JPH02211137A - Mammal fertilization timing detector device - Google Patents

Abstract

PURPOSE:To adequately detect fertilization timing by setting the suitable timing of injecting a spermatozoon before ovulation with a minimum value of sodium ion concentration in saliva just before ovulation serving as the reference and displaying a detection value of the sodium ion concentration of a vagina mucous membrane within a preset range. CONSTITUTION:A sodium ion concentration detecting means, inserting a detecting part 12 into the vagina of mammal and applying voltage across a pair of electrodes 14 in a point end part 12A, detects interpole impedance, that is, sodium ion concentration. With a minimum value just before ovulation, when the impedance is almost equal to equivalent impedance of salive, serving as the reference, setting a range of the sodium ion concentration of the suitable spermatozoon injection timing before ovulation, the detected concentration, when it is within the set range, is displayed in a display means 20. While the concentration, when it is almost equal to the sodium ion concentration in blood, is set as a maximum value in non-ovulation time, and setting with this value serving as the reference a range of value corresponding to a pregnancy impossible period, the concentration is similarly displayed. Thus, the fertilization timing can be accurately detected.

Description

[Detailed description of the invention] [Industrial application field]

The present invention relates to a device for detecting the appropriate time for insemination of mammals including humans.

[Conventional technology]

Conventionally, for example, JP-A-60-188142 to 18814
8, Japanese Patent Publication No. 60-190942-190944.111
1&60-220052, JP-A-60-227746,
JP-A-61-90651-90655, JP-A-61-1
37543-137545, JP-A-61-137554
As disclosed in Japanese Patent Application Laid-Open No. 61-217157, a device has been proposed for detecting the ovulation period or suitable insemination period of a mammal based on the equivalent DC resistance value of the mammal's vaginal wall. These detect the sodium ion concentration in the vaginal wall from the equivalent direct current resistance value, which is inversely proportional to this concentration. By the way, each of the above-mentioned ovulation prediction and detection devices or suitable insemination period detection devices calculate the maximum value and minimum value of the equivalent DC resistance value based on the experience that the equivalent DC resistance value of the vaginal wall is the maximum immediately before ovulation. The space is divided into a plurality of sections, and a lamp is lit corresponding to each division. For example, in the case of pigs, refrigerated or live sperm should be injected into the uterus 5 to 7 hours before ovulation, and frozen sperm should be injected into the uterus 2 hours before ovulation. , has been found to have the highest insemination and conception rates. Therefore, the detected equivalent DC resistance value of the vaginal wall is 7
It would be ideal if the corresponding lamp could be turned on when the equivalent DC resistance value corresponds to ~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 during the non-ovulatory period have been unknown. Therefore, the lamp that displays the sperm injection timing in the ovulation prediction detection device or insemination suitable time detection device is
It did not necessarily indicate accurate timing. Furthermore, even if artificial insemination is performed when it is determined that fertilization is the optimal time using an ovulation prediction/detection device or an appropriate insemination time detection device, the success rate is not 100%. Furthermore, even if it was desired to use an insemination suitable time display device for the human body for contraceptive purposes, it could not be used because the minimum equivalent direct current resistance value of the M wall, that is, the standard for setting the zero point, was unclear. In contrast, the present inventor has proposed PCT/JP871010
According to the patent application No. 11, the sodium ion concentration in the vaginal mucosa of mammals is at its minimum during the ovulation period, and is approximately equal to the sodium ion concentration in water, and furthermore, the sodium ion concentration is at its maximum during the non-ovulation period. Based on the discovery that the value approximately coincides with the sodium ion concentration in the blood of the mammal, a device for detecting the appropriate time for insemination of mammals was proposed. This proposal also
Conventionally, the sodium ion concentration was assumed to be inversely proportional to the equivalent DC resistance value of the vaginal mucosa, but this is based on the discovery that it is more precisely inversely proportional to the equivalent impedance value of the vaginal mucosa.

[Problem to be solved by the invention]

By the way, the water in the above proposal is actually tap water from Hamamatsu City, Shizuoka Prefecture, Japan, but the sodium ion concentration in this tap water varies slightly depending on the season or even during the day. Although the variation in measurement results due to this variation was very small, it goes without saying that greater accuracy is desirable. The present invention provides an HM for detecting suitable insemination period for mammals, which enables accurate setting of the minimum value of the sodium ion concentration in the vaginal mucous membrane of mammals, thereby making it possible to accurately determine the appropriate period for insemination or the period of infertility in mammals. The purpose is to provide '4rR.

[Means for Solving the Problems] Through trial and error, the inventor has determined that the minimum sodium ion concentration in the vaginal mucosa of a mammal is the sodium ion concentration in the saliva of the mammal. This is based on the discovery that . The present invention provides a means for detecting the sodium ion concentration in the vaginal mucosa of a mammal, and a means for detecting the sodium ion concentration approximately equal to that in the saliva of the mammal as the minimum value of the sodium ion concentration immediately before ovulation, and using the minimum value as a reference. A display means for setting a range of sodium ion concentration at an appropriate time for sperm injection before ovulation and displaying when the detected sodium ion concentration corresponds to the set range. The above object is achieved by this insemination suitable time detection device. Further, the sodium ion concentration detection means includes a detection section that can be inserted into the vagina of the mammal, a plurality of electrodes of the detection section that are arranged at positions that can contact the vaginal mucous membrane, and a detection section between the plurality of electrodes. voltage generating means for applying a voltage to;
an impedance detection device for detecting an impedance value between the electrodes, and the display means takes an equivalent impedance value of the saliva of the mammal between the electrodes as a maximum value, and uses the maximum value as a reference to determine whether or not ovulation is occurring before ovulation. The above object is achieved by setting a range of impedance values at an appropriate time for sperm injection, and displaying this when the equivalent impedance value of the vaginal mucosa detected by the impedance detection device is within the range. . The present invention also provides a means for detecting sodium ion concentration in the vaginal mucosa in a mammal, and
When the sodium ion concentration detected by the detection means is set as the maximum value during non-ovulation when it is approximately equal to the sodium ion concentration in the blood of the mammal, the sodium ion concentration detected by the detection means is set as a reference to the maximum value during the non-fertile period during non-ovulation. The above object is achieved by an apparatus for detecting suitable insemination time for a mammal, which comprises a display means for displaying a corresponding value when the value is a corresponding value. Further, the sodium ion concentration detection means is arranged between a detection section that can be inserted into the vagina of the mammal, a plurality of N8i's of this detection section arranged at a position where they can contact the mucous membrane, and the plurality of electrodes. Voltage generating means for applying voltage;
an impedance detection device for detecting an impedance value between the electrodes, and the display means indicates that when the equivalent impedance value of the vaginal mucosa is approximately equal to the equivalent impedance value of blood in the mammal, the mammal is not ovulating. This is displayed as the minimum value when the equivalent impedance value of the vaginal mucosa detected by the impedance detection device is a value corresponding to the sterile period at the time of non-ovulation, which is set based on the minimum value. This aims to achieve the above objectives. Furthermore, the present invention provides means for detecting the concentration of sodium ions in the vaginal mucosa of a mammal; The sodium ion concentration detected by the detection means is set as the maximum value during non-ovulation when it is approximately equal to the sodium ion concentration, and the value corresponds to the sterile period during non-ovulation, which is set based on the minimum and maximum values. The above object is achieved by an apparatus for detecting an appropriate time for insemination of a mammal, which includes a display means for displaying the appropriate time for insemination when the present invention is performed. Further, the sodium ion concentration detection means includes a detection section that can be inserted into the vagina of the mammal, a plurality of electrodes of the detection section that are arranged at positions that can contact the vaginal mucous membrane, and a gap between the plurality of electrodes. voltage generating means for applying a voltage to;
an impedance detection device for detecting an impedance value between the electrodes, and the display means indicates that ovulation is detected when the equivalent impedance value of the vaginal mucosa is approximately equal to the equivalent impedance value of saliva of the mammal. The equivalent impedance value of the vaginal mucosa detected by the impedance detection device is the maximum value, with the immediately preceding maximum value and the time substantially equal to the equivalent impedance value in the blood of the mammal as the minimum value during non-ovulation. The above object is achieved by displaying the minimum value when the value corresponds to the sterile period at the time of non-ovulation, which is set as a reference. [Function] In the present invention, the display means for displaying the suitable period for insemination is based on the fact that the sodium ion concentration in the vaginal mucosa becomes approximately equal to the sodium ion concentration in saliva immediately before ovulation. The time when it is almost equal to is regarded as the minimum value just before ovulation, and based on this minimum value, the optimal time for sperm injection before ovulation is displayed.
Ovulation period and based on this (the optimum period for insemination can be detected more accurately).

[Example] Hereinafter, an example of the present invention will be described in detail with reference to the drawings. As shown in the figure, this embodiment includes a rod-shaped detection section 12 that can be inserted into the womb of a mammal, and a distal end 12A of this detection section 12 arranged at a position where it can come into contact with the vaginal mucous membrane of the mammal. a pair of electrodes 14, a voltage generating means 16 for applying a voltage between the pair of electrodes 14.14, and a level determination device 18 for detecting an impedance value between the electrodes 14.14. a sodium ion concentration detection means 1o consisting of; a time when the equivalent impedance value of the vaginal mucous membrane is approximately equal to the equivalent impedance value of the saliva of the mammal is the maximum value immediately before ovulation;
The minimum value is when the equivalent impedance value of the vaginal mucosa is approximately equal to the equivalent impedance value in the blood of the target mammal, and the maximum value, the minimum value, and the maximum value and the minimum value are used as standards for sperm injection before ovulation. A display means 20 configured to display the suitable period and the non-fertile period at the time of non-ovulation constitutes an apparatus for detecting the suitable period for insemination of mammals. The voltage generating means 16 includes an alternating current generating means 22, a booster 24, and a voltage comparator 26. The alternating current generating means 22 includes an astable multivibrator 2
2A and a positive/negative pulse amplifier 22B. The astable multivibrator 22A mainly includes transistors TR1 and TR2, resistors R1 to R4, and capacitor C1.
, C2, and the positive/negative pulse amplifier 2
2B are transistors TR3 to TR7 for amplifying the pulses output by the astable multivibrator 22A.
, resistors R5 to R16. The booster 24 includes an inverter circuit for boosting the power supply voltage supplied from the power supply battery 28 to a required voltage, and includes transistors TR8 and TR9 for amplification.
are provided with capacitors C4 to C7, resistors R25 to R'27, and resistors R25 to R'27 for applying the power supply voltage from the distribution power supply battery 28 to the transistors TR8 and TR9 to perform a boosting action.
It has coils L1 and L2, a diode D2, and Zener diodes zD1 and ZD2. The positive electrode sides of this diode D2 and Zener diode ZD1 are connected to the AC generating means 22.
It is connected to the resistor R10 of the level determining device 30 and the resistor R17 of the level determining device 30, so that a boosted voltage is input and a current flows therein. The level determination device 18 includes a plurality of voltage comparators for detecting the impedance level of the impedance equivalent circuit 18A of the detected portion (vaginal mucous membrane) by alternating current applied to the electrodes 14.14, and the display means Reference numeral 20 displays the levels determined by the level determining device 18 using light emitting diodes DPI to DP5 according to the respective levels. More specifically, the level determining device 18 determines the impedance level of the impedance equivalent circuit 18A from the voltage signal output from the electrode 14.14 via the diode D1, and the voltage signal ψ input from the booster bag @24. resistors R17-R23 for dividing the voltages, operational amplifiers OP1-OP6 for comparing each divided voltage with the voltage signal, and the display means 20 from the output signals of the operational amplifiers 0'P1-OP6. light emitting diode DP1
Exclusive OR circuits EOR1 to EO for performing exclusive OR operation in order to create the light emission signal of ~DP5
It is equipped with R5. Note that characteristic elements such as a capacitor C3 and a resistor R24 are connected to the positive electrode side of the diode D1 for stabilizing the input voltage signal to each operational amplifier OP1 to OP6. The voltage comparison device 26 is for checking (diagnosing) a voltage drop in the power supply battery 28, and is activated by turning on the operation switch 32. Reference numeral 34 in FIG. 2 indicates an operating switch for operating the level determining device 18. Further, the voltage comparison device 26 includes resistors R28 to R30, a diode array D3, and resistors R28 to R30 in order to diagnose the voltage of the power supply battery 28 inputted via the operation switch 32.
A contact 32 is provided with an operational amplifier OP7 for comparing the voltages divided by R30 and the diode array D3, and opens and closes the comparison and diagnosis results at the same time as the operation switch 32.
A to the light emitting diode DP5 in the display means 20
is input as a determination signal to cause the light emitting diode DP5 to emit light in accordance with the determination signal. Note that the output signal of the arithmetic unit 11 amplifier OP7 is connected to the resistor R31 and the diode D4.
The light is input to the light emitting diode DP5 via the light emitting diode DP5. or,
A diode D5 is provided at the connection point of the diode D4 in order to prevent the judgment signal from flowing backward to the exclusive OR circuit EOR5. Note that voltage dividing resistors R32 to R36 are connected to the output side of each exclusive shift OR circuit EOR1 to EOR5 for dividing the voltage of the light emission signal applied to each light emitting diode DP1 to DP5. Here, the voltage dividing resistor R1 in the level determination device 18
The sum of the resistance values of 8 to R23 is set to be slightly smaller than the impedance value of saliva of the mammal. For example, in the case of a pig, the body temperature is normally 38.5°C, so if the electrode 14.14 is made of circular gold with a diameter of 3.5n, and the distance between the centers of the picture electrode 14.14 is 5n. , approximately 2.14Ω, which is slightly smaller than the equivalent impedance value of saliva between the electrodes 14 and 14 at 38.5° C. (hereinafter, all impedance values are values between the electrodes 14 and 14). Specifically, the sum of the resistance values of the voltage dividing resistors R18 and R23 may be set so that the light emitting diode DP1 lights up when the electrodes 14.14 are immersed in a liquid having the same resistance as saliva. Further, the resistance value of the voltage dividing resistor R23 is set to be approximately equal to the equivalent impedance value of the blood of the target mammal. For example, in the case of a pig, it is set to about 0.78Ω. Specifically, the electrodes 14.14 are immersed in blood, and the resistance value of the voltage dividing resistor R23 is set so that the light emitting diode DP5 is turned off at this time. Furthermore, the sum of the resistance values of the voltage dividing resistors R19 to R23 is
It is made to be approximately equal to the value of equivalent impedance in the vaginal wall of the mammal at a time suitable for injecting liquid semen into the uterus. For example, in the case of a pig, it is said to be about 1.88Ω. Furthermore, the sum of the resistance values of the voltage dividing resistors R20-R23 is
It is set to be approximately equal to the value of the equivalent impedance in the vaginal wall of the mammal at a time suitable for injecting frozen semen (1"r'ozen 3 emmen). For example, in the case of a pig, the impedance is set to 1.644 Ω. Furthermore, the sum of the resistance values of the partial voltage resistors R21, to R23 is set to be approximately equal to the maximum equivalent impedance of the vaginal wall in the non-ovulatory state of the mammal in an infertile state. For example, in the case of a pig, it is approximately 1.0 OKΩ.Furthermore, the sum of the resistance values of the partial voltage resistors R22 and R23 is M
It is made equal to the lower half of the wall impedance value. In the case of pigs, it is approximately 0.867Ω. Here, as shown in FIG. 1, the rod-shaped detection section 12 to which the electrodes 14, 14 are attached is attached to a main body 38 in which the detection circuit, power source battery, etc. are housed. The main body 38 has the light emitting diodes DP1 to DP5 of the display means 20 and the operation switch 32.3 on its surface.
4 is attached and exposed on the surface. Next, a process of detecting the ovulation period of a mammal using the above embodiment device will be explained. First, the rod-shaped detection section 12 is inserted into the vagina of a mammal. Next, the electrode 14.14 at the tip of the rod-shaped detection part 12 is pressed against the vaginal mucous membrane, 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 applied to the diode D.
1 to the non-inverting input terminals of each operational amplifier OP1 to OP6. On the other hand, these operational amplifiers ○P1~OP
The voltage divided by each resistor R17 to R23 is applied to the inverting input terminal of No. 6, and therefore, the voltage value from the impedance equivalent circuit 18A and the voltage value for each operational amplifier oP1 to OP6 are compared. The results are input to exclusive OR circuits EOR1 to EOR5. In this case, the voltage input to each inverting input terminal is applied from the operational amplifier OP6 to OPI in a stepwise manner in accordance with the resistors R23 to R17. Each of the exclusive OR circuits EOR1 to EOR
Since OR5 takes the exclusive OR of adjacent operational amplifiers ○P1 to OP6, the impedance equivalent circuit 18
One of the light emitting diodes DP1 to DP5 is turned on depending on the value of A. Here, as described above, the sum of the resistance values of the voltage dividing resistors R18 to R23 is set to be approximately equal to the equivalent impedance value of saliva, and the sum of the resistance values of the voltage dividing resistors R19 to R23 is set to be approximately equal to the equivalent impedance value of saliva. Since the equivalent impedance value is equal to the value in a state suitable for injecting liquid semen,
When the light emitting diode DPI is lit, it indicates the time to inject frozen semen. Similarly, when the light emitting diode DP2 lights up, it indicates a suitable time for injecting liquid semen. When the impedance value between the electrodes 14 and 14 is equal to the equivalent impedance value in water, signals are input from both operational amplifiers OP1 and OR3 to the exclusive OR circuit EOR1, so the light emitting diode DPI is turned off. . Therefore, by utilizing this fact, the electrode 14.14 can be placed in water to check the appropriate insemination timing display device. The sum of the resistance values of the voltage dividing resistors R2i to R23 is set equal to the maximum impedance value of the impedance equivalent circuit 18A of the vaginal wall during the period of non-ovulation and infertility, so that the light emitting diode OP4 or DP5 is When lit, it indicates the period when the mammal is unable to conceive. Furthermore, since the light emitting diode DP4 represents a high level impedance value during the infertile period, and the light emitting diode DP5 represents a low level impedance value during the infertile period, when the mammal is in heat, it indicates that the mammal is approaching ovulation or has not ovulated. You can determine whether it has finished. The light emitting diode DP3 indicates the unknown period between fertile and impotent states, the so-called gray zone. 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, when the electrode 14.14 is immersed in the blood of the target mammal, the light emitting diode 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, it is possible to check the zero level of the ovulation time detection device. According to actual measurements by the present inventor, as shown on the right side of FIG. 4, in the case of pigs, the equivalent impedance value of the vaginal mucosa varies from zero (equivalent impedance value of blood) to 1.
It shows a stable curve that periodically increases and decreases over time between 0 and Ω, but the equivalent impedance value begins to increase from 42 to 38 hours before ovulation, and is not limited to (approaches) the equivalent impedance value of saliva. Immediately before ovulation, the equivalent impedance value becomes approximately equal to the saliva equivalent impedance value, and after that, the equivalent impedance value rapidly decreases and reaches the bottom value in 2 to 3 hours. In the case of normal liquid semen, injection is performed approximately 7 to 5 hours before ovulation.Since the relationship between the equivalent impedance value of the pig's vaginal mucosa and time is constant, as mentioned above, when the light emitting diode DP2 lights up The timing of semen injection can be determined by setting the above 7 to 5 hours before. Also, in the case of frozen semen, injecting it 2 hours before ovulation can ensure the highest conception rate. In the case of cold AM liquid, the capacity John (Ca
t) Acitatiofl, the membrane that covers the sperm (sperm coat antigen, plasma membrane, extra-biological membrane) has fallen off, making it easier to fertilize immediately compared to liquid or raw semen. It is from. Therefore, injection of frozen semen is
This can be done when the light emitting diode DPI lights up. Therefore, in the case of frozen semen, pregnancy does not occur when any of the light emitting diodes DP2 to DP5 is lit. Note that in the above embodiment, the level determination device 18
Although the size of the impedance is detected, the present invention is not limited to this, and if necessary, an impedance that can detect whether or not the impedance value corresponds to the level as it is or the level divided appropriately. Any detection device 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 device that can appropriately display the range between values is sufficient. Therefore, the display means 20 may be an ordinary meter 36 or the like that displays an impedance value as shown in FIG. In this embodiment, the equivalent impedance value of saliva may be any value that can detect the sodium ion concentration of the most vaginal mucous membrane. Therefore, other means than measuring the impedance value may be used to detect the sodium ion concentration in the vaginal mucosa. Furthermore, although the above-mentioned embodiment detects the suitable period for insemination or the period of infertility in pigs, the present invention can naturally be applied to other mammals (including humans). Effects of the Invention The present invention, configured as described above, has the excellent effect of being able to accurately detect the insemination timing of mammals. Furthermore, it is possible to accurately detect the period when pregnancy is no longer possible. According to the inventor's experiments, the level determination device (impedance detection device) was used as described above, and its peak value was determined to be the equivalent impedance value of the saliva of the mammal concerned, and the bottom value was determined to be the equivalent impedance value of the blood of the concerned mammal. If the impedance values are set approximately equal to each other and artificial insemination is performed,
In pigs and cows, unless there are abnormalities such as endometrial bundles,
The success rate was 100%.

[Brief explanation of the drawing]

FIG. 1 is a front view showing an embodiment of the apparatus for detecting suitable insemination period for mammals according to the present invention, FIG. 2 is an electric circuit diagram showing electrical components in the embodiment, and FIG. 3 is a block diagram of the same. Fourth
The figure is a diagram showing temporal changes in impedance of a pig's vaginal mucosa, and FIG. 5 is a front view showing another embodiment of the present invention. 12... Detection unit, 14... Electrode, 16... Voltage generating means, 18... Level determination device, 20... Display means.

Claims (6)

[Claims] (1) A means for detecting the sodium ion concentration in the vaginal mucosa of a mammal, and a sodium ion concentration approximately equal to that in the saliva of the mammal as the minimum value of the sodium ion concentration immediately before ovulation, and using this minimum value as a reference before ovulation. a display means for setting a range of sodium ion concentration at an appropriate time for sperm injection, and displaying when the detected sodium ion concentration corresponds to the set range. Appropriate time detection device. (2) The sodium ion concentration detection means includes a detection section that can be inserted into the vagina of the mammal, a plurality of electrodes of the detection section that are arranged at positions that can make contact with the vaginal mucous membrane, and a plurality of electrodes that can be inserted into the vagina of the mammal. a voltage generating means for applying a voltage between the electrodes; and an impedance detection device for detecting an impedance value between the electrodes; is set as the maximum value, a range of impedance values at a suitable time for sperm injection before ovulation is set based on the maximum value, and when the equivalent impedance value of the vaginal mucous membrane detected by the impedance detection device is within the range, this is displayed. The apparatus for detecting suitable time for insemination of mammals according to claim 1, which is configured as follows. (3) means for detecting the sodium ion concentration in the vaginal mucosa of a mammal, and the detection means detecting when the sodium ion concentration is approximately equal to the sodium ion concentration in the mammal's blood as the maximum value during non-ovulation; 3. The feeding device according to claim 1, further comprising display means for displaying when the determined sodium ion concentration is a value corresponding to a non-fertile period at the time of non-ovulation, which is set based on the maximum value. Appropriate insemination period detection device for animals. (4) The sodium ion concentration detection means includes a detection section that can be inserted into the vagina of the mammal, a plurality of electrodes of the detection section that are arranged at positions that can contact the mucous membrane, and a gap between the plurality of electrodes. voltage generating means for applying a voltage to;
an impedance detection device for detecting an impedance value between the electrodes, and the display means indicates that when the equivalent impedance value of the vaginal mucous membrane is approximately equal to the equivalent impedance value of the blood of the mammal, it is determined that the mammal is not ovulating. This is displayed as the minimum value when the equivalent impedance value of the vaginal mucosa detected by the impedance detection device is a value corresponding to the sterile period at the time of non-ovulation, which is set based on the minimum value. Claim 3
Appropriate time detection device for mammalian insemination. (5) A means for detecting the concentration of sodium ions in the vaginal mucosa of a mammal; a time when the concentration of sodium ions is approximately equal to that of the saliva of the mammal is the minimum value immediately before ovulation; and a means for detecting the concentration of sodium ions in the blood of the mammal; When the sodium ion concentration detected by the detection means is the maximum value during non-ovulation when it is approximately equal to the concentration, the sodium ion concentration detected by the detection means is a value corresponding to the non-fertile period during non-ovulation, which is set based on the minimum and maximum values. A device for detecting an appropriate time for insemination of a mammal, comprising: a display means for displaying the information. (6) The sodium ion concentration detection means includes a detection section that can be inserted into the vagina of the mammal, a plurality of electrodes of the detection section that are arranged at positions that can make contact with the vaginal mucous membrane, and a plurality of electrodes that can be inserted into the vagina of the mammal. and an impedance detection device for detecting an impedance value between the electrodes, and the display means indicates that the equivalent impedance value of the vaginal mucosa is the saliva of the mammal. The maximum value immediately before ovulation is when the value is approximately equal to the equivalent impedance value of
A claim for displaying when the equivalent impedance value of the vaginal mucosa detected by the impedance detection device is a value corresponding to the sterile period at the time of non-ovulation, which is set based on the maximum value and the minimum value. Item 5. Appropriate insemination period detection device for mammals.