G 7 .
- the signal is digitized by an analog to digital digitizer and passed, via a USB communication interface to a processing and display unit.
- the processing unit includes a dynamically variable filter according to various exemplary embodiments of the present invention.
- Figure 9b shows a block diagram of electronic circuitry to be used with two electrodes of brain intra-luminal blood volume measurements. As there are only two electrodes E 2 and Ii are combined to a single lead I 1 .
- the output signal is channeled through a differential amplifier G 1 , a band pass filter BPF and a differential amplifier G 2 .
- the input signal is channeled through a differential amplifier G 2 , a band pass filter BPF and an envelope elimination unit EEU which eliminates the amplitude modulation from the input signal.
- Both input and output signal are mixed by mixer DMB, to form the frequency sum and difference.
- the low pass filter LPF filters out the frequency sum and the resulting signal is further amplified by additional differential amplifiers G 4 , G 5 and G 6 .
- the signal is digitized by an analog to digital digitizer and passed, via a USB communication interface to a processing and display unit.
- Figure 9c shows a block diagram of electronic circuitry to be used with four electrodes.
- the four leads, designated E 1 , E 2 , 1 1 and I 2 where the output radiofrequency signal, generated by radiofrequency generator OSC, is outputted through E 1 and E 2 and the input radiofrequency signal, as measured of the body are inputted through I 1 and I 2 .
- the four leads, E 1 , E 2 , 1 1 and I 2 are connected to the body through capacitors designated C 1 , C 2 , C 3 and C 4 .
- FIG. 9c shows a block diagram of the analog amplification circuit, which was used to amplify the radiofrequency signal after the low pass filtering in which the radiofrequency sum was filtered out.
- Example 1 The prototype system described in Example 1 was tested on human volunteers.
- the present Example includes a representative collection of trials performed on four of the volunteers.
- Each subject was connected to four electrodes of the prototype system. Two electrodes served for input/output radiofrequency signals and two served as ECG leads. A radiofrequency signal pertaining to hemodynamic reactance was sampled at a sampling rate of 500 samples per second during continuous time intervals of 8 seconds.
- the signal was filtered by an analog low pass filter of 9 Hz.
- An ECG signal was sampled at the same rate (500 samples per seconds) and filtered using an analog filter of 250 Hz.
- the signals acquired from each subject were filtered using two types of digital filters: a fixed filter with a lower bound of 0.9 Hz and an upper bound of 6 Hz, and a dynamically variable filter in which the frequency bounds were varied in response to changes in the heart rate of the respective subject. To this end, the linear dependence as illustrated in Figures 2a-b was used.
- Figures 10a-e show snapshots of the display of the prototype system obtained during a trial in which the electrodes of the system were connected to subject No. 1. Signals were acquired while the subject was stable (heart rate of 95 bpm).
- Figures 10a-b show results obtained using a fixed filter (Figure 10a) and dynamically variable filter (Figure 10b).
- Figures 10a-b there are seven curves, designated, from top to bottom, I, II, dl, dll, N, dN and ddN.
- the four top curves (I, II, dl and dll) are ECG signals (leads I and II) and derivatives thereof (dl and dll, respectively).
- the three lowermost curves (N, dN and ddN) correspond to a hemodynamic reactance (N), its first time-derivative (dN) and second time-derivative (ddN).
- the right pane of Figure 10a show various calculated values, such as heart rate (BPM), cardiac output (CO), stroke volume (SV), ventricular ejection time (VETM), and the like.
- Figures lOc-d demonstrate the data analysis performed to provide the results presented in Figures 10a-b.
- Figure 10c demonstrates application of the fixed filter on the ECG signal
- Figure 1Od demonstrates the application of the fixed on the hemodynamic reactance signal
- Figure 1Oe demonstrates the application of the dynamically variable filter on the hemodynamic reactance signal.
- the lower and upper frequency bounds of the filter for the ECG signal were 1.2 Hz and 40 Hz, respectively; the lower and upper frequency bounds of the fixed filter for the hemodynamic reactance signal were 0.9 Hz and 6 Hz, respectively; and the lower and upper frequency bounds of the dynamically variable filter for the hemodynamic reactance signal were 1.4 Hz and 6.9 Hz, respectively.
- the abscissae are scaled to 300 ms per division in the time domain representations, and 3 Hz per division in all frequency domain representations.
- the abscissae are scaled to 300 ms per division in the time domain representations, and 0.5 Hz per division in the frequency domain representations.
- Figures l la-e show snapshots of the display of the prototype system obtained during another trial in which the electrodes of the system were connected to subject No. 1. In this trial, the subject was also stable (heart rate of 114 bpm). The graphical representations in Figures 1 la-e correspond to the same observables as Figures 10a-e.
- the lower and upper frequency bounds of the fixed filters were the same as in the trial above.
- the lower and upper frequency bounds of the dynamically variable filter for the hemodynamic reactance signal were 1.7 Hz and 7.4 Hz, respectively.
- Figures 12a-e show snapshots of the display of the prototype system obtained during another trial in which the electrodes of the system were connected to subject No. 1. In this trial, the subject was agitated (heart rate of 140 bpm).
- the graphical representations in Figures 12a-e correspond to the same observables as Figures 10a-e.
- the lower and upper frequency bounds of the fixed filters were the same as in the trials above.
- the lower and upper frequency bounds of the dynamically variable filter for the hemodynamic reactance signal were 2.1 Hz and 8 Hz, respectively.
- Figures 13a-e show snapshots of the display of the prototype system obtained during another trial in which the electrodes of the system were connected to subject No. 1. In this trial, the subject was also agitated (heart rate of 137 bpm).
- the graphical representations in Figures 13a-e correspond to the same observables as Figures 10a-e.
- the lower and upper frequency bounds of the fixed filters were the same as in the trials above.
- the lower and upper frequency bounds of the dynamically variable filter for the hemodynamic reactance signal were 2.1 Hz and 7.9 Hz, respectively.
- Figures 14a-e show snapshots of the display of the prototype system obtained during a trial in which the electrodes of the system were connected to subject No. 2. In this trial, the subject was agitated (heart rate of 121 bpm). The graphical representations in Figures 14a-e correspond to the same observables as Figures 10a-e. The lower and upper frequency bounds of the fixed filters were the same as in the trials above. The lower and upper frequency bounds of the dynamically variable filter for the hemodynamic reactance signal were 1.8 Hz and 7.5 Hz, respectively.
- Figures 15a-e show snapshots of the display of the prototype system obtained during another trial in which the electrodes of the system were connected to subject No. 2.
- Figures 16a-g show snapshots of the display of the prototype system obtained during a trial in which the electrodes of the system were connected to subject No. 3. In this trial, the subject was agitated (heart rate of 121 bpm).
- the graphical representations in Figures 16a-b correspond to the same observables as Figures 10a-b
- the graphical representations in Figures 16e-g correspond to the same observables as Figures lOc-e.
- Figures 16c-d are respective zoom-in images of Figures 16a-b.
- the lower and upper frequency bounds of the fixed filters were the same as in the trials above.
- the lower and upper frequency bounds of the dynamically variable filter for the hemodynamic reactance signal were 1.8 Hz and 7.5 Hz, respectively.
- Figures 17a-g show snapshots of the display of the prototype system obtained during a trial in which the electrodes of the system were connected to subject No. 4. In this trial, the subject was agitated (heart rate of 139 bpm).
- the graphical representations in Figures 17a-g correspond to the same observables as Figures 16a-g.
- Figures 17c-d are respective zoom-in images of Figures 17-b.
- the lower and upper frequency bounds of the fixed filters were the same as in the trials above.
- the lower and upper frequency bounds of the dynamically variable filter for the hemodynamic reactance signal were 2.1 Hz and 8 Hz, respectively.
- the dynamically varying filter significantly improves the quality of the results, particularly when the subjects are agitated ( Figures 12a-17g).
- the dynamically variable filtering technique of the present embodiments allows consistent calculation of CO values.
- the two filtering techniques resulted in different CO values: 35.6 L/min for the fixed filtering technique and 21.99 L/min for dynamically variable filtering technique. Similar improvements were observed in other subjects.
- Plots of cardiac output as calculated from signals filtered using the two filtering techniques are shown in Figures 18a-b, 19a-b and 20a-b for subjects Nos. 2, 3 and 4, respectively.
- Figures 18a, 19a and 20a show results obtained using the dynamically variable filter of the present embodiments and Figures 18b, 19b and 20b show results obtained using fixed filter. As demonstrated, the CO values obtained using the dynamically variable filter of the present embodiments are more accurate.
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EP08789780A EP2182847B1 (en) | 2007-08-13 | 2008-08-11 | Dynamically variable filter |
AU2008288084A AU2008288084B2 (en) | 2007-08-13 | 2008-08-11 | Dynamically variable filter |
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US20150272450A1 (en) | 2015-10-01 |
US8790267B2 (en) | 2014-07-29 |
US20090048497A1 (en) | 2009-02-19 |
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EP2182847B1 (en) | 2013-03-06 |
AU2008288084A1 (en) | 2009-02-19 |
AU2008288084B2 (en) | 2013-03-07 |
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WO2009022330A3 (en) | 2009-05-22 |
US20110218419A1 (en) | 2011-09-08 |
US10842386B2 (en) | 2020-11-24 |
CA2695726A1 (en) | 2009-02-19 |
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