MICRO DEVICE FOR MEASURING TISSUE IMPEDANCE
A micro-device for measuring impedance of animal tissue by simulating alternating current with low power direct current to provide a miniaturized device that carries out electrical impedance procedures.
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There is a need for Electrical Impedance Spectroscopy (EIS) in a variety of industries. For example, this technique, that employs alternating current, is used to measure two-terminal impedance over a wide frequency range in material and biomedical sciences. With measurement frequencies less than about 100 KHz, the EIS technique often uses a Kelvin type connection to the target material. The Kelvin method normally drives a constant and known sinusoidal current of specified frequency into the target material using one pair of electrodes and then, with a second pair of interposed electrodes, measures the real and imaginary voltage components using multiplicative phase detectors, amplifiers and data acquisition methods. The ratio of these “real” and “imaginary” voltages to the known drive current is the impedance at the drive frequency. The physical equipment to implement EIS is normally quite large as compared to, say, a postage stamp.
Further, this equipment requires multiple watts of power during operation. However, new applications for EIS require substantial miniaturization and extremely low power compatible with long term, unattended battery operation.
For example, the medical arena of wearable medical monitors is now becoming popular and, in particular, Electrical Impedance Tomography holds promise for identifying various medical disorders before they are otherwise apparent. This application requires that a plurality of EIS devices be placed on a patient's body and that ideally, the person must be ambulatory and able to function normally. Further, EIS has been shown to be particularly helpful in the prediction of fluid build-up in tissue. These applications require a substantially smaller measurement device which operates with micro-watts of average power. No such device is known to be available.
What is sought is an EIS means and method which is capable of measuring bio-logical impedances from 10 Hz to 100 KHz, capable of being miniaturized to approximately one-half the size of a postage stamp with a thickness of tens of mills and able to function on similarly small batteries for days to months. Further, it's collected EIS data must be wirelessly accessed on a regular interval to fulfill its “wearable” mission. The subject invention employs very small micro-computer based techniques with a minimal number of external components to accomplish the above goals and is hereafter called the Pulsed-Kelvin Impedance Measurement method (PKIM).
SUMMARY OF THE INVENTIONThe system and the method of this invention is herein referred to as Pulsed Kelvin-connected Impedance Measurement (PKIM). PKIM can be employed wherever miniaturization and low power usage are required to determine potential of current flow through a biological load such as, for example, measuring impedance of biological tissue.
In accordance with the invention, timed, binary voltage pulses of known frequency, amplitude and driver resistance are applied to a material, typically a biological load, via at least two separate electrodes operatively connected to specifically timed sample and hold circuits. The voltage output from these sample and hold circuits is converted to numbers with one or more analog-to-digital convertors (ADC). By a combination of local data processing and post-processing of these numbers, the desired EIS data is extracted and reported.
As used hereinafter the term “biological load” refers to biological tissue for which determination of tissue impedance is desired.
As used herein the term “sample” means a rapid closure, then opening of a switch which is coupled to a time varying voltage source. The switch closure time is understood to be small compared to the time rate of change of the voltage source. This switch may be coupled to an ADC or a sample and hold capacitor for charge-up purposes.
“Sampling” may be considered to be the act of sensing a potential at a specific point in time on a time varying potential source, and this potential source may have a non-zero source impedance.
“Binary” as applied to current pulses means that the pulse may be positive or negative depending on the polarity of the circuit.
Referring to
As illustrated a four-electrode configuration of the micro device of the invention is shown and described. However, it will be understood that as few as two or more than four electrodes may be used. Best results in regard to component parts, impedance results and miniaturization are obtained by the preferred four electrode configuration.
As shown, a low power direct current supply line 11 provides supply current (Vs) from a source of low power direct current (not shown) to a micro-controller 12. Micro-controller 12 controllably drives current-limited binary current pulses of supply current through resistors 17, 18 and 19 into a biological load via the positive driving electrode 14 and negative driving electrode 16. The current pulses are positive when supply current is drawn through current supply line 11 and negative when supply current is drawn through common line 28. Micro-controller 12 controllably switches between the supply line I1 and the common line 28 to alternate the polarity of the supply current and the resultant pulses.
The current is limited by resistors 17 (1.0K), 18 (3.16K) and 19 (10K) which may be enabled by the micro-controller 12 in any combination. These resistors set a desired range of current injected into the tissues via electrodes 14 and 16. It is understood by one skilled in the art that additional resistors and microcontroller port drivers could be employed if so desired. The actual current driven into the tissues may be computed by measurement of the potential at electrode 14 (Vel) and a knowledge of the pulse drive voltage, (VgP) for positive pulses and at electrode 16 and a knowledge of pulse drive voltage (VgN) for negative pulses. VgP and VgN are typically either the micro-computer's supply voltage for positive pulse production or supply voltage through the local common 28 for negative pulse production.
The center pair of Kelvin-configured electrodes 21 and 22 are each series connected to the fast analog switches 24 which in turn are connected to relatively large storage sample and hold capacitors 25, (Cl), and the micro-controller 12 to accumulate charge from specifically timed samples of the tissue potentials through line 38a, 38b and 38c. Micro-controller 12 operates the fast-acting analog switches 24 for timed, rapid closing and opening to make and break a circuit between each of the electrodes 21 and 22 and their respective sample and hold capacitors 25 for sensing a segment of the potential of a pulse at a specific point in time on a pulse waveform and accumulating an incremental segment of the potential of each of the pulses through the bioload until maximum potential is accumulated. The sample and hold capacitors 25 permit conventional, slower sampling analog to digital converters 26 (ADC's) to be used without incorporating active operational amplifier buffers at the electrode nodes 14, 16, 20 and 22. This reduces parts count and power draw, both critical to the intended applications.
As illustrated, the polarity of the circuit is positive, and the resulting pulses are positive.
Reversing current flow by drawing the supply voltage through the local common 28 reverses polarity of the circuit and the resulting pulses are negative.
Circuit polarity is controlled by the micro-controller 12.
1. By application of PKIM, applicant:
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- a. substantially reduces the parts count and size of the circuitry as compared to conventional AC coupled, sine-wave driven, dual-phase detector EIS;
- b. measure real and imaginary impedance components of any impedance in a frequency range under approximately 100 KHz provided the impedance does not rise sharply with frequency.
- c. in the special case of human tissue impedance, extract the real component of a low frequency (25 Hz), mid-frequency (2 KHz) and high frequency (100 KHz) equivalent cervical tissue impedance, Re [Zc21, with good accuracy. For example, these particular impedances are an early measure of the physiological condition of tissue;
- d. measure the total electrode to electrode impedance (14 to 16) over a similar range of frequencies. For the special-case of breast tissue impedance monitoring, this may be a more reliable indicator of cancer in a continuously monitored patient; and produce a circuit that operates on low power and can be fitted into a small sensing device.
The system of the present invention includes circuitry that is miniaturized and operates on a low voltage DC supply such as a 3 volt battery. Present day microcontrollers such as the Texas Instruments MSP430 series have become quite competent with peripheral resources and the invention's methods attempt to take advantage of those capabilities to reduce parts count and size of the PKIM process.
Conventionally, an EIS measurement system would use sinusoidal voltage drive signals to the measured tissues. PKIM uses two methods to approximate EIS using a binary pulse driver. The first method modifies the timing on the pulse wave form to better approximate the harmonic content of a sine wave.
For example, instead of complex sine-wave shaping of the voltage drive to the Kelvin electrodes, the micro-controller 12 port-driven, positive pulse (VgP) 30 and negative pulse (VgN) 31 are square wave form as shown in
By proper timing of pulse sampling, the odd harmonic components of these pulses are substantially reduced, permitting a much closer approximation to a sinusoidal drive waveform. As illustrated in
Secondly, in order to approximate a sinusoidal driven EIS system drive frequency is selected in which the pulse harmonics encounter essentially the same impedance as the fundamental frequency.
Conventionally, some embodiments of the aforementioned micro-controller 12 include up to four Delta-Sigma, 24 bit Analog-to-Digital convertors (ADC) permitting extra-ordinarily small signals to be digitized with adequate resolution for these EIS applications. However, the Delta-Sigma ADC's acquisition time is too long to acquire phase-sensitive analog data for frequencies much higher than 5 KHz while tissue monitoring may require impedance determination up to 100 KHz. Further, while available micro-controller ADC's incorporate their own sample and hold circuits, these circuits require a low-impedance drive source and are not suitable therefore to be directly connected to biological tissues. PKIM employs a novel repetitive sampling method to affect the desired measurement while using this type of ADC.
Referring to
In conventional EIS instrumentation, relatively large AC coupling sample and hold capacitor s are typically used with biological tissue measurements because the electrode to tissue conductors forms a half-cell potential which can severely bias the computed impedance results. This equivalent DC voltage is shown in
Electrodes connected to tissues typically develop half-cell potentials as shown in
To forestall their use and keep component count and size to a minimum, PKIM takes advantage of the microcontroller 12 binary port drivers 13 to invert the drive potentials at Vel and Ve4 and make a second series of sampled measurements at each frequency so that DC offsets are cancelled. For example, and with reference to
It is important to note that in practice with biological loads, that the electrode DC offsets (Vb #) will change when driven with an AC signal versus direct measurement. Thus, simply measuring Vb # by making VgP and VgN zero and then subtracting that value from AC measured sample values will not usually give a correct result. For instance, in one case, a zero excitation DC potential between two electrodes connected to a biological load measured 55 millivolts but when excited by AC currents, it increased to 83 millivolts. With a 3 V supply voltage-based measurement, this difference would cause substantial measurement error if a direct DCV offset correction method had been used.
In a conventional EIS system using Kelvin configured electrodes, a constant-current, sinusoidal signal is applied to the E1 and E4 electrodes. However, due to the low battery voltage (3 V approx.) and minimal parts count goal, a constant-current driver is not a good choice. Further, as will be described, the above DC offset correction method requires that the measured voltage drop across the Kelvin electrodes (E2, E3) not reverse in potential sign due to comparatively large bias voltages, Vb2, Vb3. This places a lower limit on the current and hence the voltage drop across the biological-load. Therefore, the pulse generator's current sensing resistor, Rg, must not be too large relative to the biological load impedance at the frequency being tested.
There is yet another important PKIM design consideration in the selection of Rg at the frequency being tested. Specifically, the selected Rg and the magnitude of the pulse amplitude potential (i.e.: the supply voltage, Vs) should not cause the total voltage across electrodes E1 and E4 to exceed approximately 2.1 volts or else electrolysis may take place at those electrode sites.
Thus, the choice of resistance, Rg, for proper PKIM operation on biological loads must be “windowed” between some minimum and some maximum value at each frequency measured before the actual measurement is made. A PKIM process for accomplishing this selection automatically is detailed in the flow diagram of
As shown in
The next actions 46 are to iteratively try each Rg value from the highest value toward the lowest values to find a drive potential which first causes the average sampled voltage, VI avg, to exceed this Ve(min) value. The sampling point was chosen to be at 45 degrees (relative to the drive wave maximum amplitude) to assure approximately equal parts of real and imaginary impedance contributions. Assuming that Vlavg is less than 2.1 vdc, then that Rg value, Rg(f) is stored and used thereafter for all EIS measurements that are made at that frequency. Once Rg values are chosen for each frequency to be measured, the PKIM method then makes impedance measurements at each pre-selected frequency. This Rg selection process is normally only performed once but may be repeated if VI is determined to be less than Ve(min) at any time in the future.
With suitable Rg values chosen, the impedance measurement process may be started. This process is summarized in
Referring to
For negative current pulses electrode 149 is at common. A variable resister 147 is in the line 146 for controlling current. Electrode 149 drives negative current pulses. The potential of each current pulse is sensed by electrodes 152 and 153 and the sensed charge is passed through lines 154 to sample and hold devices 156 and 157. The sample and hold device 158 determines the potential of the input current pulses before reaching the biological load 150. A series of positive and negative pulses are generated during each sampling cycle. For measuring the positive potential the pulse sampling point is preferably about 90° of the wave form until maximum positive potential is built up at the sample and hold devices 156 and 157. The sampling point along the wave form for the negative pulses is then changed by the micro-controller 140 to about 270° until maximum negative potential is built up at the sample and hold devices 156 and 157. Sampling current pulses after maximum potential is stored by the sample and hold capacitors 156 and 157 has no further effect on the stored charge. This maximum potential is routed through line 159 to an analog to digital converter 160 for digitization and the digitized potential is stored in the random-access memory of the micro-controller 140.
The digitized potential is wirelessly transmitted to an external receiver 162. The external receiver 162 may be a nearby computer for computation to impedance and subsequent display of the computed impedance or a computer or other device, such as a cell phone, that includes a more robust transmission system for relaying the digitized potential to a remote computer 164 for computing the impedance of the positive and negative pulses and for averaging the positive and negative impedance. The averaged impedance results may be displayed on any suitable monitor.
ExampleLymphedema is a chronic disease that produces swelling in body tissue due to fluids caused by a malfunction of the lymphatic system, Breast cancer patients who have had some or all the lymph nodes removed from an arm due to the progress of the cancer are subject to contracting lymphedema. Early detection and treatment can reduce the severity of the disease although in its very early stages (subclinical lymphedema) it is extremely difficult to detect by conventional clinical methods, such as measurement of the dimensions of the arm, to detect swelling in the case of breast cancer patients. Subclinical lymphedema normally progresses into chronic lymphedema. Subclinical lymphedema can exist in the body with no outward or detectable sign for months.
EIS as a screening tool for subclinical lymphedema is under study, particularly as it is non-invasive and is relatively inexpensive. The impedance of the tissue is affected by the buildup of fluid. While EIS is useful for the detection of tissue fluid the procedure requires a source of constant current alternating current and requires components that do not lend themselves to miniaturization. A patient undergoing EIS tissue screening must be physically present at the screening site while impedance data is being collected.
Unlike EIS, the micro-device of the invention employs circuitry that operates on low power DC utilizing fewer and smaller components. The microdevice of the present invention is highly suited for screening purposes as it simulates electro impedance spectroscopy (EIS) in its operation. The circuitry is packaged in a micro-device that can be conveniently worn by the patient even while the patient is ambulatory. With wireless transmission a patient using the microdevice of the invention can engage in normal everyday activities while tissue impedance data is collected at the physician's location.
Referring to
As described above in connection with
Good practice will have a micro-device 10 applied on an area of the patient's body, such as the other arm for reference impedance measurements. It will be understood that the strip 200 can be readily moved to other parts of the patient's body such as the leg where lymphedema often occurs. As an alternative embodiment, the micro-device may form part of an elastomeric or adjustable band that can be conveniently worn on the patient's arm or leg.
It will be understood that the micro-device presents a non-invasive and painless method for early detection of tissue fluid and may be utilized in a form that can be worn for an extended period. Persons at risk for tissue fluid build-up, for example breast cancer patients at risk for lymphedema, may be screened immediately after surgery and for a period of time thereafter so that tissue swelling due to fluids may be recognized early on and treatment can be started to reduce the effects of lymphedema.
It will be further understood that the PKIM method described herein can be applied in any situation where simulated alternating current using low DC power is required, particularly where miniaturization is desirable or required.
The present invention allows for the advantages of electro-impedance spectroscopy to be achieved by a micro-device powered by a low voltage direct current battery. The parts count of the micro-device is reduced allowing for substantial miniaturization.
The embodiments disclosed above are illustrative only, as the disclosure may be modified and practiced in different but equivalent manners apparent to those skilled in the art having the benefit of the teachings herein. Furthermore, no limitations are intended to the details of construction or design herein shown, other than as described in the claims below. The embodiments disclosed above may be altered or modified and all such variations are considered within the scope and spirit of the disclosure. Accordingly, the protection sought herein is as set forth in the claims below.
Claims
1. A micro-device for the measurement of tissue impedance by electrical impedance spectroscopy technique utilizing low power direct current, said device comprising:
- a. a low voltage source of direct supply current;
- b. a micro-controller operatively connected to said source of direct current by circuitry including a current supply line and a common line, said micro-controller controlling the polarity of said circuit by alternating supply current draw between the current supply line and the common line,
- c. said micro-controller controllably generating positive current pulses when said supply current is drawn through said supply current line and controllably creating negative current pulses when said supply current is drawn through said common line;
- d. a Kelvin-configured positive driving electrode operatively connected to said microcontroller for driving a series of positive pulse signals into a biological load when said supply current is drawn through said supply current line and a Kelvin configured negative driving electrode operatively connected to said micro-controller for driving a series of negative pulse signals into said biological load when said supply current is drawn through said common line;
- e. a Kelvin-configured sensing electrode series connected to a fast analog switch and a sample storage and hold capacitor for accumulating microsamples of charge of incremental specifically timed samples of potential of said series of pulse signals through said biological load as said at least one fast acting analog switch is closed by said micro-controller,
- f. at least one analog to digital converter operatively connected to said sample storage and hold capacitor for converting an accumulated charge from said storage sample and hold capacitor to digital format;
- g. wireless transmission circuitry operatively connected to said micro-controller for transmitting said accumulated charge to an external receiver for computation of impedance;
- whereby alternating current is simulated by injecting a series of positive and negative pulses of direct current into a biological load and sampling an incremental charge of a micro section of each pulse and accumulating said incremental charge of each pulse until maximum potential of said biological load is accumulated, thereafter converting said maximum accumulated potential to digital format and computing impedance therefrom.
2. The micro-device of claim 1 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein said micro-device is employed to simulate AC coupled, sine-wave driven, dual-phase detector EIS ‘using low power direct current.
3. The micro-device of claim 1 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein said positive driving electrode drives positive currant limited positive voltage pulses of known frequency into said biological load and said negative driving electrode drives negative voltage pulses of known frequency into said biological load.
4. The micro-device of claim 1 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein at least one resistor is provided in said currant supply line for limiting said supply current frequency.
5. The micro-device of claim 1 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein said supply current is limited by at least three resistors to a low frequency of 25 Hz, a mid-frequency of 2 KHz and a high frequency of 100 KHz, said current supply lines being operatively connected to said micro-controller for selection of said supply current frequency by said micro-controller.
6. The micro-device of claim 1 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein said positive pulse signals and said negative pulse signals are square wave form.
7. The micro-device of claim 1 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein said fast acting analog switch is closed by said micro-controller for a closure period of less than three microseconds to obtain a microsample of potential of each said pulse signal.
8. The micro-device of claim 6 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein said each said pulse of said series of pulses is sampled at precisely the same point on a wave form of each said pulse of said series.
9. The micro-device of claim 7 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein said each said pulse of said series of pulses is sampled at precisely the same time during the closure period of said fast acting analog switch.
10. The micro-device of claim 9 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein said series of pulses is sampled at 66% of said fast acting switch closure period.
11. The micro-device of claim 8 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein each pulse of said series of positive pulses is sampled at about 90° of said wave form.
12. The micro-device of claim 8 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein each pulse of said series of negative pulses is sampled at about 270° of said wave form.
13. The micro-device of claim 7 for the measurement of tissue impedance by electrical impedance spectroscopy technique wherein each pulse of said series of pulses is sampled at approximately 66% of closure period of said fast acting switch.
14. The micro-device for the measurement of tissue impedance by electrical impedance spectroscopy technique of claim 1 wherein a Kelvin-configured positive driving electrode is operatively connected to said positive pulse generator and a Kelvin-configured negative driving electrode is operatively connected to said negative pulse generator, said positive and negative pulse generators being alternately operated and two Kelvin-configured sensing electrodes are each series connected to said fast analog switch and said sample storage and hold capacitor for accumulating microsamples of charge of incremental specifically timed samples of potential of said series of positive and negative pulse signals through said biological load as said fast acting analog switch are closed by said micro-controller,
15. A non-invasive, wearable bioimpedance device for screening animal tissue comprising: whereby low power direct current simulates alternating current and tissue is screened by electro impedance spectroscopy (EIS) technique.
- a. a low voltage battery for supplying direct current;
- b. a micro-controller operatively connected to said source of direct current by circuitry including a current supply line and a common line, said micro-controller controlling the polarity of said circuit by alternating supply current between the current supply line and the common line,
- c. a positive pulse generator operatively connected to and controlled by said microcontroller for creating positive pulse signals when said direct current is drawn through said current supply line and a negative pulse generator operatively connected to and controlled by said micro-controller for creating negative pulse signals when said supply current is drawn through said common line;
- d. two fast acting analog switches operatively connected to said micro-controller for being opened and closed thereby,
- e. a Kelvin-configured positive driving electrode operatively connected to said positive pulse generator for driving a series of positive pulse signals from said positive pulse generator into said tissue and a Kelvin-configured negative driving electrode operatively connected to said negative pulse generator for driving a series of negative pulse signals from said negative pulse generator into said tissue, said series of positive and negative pulses being alternately driven into said tissue;
- f. a pair of Kelvin-configured sensing electrodes, each sensing electrode series connected to a fast analog switch and a sample storage and hold capacitor for accumulating microsamples of charge of incremental specifically timed samples of potential from each pulse signal of said series of pulse signals through said biological load as said at least one fast acting analog switch is closed by said micro-controller,
- g. at least one analog to digital converter operatively connected to said sample storage and hold capacitor for converting an accumulated charge from said storage sample and hold capacitor to digital format;
- h. wireless transmission circuitry operatively connected to said micro-controller for transmitting said accumulated charge to an external receiver for computation of tissue impedance; and
- i. a device for securing said bioimpedance device electrodes in place while said device is being worn;
Type: Application
Filed: Nov 2, 2021
Publication Date: May 26, 2022
Applicant: MB Device LLC (Louisville, KY)
Inventors: Thomas V. Saliga (Tampa, FL), Vasiliy Abramov (Louisville, KY)
Application Number: 17/516,805