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Claims  |
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What is claimed is:
1. An apparatus for disease screening or diagnosis at a potential disease
site on a human or animal subject by measuring the electrical potentials
which are a function of the electromagnetic fields which originate from
within the subject and are present on the skin surface of the subject in
an area of said potential disease site, comprising
a plurality of electrode means adapted for contact with the skin surface of
the subject at spaced locations in the area of the potential disease site
to detect only the potentials of said electromagnetic fields which
originate from within the subject and are present in the area of said
potential disease site during a test period and to provide test potentials
as a function of each of said potentials detected,
and processing means connected to receive said test potentials provided by
said electrode means, said processing means operating during said test
period to select at least one of said electrode means as a reference
electrode and another of said electrode means as a test electrode and to
cause said test electrode to operate with said reference electrode to
detect the potential of the electromagnetic field present therebetween and
to provide a test potential as a function thereof.
2. The apparatus for disease screening or diagnosis of claim 1, wherein
said processing means operates to select from said electrode means a
plurality of different test electrode-reference electrode combinations
during the test period and to receive test potentials from each of said
plurality of combinations.
3. The apparatus for disease screening or diagnosis of claim 2, wherein
said processing means operates to sample and receive a plurality of test
potentials from each of said selected test electrode-reference electrode
combinations during the test period and to average the test potentials for
each of said test electrode-reference electrode combinations to obtain an
average signal therefor at the end of the test period, said processing
means operating to compare said average signals obtained for a test period
to identify potential difference relationships therebetween.
4. The apparatus for disease screening or diagnosis of claim 3, wherein
said electrode means include a plurality of spaced electrodes mounted in a
unitary electrode matrix.
5. The apparatus for disease screening or diagnosis of claim 2 wherein said
processing means includes sequencer switching means connected to said
electrode means and operative to select said plurality of test
electrode-reference electrode combinations and to receive the test
potential from the plurality of selected test electrode-reference
electrode combinations.
6. The apparatus for disease screening or diagnosis of claim 5 wherein said
processing means includes amplifier means connected to said sequencer
switching means to receive and amplify test potentials from said sequencer
switching means.
7. The apparatus for disease screening or diagnosis of claim 6 wherein said
amplifier means includes a single amplifier for receiving all test
potentials from said sequencer switching means.
8. The apparatus for disease screening or diagnosis of claim 7 wherein said
processing means includes analog-to-digital converter means connected to
separately receive each said test potential from said amplifier means for
providing a separate digital test signal indicative of each said test
potential obtained during said test period.
9. The apparatus for disease screening or diagnosis of claim 8 wherein said
processing means includes filter means between said amplifier and said
analog to digital converter means, said filter means including a single
low pass filter, said filter means and amplifier means forming a single
channel between said sequencer switching means and said analog-to-digital
converter means for said test potentials.
10. The apparatus for disease screening or diagnosis of claim 5 wherein
said processing means includes analog-to-digital converter means connected
to separately receive each said test potential from said sequencer
switching means for providing a separate digital test signal indicative of
each said test potential obtained during said test period,
and central processor means connected to separately receive each said
separate digital test signal, said processor means operating to compare
said digital test signals obtained during said test period to identify
potential relationships therebetween indicative of the presence of a
disease condition.
11. The apparatus for disease screening or diagnosis of claim 10 wherein
said central processing means comprises digital test signal comparing said
digital test signals to obtain a maximum voltage differential by obtaining
from the digital test signals for said measurement period maximum and
minimum digital signals and subsequently obtaining a differential value
signal indicative of the difference between said maximum and minimum
digital signals.
12. The apparatus for disease screening or diagnosis of claim 11, wherein
said central processor means further comprises differential value signal
comparing means for comparing said differential value signal to a first
reference value, and providing an output signal indicative of the presence
of a disease condition in accordance with a relationship between said
first reference value and said differential value signal.
13. An apparatus for disease screening or diagnosis at a potential disease
site on a human or animal subject by measuring the electrical potentials
which are a function of the electromagnetic field present on the skin
surface of the subject in an area of said potential disease site
comprising
a plurality of electrode means adapted for contact with the skin surface of
the subject at spaced locations in the area of the potential disease site
to detect the potentials of electromagnetic fields present in the area of
said potential disease site during a test period and to provide test
potentials as a function of each of said potentials detected;
processing means connected to receive said test potentials from said
electrode means, said processing means operating during said test period
to select at least one of said electrode means as a reference electrode
and another of said electrode means as a test electrode and to cause said
test electrode to operate with said reference electrode to detect the
potential of the electromagnetic field present therebetween and to provide
a test potential as a function thereof, wherein said processing means
further operates to select from said electrode means a plurality of
different test electrode-reference electrode combinations during the test
period and to receive test potentials from each of said combinations; and
wherein said processing means includes sequencer switching means connected
to said electrode means and operative to select said test electrode means
and operative to select said test electrode-reference electrode
combinations and to receive the test potential from said selected test
electrode-reference electrode combinations;
analog-to-digital converter means connected to separately receive each said
test potential from said sequencer switching means for providing a
separate digital test signal indicative of each said test potential
obtained during said test period;
and central processor means connected to separately receive each said
separate digital test signal, said processor means operating to compare
said digital test signals obtained during said test period to identify
potential relationships therebetween indicative of the presence of a
disease condition; and wherein said central processor means further
comprises digital test signal comparing means for comparing said digital
test signals to obtain a maximum voltage differential by obtaining from
the digital test signals for said measurement period maximum and minimum
digital signals and subsequently obtaining a differential value signal
indicative of the difference between said maximum and minimum digital
signals, differential value signal comparing means for comparing said
differential value signal to a first reference value, and providing an
output signal indicative of the presence of a disease condition in
accordance with a relationship between said first reference value and said
differential value signal, and minimum digital signal comparing means that
operates when the relationship between said first reference value and said
differential value signal is not indicative of the presence of a disease
condition for comparing said minimum digital signal to a second reference
value, and providing an output signal indicative of the presence of said
disease condition in accordance with a second relationship between said
second reference value and said minimum digital signal.
14. The apparatus for disease screening or diagnosis of clam 13, wherein
said central processor means further comprises output signal means for
providing an output signal indicative of the presence of said disease
condition if said differential value signal is of a greater value than
said first reference value and if said minimum digital signal is of a
lesser value than said second reference value.
15. A method for determining the presence or absence of a disease condition
at a test site on a human or animal subject as a function of the potential
of an electromagnetic field which originates from and is present in the
subject sensed by a plurality of spaced electrodes in contact with the
skin surface of the subject in the area of the test site, which includes:
sequentially selecting during a test period pairs of electrodes from said
plurality of spaced electrodes and detecting only the respective
electrical potential of the electromagnetic filed which originates from
and is present in the subject between each of said selected pairs of
electrodes,
comparing the respective electrical potentials so obtained to identify a
high and a low level potential,
obtaining a differential value indicative of the difference between said
high and low level potentials,
comparing said differential value to a predetermined reference value to
determine a relationship therebetween, and
obtaining an indication of the presence or absence of a disease condition
from said relationship of the differential value to the reference value.
16. The method of claim 15 which includes selecting in sequence different
single pairs of said electrodes during the test period to obtain
electrical potentials from a plurality of different electrode pairs.
17. The method of claim 16 which includes taking a plurality of electrical
potential measurements from each said selected electrode pair during the
test period,
obtaining an average measurement value from the potential measurements
taken by each selected electrode pair during the test period,
an comparing said average measurement values to identify therefrom said
high and low level potentials.
18. A method for determining the presence or absence of a disease condition
at a test site on a human or animal subject as a function of the potential
of the electromagnetic field present in the subject sensed by a plurality
of spaced electrodes in contact with the skin surface of the subject in
the area of the test site which includes:
sequentially selecting during a test period different pairs of electrodes
from said plurality of spaced electrodes and detecting the respective
electrical potential of the electromagnetic field in the subject between
each selected pair of electrodes to obtain electrical potentials from a
plurality of different electrode pairs,
comparing the individual respective electrical potentials so obtained to
identify a high and a low level potential,
obtaining a differential value indicative of the difference between said
high and low level potentials,
comparing said differential value to a predetermined reference value to
determine a relationship therebetween,
taking a plurality of electrical potential measurements from each said
selected electrode pair during the test period,
obtaining an average measurement value from the potential measurements
taken by each selected electrode pair during the test period,
comparing said average measurement values to identify therefrom said high
and low level potentials, and
obtaining an indication of the presence or absence of a disease condition
based upon whether said differential value exceeds or is less than said
predetermine reference value,
if the absence of a disease indication is indicated, comparing said low
level potential to a second predetermine reference value to determine a
second relationship therebetween,
and obtaining a second indication of the presence or absence of said
disease condition from the second relationship of said low level potential
to said second reference value. |
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Claims |
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Description |
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TECHNICAL FIELD
The present invention relates generally to a method and apparatus for
diagnosing or screening disease states in a living organism by detecting
the potential of the electromagnetic field present between a reference and
a plurality of test points on the living organism to measure the gradient
of electrical activity which occurs as a function of underlying biological
activity.
BACKGROUND ART
In recent years the theory that measurement of the potential level of the
electromagnetic field of a living organism can be used as an accurate
diagnostic tool is gaining greater acceptance. Many methods and devices
have been developed in an attempt to implement this theory. For example,
U.S. Pat. No. 4,328,809 to B.H. Hirschowitz et al deals with a device and
method for detecting the potential level of the electromagnetic field
present between a reference point and a test point of a living organism.
Here, a reference electrode provides a first signal indicative of the
potential level of the electromagnetic field at the reference point, while
a test electrode provides a second signal indicative of the potential
level of the electromagnetic field at the test point. These signals are
provided to an analog-to-digital converter which generates a digital
signal as a function of the potential difference between the two, and a
processor provides an output signal indicative of a parameter or
parameters of the living organism as a function of this digital signal.
Similar biopotential measuring devices are shown by U.S. Pat. No. 4,407,300
to Davis, and U.S. Pat. No. 4,557,271 and 4,557,273 to Stoller et al.
Davis in particular discloses the diagnosis of cancer by measuring the
electromotive forces generated between two electrodes applied to a
subject.
Often, the measurement of biopotentials has been accomplished using an
electrode array, with some type of multiplexing system to switch between
electrodes in the array. The aforementioned Hirschowitz et al patent
contemplates the use of a plurality of test electrodes, while U.S. Pat.
No. 4,416,288 to Freeman and U.S. Pat. No. 4,486,835 to Bai disclose the
use of measuring electrode arrays.
Unfortunately, previous methods for employing biopotentials measured at the
surface of a living organism as a diagnostic tool, while basically valid,
are predicated upon an overly simplistic hypothesis which does not provide
an effective diagnosis for many disease states. Prior methods and the
devices which implement them operate on the basis that a disease state is
indicated by a negative polarity which occurs relative to a reference
voltage obtained from another site on the body of a patient, while normal
or non-malignant states, in the case of cancer, are indicated by a
positive polarity. Based upon this hypothesis, it follows that the
detection and diagnosis of disease states can be accomplished by using one
measuring electrode situated on or near the disease site to provide a
measurement of the polarity of the signal received from the site relative
to that from the reference site. Where multiple measuring electrodes have
been used, their outputs have merely been summed and averaged to obtain
one average signal from which a polarity determination is made. This
approach is subject to major deficiencies which lead to diagnostic
inaccuracy.
First, the polarity of diseased tissue underlying a recording electrode has
been found to change over time. This fact results in a potential change
which confounds reliable diagnosis when only one recording electrode is
used. Additionally, the polarity of tissue as measured by skin surface
recording is dependent not only upon the placement of the recording
electrode, but also upon the placement of the reference electrode.
Therefore, a measured negative polarity is not necessarily indicative of
diseases such as cancer, since polarity at the disease site depends in
part on the placement of the reference electrode.
As disease states such as cancer progress, they produce local effects which
include changes in vascularization, water content, and cell division rate.
These effects alter ionic concentrations which can be measured at the skin
surface. Other local effects, such as distortions in biologically closed
electrical circuits, may also occur. A key point to recognize is that
these effects do not occur uniformly around the disease site. For example,
as a tumor grows and differentiates, it may show wide variations in its
vascularity, water content and cell division rate, depending on whether
examination occurs at the core of the tumor (which may be necrotic) or at
the margins of the tumor (which may contain the most metabolically active
cells). Once this fact is recognized, it follows that important electrical
indications of disease are going to be seen in the relative voltages
recorded from a number of sites at and near a diseased area, and not, as
previously assumed, on the direction (positive vs. negative) of polarity.
DISCLOSURE OF THE INVENTION
It is a primary object of the present invention to provide a novel and
improved method and apparatus for providing a discriminant function
analysis for disease diagnosis. Such method and apparatus operate to
determine the relationships between a set of voltages taken from the area
of a disease site on a living organism.
Another object of the present invention is to provide a novel and improved
method and apparatus for the discriminant analysis of a disease site on a
living organism wherein voltage potentials are measured in the area of the
disease site over time. A maximum voltage differential is obtained from an
average of multiple readings taken over time which constitutes a minimum
voltage that is subtracted from a maximum voltage where two or more
electrodes are recording voltages simultaneously or concurrently from a
specific disease site or organ.
A further object of the present invention is to provide a novel and
improved method and apparatus for providing a discriminant analysis for
cancer diagnosis. Relative voltages are recorded from a number of sites at
and near a diseased area using a variety of different electrode arrays
depending on the intended application. A discriminant analysis is then
used to determine the relationships between a set of voltages taken from
such sites, and subsets of voltage relationships are used to provide a
diagnosis of either the presence or absence of serious disease.
Yet another object of the present invention is to provide a novel and
improved method and apparatus for providing a discriminant function
analysis for screening a site on a living organism for a disease
condition. Potential levels are taken from a plurality of locations at the
site being screened, and the potential levels obtained are analyzed
mathmatically to produce greater accuracy. Thus the relationships between
the potentials obtained and different subsets of such relationships are
analyzed to indicate either the presence or absence of a disease
condition.
A still further object of the present invention is to provide a novel and
improved method and apparatus for discriminant analysis in cancer
diagnosis. Recordings from multiple sites at or near a disease site are
taken and the voltage levels recorded from multiple sites are analyzed in
terms of a discriminant mathematical analysis to produce greater
diagnostic accuracy. Different electrode arrays, electrode shapes and
electrode patterns are employed depending upon the intended application,
and for some diagnostic procedures, the electrode array covers various
areas of a lesion as well as relatively normal tissue near the lesion
site. The aim of the method and apparatus is to measure the gradient of
electrical activity which occurs as a function of the underlying
biological activity of a specific organ system. Relationships between a
set of voltages taken simultaneously or concurrently from a lesion site
and possibly adjacent areas are derived, and different subsets of such
relationships are obtained to indicate either the presence or absence of
serious disease. The method and apparatus may be effectively employed in
screening procedures to determine if a disease condition is likely to be
present.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a block diagram of the apparatus of the present invention;
FIG. 2 is a sectional diagram of an electrode for the apparatus of FIG. 1;
FIG. 3 is a flow diagram of the measurement operation of the apparatus of
FIG. 1 used to obtain a maximum voltage differential and a low individual
channel value;
FIG. 4 is a flow diagram of the disease decision analysis provided by the
apparatus of FIG. 1;
FIG. 5 is a flow diagram of an auxilliary decision sequence used with the
flow diagram of FIG. 4; and
FIG. 6 is a block diagram of a second embodiment of the apparatus of the
present invention.
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 discloses a basic block diagram of the apparatus of the present
invention indicated generally at 10 for performing a discriminant analysis
for disease screening or diagnosis. For purposes of illustration, the
apparatus 10 will be described in connection with methods involving the
screening for, or diagnosing of breast cancer. However, it should be
recognized that the method and apparatus of the invention can be similarly
employed for screening or diagnosis at other disease sites involving other
portions or organs of a living human or animal.
In FIG. 1, a human subject 12 may have a cancerous lesion 14 on one breast
16. This cancerous lesion has a core 18 and an outer zone 20 surrounding
the core where various differing local effects, such as changes in
vascularization, water content and cell division rate occur. Assuming
first, for purposes of discussion, that the location of the lesion 14 is
not known, and the device 10 is to be used to screen the breast 16 to
determine whether or not a disease condition exists, skin surface
potentials will be measured in an area of the breast, including the zone
20 using an electrode array 22. In FIG. 1, the electrode array includes a
central electrode 24 surrounded by four peripheral electrodes 26. However,
the device and method of this invention contemplate the use of a variety
of different electrode arrays depending upon the intended application for
which the device 10 is used. For example, in the diagnosis of clinically
symptomatic breast or skin lesions, the electrode array should cover
various areas of the lesion as well as relatively normal tissue near the
lesion site. For breast cancer screening (where patients are asymptomatic)
the array should give maximum coverage of the entire breast surface. The
aim in both of these cases is to measure the gradient of electrical
activity which occurs as a function of the underlying biological activity
of the organ system. The number of electrodes used in the measurement will
also be a function of specific application, and breast cancer screening
may require the use of as few as twelve or as many as forty or more
electrodes for each breast, while in screening for prostate cancer, as few
as two measurement electrodes might be used.
The core electrode 24 and the peripheral electrodes 26 are mounted upon a
flexible backing sheet 28 which permits the electrodes to be positioned
against the curved surface of the breast 16 while still maintaining the
position of the electrodes in a predetermined pattern. However, other
electrode arrays may be employed wherein each individual electrode can be
individually positioned, and the relative position between electrodes can
be altered. The electrode array 22 is used in conjunction with a reference
electrode 30, and all of these electrodes may be of a known type used for
detecting the potential level of the electromagnetic field present in a
living organism. Ideally, the electrodes 24, 26 and 30 should be of a type
which do not cause a substantial battery effect between the organism under
test and the electrode. A common electrode suitable for use as the
electrodes 24, 26 and 30 is illustrated in FIG. 2, and includes a layer of
silver 32 having an electrical lead 34 secured in electrical contact
therewith. In contact with the silver layer 32 is a layer 37 of silver
chloride, and extending in contact with the silver chloride layer is a
layer of bridging material 38, such as sodium chloride, which contacts the
surface of a living organism.
The device 10 is a multi-channel device having electrode leads 34 extending
separately from the central electrode 24, the peripheral electrodes 26,
and the reference electrode 30 to a low pass filter 36. This filter
operates to remove undesirable high frequency AC components which appear
on the slowly varying DC voltage signal outputs provided by each of the
electrodes as a result of the electromagnetic field measurement. The low
pass filter 36 may constitute one or more multiple input low pass filters
of known type which separately filter the signals on each of the input
leads 34 and then pass each of these filtered signals in a separate
channel to a multiple input analog-to-digital converter 40. Obviously, the
low pass filter 36 could constitute an individual low pass filter for each
of the specific channels represented by the leads 34 which would provide a
filtering action for only that channel, and then each filtered output
signal would be connected to the input of the analog-to-digital converter
40.
The converter 40 is a multiple input multiplex analog-to-digital converter
of a known type, such as that manufactured by National Semiconductor, Inc.
and designated as ADC808. For multiple channels, it is possible that more
than one multiple input analog-to-digital converter will be used as the
converter 40. For example, if an 8-input analog-to-digital converter is
used and there are 24 input and output channels from the low pass filter
36, then the analog-to-digital converter 40 might include three 8-input
converters.
The analog-to-digital converter 40 converts the analog signal in each input
channel to a digital signal which is provided on a separate output channel
to the multiple inputs of a central processing unit 42. The central
processing unit is a component of a central control unit indicated
generally at 44 which includes RAM and ROM memories 46 and 48. Digital
input data from the analog-to-digital converter 40 is stored in memory and
is processed by the CPU in accordance with a stored program to perform the
diagnostic and scanning methods of the present invention. The information
derived by the CPU as a result of this processing is then fed to a
suitable indicator device 50 which may constitute a printer, a CRT display
device, or a combination of such conventional indicators.
The operation of the discriminant analysis device 10 will be cl early
understood from a brief consideration of the broad method steps of the
invention which the device is intended to perform. When the lesion 14 has
not been identified and a screening operation is performed to determine
whether or not a lesion is present, a screening electrode array 22 is
positioned in place with the central electrode 24 in the center of the
site being screened and the peripheral electrodes 26 over various diverse
areas of the site. If a breast 16 is screened, the electrode array may
cover either the complete breast or a substantial area thereof. The
reference electrode 30 is then brought into contact with the skin of the
subject 12 in spaced relationship to the electrode array 22, and this
reference electrode might, for example, be brought into contact with a
hand of the subject. Then, the electromagnetic field between the reference
electrode and each of the electrodes 24 and 26 is measured, filtered,
converted to a digital signal and stored for processing by the central
processing unit 42. The program control for the central processing unit
causes a plurality of these measurements to be taken over a period of
time, and the measurements on all channels may be taken simultaneously and
repetitively for the predetermined measurement time period. Alternatively,
sequential measurements between the reference electrode and one of the
electrodes 24 and 26 can be taken until each channel is sampled, and then
the sequential measurement is repeated for the predetermined measurement
period. In prior art units, a plurality of measurements have been taken
over a period of time and often from a plurality of electrodes, but then
these plural measurements are merely averaged to provide a single average
output indication. In accordance with the method of the present invention,
the measurement indications on each individual channel are not averaged
with those from other channels, but are instead kept separate and averaged
by channel within the central processing unit 42 at the end of the
measurement period. For the duration of a single predetermined measurement
period, with five measurement channels as shown, the central processor
will obtain five average signals indicative of the average electromagnetic
field for the period between the reference electrode 30 and each of the
electrodes in the electrode array 22.
Having once obtained an average signal level indication as measured by each
channel, the results of the measurements taken at multiple sites are
analyzed in terms of a mathematical analysis to determine the
relationships between the average signal values obtained. It has been
found that the result of such an analysis is that a subset of
relationships can be obtained which are indicative of the presence of more
serious disease, while a different subset might be obtained which will be
indicative of the absence of serious disease. Although a number of methods
and decision making logic may be designed to obtain and analyze the
relationships between the average potential values in accordance with this
invention for screening or diagnostic purposes, the discriminant
mathmatical analysis procedure to be hereinafter described is a method
which appears to be effective.
The most important relationship which may be obtained is designated the
maximum voltage differential (MVD), which is defined as the minimum
average voltage value obtained during the measurement period subtracted
from the maximum average voltage value obtained for the same period where
two or more electrodes are recording voltages from a lesion. Thus, for
each predetermined measurement period, the lowest average voltage level
indication obtained on a ny of the channels is subtracted from the highest
average voltage level indication obtained on any one of the channels to
obtain an MVD voltage level. If this MVD voltage level is above a desired
level<x, for example, 20.0 mV, then a disease condition, such as a
maligancy, may be indicated. Similarly, if the average taken over the
measurement period from one channel is an abnormally low value<y, for
example below 5.0 mV, then a disease condition, such as malignancy may
also be indicated. Thus, in accordance with the present method, an
abnormally low individual electrode reading (IER) or an abnormally high
MVD are used to provide an indication of the existence of a disease
condition. These primary indicators may be further analyzed in accordance
with a control program to be subsequently described to reduce the number
of false positive diagnoses, usually cases of non-malignant hyperplasia
which may be falsely identified as cancer on the basis of high MVD or low
IER readings.
When the device 10 is used in accordance with the method of the present
invention for a screening function where a specific lesion 14 has not yet
been identified, using as an example breast screening where the patient is
asymptomatic, an array 22 is employed which will give maximum coverage of
the entire breast surface. Then MVD levels and IER levels are obtained in
accordance with the method previously described.
The general overall operation of the central processor unit 42 will best be
understood with reference to the flow diagram of FIG. 3. The operation of
the unit 10 is started by a suitable start switch as indicated at 52 to
energize the central processing unit 42, and this triggers an initiate
state 54. In the initiate state, the various components of the device 10
are automatically brought to an operating mode, with for example, the
indicator 50 of FIG. 1 being activated while various control registers for
the central processing unit are reset to a desired state. Subsequently, at
56, a predetermined multiple measurement period is initiated and the
digital outputs from the analog-to-digital converter 40 are read. The
central processing unit may be programmed to simultaneously read all
channel outputs from the analog-to-digital converter, or these channel
outputs may be sequentially read.
Once all channels from the analog-to-digital converter are read, an average
signal for each channel is obtained at 58 for that portion of the
measurement period which has expired. The average or normalized value for
each channel is obtained by summing the values obtained for that channel
during the measurement period and dividing the sum by the number of
measurements taken. Then, at 60, the central processor unit determines
whether the measurement period has expired and the desired number of
measurements have been taken, and if not, the collection of measurement
samples or values continues.
Once the measurement period has expired, the microprocessor will have
obtained a final average value for each channel derived from the
measurements taken during the span of the measurement period. From these
average values, the highest and lowest average values obtained during the
measurement period are sampled at 62, and at 64, and the lowest average
channel value which was sampled at 62 is subtracted from the highest
sampled channel value to obtain a maximum voltage differential value.
The maximum voltage differential value is analyzed at 66 to determine if
the value is greater than a predetermined level x(mV). If the maximum
voltage differential is above the predetermined level, the existence of a
disease condition is indicated at 68, but if it is not, then the lowest
average channel output IER from 62 is analyzed at 70 to determine if this
value is lower than a predetermined value (mV). If it is determined at 70
that the IER value is not lower than the predetermined value, then no
disease condition is indicated at 72. On the other hand, if the IER value
is lower than the predetermined value, then the presence of a disease
condition is indicated at 68. After the indication of the presence or
nonpresence of disease at 68 or 72, the routine is ended at 74.
Operation of the device 10 in accordance with the flow diagram of FIG. 3
for screening, provides a good indication of whether or not a disease
condition is present in the area screened, and this simplified mode of
operation may be used effectively for general screening purposes.
When a lesion 14 has been identified and located by screening in accordance
with this invention or by other methods, a diagnosis is required to
determine whether or not the lesion is malignant. For diagnostic purposes,
the electrode array 22 is positioned in place with the central electrode
24 over the lesion core 18 and the peripheral electrodes 26 over various
diverse areas of the outer zone 20 as well as over relatively normal
tissue beyond but near the outer zone. The reference electrode 30 is then
brought into contact with the skin of the subject 12 in spaced
relationship to the electrode array 22, and again, for a breast malignancy
diagnosis, this reference electrode might, for example, be brought into
contact with a hand of the subject 12. Then, the electromagnetic field
between the reference electrode and each of the electrodes 24 and 26 is
measured, filtered, converted to a digital signal and stored for
processing by the central processing unit 42. The central processing unit
processes these signals in the same manner as previously described in
connection with FIG. 3, but the operation exemplified by the flow diagram
of FIG. 3 has no provision for the reduction of the number of false
positive diagnoses which may be obtained from such conditions as
nonmalignant hyperplasia and which can be falsely identified as cancer on
the basis of high MVD levels or low IER levels. To reduce the occurrence
of these false positives, the expanded flow diagram of FIGS. 4 and 5 is
employed for diagnostic purposes where greater accuracy is required.
Referring now to FIG. 4, the initial portion of the flow diagram of FIG. 3
down to the determination of the expiration of the measurement period at
60 is incorporated by reference. Once the measurement period expires, the
system operates at 76 to determine if auxiliary measurements are present.
If such auxiliary measurements are not present, then the flow diagram
passes on to the sampling process 62 of the flow diagram of FIG. 3 and
continues on through this flow diagram which is incorporated by reference.
On the other hand, if auxiliary measurements are sensed, then the flow
diagram of FIG. 4 proceeds with an analysis of the primary measurement
channels as well as the auxiliary measurement channels. To understand the
source of the auxiliary measurements, it can be noted from FIG. 1 that
multiple measurements can be taken and averaged from a symptomatic organ,
such as the breast 16 and also from a similar asymptomatic or symptomatic
organ such as the opposite breast 78. The measurements obtained from the
breast 78 and from the core electrode 24 can form the auxiliary channel
measurements, while those obtained from the breast 16 form the primary
channel measurements. The auxiliary channel measurements may be taken
sequentially after the primary channel measurements, or alternatively, may
be taken simultaneously by using a second electrode array 80. The primary
and secondary channels would be separated as they pass through the low
pass filter 36 and analog-to-digital converter 40 to the central
processing unit 42, but otherwise the measurements and averaging would
occur for the auxiliary channels in exactly the same manner as previously
described in connection with the primary channels.
Returning to FIG. 4, if the presence of auxiliary channels are sensed at
76, then the high and low auxiliary channel values are determined at 82,
and a maximum voltage differential for the auxiliary channel high and low
values is determined at 84. At the same time, the average value for the
channel dedicated to the central electrode 24 is determined at 86 and the
high and low average channel values for the primary measurement channels
are determined at 88. Then at 90, the maximum voltage differential for the
primary measurement channels is determined and at 92 a decision is made as
to whether or not the primary measurement channel maximum voltage
differential exceeds a predetermined voltage x.
As in the case of the flow diagram of FIG. 3, if the predetermined voltage
x is not exceeded by the primary channel maximum voltage differential at
92, then at 94 a determination is made as to whether there is at least one
low average value for the primary measurement channels which is less than
a predetermined voltage level y. If there is, then the decision making
logic of FIG. 5 comes into operation, but if there is not, then a NO
CANCER indication is provided at 96 and the routine ends at 98.
Should the determination at 92 show that the primary channel maximum
voltage differential is greater than the predetermined value x, then at
100, a determination is made as to whether or not the auxiliary channel
maximum voltage differential is greater than x. If the auxiliary channel
maximum voltage differential is less than x, then the decision sequence of
FIG. 5 is instituted. On the other hand, if this auxiliary maximum voltage
differential is greater than x, then a decision is made at 102 as to
whether or not the second breast 78 is symptomatic or asymptomatic. If
this breast is symptomatic, then the decision logic flow diagram of FIG. 5
is instituted, but if the breast is not symptomatic, then an equation at
104 is performed. Basically, the equation at 104 determines whether the
primary channel maximum voltage differential minus 25 divided by the
absolute value of the primary channel maximum voltage differential minus
the auxiliary channel multiple voltage differential is equal to a value
greater than the predetermined value x. If it is, then the decision
sequence flow diagram of FIG. 5 is instituted, but if it is not, then a NO
CANCER indication is provided at 96 and the routine is terminated at 98.
Turning now to FIG. 5, t | | |
