JPH0787841B2 - Mammalian insemination time detection device - Google Patents

Description

Detailed Description of the Invention [Industrial applications]

The present invention relates to a fertilization appropriate period detection device for mammals including humans.

[Prior art]

Conventionally, for example, JP-A-60-188142-188148, JP-A-60-
190942-190944, JP-A-60-220052, JP-A-60-22774
6, JP-A-61-90651 to 90655, JP-A-61-137543 to 13754
5, as disclosed in JP-A-61-137554 and JP-A-61-217157, based on the equivalent DC resistance value of the vaginal wall of the mammal, to detect the ovulation time or the optimal fertilization period of the mammal A device for doing so has been proposed. These detect the sodium ion concentration in the vaginal wall from the equivalent DC resistance value that is inversely proportional to this. By the way, the ovulation prediction detection device or the fertilization appropriate period detection device of each of the above items is based on the empirical fact that the equivalent DC resistance value of the vaginal wall immediately before ovulation becomes maximum, and the maximum value and the minimum value of the equivalent DC resistance value The space is divided into a plurality of parts, and the lamps are turned on in correspondence with the respective divided sections. That is, for example, in the case of pigs, in the case of refrigerated or raw sperm, it is injected into the uterus 5 to 7 hours before ovulation, and in the case of frozen sperm, it is injected into the uterus 2 hours before ovulation. It is known that fertilization and conception rates are highest. Therefore, the detected equivalent DC resistance value of the vaginal wall is 7
Ideally, it is possible to light the corresponding lamp when it corresponds to the equivalent DC resistance value of 5 hours ago or 2 hours ago. However, conventionally, both the maximum value of the equivalent DC resistance value of the vaginal wall immediately before ovulation and the minimum value of the non-ovulation period have been unknown. Therefore, in the ovulation prediction detection device or the fertilization appropriate period detection device, the lamp for displaying the sperm injection timing,
It did not necessarily display the exact timing. Therefore, even if artificial insemination was performed in a state where it was judged by the ovulation prediction detection device or the insemination appropriate period detection device that insemination was the optimum time, the success rate was not 100%. Further, for example, even when it is desired to use an insemination suitable period display device for a human body for the purpose of contraception, the minimum equivalent direct current resistance value of the vaginal wall, that is, the zero-point setting standard is unclear, so it cannot be used. On the other hand, the present inventor, by the patent application of PCT / JP87 / 01011, the sodium ion concentration in the vaginal mucosa of mammals becomes the minimum at the ovulation time, and this is approximately equal to the sodium ion concentration of water. The maximum value of sodium ion concentration during the non-ovulation period is
Based on the finding that the concentration of sodium ions in the blood of the mammal is approximately the same, a device for detecting the optimal fertilization period for the mammal was proposed. This proposal also assumed that the sodium ion concentration was inversely proportional to the equivalent DC resistance of the vaginal mucosa, but it was based on the discovery that it was inversely proportional to the equivalent impedance value of the vaginal mucosa. is there.

[Problems to be Solved by the Invention]

By the way, the water in the above proposal is actually the tap water of Hamamatsu City, Shizuoka Prefecture, Japan, but the sodium ion concentration in this tap water varies slightly depending on the season or one day. Although there are few variations in the measurement results due to this variation, it is needless to say that more accurate results are desirable. This invention provides a mammal fertility optimal period detection device capable of accurately setting the minimum value of sodium ion concentration in the vaginal mucosa of a mammal, and accurately determining the fertilization optimal period or infertility period of the mammal. The purpose is to provide.

[Means for Solving the Problems]

This invention is based on the inventors' subsequent trial and error finding that the minimum value of sodium ion concentration in the vaginal mucosa of a mammal is equal to that of saliva of the mammal. It is based. This invention, a detection unit that can be inserted into the vagina of a mammal,
A plurality of electrodes of the detection unit, which are arranged at positions where they can come into contact with the vaginal mucosa, voltage generating means for applying a voltage between the plurality of electrodes, and impedance detection for detecting an impedance value between the electrodes. A means for detecting sodium ion concentration in the vaginal mucosa of a mammal, including a device, and the maximum value immediately before ovulation when the equivalent impedance value of the vaginal mucosa is substantially equal to the equivalent impedance value in the saliva of the mammal, and As the minimum value during non-ovulation when the equivalent impedance value of the vaginal mucosa is substantially equal to the equivalent impedance value in mammalian blood, the equivalent impedance value of the vaginal mucosa detected by the impedance detection device is based on the maximum value. If it is equal to this, it is determined that it corresponds to the proper period of sperm injection before ovulation,
In addition to displaying this, when it becomes equal to this based on the minimum value, it is determined that it corresponds to the infertile period at the time of non-ovulation, and display means for displaying this, and a mammal characterized by the above-mentioned. By the insemination suitable period detection device of
The above object is achieved.

[Action]

In the present invention, the display means for displaying the optimal insemination period is based on the fact that the sodium ion concentration in the vaginal mucosa becomes substantially equal to the sodium ion concentration in saliva immediately before ovulation, and the detected sodium ion concentration is substantially equal to saliva. We capture the time as the minimum value immediately before ovulation, and based on this minimum value, the appropriate sperm injection period before ovulation is displayed.
It is possible to detect more accurately from the ovulation time and the appropriate fertilization period based on this.

【Example】

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In this embodiment, as shown in the figure, a rod-shaped detection part 12 that can be inserted into the vagina of a mammal, and a tip part 12A of this detection part 12 is arranged at a position where it can contact the vaginal mucosa of the mammal. A pair of electrodes 14 and the pair of electrodes 14,
Sodium ion concentration detecting means 10 including a voltage generating means 16 for applying a voltage between 14 and a level determining device 18 for detecting an impedance value between the electrodes 14, 14, and the vaginal mucosa When the equivalent impedance value of is substantially equal to the equivalent impedance value of saliva of the mammal as the maximum value immediately before ovulation, and the equivalent impedance value of the vaginal mucosa is substantially equal to the equivalent impedance value in the blood of the target mammal. As the minimum value, the maximum value, the minimum value, and the maximum and minimum values as a reference, and the display means 20 adapted to display the proper period of sperm injection before ovulation and the infertile period during non-ovulation. This is a device for detecting an appropriate period for fertilization of animals. The voltage generator 16 includes an AC generator 22 and a booster 24.
And a voltage comparison device 26. The AC generator 22 is an astable multivibrator 22A.
And a positive / negative pulse amplifier 22B. The astable multivibrator 22A is mainly composed of transistors TR1 and TR2, resistors R1 to R4, capacitors C1 and C2, and the positive and negative pulse amplifier 22B is output by the astable multivibrator 22A. Transistors TR3 to TR7 and resistors R5 to R16 are provided to amplify the pulse. The booster device 24 includes an inverter circuit for boosting the power supply voltage supplied from the power supply battery 28 to a required voltage, is provided with amplification transistors TR8 and TR9, and supplies power from the power supply battery 28. Voltage to the transistor TR
Capacitor for applying boost to 8 and TR9
C4 to C7, resistors R25 to R27, coils L1 and L2, diode D2,
And zener diodes ZD1 and ZD2. The positive electrodes of the diode D2 and the zener diode ZD1 are connected to the resistor R10 of the AC generator 22 and the resistor R17 of the level determination device 30 so that a boosted voltage is input and a current flows. The level determination device 18 includes an impedance equivalent circuit 18 of the detected part (vaginal mucosa) due to the alternating current applied to the electrodes 14, 14.
A plurality of voltage comparators for detecting the impedance level of A are provided, and the display means 20 is a level determination device 18
The levels determined in step 1 are displayed on the light emitting diodes DP1 to DP5 according to the respective levels. More specifically, the level determination device 18 is input from the booster device 24 to determine the impedance level of the impedance equivalent circuit 18A from the voltage signal output from the electrodes 14 and 14 via the diode D1. Resistors R17 to R23 for dividing the voltage, operational amplifiers OP1 to OP6 for comparing each divided voltage with the voltage signal, and the light emitting diode DP1 of the display means 205 from the output signals of the operational amplifiers OP1 to OP6. ~ Exclusive OR circuit EOR1 for exclusive-OR operation to create emission signal of DP5
~ EOR5 and equipped. A special element such as a capacitor C3 and a resistor R24 for stabilizing the input voltage signals to the operational amplifiers OP1 to OP6 is connected to the positive side of the diode D1. The voltage comparison device 26 is for checking (diagnosing) the voltage drop of the power supply battery 28, and the operation switch 32
It is activated by turning on. Reference numeral 34 in FIG. 2 indicates an operation switch for operating the level determining device 18. Further, the voltage comparison device 26 uses a resistor R28 to diagnose the voltage of the power supply battery 28 input through the operation switch 32.
~ R30, diode string D3, resistors R28 to R30, and operational amplifier OP7 for comparing the voltage divided by the diode string D3.
Are equipped with and operate the compared and diagnosed results switch 32
At the same time, it is input as a determination signal to the light emitting diode DP5 in the display means 20 via the contact 32A that opens and closes, and the light emitting diode DP5 emits light in accordance with the determination signal. The output signal of the operational amplifier OP7 is input to the light emitting diode DP5 via the resistor R31 and the diode D4. Further, a diode D5 is provided at the connection point of the diode D4 to prevent the determination signal from flowing back to the exclusive OR circuit EOR5. Note that voltage dividing resistors R32 to R36 for dividing the light emission signals applied to the light emitting diodes DP1 to DP5 are connected to the output sides of the exclusive OR circuits EOR1 to EOR5. Here, the voltage dividing resistors R18 to R in the level determination device 18
The sum of the resistance values of 23 is set to be slightly smaller than the impedance value of saliva of the mammal. For example, in the case of pigs, the body temperature is usually 38.5 ° C.
14.14 made of circular gold with a diameter of 3.5 mm and both electrodes 1
Electrode at 38.5 ° C with center distance of 4.14 set to 5 mm 14.
Slightly smaller than the equivalent impedance value of saliva between 14
2.14KΩ or so (impedance values below are all values between electrodes 14.14). Specifically, when the electrode 14.14 is immersed in a liquid having the same resistance as saliva, the voltage dividing resistor R
The sum of resistance values of 18 to R23 should be set. The resistance value of the voltage dividing resistor R23 is set to be substantially equal to the equivalent impedance value of the blood of the target mammal.
For example, in the case of pigs, it should be about 0.78KΩ. In particular,
Dip electrode 14.14 into the blood, at this time light emitting diode DP5
Set the resistance value of the voltage dividing resistor R23 so that turns off. Furthermore, the sum of the resistance values of the partial pressure resistors R19 to R23 should be approximately equal to the equivalent impedance value in the vaginal wall of the mammal at a time suitable for injecting liquid semen (Chilled Semen) into the uterus. Has been For example, in the case of pigs, it is about 1.88 KΩ. Furthermore, the sum of the resistance values of the partial pressure resistors R20 to R23 is set to be approximately equal to the equivalent impedance value in the vaginal wall of the mammal at a time suitable for injecting frozen semen (Frozen Semen). . For example, in the case of pigs, it is set to 1.644 KΩ. Furthermore, the sum of the resistance values of the partial pressure resistors R21 to R23 is set to be substantially equal to the value of the maximum equivalent impedance of the vaginal wall in a non-pregnant state when the mammal is not ovulating. For example, in the case of pigs, it should be about 1.00KΩ. Furthermore, the sum of the resistance values of the partial pressure resistors R22 and R235 is set to be equal to the lower half value of the impedance value of the vaginal wall when the mammal cannot be pregnant during the non-ovulation period. In the case of pigs, it should be about 0.867KΩ. Here, as shown in FIG. 1, the rod-shaped detection portion 12 to which the electrodes 14 and 14 are attached is attached to the main body 38 in which the detection circuit, the power supply battery and the like are housed. On the surface of the main body 38, the light emitting diodes DP1 to DP5 of the display means 20 and the operation switches 32 and 34 are mounted so as to be exposed on the surface. Next, the process of detecting the ovulation time of a mammal using the apparatus of the above embodiment will be described. First, the rod-shaped detection unit 12 is inserted into the vagina of a mammal. Next, the electrodes 14, 14 at the tip of the rod-shaped detection unit 12 are pressed against the vaginal mucosa, and in this state, the operation switch 34 is turned on. In this way, the voltage generated according to the value of the impedance equivalent circuit 18A between the electrodes 14 and 14 is input to the non-inverting input terminals of the operational amplifiers OP1 to OP6 via the diode D1. On the other hand, the voltage divided by the resistors R17 to R23 is applied to the inverting input terminals of these operational amplifiers OP1 to OP6, and accordingly, the voltage value from the impedance equivalent circuit 18A and each operational amplifier OP1 to OP6. The voltage values are compared and the comparison result is input to the exclusive OR circuits EOR1 to EOR5. In this case, the voltage input to each inverting input terminal is sequentially applied to the operational amplifiers OP6 to OP1 with gradually increasing values in accordance with the resistors R23 to R17. Then, since each of the exclusive OR circuits EOR1 to EOR5 takes an exclusive OR of adjacent ones of the operational amplifiers OP1 to OP6, one of the light emitting diodes DP1 to DP5 is turned on according to the value of the impedance equivalent circuit 18A. Will be done. Here, as described above, the sum of the resistance values of the voltage dividing resistors R18 to R23 is set to be substantially equal to the equivalent impedance value of saliva, and the sum of the resistance values of the voltage dividing resistors R19 to R23 is equivalent to the vaginal wall. Since the impedance value is made equal to the value in a state suitable for injecting liquid semen, the light emitting diode
When DP1 is lit, it indicates the time to inject frozen semen. Similarly, when the light emitting diode DP2 is turned on, it indicates a time suitable for injecting the liquid semen. When the impedance value between the electrodes 14 and 14 is equal to the equivalent impedance value in saliva, signals are input from both the operational amplifiers OP1 and OP2 to the exclusive OR circuit EOR1, so that the light emitting diode DP1 is turned off. Therefore, by utilizing this fact, the electrodes 14, 14 can be attached to the saliva to check the fertilization appropriate period display device. The sum of the resistance values of the voltage dividing resistors R21 to R23 is the impedance equivalent circuit 18A of the vaginal wall at the time of infertility in the non-ovulatory state.
Since it is set equal to the maximum impedance value of
When the light emitting diode DP4 or DP5 is lit, it indicates the infertile period of the mammal. Further, since the light emitting diode DP4 represents a high level in the infertile period, and the light emitting diode DP5 represents a low level in the infertile period, when the mammal is in the estrus, it is approaching or ovulating. You can judge whether it is finished. Light emitting diode
DP3 represents the so-called gray zone, an unknown time between fertile and infertile. Further, since the resistance value of the voltage dividing resistor R23 is set to be slightly larger than the impedance value in the blood of the target mammal, the light emitting diode when the electrodes 14 and 14 are immersed in the blood of the mammal. DP5 will be turned off. That is, by immersing the electrodes 14, 14 in blood or a liquid having a resistance equal to that of saliva, a zero level check of the ovulation timing detection device can be performed. According to the measurement by the present inventor, as shown in the right end of FIG. 4, in the case of pig, the equivalent impedance value of the vaginal mucosa is 1.0 K from the zero point (equivalent impedance value of blood) during non-ovulation.
It shows a stable curve that periodically increases and decreases between Ω with time, but the equivalent impedance value begins to increase 42 to 38 hours before ovulation, approaches the equivalent impedance value of saliva infinitely, and immediately before ovulation It becomes substantially equal to the equivalent impedance value of saliva, and thereafter, the equivalent impedance value sharply decreases and reaches the bottom value in 2 to 3 hours. Here, in the case of artificial insemination of pigs, the injection of sperm into the vagina is performed about 7 to 5 hours before ovulation in the case of ordinary liquid semen. Since the relationship between the equivalent impedance value of the vaginal mucosa of pig and time is constant, the timing of semen injection can be determined by setting the time when the light emitting diode DP2 is turned on as described above 7 to 5 hours before. In the case of frozen semen, the highest conception rate can be ensured by injecting it 2 hours before ovulation. In the case of frozen semen, this is
citation) and the capsular layer (sperm coat antigen,
This is because the plasma membrane and the in vitro membrane) have fallen off, and it is easier to inseminate immediately than liquid or semen. Therefore, the injection of the frozen semen, the light emitting diode DP1
You can do it when is lit. Therefore, in the case of frozen semen,
You will not be pregnant if any of the light emitting diodes DP2 to DP5 are lit. Incidentally, in the above embodiment, by the level determination device 18,
Although the magnitude of the impedance is detected, the present invention is not limited to this, and if necessary, the impedance value can be detected as it is or it can be detected whether or not it corresponds to an appropriately divided level. Any detector may be used. Further, in the above embodiment, the display means 20 is composed of a plurality of light emitting diodes DP1 to DP5, but the present invention is not limited to this. Any value can be displayed as long as it can be displayed between the values as appropriate. Therefore, the display means 20 may be an ordinary meter 36 or the like for displaying the impedance value, as shown in FIG. In this example, the equivalent impedance value of saliva is the maximum value, and the equivalent impedance value of blood is the minimum value,
The interval can be appropriately divided, and can be directly displayed on the meter. Also, one resistance can be used instead of the level determination device 18. When a light emitting diode or the like is used, the method of the fifth embodiment
The number is not limited to three, and may be three, two, or even six or more. Furthermore, although the above-mentioned examples detect the insemination period or infertility period of pigs, the present invention can naturally be applied to other mammals (including humans).

【The invention's effect】

Since the present invention is configured as described above, it has an excellent effect that the fertilization time of a mammal can be accurately detected. In addition, the infertile period can be accurately detected. According to the experiments conducted by the present inventor, the level determination device (impedance detection device) is used as described above, the peak value thereof is the equivalent impedance value of saliva of the mammal, and the bottom value is the equivalent of blood of the mammal. When the impedance values are set to be approximately equal to each other, and artificial insemination is performed by this,
Except in the case of abnormalities such as endometritis in pigs and cows,
The success rate was 100%.

[Brief description of drawings]

FIG. 1 is a front view showing an embodiment of a mammal fertilization appropriate period detection device according to the present invention, FIG. 2 is an electric circuit diagram showing the electric components of the embodiment, FIG. 3 is a block diagram thereof, and FIG. Four
FIG. 5 is a diagram showing changes in impedance of vaginal mucosa of pigs with time, and FIG. 5 is a front view showing another embodiment of the present invention. 10 …… Sodium ion concentration detection means, 12 …… detection section, 14 …… electrodes, 16 …… voltage generation means, 18 …… level determination device, 20 …… display means.

Claims (1)

[Claims] 1. A detection unit that can be inserted into the vagina of a mammal,
A plurality of electrodes of the detection unit, which are arranged at positions where they can come into contact with the vaginal mucosa, voltage generating means for applying a voltage between the plurality of electrodes, and impedance detection for detecting an impedance value between the electrodes. A means for detecting sodium ion concentration in the vaginal mucosa of a mammal, including a device, and the maximum value immediately before ovulation when the equivalent impedance value of the vaginal mucosa is substantially equal to the equivalent impedance value in the saliva of the mammal, and As the minimum value during non-ovulation when the equivalent impedance value of the vaginal mucosa is substantially equal to the equivalent impedance value in mammalian blood, the equivalent impedance value of the vaginal mucosa detected by the impedance detection device is based on the maximum value. If it is equal to this, it is determined that it corresponds to the proper period of sperm injection before ovulation,
In addition to displaying this, when it becomes equal to this based on the minimum value, it is determined that it corresponds to the infertile period at the time of non-ovulation, and display means for displaying this, and a mammal characterized by the above-mentioned. Insemination time detection device.