U.S. patent application number 12/536025 was filed with the patent office on 2010-02-11 for apparatus, method and system for determining a physiological condition within a mammal.
Invention is credited to Harry T. Rieth.
Application Number | 20100036212 12/536025 |
Document ID | / |
Family ID | 41663951 |
Filed Date | 2010-02-11 |
United States Patent
Application |
20100036212 |
Kind Code |
A1 |
Rieth; Harry T. |
February 11, 2010 |
APPARATUS, METHOD AND SYSTEM FOR DETERMINING A PHYSIOLOGICAL
CONDITION WITHIN A MAMMAL
Abstract
A system, method and apparatus for determining a physiological
condition within a mammal based on pH and/or temperature
measurements. In one aspect, the invention is directed to an
apparatus for measuring a physiological condition within a mammal
comprising: a probe for insertion into a body lumen of the mammal,
the probe housing a first circuit board operably coupling a pH
sensor for measuring pH within the body lumen and generating a pH
signal indicative of the measured pH, a memory device storing
parametric data unique to the pH sensor, and a first interface
connector located at a proximal potion of the probe; a handle for
manipulating the probe, the handle housing a second circuit board
operably coupling a microprocessor for processing the pH signal and
generating an output signal based on the processing of the pH
signal, an indicia device for communicating the output signal
generated by the microprocessor, and a second interface connector;
the probe connected to the handle in a manner that allows the probe
and handle to be repetitively engaged and disengaged from each
other; and wherein when the probe is connected to the handle, the
first and second interface connectors are in operable connection so
that the microprocessor can retrieve the parametric data from the
memory device of the probe and receive the pH signal.
Inventors: |
Rieth; Harry T.;
(Doylestown, PA) |
Correspondence
Address: |
The Belles Group, P.C.
1518 Walnut Street, Suite 1706
Philadephia
PA
19102
US
|
Family ID: |
41663951 |
Appl. No.: |
12/536025 |
Filed: |
August 5, 2009 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
61086403 |
Aug 5, 2008 |
|
|
|
61231076 |
Aug 4, 2009 |
|
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Current U.S.
Class: |
600/301 ;
600/551; 600/591 |
Current CPC
Class: |
A61B 2010/0019 20130101;
G01N 33/84 20130101; A61B 5/14539 20130101; A61B 2010/0032
20130101; A61B 5/1473 20130101; A61B 5/4294 20130101; A61B 5/4277
20130101; A61B 5/01 20130101; A61B 10/0012 20130101; A61B 5/4337
20130101 |
Class at
Publication: |
600/301 ;
600/551; 600/591 |
International
Class: |
A61B 10/00 20060101
A61B010/00; A61B 5/00 20060101 A61B005/00 |
Foreign Application Data
Date |
Code |
Application Number |
Aug 4, 2009 |
US |
PCT/US09/52696 |
Claims
1. An apparatus for measuring a physiological condition within a
mammal comprising: an elongated probe for insertion into a body
lumen of the mammal, the probe comprising a first circuit board
operably coupling a pH sensor for measuring pH within the body
lumen and generating a pH signal indicative of the measured pH, a
memory device storing parametric data unique to the pH sensor and a
first interface connector located at a proximal portion of the
probe; a handle for manipulating the probe, the handle comprising a
second circuit board operably coupling a microprocessor for
processing the pH signal and generating an output signal based on
the processing of the pH signal, a display device for displaying
the output signal generated by the microprocessor, and a second
interface connector; the probe connected to the handle in manner
that allows the probe and handle to be repetitively engaged and
disengaged from each other; and wherein when the probe is connected
to the handle, the first and second interface connectors are in
electrical connection so that the microprocessor can retrieve the
parametric data from the memory device of the probe and receive the
pH signal.
2. The apparatus of claim 1 wherein the pH sensor is an
ion-sensitive field effect transistor (ISFET).
3. The apparatus of claim 2 wherein the parametric data includes
ISFET slope data.
4. The apparatus of claim 2 wherein the parametric data includes
first ISFET slope data determined at ambient temperature and second
ISFET slope data determined at normal body temperature.
5. The apparatus of claim 4 wherein the first and second ISFET
slope data is based on at least three points of pH parametric
data.
6. The apparatus of claim 1 further comprising: the probe
comprising a temperature sensor for measuring temperature within
the body lumen and generating a temperature signal indicative of
the measured temperature, the temperature sensor operably coupled
to the first circuit board; and wherein the microprocessor
processes the temperature signal and generates the output signal
based on the processing of the pH signal and/or the temperature
signal.
7. The apparatus of claim 6 wherein the pH sensor is an ISFET and
the parametric data includes first ISFET slope data determined at
ambient temperature and second ISFET slope data determined at
normal body temperature.
8. The apparatus of claim 6 wherein the elongated probe has a
distal portion and a proximal portion, the pH sensor and the
temperature sensor located at the distal portion and the first
interface connector is located at the proximal portion.
9. The apparatus of claim 8 wherein the handle further comprises a
socket forming a passageway into the handle, the second interface
connector aligned with the socket, and wherein when the probe is
connected to the handle, the proximal portion of the probe extends
into the socket of the handle.
10. The apparatus of claim 9 wherein the probe and the handle are
connected together by one of a tight-fit engagement, a threaded
engagement, and a snap-fit engagement.
11. The apparatus of claim 8 wherein the probe extends along a
longitudinal axis, and wherein the temperature sensor and pH sensor
are aligned along an axis that is substantially parallel to the
longitudinal axis.
12. The apparatus of claim 6 wherein the handle further comprises a
power source located within the handle, the power source providing
power to the second circuit board and to the first circuit board
when the probe is secured to the handle.
13. The apparatus of claim 12 wherein the handle further comprises
user controls located on the handle and operably coupled to the
second circuit board.
14. The apparatus of claim 6 wherein the probe further comprises a
first internal chamber, a second internal chamber, and a diaphragm,
the first circuit board located within the first internal chamber,
and the second chamber being hermetically sealed and filed with an
electrolyte solution buffered at a known pH, and the diaphragm
having a first portion in contact with the electrolyte solution and
a second portion exposed to the body lumen.
15. The apparatus of claim 14 wherein the probe extends along a
longitudinal axis and wherein the temperature sensor, the pH sensor
and the diaphragm are aligned along an axis that is substantially
parallel to the longitudinal axis.
16. The apparatus of claim 15 wherein the temperature sensor, the
pH sensor and the diaphragm are located within a well formed into a
distal portion of the probe.
17. The apparatus of claim 16 wherein the temperature sensor, the
pH sensor and the diaphragm are located on a substantially planar
floor of the well.
18. The apparatus of claim 1 wherein the body lumen is the vagina
and the handle further comprises a second memory device operably
coupled to the second circuit board, the second memory device
storing algorithms for identifying a fertility period based or
cervical pH and/or temperature.
19. An apparatus for measuring a physiological condition within a
mammal comprising: an elongated probe for insertion into a body
lumen of the mammal, the probe comprising a first circuit board
operably coupling an ion-sensitive field effect transistor (ISFET)
for measuring pH within the body lumen and generating a pH signal
indicative of the measured pH, a temperature sensor for measuring
temperature within the body lumen and generating a temperature
signal indicative of the measured temperature, a diaphragm in
contact with an electrolyte solution buffered at a known pH, a
memory device storing ISFET slope data at both ambient temperature
and normal body temperature for the ISFET, and a first interface
connector located at a proximal portion of the probe; a handle for
manipulating the probe, the handle comprising a second circuit
board operably coupling a microprocessor for receiving the pH and
temperature signals and generating an output signal based on the
processing of the pH and temperature signals and the ISFET slope
data, a display device for displaying the output signal generated
by the microprocessor, and a second interface connector; the probe
connected to the handle in manner that allows the probe and handle
to be repetitively engaged and disengaged from each other; and
wherein when the probe is connected to the handle, the first and
second interface connectors are in electrical connection so that
the microprocessor can retrieve the ISFET slope data from the
memory device of the probe and receive the pH and temperature
signals.
20. The apparatus of claim 19 wherein the elongated probe has a
distal portion and a proximal portion, the ISFET, the temperature
sensor and the diaphragm located at the distal portion and the
first interface connector located at the proximal portion.
21. The apparatus of claim 20 wherein the handle further comprises
a socket forming a passageway into the handle, the second interface
connector aligned with the socket, and wherein when the probe is
connected to the handle, the proximal portion of the probe extends
into the socket of the handle.
22. The apparatus of claim 21 wherein the probe and the handle are
connected together by one of a tight-fit engagement, a threaded
engagement, and a snap-fit engagement.
23. The apparatus of claim 19 wherein the probe extends along a
longitudinal axis, and wherein the temperature sensor, the
diaphragm and the ISFET are aligned along an axis that is
substantially parallel to the longitudinal axis.
24. The apparatus of claim 19 wherein the temperature sensor is a
thermistor covered by a metal cap that is exposed through a first
opening in a wall of the probe, wherein the ISFET is exposed
through a second opening in the wall of the probe, and wherein the
diaphragm is exposed through a third opening in the wall of the
probe.
25. The apparatus of claim 24 wherein the probe extends along a
longitudinal axis, and wherein the first, second and third openings
in the wall of the probe are aligned along an axis that is
substantially parallel to the longitudinal axis.
27. The apparatus of claim 24 wherein a space between the
thermistor and the metal cap is filled with a thermally conductive
epoxy that is not electrically conductive.
28. The apparatus of claim 2 wherein a seal is formed between each
of the metal cap and the ISFET and the wall of the probe so that
fluids from the body lumen can not reach the second printed circuit
board through the first and/or second openings.
29. The apparatus of claim 24 wherein the temperature sensor, the
pH sensor and the diaphragm are located within a well formed into a
distal portion of the probe.
30. The apparatus of claim 19 wherein the handle further comprises
a power source located within the handle, the power source
providing power to the second circuit board and to the first
circuit board when the probe is secured to the handle.
31. The apparatus of claim 30 wherein the handle further comprises
user controls located on the handle and operably coupled to the
second circuit board.
32. The apparatus of claim 19 wherein the body lumen is the vagina
and the handle further comprises a second memory device operably
coupled to the second circuit board, the second memory device
storing algorithms for identifying a fertility period based on
cervical pH and/or temperature.
33. An apparatus for measuring a physiological condition within a
mammal comprising: a probe for insertion into a body lumen of the
mammal, the probe comprising: an elongated tubular housing
extending along a longitudinal axis from a proximal end to a distal
end, the elongated tubular housing having a first internal cavity;
a first circuit board located within the first internal cavity; a
pH sensor for measuring pH within the body lumen located at a
distal portion of the elongated tubular housing, the pH sensor
generating a pH signal indicative of the measured pH and operably
coupled to the first circuit board; a temperature sensor for
measuring temperature within the body lumen located at the distal
portion, the temperature sensor generating a temperature signal
indicative of the measured temperature and operably coupled to the
first circuit board; a first memory device storing parametric data
unique to the pH sensor, the memory device housed within the
internal cavity of the elongated tubular housing and operably
coupled to the first circuit board; and a first interface connector
located at a proximal portion of the elongated tubular housing and
operably coupled to the circuit board; a handle for manipulating
the probe, the handle comprising; a second housing having a second
internal cavity and a socket forming a passageway into the second
internal cavity; a second circuit board located within the second
internal cavity; a microprocessor located within the second housing
and operably coupled to the second circuit board for receiving and
processing the pH signal and the temperature signal, the
microprocessor generating an output signal based on the processing
of the pH signal and the temperature signal and the parametric
data; a power source located within the second housing and operably
coupled to the second circuit board; user controls located on the
second housing and operably coupled to the second circuit board; a
display device operably coupled to the second circuit board for
displaying the output signal generated by the microprocessor; a
second interface connector operably coupled to the circuit board
and aligned with the socket; and wherein the probe is removably
secured to the handle, the proximal portion of the elongated
tubular housing extending into the socket of the second housing so
at the first and second connectors are in electrical connection.
Description
CROSS-REFERENCE TO RELATED PATENT APPLICATIONS
[0001] The present application claims the benefit of U.S.
Provisional Patent Applications Ser. No. 61/086,403, filed Aug. 5,
2008 and Ser. No. 61/231,076, filed Aug. 4, 2009, the entireties of
which are hereby incorporated by reference.
FIELD OF THE INVENTION
[0002] The present invention relates generally to the field of
determining a physiological condition within a mammal, and
specifically to apparatus, methods and systems of determining a
physiological condition within a mammal based on pH measurements of
biological fluids taken either in vivo or externally, such as
ovulation, vaginal, and/or cervical health, and other physiological
conditions.
[0003] The device is particularly suited for insertion into the
vagina but allows for easy pH measurement of small samples of
various other bodily fluids (urine, saliva, blood) external of the
body. The device shown is designed for female end user self testing
but can also be a valuable aid in physicians offices and clinical
labs. The invention can be used for various mammals, including
human and veterinary applications.
BACKGROUND OF THE INVENTION
[0004] pH is a measure of the acidity of alkalinity of a solution
or substance. Solutions with a pH less than seven are considered
acidic, while those with a pH greater than seven are considered
basic or alkaline. A pH level of 7.0 is considered neutral. When a
pH level is 7.0, it is defined as `neutral` because at this pH the
concentration of H.sub.3O.sup.+ equals the concentration of
OH.sup.- in pure water. The pH value is a measure of the activity
of hydrogen ions in the solution. The pH scale is typically between
1 and 14 with 1 being the most acidic and 14 the most alkaline. The
pH scale is an inverse logarithmic representation of hydrogen
proton concentration. Therefore a value change of 1 pH unit
represents a factor of 10 increase or decrease.
[0005] The vagina is the muscular canal extending from the vaginal
opening to the cervix and consists of three layers of tissue. The
mucosa is the surface layer and consists of mucus membranes. The
next layer of tissue is a layer of muscle concentrated mostly
around the outer third of the vagina. The third layer is the
innermost layer and consists of fibrous tissue.
[0006] The vagina contains folds or wrinkles rather than a smooth
surface. It is usually about 3 to 5 inches in length and its walls
are lined with a mucus membrane. The vagina includes numerous tiny
glands that generate vaginal secretions/fluids. The vaginal walls
are continually producing secretions/fluids necessary to provide
lubrication, to cleanse the vagina and to maintain the proper
acidity to prevent infection. The vagina tends to be fairly acidic
usually in the range of 3.5 to 4.5 pH. The walls of the vagina are
normally in contact with each other, which is contrary to most
anatomical illustrations. When something enters the vagina its
walls separate to make room for the object. Because of its muscular
tissue, the vagina has the ability to expand and contract adjusting
to fit snugly around the object inserted.
[0007] Accurate monitoring of vaginal pH is an important part of in
the diagnosis of vaginal infections such as Bacterial Vaginitis
(BV). The normal vaginal pH in reproductive age women is usually
3.5 to 4.5. A value greater the 4.5 can indicate a variety of
vaginal infections which are usually accompanied by unusual
discharge, itching, burning and irritation. The three diseases most
frequently associated with vaginal discharge are BV, trichomoniasis
(caused by a sexually transmitted infectious parasite) and
candidiasis (usually caused by Candida albicans).
[0008] Bacterial vaginosis (BV) is the most common cause of vaginal
infections. BV is caused by an imbalance of naturally occurring
bacterial flora. To control bacterial growth, the vagina is
normally slightly acidic with a pH of 3.5-4.5. A pH greater than
4.5 is considered alkaline and is suggestive of bacterial
vaginosis.
[0009] Candidiasis, also known as a "yeast infection" or VVC, is a
common fungal infection that occurs when there is overgrowth of the
fungus called Candida. Candida is always present in the body in
small amount, however when an imbalance occurs, such as when the
normal acidity of the vagina changes or when hormonal balance
changes, Candida can multiply. When that happens, symptoms of
candidiasis appear.
[0010] Trichomoniasis, sometimes referred to as "trich," is a
common cause of vaginitis. Trichomoniasis is primarily an infection
of the urogenital tract with the most common site of infection the
vagina or urethra in women. With a trichomonas infection, the
vagina is likely to be more alkaline than normal. An estimated five
million cases of trichomoniasis occur each year in the United
States. Men also can contract trichomoniasis however do not often
have signs or symptoms. Some men may temporarily have an irritation
inside the penis, mild discharge, or slight burning after urination
or ejaculation.
[0011] According to the Centers for Disease Control (CDC), there
are some serious risks from BV such as; [0012] An increase in a
woman's susceptibility to HIV infection if she is exposed to HIV
virus. [0013] An increase in the chances that an HIV-infected woman
can pass HIV to her sex partner. [0014] An increase in a woman's
susceptibility to further STDs such as herpes simples virus (HSV)
Chlamydia and gonorrhea. [0015] An increase in the development of
an infection following surgical procedures such as a hysterectomy
or an abortion. [0016] During pregnancy, an increase in adverse
pregnancy outcomes has been detected, including premature rupture
of the membranes, preterm labor, preterm birth, intraamniotic
infection, and postpartum endometritis.
[0017] The results of several investigations indicate that
treatment of pregnant women with BV who are at high risk for
preterm delivery (i.e. those who previously delivered a premature
infant) might reduce the risk for prematurity. Monitoring of pH
level during pregnancy is an important criterion in reducing the
incidences of Preterm labor and birth. Studies have shown that
bacterial vaginosis was associated with the preterm delivery of
low-birth-weight infants independently of other recognized risk
factors. Reduction in the instances of premature birth improves the
health of the newborn and significantly reduces the cost of
care.
[0018] Oral clindamycin prevents spontaneous preterm birth and mid
trimester miscarriage in pregnant women with bacterial vaginosis.
Based on estimates from the CDC, the number of pregnant women in
the United States alone that are annually infection with BV is
1,080,000 and Trichomoniasis is 124,000.
[0019] Untreated bacterial vaginosis is a risk factor for post
abortion pelvic inflammatory disease (PID). Studies have shown that
preabortal screening and subsequent treatment of those who test
clinically positive does lower the incidence of postabortion
PID.
[0020] BV can be diagnosed by the use of clinical criteria or Gram
stain. In clinical practice BV is diagnosed using the Amsel
criteria. Clinical criteria require typically three of the
following symptoms or signs: [0021] homogeneous, thin, white
discharge that smoothly coats the vaginal walls; [0022] presence of
clue cells on microscopic examination;
[0023] pH of vaginal fluid >4.5; and [0024] a fishy odor of
vaginal discharge before or after addition of 10% KOH (i.e., the
whiff test).
[0025] Current methods of monitoring vaginal pH include various
methods of checking pH paper type products. The accuracy of these
products are generally in the range of 0.3 pH to 0.5 pH. They
generally require the user to subjectively compare color in order
to determine the pH value and are subject to inaccuracies.
Inaccuracies can be due to lighting conditions or the ability of
the user to accurately compare color. Manual recording of the
subjective readings is required.
[0026] The cervix is the lower portion of the uterus and forms the
neck of the uterus. The cervix joins with the top end of the vagina
and the uterine cavity. The cervix protrudes into the vagina and
this area is called the ectocervix. Typically the ectocervix is
about 2.5 to 3 cm in diameter and has an elliptical surface. The
ectocervix is also called the external os. The size and shape of
the external os can vary widely depending on the age of the woman
or if she has given vaginal birth. The passage way between the
external os and the uterus is referred to as the endocervical
canal. The endocervical canal terminates at the internal os which
is the opening of the cervix inside the uterine cavity. The
cervical canal of the uterus is covered by a thin layer of mucus.
Pockets within the lining of the cervix function to produce
cervical fluid.
[0027] Studies by George I. Gorodeski et al, such as those
disclosed in U.S. Patent Application U.S./2008/0071190 published
Mar. 20, 2008, show that cervical pH changes dramatically during
the ovulation cycle while the vaginal pH remains relatively
constant. The in-vivo vaginal and cervical pH values recorded were
measured in Gorodeski by attaching a strip of pHydrion paper at the
tip of uterine forceps. In addition, another more complicated
clinical lab test was preformed by measuring cell cultures of the
human Ecto-cervical Epithelial cells and human Endocervical cells.
These tissue samples were collected and then analyzed and measured
using an elaborate clinical procedure. Using these techniques, it
was shown that the pH of the ectocervix changes as much as 2 pH
during the ovulation cycle with the peak occurring during days
11-14 of the cycle (ovulation period). During the same periods the
vaginal readings remained relatively constant.
[0028] Studies have also shown that monitoring of vaginal pH can be
a good indicator of menopause in women who are without vaginitis
and are not receiving estrogen therapy. A pH reading greater than
4.5 could indicate menopause and the need for estrogen therapy. Low
levels of estrogen can cause elevated pH levels in the area of 6.0
or higher. The sensitivity, of FSH blood work was no different than
vaginal pH in the diagnosis of menopause. Estrogen causes
deposition of glycogen in mature epithelial cells, which is then
converted by bacterial enzymes to glucose. The glucose is
anaerobically fermented to lactic acid, which gives the vagina a pH
of 3.5 to 4.5.
[0029] Further studies have shown that an important function of the
vaginal and cervical epithelial cells is to regulate the pH of the
lumen of the lower genital tract. During premenopausal years
vaginal luminal pH ranges between 4.5 and 6.0 with mild
alkalinization to about 6.5 before ovulation. Lack of estrogen,
such as after menopause, is associate with alkalinization to about
6.5-7.0, whereas replacement with estrogen can acidify the luminal
vaginal pH to about 5.5.
[0030] On a related note, there are times when urine pH can
indicate serious health issues. For example, a very high (alkaline)
urine pH could be caused by kidney failure or a urinary tract
infection. A very low (acidic) urine pH could be the result of lung
disease, complications of diabetes, starvation or diarrhea. The
glomerular filtrate of blood is usually acidified by the kidneys
from a pH of approximately 7.4 to a pH of about 6 in the urine.
Depending on the person's acid-base status, the pH of urine may
range from 4.5 to 8. The kidneys maintain normal acid-base balance
primarily through the reabsorbition of sodium and the tubular
secretion of hydrogen and ammonium ions. Urine becomes increasingly
acidic as the amount of sodium and excess acid retained by the body
increases .Alkaline urine usually containing bicarbonate-carbonic
acid buffer, is normally excreted when there is an excess of base
or alkali in the body. Secretion of acidic or alkaline urine by the
kidneys is one of the most important mechanisms the body uses to
maintain a constant body pH.
[0031] A highly acidic urine pH occurs in: [0032] Acidosis [0033]
Uncontrolled diabetes [0034] Diarrhea [0035] Starvation and
dehydration [0036] Respiratory diseases in which carbon dioxide
retention occurs and acidosis develops
[0037] A highly alkaline urine occurs in: [0038] Urinary tract
obstruction [0039] Pyloric obstruction [0040] Salicylate
intoxication [0041] Renal tubular acidosis [0042] Chronic renal
failure [0043] Respiratory diseases that involve hyperventilation
(blowing off carbon dioxide and the development of alkalosis)
[0044] Urine pH is often used to monitor a person's diet. In people
who are not vegetarians the pH of urine tends to be acidic. A diet
rich in citrus fruits, legumes, and vegetables raises the pH and
produces urine that is more alkaline. Generally an accurate
measurement of urinary pH can be done only on a freshly voided
specimen. If urine pH is to be useful, it is necessary to use pH
information in comparison with other diagnostic information.
SUMMARY OF THE INVENTION
[0045] It is therefore an object of the present invention to
provide an apparatus, system and method for determining one or more
physiological conditions within a mammal based on pH measurements,
including without limitation one or more of the physiological
conditions discussed above.
[0046] Another object of the present invention is to provide an
apparatus, system and method for measuring pH and temperature of
biological fluid.
[0047] Yet another object of the present invention is to provide an
apparatus, system and method for determining a physiological
condition within a mammal based on either in vivo or external
measurements of biological fluids.
[0048] Still another object of the present invention is to provide
an apparatus, system and method for determining a physiological
condition within a mammal that requires minimal calibration.
[0049] A further object of the present invention is to provide an
apparatus, system and method for determining a physiological
condition within a mammal that utilizes a replaceable
"plug-and-play type" of probe.
[0050] A yet further object of the present invention is to provide
an apparatus system and method for determining g a physiological
condition within a mammal that utilizes a dark environment for
calibration.
[0051] A still further object of the present invention is to
provide an apparatus, system and method for determining a
physiological condition within a mammal that utilizes an
ion-sensitive field effect transistor (ISFET) for measuring pH.
[0052] An even further object of the present invention is to
provide an apparatus, system and method for determining a
physiological condition within a mammal wherein the processing and
logic circuitry is maintained in a handle and a minimal amount of
circuitry is maintained in a replaceable probe.
[0053] Another object of the present invention is to provide an
apparatus, system and method for determining the fertility status
of a female mammal.
[0054] Yet another object of the present invention is to provide an
apparatus, system and method for predicting ovulation in a female
mammal based on current and stored pH and/or temperature
measurements.
[0055] These and other objects are met by the present invention
which, in one aspect, is an apparatus for measuring a physiological
condition within a mammal comprising: an elongated probe for
insertion into a body lumen of the mammal, the probe comprising a
first circuit board operably coupling a pH sensor for measuring the
pH within the body lumen and generating a pH signal indicative of
the measured pH, a memory device storing parametric data unique to
the pH sensor, and a first interface connector located at a
proximal portion of the probe; a handle for manipulating the probe,
the handle comprising a second circuit board operably coupling a
microprocessor for processing the pH signal and generating an
output signal based on the processing of the pH signal, a display
device for displaying the output signal generated by the
microprocessor, and a second interface connector; the probe
connected to the handle in manner that allows the probe and handle
to be repetitively engaged and disengaged from each other; and
wherein when the probe is connected to the handle, the first and
second interface connectors are in electrical connection so that
the microprocessor can retrieve the parametric data from the memory
device of the probe and receive the pH signal.
[0056] In another aspect, the invention can be an apparatus for
measuring a physiological condition within a mammal comprising: an
elongated probe for insertion into a body lumen of the mammal, the
probe comprising a first circuit board operably coupling an
ion-sensitive field effect transistor (ISFET) for measuring pH
within the body lumen and generating a pH signal indicative of the
measured pH, a temperature sensor for measuring temperature within
the body lumen and generating a temperature signal indicative of
the measured temperature, a diaphragm in contact with an
electrolyte solution buffered at a known pH, a memory device
storing ISFET slope data at both ambient temperature and normal
body temperature for the ISFET, and a first interface connector
located at a proximal portion of the probe; a handle for
manipulating the probe, the handle comprising a second circuit
board operably coupling a microprocessor for receiving the pH and
temperature signals and generating an output signal based on the
processing of the pH and temperature signals and the ISFET slope
data, a display device for displaying the output signal generated
by the microprocessor, and a second interface connector; the probe
connected to the handle in manner that allows the probe and handle
to be repetitively engaged and disengaged from each other; and
wherein when the probe is connected to the handle, the first and
second interface connectors are in electrical connection so that
the microprocessor can retrieve the ISFET slope data from the
memory device of the probe and receive the pH and temperature
signals.
[0057] In yet another aspect the invention can be an apparatus for
measuring a physiological condition within a mammal comprising: a
probe for insertion into a body lumen of the mammal, the probe
comprising: an elongated tubular housing extending along a
longitudinal axis from a proximal end to a distal end, the
elongated tubular housing having a first internal cavity; a first
circuit board located within the first internal cavity; a pH sensor
for measuring pH within the body lumen located at a distal portion
of the elongated tubular housing, the pH sensor generating a pH
signal indicative of the measured pH and operably coupled to the
first circuit board; a temperature sensor for measuring temperature
within the body lumen located at the distal portion, the
temperature sensor generating a temperature signal indicative of
the measured temperature and operably coupled to the first circuit
board; a first memory device storing parametric data unique to the
pH sensor, the memory device housed within the internal cavity of
the elongated tubular housing and operably coupled to the first
circuit board; and a first interface connector located at a
proximal portion of the elongated tubular housing and operably
coupled to the circuit board; a handle for manipulating the probe,
the handle comprising: a second housing having a second internal
cavity and a socket forming a passageway into the second internal
cavity; a second circuit board located within the second internal
cavity; a microprocessor located within the second housing and
operably coupled to the second circuit board for receiving and
processing the pH signal and the temperature signal, the
microprocessor generating an output signal based on the processing
of the pH signal and the temperature signal and the parametric
data; a power source located within the second housing and operably
coupled to the second circuit board; user controls located on the
second housing and operably coupled to the second circuit board; a
display device operably coupled to the second circuit board for
displaying the output signal generated by the microprocessor; a
second interface connector operably coupled to the circuit board
and aligned with the socket; and wherein the probe is removably
secured to the handle, the proximal portion of the elongated
tubular housing extending into the socket of the second housing so
that the first and second connectors are in electrical
connection.
[0058] In still another aspect, the invention can be an apparatus
for measuring a physiological condition within a mammal comprising:
an elongated tubular housing extending along a longitudinal axis
from a distal end to a proximal end, the housing having an internal
cavity; a first opening in the elongated housing forming a first
passageway into the internal cavity; an ISFET for measuring pH
within a body lumen of the mammal, the ISFET positioned in the
internal cavity, the ISFET aligned with the first opening so that
at least a portion of the ISFET is exposed via the first opening;
and a first seal between the ISFET and the housing forming a
hermetic seal about a perimeter of the first opening.
[0059] In a further aspect, the invention can be an apparatus for
measuring a physiological condition within a mammal comprising: an
elongated tubular housing extending along a longitudinal axis from
a distal end to a proximal end; and an ISFET for measuring pH
within a body lumen of the mammal, the ISFET located on a distal
portion of the housing and having at least a portion of the ISFET
exposed for contact with fluid of the body lumen.
[0060] In a yet further aspect, the invention can be an apparatus
for measuring a physiological condition within a mammal comprising:
an elongated tubular housing extending along a longitudinal axis
from a distal end to a proximal end; an ion-sensitive field effect
transistor (ISFET) for measuring pH within a body lumen of the
mammal, the ISFET located on a distal portion of the housing and
having at least a portion of the ISFET exposed; a temperature
sensor for measuring temperature within the body lumen, the
temperature sensor located on a distal portion of the housing and
having at least a portion of the temperature sensor exposed; a
memory device storing parametric data unique to the pH sensor the
parametric data includes first ISFET slope data determined at
ambient temperature and second ISFET slope data determined at
normal body temperature; a first interface connector operably
coupled to the ISFET, the temperature sensor and the memory device,
the first interface connector located at the proximal end of the
housing; and a first circuit board located within the housing, the
ISFET, the temperature sensor, the memory device and the first
interface connector operably coupled to the first circuit
board.
[0061] In a still further aspect, the invention can be an apparatus
for measuring a physiological condition within a mammal comprising
an elongated housing extending along a longitudinal axis from a
proximal end to a distal end, the housing having an internal
cavity; a transverse wall extending along the longitudinal axis
that separates the internal cavity into a first chamber and a
second chamber, the first and second chamber isolated from one
another and extending in an axial adjacent manner along the ion
longitudinal axis; a par-cylindrical cutout in the elongated
housing forming an open end of the first chamber and exposing a
portion of the transverse wall; a pH sensor for measuring pH within
a body lumen of the mammal and a temperature sensor for measuring
temperature within the body lumen, the pH sensor and the
temperature sensor located on the exposed portion of the transverse
wall; a par-cylindrical cover having a well for collecting
biological fluids, the well having an annular wall and a floor, and
first and second openings forming first and second passageways
through the floor of the well respectively; and the par-cylindrical
cover secured to the elongated housing so that the pH sensor is
exposed via the first opening and the temperature sensor is exposed
via the second opening, the par-cylindrical cover covering the
par-cylindrical cutout so as to hermetically seal the open end of
the first chamber.
[0062] In an even further aspect, the invention can be an apparatus
for measuring a physiological condition within a mammal comprising:
an elongated housing extending along a longitudinal axis from a
proximal end to a distal end, the housing having an internal
cavity; a transverse wall separating the internal cavity into a
first chamber and a second chamber; a cutout in the elongated
housing forming an opening into the first chamber and exposing a
portion of the transverse wall; a pH sensor for measuring pH within
a body lumen of the mammal and a temperature sensor for measuring
temperature within the body lumen, the pH sensor and the
temperature sensor located on the exposed portion of the transverse
wall, a cover having a well for collecting biological fluids, first
and second openings forming first and second passageways through a
floor of the well; and the cover secured to the elongated housing
so that the pH sensor is exposed via the first opening and the
temperature sensor is exposed via the second opening, the cover
covering the cutout so as to hermetically seal the opening into the
first chamber.
[0063] The invention may also, in one aspect, be an apparatus for
measuring a physiological condition within a mammal comprising: an
elongated housing extending along a longitudinal axis from a
proximal end to a distal end, the housing having an internal
cavity; a wall within the internal cavity; a cutout in the
elongated housing forming an opening into the internal cavity and
exposing at least a portion of the transverse wall, a pH sensor for
measuring pH within a body lumen of the mammal and located on the
exposed portion of the transverse wall; a cover having a first
opening forming a first passageway through the cover; and the cover
secured to the elongated housing so that the pH sensor is exposed
via the first opening, the cover covering the cutout so as to
hermetically seal the opening into the internal cavity.
[0064] In another aspect, the invention can be a system for
measuring a physiological condition within a mammal comprising: an
apparatus comprising: an elongated housing extending along a
longitudinal axis from a proximal end to a distal end; a pH sensor
for measuring pH within a body lumen of the mammal, the pH sensor
located at a distal portion of the elongated housing; a temperature
sensor for measuring temperature within the body lumen, the
temperature sensor located at the distal portion of the elongated
housing; and a handle having a second housing for manipulating the
elongated housing, the second housing having a top surface, a
bottom surface and a plurality of lateral surfaces bounding the top
and bottom surfaces, the elongated housings protruding from one of
the lateral surfaces of the second housing; a removable cap for
enclosing the distal portion of the elongated housing, the cap
comprising: a base having a first channel in a top surface of the
base, a lid having a second channel in a bottom surface of the lid;
and wherein when the removable cap is in a closed position, the lid
is positioned atop the base so that the bottom surface of the lid
opposes the top surface of the base and the first and second
channels form a cavity having an open end and a closed end; and
wherein when the removable cap is secured to the elongated housing
in the closed position, the distal portion of the elongate housing
nests within the cavity and a remaining portion of the elongated
housing protrudes from the open end of the cavity.
[0065] In yet another aspect, the invention can be a system for
measuring a physiological condition within a mammal comprising: an
apparatus comprising: an elongated housing extending along a
longitudinal axis; a pH sensor for measuring pH within a body lumen
of the mammal, the pH sensor located at a distal portion of the
elongated housing; and a second housing for manipulating the
elongated housing, the elongated housing protruding from the second
housings, a removable cap for enclosing the distal portion of the
elongate housing, the cap comprising: a base having a first channel
in a top surface of the base, a lid having a second channel in a
bottom surface of the lid; and wherein the lid is pivotably mounted
to the base so as to be pivotable between: (i) an open position
wherein the distal portion of the elongated housing can be laid
into the first channel by movement in a direction substantially
perpendicular to the longitudinal axis; and (ii) a closed position
wherein the first and second channels form a heretically sealed
cavity about the distal portion of the elongated housing.
[0066] The invention can, in even another aspect, be a system for
measuring a physiological condition within a mammal comprising: an
apparatus comprising; an elongated housing extending along a
longitudinal axis, a pH sensor for measuring pH within a body lumen
of the mammal, the pH sensor located at a distal portion of the
elongated housing; and a removable cap for enclosing the distal
portion of the elongate housing, the cap comprising: a base having
a first channel in a top surface of the base; a lid having a second
channel in a bottom surface of the lid; and wherein the lid is
pivotably mounted to the base so as to be pivotable between: (i) an
open position wherein the distal portion of the elongated housing
cab be laid into the first channel by movement in a direction
substantially perpendicular to the longitudinal axis; and (ii) a
closed position wherein the first and second channels form a
heretically seated cavity about the distal portion of the elongated
housing.
[0067] In still another aspect, the invention can be a method of
determining fertility and/or vaginal health status in a female
mammal comprising: inserting a probe into a vagina of the female
mammal, a distal portion of the probe comprising an ISFET for
measuring pH and temperature sensor for measuring temperature, the
probe comprising a memory device storing parametric data unique to
the pH sensor; measuring pH and temperature with the ISFET and the
temperature sensor of the probe; transmitting signals indicative of
the measured pH and temperature to a microprocessor; the
microprocessor generating an output signal indicative of the
fertility and/or vaginal health status in the female mammal based
on the signals indicative of the measured pH and temperature and
the parametric data; and displaying the output signal on a display
device of the probe.
[0068] In a further aspect, the invention can be a method of
determining fertility and/or vaginal health status in a female
mammal comprising; inserting a probe into a vagina of the, a distal
portion of the probe comprising a pH sensor for measuring pH and a
temperature sensor for measuring temperature, the probe comprising
a first memory device storing parametric data unique to the pH
sensor; measuring pH and temperature with the pH sensor and the
temperature sensor of the probe; transmitting signals indicative of
the measured pH and temperature to a logic controller; the logic
controller generating an output signal indicative of the fertility
and/or vaginal health status in the female mammal based on the
signals indicative of the measured pH and temperature and the
parametric data; and communicating the output signal to a user.
[0069] In an even further aspect, the invention can be a method of
determining fertility and/or vaginal health status in a female
mammal comprising; inserting a probe into a vagina of the female
mammal, a distal portion of the probe comprising an ISFET for
measuring pH and a temperature sensor for measuring temperature;
measuring pH and temperature with the ISFET and the temperature
sensor of the probe; transmitting signals indicative of the
measured pH and temperature to a microprocessor; the microprocessor
generating an output signal indicative of the fertility and/or
vaginal health status in the female mammal based on the signals
indicative of the measured pH and temperature; and communicating
the output signal to a user.
[0070] The invention may, in yet another aspect, be a method of
determining fertility and/or vaginal health status in a female
mammal comprising: providing an apparatus comprising: an elongated
probe housing a first circuit board operably coupling a pH sensor,
a temperature sensor, and a first interface connector located at a
proximal portion of the probe; and a handle for manipulating the
elongate probe the handle housing a second circuit board operably
coupling a microprocessor, an indicia device, and a second
interface connector; connecting the elongated probe to the handle
so that the first and second interface connectors are in electrical
connection; inserting the elongated probe into a vagina of the
female mammal; measuring pH and temperature with the pH sensor and
the temperature sensor of the probe; transmitting signals
indicative of the measured pH and temperature to the
microprocessor; the microprocessor generating an output signal
indicative of the fertility and/or vaginal health status in the
female mammal based on the signals indicative of the measured pH
and temperature and the parametric data; and communicating the
output signal to a user via the indicia device.
[0071] In still another aspect, the invention can be a method of
calibrating an apparatus for taking in vivo pH measurements
comprising; a) providing a probe having an elongated housing
extending along a longitudinal axis, a well formed in a top edge of
the elongate housing for holding fluids, a pH sensor located on a
floor of the well, the well located at a distal portion of the
elongated housing; b) positioning the distal portion of the
elongated housing on a base of a removable cap, the removable cap
having a lid in an open position; c) supplying a liquid buffered to
a known pH to the well and in contact with the pH sensor; d) moving
the lid of the removable cap to a closed position so that the
distal portion of the elongated housing is enclosed in a cavity of
the removable cap, the cavity being substantially free of visible
light; and e) calibrating the pit sensor to the known pH.
BRIEF DESCRIPTION OF THE DRAWINGS
[0072] FIG. 1 is an isometric view of a vaginal health apparatus
according to an embodiment of the present invention wherein the
probe has been disassembled from the handle.
[0073] FIG. 2 is a high level electrical schematic for the probe of
the vaginal health apparatus of FIG. 1.
[0074] FIG. 3 is high level electrical schematic for the handle of
the vaginal health apparatus of FIG. 1.
[0075] FIG. 4 is a top view of the probe of the vaginal health
apparatus of FIG. 1.
[0076] FIG. 5 is a cross-sectional view of the probe of FIG. 4
taken along view V-V.
[0077] FIG. 6 is an exploded view of the probe of FIG. 4.
[0078] FIG. 7 is a close-up top view of the distal portion of the
probe of FIG. 4.
[0079] FIG. 8 is a cross-sectional view of the distal portion of
the probe taken along view VIII-VIII of FIG. 7.
[0080] FIG. 9 is a top view of the vaginal health apparatus of FIG.
1 in an assembled state.
[0081] FIG. 10 is a cross-sectional view of the virginal health
apparatus along view X-X of FIG. 9.
[0082] FIG. 11 is a close-up view of area XI of FIG. 10.
[0083] FIG. 12A is a perspective view of a removable cap according
to one embodiment of the present invention, the removable cap being
in an open position.
[0084] FIG. 12B is a perspective view of a vaginal health system
according to one embodiment of the present invention including the
vaginal health apparatus of FIG. 1 and the removable cap of FIG.
12A.
[0085] FIG. 13A is a schematic of the vaginal health apparatus of
FIG. 1 inserted into the vagina of a humane female and positioned
for vaginal pH and temperature measurements.
[0086] FIG. 13B is a schematic of the vaginal health apparatus of
FIG. 1 inserted into the vagina of a human female and positioned
for cervical pH and temperature measurements.
[0087] FIG. 14 is a graph of in vivo pH measurement versus time for
a human female subject over a six day period wherein readings were
taken every ten seconds over a two minute period.
[0088] FIG. 15 is a data chart and corresponding graph of pH
measurements versus voltage of three different pH buffers based on
sample size so that effects of the well size on pH readings could
be evaluated.
[0089] FIG. 16 is a graph of measured pH versus time for urine over
a four day period wherein the urine was externally measured in the
sample well.
[0090] FIG. 17 its a four day trend line graph of the final urine
pH measurements of FIG. 16.
DETAILED DESCRIPTION OF THE INVENTION
[0091] One or more embodiments of the present invention will be
discussed in this section with reference to FIGS. 1-17. The
embodiments illustrated herein are not intended to be exclusive or
to limit the invention to the precise form or application
disclosed. The embodiments are chosen and described merely to
explain one or more desired embodiment of the structure, use and/or
application of the invention. While the invention is specifically
described below as a vaginal health device. The invention is not
limited to this application or to the exact structure exemplified.
The present invention can be used to determine any physiological
condition of a mammal that can be determined by pH and/or
temperature values and/or variations thereof over a period of time.
The invention can be used to determine any physiological condition,
such as fertility, vaginal health, oral health, gastro-intestinal
health, dietary health, etc. Specific examples of physiological
conditions within the scope of this invention include without
limitation ovulation, menopause, acidosis, diabetes, diarrhea,
starvation and dehydration, respiratory disease, urinary tract
obstruction, pyloric obstruction, salicylate intoxication, renal
tubular acidosis, chronic renal failure, BV, candidiasis and
trichomoniasis. Moreover, the present invention can be used to
measure the pH and/or temperature of biological fluids both
externally and in vivo. For external measurements, the sample well
allows for the accurate measurement of pH and/or temperature for
bodily fluids such as saliva, urine, and blood. For in vivo
measurements, the invention can also take pH and/or temperature
measurements in any desired body lumen, including without
limitation the vagina, cervix, esophagus, mouth, nasal passages,
auditory canals, digestive tract, urethra, and vascular system.
[0092] The invention is generally described in relation to the
human female. However, the inventive principals can be applied in
veterinary applications with a simple modification of the size
(length and diameter) and/or shape of the structure to fit various
mammals including dogs, cats, dairy cows and horses. As a result,
veterinary applications for monitoring vaginal pH, cervical pH,
oral pH or urinary pH can be accomplished for diagnosis and
determination of a physiological condition in the art of veterinary
medicine.
[0093] The invention allows for measurement of the pH and/or
temperature of biological fluids in a private (i.e., in the home)
or clinical lab environment. As will be discussed in detail below,
the invention allows for easy change, updating and/or replacing of
the probe of the apparatus to keep up with latest technologies in
measuring pH. For example, in some embodiments of the invention,
the pH sensor may be a reference FET (REFFT) which could be
implemented with an ISFET and a pseudo reference electrode. In such
a design, the electrode wire (which is typically an Ag/AgCL coated
wire) and electrolyte solution may be eliminated.
[0094] Additionally, the incorporation of the vital product data
(VPD) into a memory device within the probe of the apparatus allows
the probe to be easily interchanged with other logic assemblies
without the need for extensive two point calibration. The
incorporation of the VPD information within the probe itself
simplifies user operation as key information about the probe
characteristics and use are stored within the memory device of the
probe itself. The logic assembly (which acts as the handle) can
easily read this information in order to guide the user through
proper operation, whether it is taking measurements or calibration.
The ability to store and retrieve important calibration and other
information within the probe make the invention a "plug-and-play"
type of device.
[0095] Referring now to FIGS. 1 and 9, a vaginal health apparatus
100 is illustrated according to one embodiment of the present
invention. The vaginal health apparatus 100 generally comprises a
probe component 200 (sometimes referred to as the "probe") and a
handle component (sometimes referred to as the "handle"). The
vaginal health apparatus 100 is illustrated in FIG. 1 in a
disassembled state wherein the probe 200 has been disconnected from
the handle 300. In FIG. 9, the vaginal health apparatus 100 is
illustrated in an assembled state wherein the probe 200 is
connected to the handle 300.
[0096] The general structure and shape of the probe 200 is formed
by its elongated housing 201, which in the illustrated embodiment,
has an elongated linear rod-like shape. The elongated housing 201
extends from a proximal end 202 to a distal end 203 along a
longitudinal axis A-A (FIG. 4), The elongated housing 201 is a
tubular structure that is specifically sized and shaped for
insertion into the human vagina so that pH and/or temperature
measurements can be taken either in the vaginal tract or at the
cervix. Of course, other elongated shapes can be utilized,
including curved rods.
[0097] The elongated housing 201 has a substantially circular
transverse cross-sectional profile. Of course, the elongated
tubular housing 201 can have a transverse cross-sectional profile
of various shapes and sizes. The exact size and shape of the
elongated housing 201 will be dictated by the end use to which the
vaginal health apparatus 100 is to be put, and is not to be
considered limiting of the present invention unless specifically
recited in the claims.
[0098] Conceptually, the elongated housing 201 comprises a proximal
portion 210, a middle portion 220 and a distal portion 230. A fluid
sample well 240 is formed in the distal portion 230 of the probe
200. The well 240 acts as a reservoir for holding biological
fluids, such as urine, saliva, blood, cervical fluids, vaginal
fluids and/or other bodily fluids. A pH sensor 250, a temperature
sensor 260 and a diaphragm 270 are located within the well 240.
[0099] Turning to the handle, the general structure and shape of
the handle 300 is formed by its box-like housing 301, which in the
illustrated embodiment, comprises a tapered portion 310 and a
generally rectangular box portion 320. The handle housing 301
provides a means by which the user can manipulate the movement of
the probe 200 within the desired body lumen (when assembled as
discussed below). The handle housing 301 comprises a top surface
302, a bottom surface 303, and a plurality of lateral surfaces 304
that bound the top and bottom surfaces 302, 303, thereby forming a
substantially closed and hollow structure. The handle 300 generally
comprises a display device 330, user controls 340-342, a first data
port 314 and a second data port 315 (these elements will be
discussed in greater detail below).
[0100] When the vaginal health apparatus 100 is assembled (as shown
in FIG. 9), the probe 200 is removably (i.e., non-fixedly) secured
to the handle 300. In other words, the probe 200 and the handle 300
are connected in a manner that allows the probe 200 and the handle
300 to be repetitively connected and disconnected without
compromising the structural or functional integrity of either the
probe 200 or the handle 300. In the illustrated embodiment, the
probe 200 is removably secured to the handle 300 by slidably
inserting the proximal portion 210 of the elongate housing 201 into
a socket 519 (visible in FIG. 11) formed into the tapered portion
310 of the handle housing 301. The socket 519 of the handle housing
301 and the proximal portion 210 of the elongated housing 201 are
correspondingly sized and shaped (relative to one another) so that
a tight fit exists between the proximal portion 210 of the elongate
housing 201 and the walls of the socket 519 of the handle housing
301 when the proximal portion 210 is fully inserted within the
socket 519. This tight fit assembly provides adequate structural
connectivity between the handle 300 and the probe 200 so that the
probe 200 does not separate (or otherwise become dislodged) from
the handle 300 during use. The proximal portion 210 of the
elongated housing 201 has a tapered transverse cross-sectional area
that helps facilitate slidable insertion into the socket 519 of the
handle housing 301 and increases frictional engagement with the
walls 521 (FIG. 11) of the socket 519.
[0101] While the non-fixed connection between the probe 200 and the
handle 300 is exemplified as a tight-fit assembly, other mechanisms
and structural arrangements can be implemented to effectuate the
desired connection, either in addition to or in replace of the
tight-fit technique. For example, one or more depressions could be
provided in either the proximal portion 210 of elongated housing
201 or the walls 521 of the socket 519 of the handle housing 301
that snap-fit (or otherwise mate) with tangs (or some other
protuberance) provided on the other one of the proximal portion 210
of elongated housing 201 or the walls 521 of the socket 519 of the
handle housing 301. Alternatively, the outer surface of the
proximal portion 210 of the elongate housing 201 and the walls 521
of the socket 519 of the handle housing 301 can be provided with
corresponding threads for threaded engagement. In other embodiments
a bayonet lock, magnets, cotter pins, or combinations of the
aforementioned techniques could be implemented.
[0102] A slot 211 is formed into the proximal portion 210 of the
elongate housing 210 of the probe 200. The slot 211 is a linear
slot that extends from the proximal end 202 toward the distal end
203 of the elongated housing 201 along a top edge of the elongated
housing 201. The slot 211 is provided on the elongated housing 201
to ensure proper rotational orientation of the elongated housing
201 when the probe 200 is connected to the handle 300. A key or
other protuberance 522 (FIG. 11) is provided on the wall 521 of the
socket 519 of the handle housing 301. When the probe 200 is in the
proper rotational orientation during assembly, the key 522 mates
with the slot 211, allowing the proximal portion 210 to enter the
socket. However, if the probe 200 is in an improper rotational
orientation during assembly, the key 522 prohibits the proximal
position 210 from entering the socket. An indicia marker 311 on the
top surface 302 of the handle housing 301 indicates the
circumferential position of the key 522 (or protuberance) within
the socket 519. The key/slot assembly also prevents undesired
rotation of the probe 200 with respect to the handle 300 once
assembly of the vaginal health apparatus 100 is achieved. As will
be disc used below, proper rotational orientation of the probe 200
with respect to the handle 300 during and after assembly is
important to ensure proper and stable electrical connection between
the separate circuit boards of the probe 200 and the handle
300.
[0103] The probe 200 can be removed for the handle 300 for easy
cleaning with warm water or mild soapy water and then rinsed with
warm water. In a clinical environment the probe 200 would need to
be sterilized with something similar to CIDEX OPA solution (Johnson
and Johnson). Alternately, the probe 200 could be designed with
material such as PEEK and be subjected to autoclaving temperatures
of about 130.degree. C. For the illustrated embodiment, the use of
non-autoclaving process is suggested. The probe 200 in this
embodiment is approximately 0.04 inches in diameter and 7 inches
long. Changes in dimensions can be accommodated in order to support
pH measurement in other female mammals.
[0104] As will be discussed immediately below, the circuitry to be
positioned within the probe 200 and the circuitry to be positioned
within the handle 300 is strategically selected so that: (1) the
probe 200 is as inexpensive as possible so that it can be discarded
and replaced as necessary; (2) the handle 300 can be used in
conjunction with different probes 200 and still prove accurate and
reliable measurements (3) all data relating to the measurements
taken over periods of time is stored within the handle 300 for
either internal or external processing; and/or (4) the need for
calibration is minimized. As a result of this strategic separation
and placement of circuitry, the handle 300 becomes the logic
controller assembly of the vaginal health apparatus 100.
[0105] Referring to FIGS. 2-3 concurrently, the strategic
separation and selection of the circuitry necessary to run the
vaginal health apparatus 100 is shown according to one embodiment
of the present invention. FIG. 2 is a high level electrical
schematic of the circuit 400 which is located within the elongated
housing 201 of the probe 200. FIG. 3 is a high level electrical
schematic of the circuit 500 which is located within the housing
301 of the handle 300.
[0106] With reference to FIG. 2, the primary components of the
circuit located within the probe 200 are the pH sensor 250, an
analog interface circuit 416, a reference electrode 421, the
temperature sensor 260, the diaphragm 270, KCL solution 422, a
non-volatile, memory 415 and an interface connector 417. All of
these components are operably coupled via a circuit board, which is
located within the elongated housing 201, as is well known in the
art.
[0107] The pH sensor 250 is preferably an ISFET which is a
semiconductor device which has the metal gate replaced with a
hydrogen-ion sensitive layer. The ISFET 250 is the primary element
in measuring the hydrogen ion concentration (i.e. the pH) of the
biological fluid to be measured with the vaginal health apparatus
100. When the hydrogen ions contact the gate sensitive layer of the
ISFET 250, the voltage between the gate and source of the ISFET is
influenced. The reference electrode 421 is required to close the
electrical circuit loop. The analog circuitry 416 drives the
electrode 421 in order to maintain a constant current through the
drain and source of the ISFET 250. It is this drive voltage change
that is used as the pH output signal and used by the A/D converter
502 (which located on the circuit 500 within the handle 300) to
measure pH of the biological fluid under examination. The reference
electrode 421 is preferably a typical Ag/AgCL coated wire and is
placed in the KCL solution 422. The diaphragm 270 is the conduit
between the KCL solution 422 and the biological fluid being
measured. While the pH sensor is preferably an ISFET, in some
embodiments of the invention the pH sensor can be a combination of
ISFET and REFET (Reference FET) with a Pseudo Reference Electrode.
As technology improves for the creation of the REFET it would be
easy to replace the combination of the ISFET and standard Reference
Electrode comprised of the reference electrode 421 and KCL solution
422. For example the ISFET and REFET could be produced on the same
substrate with a platinum electrode which may consist simple of an
evaporated layer of Pt deposited on the ISFET/REFET substrate. It
is also possible for a totally solid-state sensing probe to be
incorporated into the invention.
[0108] The temperature sensor is preferably a thermistor, and more
preferably, a typical NTC (negative temperature coefficient)
device. While the temperature sensor is preferably a thermistor, in
some embodiments of the invention the temperature sensor can be a
thermocouple or infared detector.
[0109] The non-volatile memory 415 is preferably a simple wire
serial memory that can be read by and written to by the
microprocessor 510 (which is located on the circuit 500 of the
handle 200). The interface connector 417 is preferably one or more
PCB pads. The invention, however, it so limited and any suitable
mechanism technique or device that can be used to repetitively
engage and disengage with a corresponding interface connector to
operably and electrically couple circuits together can be used. For
example, the interface connector 417 could be multi-pin connector,
a USB connector, a firewire connector, or other jack or pin and
socket combination.
[0110] Referring now to FIG. 3, the primary components of the
circuit 500 located within the handle 300 are the microprocessor
510, A/D converter 502, the display device 330, control switches
340-342, the first and second data ports 314, 315, an interface
connector 517 a DC/DC converter 515, an audible device 516, and a
battery 520. All of these components are operably coupled via a
circuit board, which is located within the handle housing 301, as
is well known in the art.
[0111] The control switches 340-342 are used to select various
functions of the vaginal health apparatus 100, such as power on/off
calibration, start/stop measurements etc. These functions can be
displayed via menu screens on the display device 330. The display
device 330 is preferably an LCD display panel such as a full
graphic display or a simple segmented and icon based display.
However, the display device 330 can be any type of device used to
visibly display information or status, such as one or more LEDs,
OLED display, or other types of screens, such as plasma or LED.
[0112] The first and second data ports 314, 315 can be any type of
wired or wireless port that can facilitate data transfer and
communication between the vaginal health apparatus 100 and an
external electronic device, such as a computer, cell phone,
handheld data assistant, or the like. Examples of data ports
include without limitation firewire ports, USB ports, mini USB
ports, IRDA ports, serial ports (such as RS232) multi-pin ports, RF
transceivers, etc.
[0113] The interface connector 517 is preferably one or more
compression connectors for operably and electrically coupling with
the interface connector 417 of the circuit 400 of the probe 200. As
discussed above, the interface connector 517 is selected to mate
with the type of interface connector 416 chosen for the probe 200.
Any of the types of connectors mentioned above for the interface
connector 417 can be used for the interface connector 517 of the
circuit 500 of the handle 300.
[0114] The interface connectors 417, 517 are selected and
positioned within the probe 200 and handle 300 respectively so that
when the probe 200 is assembled/connected to the handle 300 (as
described above) the interface connectors 417, 517 come into and
stay in operable connection with one another so that data signals
and power can be transmitted between the two circuits 400, 500.
When the interface connectors 417, 517 are in operable connection
the power source 520, which is preferably in the form of a lithium
coin cell battery, provides the necessary power for both of the
circuits 400, 500. Additionally, pH and temperature signals
generated by the pH and temperature sensors 250, 260 are
transmitted to the microprocessor 510 (after passing through the
A/D converter 502) for processing and or storage. Additionally, the
microprocessor 510 can access and retrieve data (such as parametric
data, such as properties and parametric data, that is inherent to
the pH sensor 250), stored in the memory device 415 of the circuit
400.
[0115] Referring now to FIGS. 4-6 concurrently, additional details
of the probe 200 will be discussed. As discussed above, the probe
200 comprises an elongated housing 201 which extends from a
proximal end 202 to a distal end 203 along the longitudinal axis
A-A. The elongated housing 201 comprises a main housing portion
204, a cover 205 and a coupling 206. Preferably, the elongated
housing 201 is constructed of a plastic, such as a medical grade
ABS material, or other biocompatible material.
[0116] The coupling 206 forms the proximal portion 210 of the
elongated housing 201 while the cap 205 extends along the distal
portion 230 of the elongated housing 201. The coupling 206
comprises four spaced apart flexible tabs 207 extending from its
distal edge for insertion into the internal chamber(s) 221, 222 of
the main housing portion 204. When the probe 200 is assembled, the
flexible tabs 207 of the coupling 206 are slid into the internal
chamber(s) 221, 222 of the main housing portion 204 until a collar
208 of the coupling 206 contacts the proximal edge of the main
housing portion 204. Frictional contact between the tabs 207 and
the inner surface of the main body portion 204 secure the coupling
206 to the main body portion 204. The connection between the
coupling 206 and the main body portion 204 can be further enhanced
by using an adhesive, sonic weld, thermal weld, or any other
connection techniques that are now known or later developed in the
art. Preferably, the interface between the coupling 206 and the
main housing portion 204 is hermetic so that fluids can not enter
the elongate housing 201 at this location.
[0117] The lower longitudinal section 209 of the coupling 206 is
solid while the upper longitudinal section comprises a cavity 212
that extends the entire length of the coupling 206, thereby forming
a longitudinal passageway through the coupling 206. The cavity 212
is in spatial communication with the slot 211 (which was discussed
above in detail). When the coupling 206 is secured to the main body
portion 204 when the probe 200 is assembled, the cavity 212 of the
coupling is in spatial communication with the top chamber 221 of
the main body portion 204. As explained in greater detail below,
this allows the circuit board 280 (the majority of which is housed
in the upper chamber 221 of the main housing portion 204 to extend
into the cavity 212 of the coupling 206.
[0118] As discussed above, the transverse cross-sectional profile
of the coupling 206 is tapered along its longitudinal length, with
the smallest area being at the proximal end 202. This allows the
coupling 206 to be inserted into the socket 519 of the handle
housing 300.
[0119] The main housing portion 204 comprises an outer tubular wall
213 that forms an elongated internal cavity. A transverse wall 214
that extends along the longitudinal axis A-A is provided within
(and integrally formed with) the outer tubular wall 213, thereby
separating the elongated internal cavity into a first longitudinal
chamber 221 and a second longitudinal chamber 222. The first and
second longitudinal chambers 221, 222 extend in an axial adjacent
manner and are hermetically isolated from one another. The
transverse wall 214 is preferably centrally arranged within the
other tubular wall 213 but can be offset from the longitudinal axis
if desired. The transverse wall 214 is preferably a flat wall
having planar upper and lower surfaces. The invention, however, is
not so limited and the transverse wall can take on other shapes and
contours if desired.
[0120] A par-cylindrical cutout 215 is provided at the distal
portion 230 of the main housing portion 204, thereby exposing a
portion 216 of the wall 214 and creating an open end for the upper
chamber 221. While the "missing portion" of the main housing
portion 204 is described as a "cutout," it is not necessary for the
opening to be the result of some type of cutting, punching or
breaking process. It is intended that the term "cutout" merely mean
an opening which, for example, may result from the main housing
portion 204 being formed in the illustrated shape during an
injection molding process. Additionally, the exact shape and
location of the cutout 215 can vary as desired.
[0121] A plurality of protuberances 217 (in the form of pins)
project upward from the upper surface 232 of the exposed portion
216 of the transverse wall 214. The protuberances 217 are provided
to mate with corresponding bores in the cap 205 to ensure proper
alignment between the cap 205 and the main housing portion 204
during assembly of the probe 200. A retaining structure 218, in the
form of a upstanding U-shaped wall, also projects upward from the
upper surface 232 of the exposed portion 216 of the transverse wall
214. The retaining structure 218 and some of the protuberances 217
retain and align the circuit board 280 in its proper position
within the upper chamber 221 when the probe 200 is assembled.
[0122] A hole/opening 219 is provided on the exposed portion 216 of
the transverse wall 214 that forms a passageway through the
transverse wall into the lower chamber 222 of the elongated housing
201. The holes is 219 is sized and shaped to accommodate the
diaphragm 270 so that a first portion of the diaphragm 270 is
exposed to the biological fluid being tested while a second portion
of the diaphragm 270 protrudes into the lower chamber 222 and is in
contact with the KCL solution 422.
[0123] The cover 205 is a par-cylindrical structure that is sized
and shaped to correspond to the cutout 215 so that the cover 205
can enclose the cutout 215 when the probe 200 is assembled. The
connection of the cover 205 to the main housing portion 204 will be
described below in greater detail with reference to FIGS. 7-8. The
cover 205 generally comprises an outer surface 225. The well 240 is
formed into the outer surface 225 of the cover 205.
[0124] The cover 205 comprises three holes/openings 226-228 (which
are located on a floor 241 of the well 240) that provide
passageways through the cover 205. The opening 226 is sized and
shaped to accommodate the diaphragm 270 so that it is exposed to
biological fluids during use via the opening 226. The opening 227
is sized and shaped to accommodate the pH sensor-ISFET 250 so that
it is exposed to biological fluids during use via the opening 227.
The opening 228 is sized and shaped to accommodate the temperature
sensor 260 so that it is exposed to biological fluids during use
via the opening 228. The walls 229 of the opening 227 are tapered
to help funnel and direct the biological fluids into contact with
the ISFET 250. The walls 231 of the opening 228 are also tapered to
help funnel and direct the biological fluids into contact with the
temperature sensor 260.
[0125] The ISFET 250, the temperature sensor 260, the non-volatile
memory chip 415, the reference electrode 421 and the interface
connector 416 are all mounted on the small printed circuit board
280. The ISFET 250 is typically mounted to the printed circuit
board 280 via epoxy and wire bonds although other mounting
techniques, such as compression connections, are possible. As will
be discussed in greater detail below, only a portion of the ISFET
250 contains the hydrogen ion sensing portion which makes contact
with the test liquid or material via the opening 227.
[0126] The non-volatile memory chip 415, which is also located on
the printed circuit board 280, is utilized to store various data.
Generally, the data stored in this memory 415 is referred to herein
as Vital Product Data (VPD). The VPD information contains
information such as probe serial number, probe manufacturer,
calibration information, parametric data unique to the ISFET and
temperature sensor being used, and time since last calibration. The
VPD information is intended to be used by the microprocessing unit
510 in the handle housing 300. The processing unit 510 will always
read the contents of the memory device 415 to identify the VPD
information in order to determine what if any actions might be
required by the user before measurement.
[0127] For example, in one embodiment of the invention, the VPD
information stored in the memory device 415 of the probe 200
includes: [0128] 1) Serial # information (fields 00-09). This
contains important information regarding build date and location.
[0129] 2) Vendor Name (fields 10-24) [0130] 3) Assembly # (fields
25-2E) [0131] 4) 3 point calibration information at ambient (room
temperature) (fields 30-37 in VPD_details) [0132] 5) 3 point
calibration information at body temperature (98.6F. or 37C.).
(fields 38-3F in VPD_details) [0133] 6) Date Last Calibrated
(fields 60-65 in VPD_details) [0134] 7) Number of Measurements
Since Last Calibration (fields 66-67 in VPD_details) [0135] 8)
Number of pH measurements Taken (fields 68-6A in VPD_details)
[0136] 9) ISFET Leakage (fields 46-47) [0137] 10) ISFET Lot #
(fields 48-4F)
[0138] Storing the "Date Last Calibrated" in the memory device 415
allows the microprocessor 510 to force the user to follow proper
operation procedures in order to maximize accurate measurements.
For example if it is determined that the vaginal health apparatus
100 has not been calibrated for an extended period of time, say 30
days, the firmware would not allow the user to take a vaginal
measurement until pH7 buffer calibration in the sample well 240 is
completed.
[0139] Storing the "Number of Measurements Since Last Calibration"
in the memory device 415 ensures proper calibration in the event
that, even if the vaginal health apparatus 100 was calibrated
within a specific time frame, but was used say 10 times without
calibration, the microprocessor 510 would then force the user to
calibrate to maintain accuracy. For example in a doctor's office or
other clinical environment, if they used it 10 times in one day the
microprocessor 510 would force the doctor to do a calibration
procedure to make sure accurate measurements are taken.
[0140] Storing the "Number of pH Measurements Taken" in the memory
device 415 ensures that the useful end of life of the product can
be monitored. For example if it is determined that drift occurs
within the vaginal health apparatus 100 (say the KCL electrolyte
solution ages or gets slightly contaminated) after 2000
measurements, the vaginal health apparatus 100 can automatically
notify the user that the probe 200 needs to be replaced with a new
one.
[0141] By storing calibration information at room and ambient
temperature in the memory device 415, more accurate pH measurements
can be attained by utilizing the unique temperature characteristics
of the ISFFT 250. The temperature correction factor can be obtained
by calculating differences in slope or absolute values. For example
if the readings at 98.6.degree. F. vary by 0.1 pH versus the
readings at ambient (say 70.degree. F.) then the microprocessor 510
can compensate for these readings when vaginal measurements are
taken. So, if a user does an occasional pH7 buffer calibration in
the sample well 240, the microprocessor 510 would be able to
determine the `correction factor` for a measurement at
98.6.degree.F. Correction for tolerances associated with the
thermistor 260 and series resistor can be automatically compensated
for as the absolute value at 98.6.degree. F. is stored during the
manufacturing test and calibration process.
[0142] Storing the VPD information in the memory device 415 within
the probe 200 allows for "plug and play" operation by the end user,
thereby simplifying operation and making this a user friendly
product. The storage of the VPD information in the memory device
415 within the probe 200 is also important to minimize the number
and level of calibration cycles required. Inclusion of parametric
data that is unique to the specific ISFET 250 and the thermistor
260 being used is an important factor in reducing and simplifying
the amount of required user interaction and calibration. For
example, the processing unit 510 may read the field indicating that
the probe was not calibrated for an extended period of time and
would automatically force the user to run a single point
calibration to insure proper measurement results.
[0143] As set forth and exemplified above, the VPD information
contains parametric data unique to the characteristics of the
particular ISFET and thermistor housed within that probe assembly.
The ability to store this unique parametric data enables the
firmware within the handle housing 300 to read specific data which
enables more accurate measurements and simplifies user operation.
The ISFET is a semiconductor device similar to a MOSFET. As such it
has characteristic curves for current and voltage. The desired mode
of operation for the ISFET is in a constant drain to source voltage
(V.sub.ds) and constant drain to source current (I.sub.ds). As the
characteristics curves of the ISFET change slightly from ISFET to
ISFET, the absolute voltage values will change as well when
implemented in the circuit. ISFETs are built on silicon wafers and
thus the parametric properties of each ISFET will vary from lot to
lot and, in some instances, even vary from wafer to wafer or device
to device (even if on the same wafer). Such differences are due to
tolerances and inherent variations in the manufacturing process.
These differences result in slight variables in ISFET
characteristic such as ISFET leakage current, drain-source
voltage/current curves, capacitance, etc. As stated earlier, the
gate portion of the ISFET is replaced with an ion sensitive layer
which can consist of material such as Si.sub.3N.sub.4,
Al.sub.2O.sub.5. Variations in the ion sensitive layer will also
contribute to the characteristics of the ISFET. The combination of
these ISFET characteristics along with temperature determines the
slope and absolute voltage for a given pH. Thus, one ISFET placed
in the circuit may exhibit a slope voltage per pH characteristic of
say 55 mv/pH while another ISFET may produce a slope characteristic
of 54 mv/pH. In addition, the absolute voltage value generated by
the circuitry for a particular ISFET placed in a fixed buffer
solution will vary among ISFETs. It is these variances and others
that effect the parametrics of the ISFET/probe combination that
require and are stored in the VPD within the probe assembly.
[0144] All of these unique characteristics add up to make each and
every ISFET 250 slightly unique, even when from the same wafer.
Thus, when the, ISFET 250 is put into the circuit 400 in the
factory, the slope of each ISFET 250 and the absolute voltage value
for a particular pH value will be different.
[0145] Also how the ISFET 250 drifts with time due to leakage
current will be different since the leakage current of each device
will be unique to the case of ISFETs, variables also exist
regarding the gate membrane material application which will
certainly have an effect as well. Each ISFET will also have unique
characteristics regarding drift with temperature. So, by storing
the parametric data that is unique to the exact ISFET 250 being
used in the completed probe 200, the vaginal health apparatus 100
can compensate for as many variables as possible that effect the
readings. Because the probe 200 also includes other electronics,
such as the op amp, the voltage reference, the Ag/AgCL electrode
and electrolyte solution (which complete the ISFET circuit), the
ISFET 250 is essentially profiled along with all the other
components that complete the probe 200.
[0146] The following are examples of parametric data unique to the
ISFET 250 (and the assembled combination of electrode 421, KCL
electrolyte 422 solution and diaphragm 270) that are stored in the
memory device 415.
ISFET xpH Factory Value Low Temp:
[0147] This is the value measured and programmed during final
production test. These values are used to determine the ISFET
slope. These values are only programmed at the factory during final
testing. They will however be read by the software within the
handle 300 to determine ISFET slope. The value programmed in this
field should reflect the ambient temperature (25C.).
Low Temperature Value:
[0148] This is the temperature value measured during the ISFET
Factory Low Temperature value calibration cycle. It is written the
same time as the ISFET xpH Factory Value Low Temp fields are
written. This temperature should be approximately 25C.
ISFET xpH Factory Value High Temp:
[0149] This is the value measured and programmed during final
production test. These values are used to determine the ISFET
slope. These values are only programmed at the factory during final
testing. They will however be read by the software within the
handle 300 to determine ISFET slope. The value programmed in this
field should reflect the high temperature value of 39C. +/-0.1C.
(98.6F. +/-0.2F.).
High Temperature Value:
[0150] This is the temperature value measured during the ISFET xpH
Factory High Temperature value calibration cycle. It is written the
same time as the ISFET xpH Factory Value High Temp fields are
written. This temperature should be 39C. +/-0.1C.
(98.6F.+/-0.2F.).
ISFET Temp Correction Value:
[0151] This is a place holder for any information that might be
required for correction of pH Value with temperature. It is assumed
that the ISFET xpH Factory Value will be calculated and programmed
while at 25.degree. C. The Correction Value should be for
measurement at 37.degree. C. or if correction is linear the
correction required per 1.degree. C.
ISFET Leakage Current:
[0152] This is a value in stored in uA so that it can be used to
possible determine ISFET drift over time and used by software to
possible compensate for this.
[0153] Referring still to FIGS. 4-6 the circuit board 280 is of an
elongated shape and is positioned within the upper chamber 221.
More specifically, the circuit board 280 is positioned within the
upper chamber 280 and secured to the upper surface 232 of the
transverse wall 214. The circuit board 280 is held in place against
the transverse wall 214 via keying system in order to make sure
that the ISFET 250 and temperature sensor 260 are properly aligned
with the openings 227, 228 of the cover 205 when the cover 205 is
secured to the main housing portion 204 to enclose (and seal) the
cutout 205.
[0154] A proximal portion 281 of the circuit board 280 extends into
the cavity 212 of the coupling 206. The proximal portion 281 of the
circuit board 280 comprises the interface connector 417, in the
form of PCB pads, which are located on the bottom surface of the
circuit board 280 for operable contact/mating with the interface
connector 517 of the handle housing 300 when the vaginal health
apparatus 100 is assembled.
[0155] While the circuit board 280 is located within the upper
chamber 221, the reference electrode 421 extends from the circuit
board 280 and into the lower chamber 222. The lower chamber 222 is
filled with an electrolyte solution 422 that is buffered at a known
pH, such as KCL at a pH of 7.0. The lower chamber 222 is
hermetically sealed in order to prevent any leakage of the
electrolyte solution 422. The sealing of the open end of the lower
chamber 222 is accomplished using an electrolyte plug 233. The
reference electrode 421 extends through a small hole 234 in the
plug 233. The appropriate hermetic seal is then formed with an
appropriate epoxy or ultrasonic or thermal welding.
[0156] Referring now to FIGS. 7-8 concurrently, the construction of
the distal portion 230 of the probe 200, and the relationship
between its components, will be described in greater detail. As
discussed above, the cover 205 of the probe 200 comprises a well
240 that acts as a reservoir for holding a biological fluid that is
to be measured with the vaginal health apparatus 100. The well 240
is a depression, channel or groove formed into a top edge of the
cover 205 that acts as a reservoir (or small bowl) for biological
fluids. In addition the well 240 provides a method for taking
in-vitro measurements. Sample material or swabs can be taken and
placed into the sample well 240 if desired.
[0157] The sample well 240 also provides a method for easy
calibration and a reduction of the amount of calibration solution
required. Only a small volume of buffer solution (a few drops) will
be required for the calibration process. Of course, the well 240
can be modified to accommodate more or less material by easily
modifying the length, width or depth of the depression.
[0158] The well 240 comprises a floor 241 and an annular rim 242
that surrounds the floor 241. The annular rim 242 provides an
upstanding wall that retains the biological fluid within the well
240. The well 240 is designed into the probe 200 so that it can be
easily inserted into the vagina for in-vivo measurement of the
vaginal wall surface or the ectocervix. During such use, the
annular rim 242 can be scraped against the vaginal wall or cervix
by rotating the probe 200 so as to force fluids into the well
240.
[0159] The ISFET 250, the temperature sensor 260 and the diaphragm
270 are embedded within the floor 241 of the well 240 in order to
provide an accurate pH measurement. The ISFET 250, the temperature
sensor 260 and the diaphragm 270 are exposed to the exterior of the
apparatus 100 via the openings 226-228, which are aligned along an
axis that is spaced from and substantially parallel to the
longitudinal axis A-A. Aligning the openings 226-228 on such an
axis ensures that the diaphragm 270, ISFET 250 and temperature
sensor 260 all make contact with the sample material, allowing for
an accurate pH measurement and/or temperature measurement.
[0160] The wall 229 of the opening 227 that surrounds the ISFET 250
is tapered/sloped to assist in capturing and directing the fluids
and/or tissue in contact with the ISFET 250. Similary, the wall 231
of the opening 228 that surrounds the temperature sensor 260 is
also tapered/sloped to assist in capturing and directing the fluids
and/or tissue in contact with the temperature sensor 260.
[0161] A fluid tight seat is required around the ISFET 250 and the
temperature sensor 260 in order to prevent contamination or leakage
of fluids into the electronics of the probe 200. However, both the
ISFET 250 and the temperature sensor 260 need to remain exposed via
the openings 227, 228 in order to take accurate pH and temperature
measurements.
[0162] The hermetic seal of the opening 27 about the ISFET 250 can
be accomplished by various means, such as an epoxy, O-ring or
gasket seal. In the illustrated embodiment, a gasket 235 is
compressed between the bottom surface of the cover 205 and the
perimeter portion of the ISFET 250. The gasket 235 can be held in
place by the plastic cover 205 or could be over molded onto the
bottom surface of the cover 205.
[0163] The temperature sensor 260 preferably comprises a metal cap
261 that is placed over and covers a thermistor 262. The metal cap
261 can be constructed of a medical grade stainless steel or other
metal which is a good thermal conductor. A small space/gap exists
between the metal cap 261 and the thermistor 262. The space/gap, in
one embodiment, its approximately 0.005 inches. This space/gap is
filled with a material, such as an epoxy, having high thermal
conductivity but that is electrically non-conductive. Filling this
gap/space with such a material reduces the thermal time constant of
taking a temperature measurement. In the illustrated embodiment, a
surface mount thermistor is used. However, a typical bead
thermistor can also be utilized and adhered to the stainless steel
cap 262.
[0164] The metal cap 261 keeps the thermal time constant as low as
possible and should have as small an area as practical with a
thickness kept as thin as practical (0.10'' in this embodiment).
The temperature sensor 260 is used for measuring the temperature of
the vagina or cervix during the pH measurement. Although an
exemplary application of the temperature sensor 260 is detailed,
those skilled in the art will appreciate that an alternate
temperature sensing device can be used, such as a thermocouple or
infared detection. The temperature sensor 260 also provides
temperature information used during the manufacturing process and
calibration in order to allow for proper thermal compensation of
the pH reading.
[0165] As with the ISFET 250, it is necessary to create a fluid
tight seal about the opening 228 while leaving the metal cap 261
exposed to the biological fluid/tissue to be tested via the opening
228. The hermetic seal of the opening 228 about the metal cap 261
can be accomplished by various means, such as an epoxy, O-ring or
gasket seal. In the illustrated embodiment, a gasket 236 is
compressed between the bottom surface of the cover 205 and the top
surface of the metal cap 261. The gasket 236 can be held in place
by the cover 205 or could be over molded onto the bottom surface of
the cover 205. The gasket 236 is compressed the proper amount when
the plastic cover 205 is secured to the main housing portion
204.
[0166] The gaskets 235, 236 are sufficiently compressed when the
plastic cover 205 is secured to the main housing portion 204. The
cover 205 is permantly secured to the main housing portion 204 so
that the cutout 215 is hermetically scaled, thereby sealing the
distal portion of the upper chamber 221. The interface between the
cover 205 and the main housing portion 204 can be sealed by epoxy,
a sonic weld, a thermal weld or another compressed gasket.
[0167] The diaphragm 270 is positioned within and extends through
the opening 226 of the cover 205 and the opening/hole 219 in the
transverse wall 214 of the elongate housing 201. A first portion
271 of the diaphragm 270 is exposed to the biological fluid being
measured via the opening 226 while a second portion 272 of the
diaphragm 270 extends into the lower chamber 222 via the hole 219.
The second portion 272 of the diaphragm 270 is in contact with the
KCL solution 422 within the lower chamber 222 of the elongate
housing 201. The walls 237 of the opening 226 extend transversely
(relative to the longitudinal axis) and contact the transverse wall
214 so as to form a seat at the interface between the two, thereby
keeping the upper chamber 221 (and the circuit board 280)
hermetically sealed from fluids and contamination.
[0168] The diaphragm 270 can be either a ceramic or PTFE material
that is commonly used in pH probe assemblies. The diaphragm 270
allows the hydrogen ion flow between the reference electrode 421
and the KCL solution 422 and the measurement fluid. The diaphragm
270 provides the electrical connection between the reference
electrode 421 and the biological fluid being measured.
[0169] Referring now to FIGS. 10-11 concurrently, the assembly of
the probe 200 to the handle 300, which also operably couples the
measuring circuit 400 to the logic circuit 500, will be discussed
in greater detail. When the probe 200 is assembled to the handle
300, the proximal portion 210 (i.e. the coupling 206) of the probe
200 is inserted into the socket 519 of the handle housing 301 as
discussed above. The assembly of the probe 200 to the handle 300
results in the operable connection of the probe circuit 400 (FIG.
2) to the logic circuit 500 (FIG. 3) because the gold plated PCB
pads 417 of the printed circuit board 280 of the probe 200 come
into operable and electrical connection with the compression
connectors 517 of the printed circuit board 580 of the handle 300.
The gold plated PCB pads 417 are configured in a manner such that
the Ground signal pin, which is the return path for the supply
voltage provided by the housing 300, is slightly longer (about
0.020'') at the proximal 210 end than the other gold plated PCB
pads. The purpose of this extended pad is so the first electrical
connection made when inserting the probe 200 into the housing 300
is the ground pin. This first "make" connection helps in providing
a discharge path for any erroneous charges that may be residing in
the probe 200 or housing 300 assemblies. The other function of this
elongated pin is to provide the last connection when disengaging
the probe 200 from the housing 300 thereby keeping the ground
connection in place as the last signal to disengage or "break".
This type of configuration is commonly referred to as `make before
break` and helps prevent damage to the electrical components within
both the probe 200 and housing 300 assemblies due to electro-static
discharge or capacitive discharge when engaging and disengaging
these assemblies.
[0170] Referring now to FIGS. 12A and 12B, a protective cap 600 for
the distal portion 230 of the probe 200 is illustrated alone and
secured to the distal portion 230 of the probe 200. The cap 600 is
preferably constructed of an opaque material that is pliable. As
illustrated in FIG. 12A, the cap 600 is in an open position. In
FIG. 12B, the cap 600 is in the closed position and secured to the
probe 200 in the intended manner.
[0171] The cap 600 generally comprises a lid 610 and a base 620.
The lid 610 is pivotably connected to the base 620 via hinges 601
so as to be capable of rotation about axis B-B. A latch assembly
630, 631 is provided to lock the cap 600 in a closed position.
[0172] The lid 610 comprises a bottom surface 611 and a channel 615
formed into the bottom surface 611. The channel 615 has an open end
616 and a closed end 617. A first rim 618 protrudes the floor 619
of the channel 615 at the open end 616. A second rim 614 extends
along the perimeter of the lid 610 and protrudes outward from the
bottom surface 611.
[0173] Similarly, the base 620 comprises a top surface 621 and a
channel 625 formed into the top surface 621. The channel 625 has an
open end 626 and a closed end 627. A first rim 628 protrudes from
the floor 629 of the channel 625 at the open end 626. The base 620
further comprises a plurality of legs 640 for supporting the base
at a desired height.
[0174] When the lid 610 is rotated about axis B-B to the closed
position, the bottom surface 611 of the lid 610 comes into contact
with the top surface 621 of the base 620. As a result, the two
channels 615, 625 come together to collectively from an internal
cavity that is sized and shaped to accommodate the distal portion
230 of the probe 200. This internal cavity has an open end through
which the remaining length of the probe 200 can protrude (as shown
in FIG. 12B). The opposite end of the internal cavity is
closed.
[0175] When the cap 600 is in the closed position, the rim 614 of
the lid 610 becomes compressed between the lid 610 and the top
surface 621 of the base 20 so as to form a gasket seal between the
lid 610 and the base 620. Similarly, when the cap 600 is in the
closed position and the cap is secured to the probe 200 (as shown
in FIG. 12B), the rims 618, 628 come together to collectively form
an annular rim that acts as a gasket seal between the outer surface
of the probe 200 and the floors 619, 629 of the cap 600. The rims
614, 618, 628 are made of material that has a sufficiently low
durometer value so as to create the gasket type seals. The latch
assembly 630, 631 keeps these gasket seals in tact when locked. As
a result, when the cap 600 is closed and secured to the probe, the
distal portion 230 of the probe 200 (including the well 240) is
housed in the sealed internal cavity of the cap 600. Moreover,
because the cap is constructed of opaque material, this internal
cavity is substantially free of visible light (i.e., it is
dark).
[0176] The cap 600 serves multiple purposes in this particular
aspect of the invention. The primary function of the cap 600 is to
protect the ISFET 250 during storage. Scratching of the ISFET 250
can damage the ion sensitive membrane and effect operation. A
secondary function of the cap 600 is to create a hermetically
sealed internal storage cavity about the distal portion 230 of the
probe 200 (which includes the ISFET 250, temperature sensor 260 and
diaphragm 270) to keep the diaphragm 270 slightly hydrated between
uses. A drop of de-mineralized or distilled water can be placed in
the cap 600 once the probe 200 is laid in the channel 625 and then
sealed with the latch mechanism 330, 331.
[0177] The third function of the cap 600 is to act as a support
mechanism for the vaginal health apparatus 100 so that the sample
well 240 of the probe 200 is held level and not susceptible to
tipping during measurements. The legs 640 of the cap act as
supports to raise the tip of the probe 200 so that the longitudinal
axis A-A of the probe 200 is substantially horizontal when the
distal portion 230 of the probe 200 is resting within the channel
625. Thought of another way, because the bottom edge of the probe
200 is non-coplanar with the bottom surface 303 of the handle 300,
the probe 200 will have a tendency to tip/tilt. Thus, the height of
the legs 640 is selected so that when the distal portion 230 of the
probe 200 is resting within the channel 625, the bottom surfaces of
the legs 640 are substantially coplanar with the bottom surface 303
of the handle 300.
[0178] A fourth function of the cap 600 is to provide a cover for
the ISFET 250 during the sample well measurement and/or during
calibration. The ISFET 250 is a semiconductor device and as such,
is susceptible to UV light. Various manufacturers of ISFET's have
different levels of sensitivity and generally measurement isn't
affected greatly unless directly exposed to sunlight or high
intensity lighting. However by placing the biological fluid to be
measured in the well 240 and securing the cap 600 to the probe 200,
the measurement will always be taken in a dark environment which
would reduce the potential effects of UV light impacting the
reading. This "dark" environment more accurately simulates the
condition within the vaginal canal and cervix or of the environment
of the fluid within the body.
[0179] Referring now to FIG. 13A, the insertion of the probe 200
into the vaginal cavity is illustrated for measuring pH within the
vagina. When inserted, the well 240 makes contact with the vaginal
wall 10. The vaginal walls 10 make contact with each other and
separate as the probe 200 is inserted. The vaginal wall 10 is
coated with mucus membrane with a muscular tissue underneath which
then forms around the probe 200 and into the well 240. The well 240
allows for the collection of the mucus fluids from the vaginal wall
10. The well 240 of the probe 200 is typically placed in the lower
portion of the vaginal canal (approximately 1 to 2 inches). Upon
the user selecting the measurement function via the user controls
340-342, the pH will be measured by the ISFET 250 and the user will
be notified with at audio tone at completion of the measurement.
The measured pH will be shown on the LCD screen 330 and saved
within the memory device within the handle 300 (which is
incorporated into the processor 510, but may be a separate device).
This stored data is stored alone with a date and time stamp so that
the data can be retrieved, analyzed and compared to later
measurements according to known algorithms or relationships to
determine a physiological condition in a mammal, such as fertility
status.
[0180] FIG. 13B shows the placement of the probe 2010 further up
the vaginal cavity and making contact with the ectocervix area of
the cervix. The well 240 makes contact with the ectocervix and
collects cervical fluid for measurement. As stated earlier, the
measurement of the cervical pH can be a useful aid in determining
the fertility cycle of the female mammal. The probe 200 would
typically be inserted about 4 to 5 inches in the vaginal canal in
order to make contact with the cervix. The device as shown provides
a simple and reliable method of measuring the cervical fluid to
determine a condition, such as fertility status.
[0181] FIG. 14 is a graph of a 6 day plot of in-vivo vaginal pH
measurement using the above described invention. The data was
gathered from a human female approximately age 55 and in good
health. The woman was post menopausal and used the device daily for
a period of 6 days. Readings were sampled every 10 seconds over a
20 second period and recorded. Data was transferred from the device
100 through the RS232 serial port 314 and ported into an Excel
spreadsheet. The data displayed represents the pH recorded during
the test period. It shows stable readings after a short initial
settling time. The final values over the 120 second measurement
period were stable and within a range of 4.41 to 5.04 over the 6
day period. No special handling or calibration was performed during
the 6 day usage other than simple cleaning with warm water.
Periodic calibration with pH7 buffer utilizing a few drops in the
sample well after extended periods of non-use is recommended to
guarantee the accuracy of measurements. If the apparatus 100 were
not used for an extended period of time, the logic unit 510 would
notify the user to proceed with a simple calibration procedure
before taking the vaginal measurement.
[0182] An additional test was performed to compare pH buffer
measurements based on sample size. FIG. 15 is a graph of the pH
voltage measured from the apparatus 100 when the probe 200 was
inserted into 25 ml of buffer solution and then compared against
0.3 cc./ml of solution placed into the sample well 240. The device
100 was allowed to stabilize for 5 minutes before measurements were
recorded and cleaned in water and dried between measurements. A
syringe was used to insure constant amount of solution was placed
into the sample well 240. As the data shows, there is no
significant difference in the measurement taken in the sample well
240 vs. the 25 ml solution. The readings are typically within 1 mv
which converts to a pH variance of about 0.02 pH. The data proves
that the sample well 240 is of appropriate size to accurately
measure small samples of solutions. It should be noted that in this
implementation of the invention about 40% of the sample well area
was occupied by the thermistor and therefore it is likely that the
results would be similar with <0.2 cc/ml of solution as that is
all that was required to submerse the ISFET 250 and the diaphragm
270 required for the pH measurement.
[0183] As the results above for the sample size comparisons
indicate, that there is no significant difference in the sample
size test results. Therefore a test was performed to measure urine
in the sample well. The device 100 was calibrated with pH buffer in
the sample well 240 prior to the start of the test. FIG. 16 shows
the results of this 4 day test. Sampling was done twice daily, once
in the early morning as soon as wakening and again in later
afternoon prior to a meal. No calibration was done during the
period however an additional test was preformed on day 3 using pH7
buffer solution in place of urine. This test was done to verify the
continued accuracy of the measurements since calibration was not
preformed between urine measurements. The data shows the device 100
was still accurate within 0.05 pH after 4 days of use w/o any daily
calibration required. The probe 200 was cleaned with warm water and
lightly patted dry with no special storage of the probe 200 between
uses. The data shown was sampled every 10 seconds over a 10 minute
(600 second) period and recorded in the memory of the logic circuit
500. Data was transferred from the RS232 serial port 314 and
imported into an Excel spreadsheet for plotting. The test subject
was a 55 year old male in good health. Samples in the morning and
late afternoon in a small paper cup with 5 drops transferred into
the sample well. The pm samples were taken 5 hours after a mid-day
meal while the am sample were taken early in the morning before any
meals and at least 10 hours after the last meal. The data shows
stable readings throughout the measurement period.
[0184] FIG. 17 shows a plot of the final readings after the 10
minute period and shows the trend line after 4 days. Diet was not
recorded during the test period to see if this had contributed to
the positive trend line. It would be simple to duplicate this
process over a larger test subject sample and monitor diet to
determine the effect of diet on urine pH.
[0185] The invention accurately measures small volumes of other
mammalian fluids. Besides the example of urine testing explained in
the text above, examples of other fluids would be saliva or blood.
By utilizing the sample well 240, the device 100 can easily be used
to monitor urine pH. A small sample of about 0.3 cc (4 or 5 drops)
of urine placed in the sample well will generate an accurate urine
pH reading. By utilizing the automatic recording function on the
device 100, these readings can be automatically stored and
monitored so that the user can be notified if any significant
changes have occurred over a period of time.
[0186] As mentioned above, the device 100 can be inserted further
into the vagina and make contact with the ectocervix area of the
cervix. Monitoring of pH of the cervix can be helpful criteria in
determining the fertility cycle of the female. The design of the
device is such that it also monitors vaginal or cervical
temperature to monitor basil body temperature (BBT). It is a well
know fact that BBT changes as much as 1.degree. F. during the
ovulation cycle and can be used as another indicator of the
fertility cycle. The ability of the device 100 to store both the pH
and temperature readings over an extended period of time allow the
device and software to create a profile of the female mammals
menstrual cycle. The ability of the device to transfer this data to
a computer can be a valuable aid in analyzing and predicting the
ovulation period for women with difficulty in conception.
[0187] The device 100 also monitors the vaginal pH which can be a
useful tool in the monitoring of Estrogen or Hormone Replacement
Therapy (HRT). Women during or post menopause can have elevated
levels of vaginal pH without having symptoms of BV. The device 100
can easily store the vaginal pH readings prior to and during the
HRT in order to assist in the effectiveness and regulation of
Estrogen replacement therapy.
[0188] The inventive apparatus 100 is capable of measuring pH with
an accuracy of 0.1 pH or better and can record measured pH values
for future reference. The device 100 has the capability of
recording multiple readings of pH values, date and time of the
measurement and logging of these readings so that automatic user
notification can be made should an unusual change in pH value
oecur. The amount of readings stored is strictly dependant on the
size of memory within the logic unit. It would be easy and
inexpensive to store hundreds of readings so that long term
monitoring is possible. This method of monitoring recording and
notification takes the guess work out of matching colors or keeping
a written log of periodic readings. Reviewing this data and
automatically detecting a noticeable chance can provide instant
feedback to the user that further testing or diagnostic procedures
may be required especially if other BV symptoms occur.
[0189] The following outlines the typical measurement process when
utilizing the device 100 to measure pH and/or temperature within
the vagina to determine fertility and vaginal health status. The
user (or other personnel) will first insert the probe 200 of the
device 100 into the vagina at a desired depth and alignment. If the
user desires to determine fertility status by measuring cervical pH
and temperature, the user will insert the probe 200 into the vagina
until the distal portion 230 of the probe 200 is adjacent and in
contact with the ectocervix area of the user. Preferably, the probe
200 is inserted so that the well 240 is aligned with the ectocervix
tissue and the diaphragm 270, pH sensor 250 and temperature sensor
260 are aligned with and in contact with the ectocervix tissue. If
the user desires to determine vaginal health status (such as the
existence of BV or any of the other condition discussed above) by
measuring vaginal pH and temperature, the user will insert the
probe 200 into the vagina until the distal portion 230 (including
the well 240) of the probe 200 is adjacent and in contact with the
vaginal wall of the user.
[0190] Once the probe 200 is in the desired position within the
vagina, the user will initiate the measurement process pressing the
appropriate control button(s) 340, 341 and/or 342 on the handle
300. When the firmware within the microprocessor 510 (which is
located in the logic unit. i.e., the handle housing 301.) detects
the control button depression (by receiving a measurement
initiation signal) it will check to make sure that the probe 200 is
electrically connected to the handle 300 through the interface
connectors 417 and 517. If connected, the microprocessor 510 will
then proceed to apply power from the battery 520 to the circuit 400
of the probe 200 through these interface connectors 417, 517 in
order to read the contents of the VPD memory 415. The power supply
from the battery 520 also enables (i.e., provides sufficient power
to) the pH and temperature sensors 250, 260 and the remaining
components of the circuitry 400. The processor 510 will verify that
this is a proper probe assembly and that the contents of the VPD
memory 415 are valid. If the firmware determines that the probe 200
has not been calibrated for an extended period of time based on the
contents of the VPD memory 415 it will indicate to the user through
the LCD that the simple single point pH7 calibration process
utilizing the sample well 240 is required. As discussed above, the
calibration process is preferably performed in the removable cap
600 in a dark environment with a solution buffered at a known
pH.
[0191] Once the microprocessor 510 detects that the device 100 is
ready to take measurements, the user activates the user control
340-342 that sends a "take measurement signal" to the
microprocessor 510. In response, microprocessor 510 initiates the
pH and temperature sensors 250, 260. The pH and temperature sensors
250, 260 then generate an analog pH signal and an analog
temperature signal indicative of the measured pH and temperature
within the vagina or at the ectocervix. These analog pH and
temperature signals from the probe 200 are then transmitted to and
processed through the analog to digital (A/D) converter 502. Once
the calibration or measurement cycle has started, the
microprocessor firmware 510 will determine when these A/D signals
are stable and then proceed to retrieve and use parametric data
(including the slope data) from the VPD memory 415 to calculate the
pH value. To determine the pH value, the firmware on the
microprocessor 510 will read the current measured temperature and
utilize the slope data for the ambient 25C. temp and the normal
body 98.6 temp to determine any pH correction factor that may be
required at the current temperature. Once this calculation is
complete, an output signal will be generated by the microprocessor
510 that corresponds to the correct pH and temperature values, the
output signal is sent to the LCD 330 for viewing. This pH and
temperature information along with the date/time stamp from the
real-time clock (RTC) will also be stored in the local memory
located (incorporated into the microprocessor 510) within the
handle 300.
[0192] The microprocessor 510 will then proceed to update the
appropriate fields within the VPD memory 415 to indicate that a
measurement was taken along with the date/time stamp of that
measurement. This stored VPD information is then used for the next
measurement cycle to determine how long since the probe 200 has
been used and/or how many measurements have been taken with this
particular probe.
[0193] As mentioned above, when utilizing the device to monitor
vaginal health, the device 100 will be used to take pH and
temperature measurements at the lower portion of the vaginal wall
as indicated FIG. 3A. A similar process of verification and
measurement as outlined above will occur for the vaginal fluid
captured in the sample well. These vaginal pH and temperature
measurements would most likely be taken when an instance of
infection like BV, Candidiasis (yeast infection) or Trichomoniasis
is suspected. These pH readings are important criteria for
diagnosing any of these infections. Continued measurements can be
taken after any diagnosis to determine the effectiveness of an OTC
or prescribed treatment. The device 100 will also save these
readings which can be downloaded for analysis. Vaginal measurements
need not only be taken when an instance of infection is suspected.
Normal periodic measurements can he taken and tracked by the
processing unit to notify the user if any significant changes or
trends have been detected over an extended period of time. This
could be particularly useful for women entering menopause as
vaginal pH generally rises due to the decreased amount of estrogen
being produced. The firmware can detect these trends and notify the
user via the LCD 330 that a noticeable change has occurred and that
a visit with a physician may be required.
[0194] As also mentioned above, when using the device to monitor
fertility status, the device 100 will be used to take the pH and
temperature measurements at the ectocervix area. For monitoring
fertility a daily measurement cycle will be taken for at least one
but preferably several female mammal fertility cycles. In the human
female, this cycle is typically 28 days. The fertility cycle for a
typical women is generally during a 3 day window on days 11-14 of
the 28 day cycle. However in women who are having a difficult time
conceiving, this could be very narrow window (i.e. a window of just
hours) or this window could be skewed from the normal cycle (i.e.
days 17-18). In the case of a very narrow window multiple readings
may need to be taken with in a short period of time to provide
optimal timing. After enough data has been stored in the memory
within the handle 300, the firmware can then analyze the stored pH
temperature and date/time stamp to determine the ovulation profile
of the user. Any new data then measured can be compared against
this profile to determine that an ovulation cycle is eminent or
present. The data from the logic unit memory could be displayed as
an output signal as a graphical indicia on the LCD 330 to show the
ovulation cycle. If a segmented LCD display 330 is used, a simple
indication that ovulation is imminent or in process would be
displayed. This could be a flashing display or an ovulation icon.
The stored data can also be downloaded to an external device like a
PC. This download function is accomplished by the user selecting
the proper control button 340, 341 and 342 functions to initiate
this data transfer through external data ports 314 or 315.
[0195] Although an exemplary embodiment of the invention has been
described in detail above, those skilled in the art will readily
appreciate that the embodiment may be modified without departing
from the novel advantages of the invention. The invention is not
limited to the embodiments disclosed, but it is intended to cover
modifications within the spirit and scope of the present invention
as defined by the following claims.
* * * * *