RU2241375C1 - Method for detecting ovulation period and device for its implementation - Google Patents

Abstract

FIELD: medicine, veterinary science, obstetrics, gynecology.

SUBSTANCE: the present innovation deals with predicting physiological state of female reproductive system, planning the pregnancy or performing the ways to avoid undesirable pregnancy and it, also, could be applied in the field of animal science to detect ovulation period in animals. The latter deals with obtaining the contact of mucosal secreta and electrodes of a sensing device followed by measuring the polar conductivity of mucosal secreta during menstrual cycle that enables to determine blood concentration of a hormone and detect ovulation period by a maximum value of polar conductivity. Measurement of polar conductivity of mucosal secreta should be carried out in impulse mode. The suggested device has got a sensing device with electrodes, scheme for signal processing including a block to isolate useful signal and that of to transform useful signal into a digital code, digital indicator and supply unit. Block for isolation of useful signal contains a loading resistor, two repeaters and a condenser. Electrodes are designed to be out of chemically homogeneous material and of equal area.

EFFECT: higher reliability and accuracy of detection.

2 cl, 3 dwg

Description

The invention relates to the field of medicine and veterinary medicine, and in particular to obstetrics and gynecology, and can be used in the process of diagnosing the physiological state of the female reproductive system, planning pregnancy or taking measures to protect against unwanted pregnancy. It can be widely used in animal husbandry in determining the period of ovulation in animals.

At present, gynecological science and practice have a wide arsenal of methods for determining the period of ovulation and the means that implement them, based on various principles that underlie their functioning. Two areas that are actively developing can be distinguished: ultrasound diagnostics and hormonal monitoring.

A known method for the diagnosis of ovulation, which consists in measuring the velocity of shear waves in biological tissues by the travel time of the leading edge of the wave pulse between the receiving and radiating, bending piezoelectric transducers. Alternately, a sensor is applied to the nipple of the right and then the left mammary gland, the propagation time of the transverse shear wave in the nipple tissues is recorded, and the day and side of the localization of ovulation are established by the maximum value (USSR author's certificate No. 1378812, IPC 6 A 61 V 5/05, 1984) .

There is a method of diagnosing a woman’s biological readiness for childbirth, which consists in measuring the shear wave propagation velocity in the skin of the nipples of the mammary glands, conducting pulsating vacuum stimulation of each nipple of the mammary gland using a decompression chamber simulating the lips and mouth of the infant, and repeated measurement of the shear wave propagation velocity the skin of the right and left nipples and with a decrease in the shear wave propagation velocity by 3 m / s or more, biological readiness for childbirth is diagnosed (author USSR Orsk Certificate No. 1380726, IPC 6 A 61 B 5/05, 1985).

There is also a method for determining ovulation by ultrasound, during which the pulse index of the uterine artery is recorded on the vaginal dopplerogram, and the approximation of ovulation is determined by the dynamics of the magnitude of the recorded indicator (RF patent No. 20133989, IPC 6 A 61 B 5/00, 1991).

However, the known methods of acoustic diagnostics do not allow to obtain accurate predictive data on the onset of ovulation, and they can only be considered as express methods.

More accurate and complete diagnostic data on the onset of ovulation is obtained using hormonal methods for determining ovulation.

There is a hormonal method for determining the period of ovulation, which consists in bringing the sensor electrodes into contact with the mucous secretions of the body, which are used as saliva or cervical mucus, and during the menstrual cycle measuring the difference in redox potentials between the electrodes made of materials that are heterogeneous in chemical composition, and determination of the ovulation period by the maximum value of the measured parameter (RF patent No. 2128943, IPC 6 A 61 B 5/05, 1999).

This method, compared with the above-mentioned acoustic diagnostic methods, can significantly increase the accuracy of the determined ovulation period, however, its implementation requires stationary conditions and appropriate instrumentation.

Closest to the claimed invention in terms of the method according to the technical essence and the result achieved using the method is a method for determining the ovulation period, including contacting the sensor electrodes with mucous secretions and subsequent measurement during the menstrual cycle of the polar conductivity of the mucous secretions in an inhomogeneous electric field, which allows indirectly determining the concentration of luteinizing hormone in the blood, and according to the obtained maximum value of the polar conductivity fissioning ovulation (RF patent №2180443, IPC 6 A 61 B 5/05, A 61 B 10/00, 2001).

In the known method, for the most part, the disadvantages characteristic of the above technical solutions representing the prior art have been eliminated, which has increased the accuracy of determining the ovulation period to several hours. It is known that this method is based on a change in the potassium-sodium balance towards potassium, the concentration of which in the mucous secretions of the body increases by at least an order of magnitude as the onset of ovulation. This changes the fine structure of the amino acids of the protein of the mucous secretions, which is fixed by a change in the polar conductivity of the mucous secretions. The magnitude of the polar conductivity is not constant and varies with time, i.e. it is a random variable. The uncertainty of the moment of determining the conductivity in the mucous secretions in each act of measurement is one of the significant disadvantages of the known method. In addition, prolonged exposure to an electric field leads to significant changes in the fine structure of amino acids of the protein of mucous secretions, and the measured conductivity in this case does not carry information about the state of the fine structure of the protein, which ultimately introduces a certain error in the reliability of the measured parameter.

A device for determining the period of ovulation, containing a sensor with two electrodes made of various metals, is connected to a measuring device. During the operation of the device, electrical parameters are measured, depending only on the oxidizing or reducing properties of the vaginal discharge, which determine the beginning of the ovulation period (patent RF 2230328, IPC A 61 B 10/00, 1974). Using information only on the redox properties of vaginal discharge causes insufficient accuracy in determining the beginning of the ovulation period.

A device is also known for determining the ovulation period, including electrodes fixed in a dielectric holder, made of materials of dissimilar chemical composition and connected to a potentiometric circuit containing a comparator, one of the inputs of which is connected to the said electrodes, and the output to the input of the indicator device, the second input of the comparator is connected to the trigger threshold connected to a stable voltage source (RF patent No. 2128943, IPC 6 A 61 V 5/05, 1999). Due to the fact that the difference of redox potentials is used to determine the period of ovulation, the accuracy of determining the desired parameter increases. However, the reliability of the determination of the desired parameter is insufficient.

Closest to the claimed invention in terms of the device in terms of technical nature and the result achieved using the device is a device for determining the ovulation period, including a sensor with electrodes having different contact surface areas for forming an inhomogeneous electric field between the electrodes, a signal processing circuit containing a block the selection of the useful signal and the conversion unit of the useful signal, while the indicator is made in the form of a digital display (RF patent No. 2195863, IPC 6 A 61 B 5/05, A 61 B 10/00, 2001).

The known device has eliminated mainly the disadvantages inherent in similar technical solutions characterizing the prior art, and to improve the accuracy of determining the beginning of the ovulation period. However, as mentioned above, the polar conductivity is a function of time and its value is informative to the state of the fine structure of the protein only a very short time. Long-term exposure to the electric field leads to significant changes in the fine structure of amino acids of the protein of the mucous secretions. The beginning of the process of measuring the conductivity of mucous secretions in time in each act of measurement is uncertain. Therefore, the obtained value of the polar conductivity is a random variable, because the conductivity of mucous secretions, as noted above, is a function of time. Thus, a comparison of random values of the conductivity of mucous secretions introduces a significant error in the reliability of the measured parameter - the ovulation period.

The task underlying the claimed invention is to create a method for determining the period of ovulation and a device for its implementation, free from the disadvantages inherent in technical solutions representing the prior art, by expanding the use of the information base of the processes occurring in the diagnosed organisms.

The technical result achieved by the implementation of the claimed invention is to create a technical solution with higher reliability and accuracy (up to several hours) of determining the beginning of the ovulation period.

The task underlying the claimed invention, with the achievement of the above technical result, is solved in part of the method due to the fact that in the known method for determining the period of ovulation, including bringing into contact of the mucous secretions with the sensor electrodes and subsequent measurement during the menstrual cycle of the polar conductivity of the mucous secretions , which allows you to indirectly determine the concentration of the hormone in the blood and by the obtained maximum value of the polar conductivity to determine the period of ovulation, measured polar conductivity of mucous secretions in each act measurement is performed in pulsed mode in a nonuniform electric field formed between the electrodes of the sensor immediately after applying voltage to the electrodes of said sensor.

The task underlying the claimed invention, with the achievement of the aforementioned technical result, is solved in part of the device due to the fact that in the known device for determining the ovulation period, containing a sensor with electrodes having different contact surfaces that form an inhomogeneous electric field, a signal processing circuit including a useful signal extraction unit and a useful signal to digital conversion unit, the output of which is connected to an input of a digital indicator, and the power supply connected to the said elements of the device, the useful signal extraction unit contains a load resistor connected in series with the sensor, two repeaters, one of which is a detecting one, is connected to the sensor electrodes and the mentioned resistor, and the output of the follower is connected to a capacitor storing the voltage value at a resistor, and with the input of the second repeater, the output of which is connected to the input of the unit for converting the useful signal into a digital code, while the said sensor electrodes are made of imicheski homogeneous material.

The invention is illustrated in graphic material, where in Fig.1 shows a schematic diagram of a device; figure 2 shows the dependence of the change in voltage drop across the load resistance from time to time; figure 3 presents the main phases of follicular development, the concentration of estradiol 17β in the blood, the concentration of total protein lysozyme in the vaginal mucus and the readings of the device during the “hunting” period.

As noted above, the effect on the potassium-sodium balance of the body of its hormonal background and the use of the concentration of luteinizing hormone in the blood to determine the period of ovulation are known. As a result of the studies conducted by the authors, it was found that, under the influence of an electric field, the fine structure of the amino acid protein is rapidly destroyed and the measured conductivity in this case no longer carries information about the real state of the fine structure of the protein. In this regard, it is proposed that the conductivity measurement be performed in a pulsed mode, which makes it possible to fix the value of the polar conductivity at the time of the appearance of an inhomogeneous electric field in the sensor. Those. in each act of measuring the magnitude of the polar conductivity of mucous secretions, the beginning of the measurement of conductivity is strictly determined in time and corresponds to the moment of voltage supply to the sensor electrodes. This made it possible to measure the maximum value of the conductivity of mucous secretions at the maximum concentration of lutenizing hormone in the blood.

The method for determining the period of ovulation in accordance with the present invention is implemented as follows. On the surface of the electrodes of the sensor 1, creating an inhomogeneous electric field in the mucous secretions, are deposited to create an electric field in the entire volume of the investigated medium. When voltage is applied to the sensor electrodes in the mucous secretions, an inhomogeneous electric field arises, under the influence of which the translational motion of multidimensional organic chains and their partial “turn” occurs. Thus, it is possible to imagine the effect of an inhomogeneous electric field on the fine structure of the amino acid protein, resulting in the polar conductivity of mucous secretions. It should be noted that there are ions in the mucous secretions. When the voltage at the electrodes of sensor 1 increases pulse, the ionic conductivity at the initial moment is greater than the polar, which is undesirable, because there is no clearly expressed maximum value of conductivity. Therefore, the voltage at the electrodes of sensor 1 increases from 0 to 3 V in 10-15 μs. In this case, ionic conductivity is the background of polar conductivity.

In accordance with the Dannon equilibrium, with an increase in the concentration of K ions, the fine structure of the amino acid protein becomes “shorter”, their inertia is less, and their mobility is higher. Subsequently, under the influence of the field in the mucous secretions, a dynamic equilibrium occurs with the predominance of ionic conductivity.

The method in accordance with the present invention is implemented by a device, a functional diagram of which is shown in figure 1.

The device consists of a sensor 1 with electrodes, load resistance 2, two repeaters 3 and 4, one of which is a repeater 3 - is a detecting capacitor 5, a unit for converting the useful signal into digital code 6, a liquid crystal digital indicator 7, a power supply 8, a battery 9, a network adapter 10. The device is powered by its own batteries 9 with the possibility of recharging from a network of 220 V. The charge of the batteries ensures intensive operation of the device for several days. An external power adapter 10 (220 V-9 V converter) is used to recharge the batteries. The power supply 8 provides the necessary power to all units of the device and the battery charge mode when connecting an external network adapter 10.

The device operates as follows. A sample of the mucous secretions taken from the test mammal is applied with the condition that the sensor surface is completely filled. In the event that it is difficult to take a sufficient amount of mucous secretions from individuals or they are too thick, the porous material used for sampling is pre-moistened with physiological saline and, after sampling, the contents of the porous material are squeezed onto the surface of the sensor.

Sensor 1, when connected to a power source 8, creates an inhomogeneous electric field in the mucous secretions deposited on the surface of the sensor electrodes. For this, the electrodes of the sensor 1 are made of chemically homogeneous material, but with different contact surfaces, between which an inhomogeneous electric field is formed.

After the voltage from the power source to the electrodes of the sensor 1, the potential at point a of the circuit is equal to the voltage drop across the resistor 2. The time dependence of the voltage (potential) at point a (Ua) is shown in FIG. 2. The voltage Ua through the buffer stage (detecting follower 3) is supplied to the capacitor 5, which is charged to the value of Ua. The resistances of the input of the buffer cascade (repeater 4) and the output of the buffer cascade (detecting repeater 3) are so great that they allow you to keep the potential on the capacitor 5 unchanged for a long time. During this time, the operator records the readings of the liquid crystal indicator 7, the input of which receives a signal from the analog-to-digital converter 6, which continuously processes the signal from the output of the repeater 4. Thus, a measurement is made proportional to the maximum polar conductivity in this measurement event.

The invention was tested in several regions of the Russian Federation. So at the Starozhilovsk stud in accordance with the present invention were covered with 240 mares. At the same time, blood samples for estradiol 17β were taken from these mares. The main results of the experiment are shown in FIG. 3, where FIG. 3A shows conditionally the main phases of follicular development, FIG. 3B shows the concentration of 17β in estradiol in the blood, FIG. 3C shows the concentration of total protein and lysozyme in the vaginal mucus, FIG. 3D - readings during follicular maturation. As follows from the results obtained, the maximum change in the conductivity in the mucous secretions corresponds to the maximum concentration of estradiol 17β in the blood. Therefore, a more accurate determination of the achievement of this moment by measuring the magnitude of the polar conductivity at a strictly defined time has significantly improved the accuracy of determining the period of ovulation. Ultimately, obtaining more accurate information about the onset of the ovulation period will allow it to be used more effectively in all areas of application of the present invention.

Claims (2)

1. A method for determining the ovulation period, including bringing into contact of the mucous secretions with the sensor electrodes and subsequent measurement during the menstrual cycle of the polar conductivity of the mucous secretions, which allows you to indirectly determine the concentration of the hormone in the blood, and the ovulation period, which differs by that the measurement of the polar conductivity of mucous secretions in each act of measurement is carried out in a pulsed mode, in an inhomogeneous electric field, formed between the electrodes of the sensor at the time of supplying voltage to the electrodes of the sensor. 2. A device for determining the ovulation period, comprising a sensor with electrodes having different contact surface areas forming an inhomogeneous electric field, a signal processing circuit including a useful signal extraction unit and a useful signal to digital conversion unit, the output of which is connected to the input digital indicator, and a power source connected to the above-mentioned elements of the device, characterized in that the useful signal extraction unit contains a load resistor included second in series with the sensor, two repeaters, the input of one of which is connected to the sensor electrodes and the aforementioned resistor, and the output is connected to the input of the second repeater, the output of which is connected to the input of the unit for converting the useful signal into a digital code, while the sensor electrodes are made of chemically uniform material.

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