JP2006034210A - Method for measuring intracorpoleal information of mouse or rat body and mouse or rat of which intracorpoleal information can be measured - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for measuring intracorpoleal information that can continuously and exactly measure the intracorpoleal information, for example, the information of heart or the like of mouse or rat that are fed under normal feeding conditions and provide mouse or rat of which intracorpoleal information can be measured. <P>SOLUTION: In this invention, a microchip at least equipped with a device for detecting intracorpoleal information and equipped with a transmission means for transmitting the information detected by the device is buried in the body of a mouse or a rat and the intracorporeal information transmitted from the microchip is analyzed with the analyzer installed outside wherein the microchip is buried in the back of mouse or rat. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to in-vivo information of a mouse or rat that enables accurate measurement of in-vivo information such as heart information of the mouse or rat in a normally reared state (awake state) without hindering daily behavior. And a mouse or a rat capable of measuring the in-vivo information.

In recent years, research on genes has been completed, and sequencing of the human genome has been completed, and the research has shifted to post-genomic research centered on functional analysis of each gene. In such post-genomic research, transgenic mice and rats that have heterologous genes incorporated into mice and rats that are mammals with high homology to human genes are an excellent model for gene function analysis. It is used as a system. Detailed analysis of in-vivo information such as a mouse with such a special function is very important for elucidating the function of an unknown gene.
In addition to such cases, acquiring in-vivo information of mice and rats is important in various scenes of research in the life science field.

  Conventionally, in-vivo information such as heart information of a mouse or rat is measured by attaching an electrode to the skin of an animal that is a subject and inputting a signal detected by the electrode to a measuring device via a lead wire. (For example, Patent Document 1). However, in the measurement method, since the animal is connected to the measurement device with a lead wire, the freedom of movement is deprived and the in-vivo information of the animal that is normally raised is continuously and accurately measured. I couldn't.

For this reason, as a device for measuring in-vivo information of a mouse or the like that is normally bred, it is embedded in the body of a mouse or the like to measure medical measurements such as electrocardiogram and myoelectricity as cardiac information, There has been proposed an implantable medical measurement and transmission device for small animals that wirelessly transmits measurement values to an external receiving device (Patent Document 2).
Special table 2003-507142 gazette Japanese Patent Laid-Open No. 2001-148962

However, in Patent Document 2, in order to measure accurate heart information, there is no examination as to where the optimal site for embedding the device in a small animal is. For this reason, when the present inventors performed measurement by embedding a small device for measuring heart information in various parts of the body of a small animal, it was found that the measurement accuracy differs depending on the part to be implanted.
Therefore, the present invention provides in vivo information of a mouse or rat that enables continuous measurement of in-vivo information such as heart information of a mouse or rat in a normal breeding state without disturbing daily activities. It is an object of the present invention to provide a measurement method and a mouse or rat capable of measuring the in-vivo information.

As a result of intensive studies by the present inventors to solve the above-mentioned problems, heart information can be obtained by implanting a microchip having a device for detecting heart information, particularly in the back of a mouse or rat. It has been found that it is possible to improve the measurement accuracy.
The method for measuring in-vivo information of a mouse or a rat according to the present invention is based on such knowledge. As described in claim 1, a device for detecting in-vivo information and in-vivo information detected by the device are obtained. A mouse or a microchip by embedding a microchip having at least a transmission means for transmitting to the outside wirelessly in the body of a mouse or rat, and analyzing the in-vivo information transmitted from the microchip with an analyzer provided outside A method for measuring in-vivo information of a rat, wherein the microchip is embedded in the back of a mouse or rat.
The measurement method according to claim 2 is the measurement method according to claim 1, wherein the in-vivo information is at least heart information.
Further, the measurement method according to claim 3 is the measurement method according to claim 1 or 2, wherein the back portion is at least one muscle and body selected from trapezius, latissimus dorsi, gluteal muscle, and spinal column standing muscle. It is between trunk skin muscles.
The measurement method according to claim 4 is the measurement method according to any one of claims 1 to 3, wherein the mouse or rat is a transgenic mouse or a transgenic rat.
Further, the measurement method according to claim 5 is the measurement method according to any one of claims 1 to 4, wherein the in-vivo information transmitted from the microchip is a cylinder having a size that allows a mouse or a rat to enter. The probe is received when a mouse or a rat enters the cylindrical probe and then transmitted to an analysis device for analysis.
In order to solve the above-mentioned problem, the mouse or rat of the present invention is a device for detecting in-vivo information, and for transmitting in-vivo information detected by the device to the outside wirelessly as described in claim 6. A microchip provided with at least a transmission means is embedded in the back.
A mouse or rat according to claim 7 is the mouse or rat according to claim 6, wherein the device is a device for detecting at least cardiac information.
The mouse or rat according to claim 8 is the mouse or rat according to claim 6 or 7, wherein the back portion is at least one muscle selected from trapezius, latissimus dorsi, gluteal muscle, and spine standing muscle. And between the trunk skin muscles.

A method for measuring in-vivo information of a mouse or a rat according to the present invention includes at least a device for detecting in-vivo information and a transmitting means for transmitting in-vivo information detected by the device to the outside wirelessly. Embedded in the back of a mouse or rat. According to the present invention, it is possible to accurately and continuously measure in-vivo information such as heart information of a mouse or rat in a normal breeding state without hindering daily activities of the mouse or rat.
In particular, when the microchip is provided with a device for detecting at least cardiac information among in-vivo information, when the microchip is embedded in the back of a mouse or rat, the microchip is placed at other parts of the body. Since the number of signals detected from organs other than the heart is reduced as compared with the case of implantation, the noise is reduced, so that heart information can be accurately measured.
Further, when the microchip is embedded between at least one muscle selected from trapezius, latissimus dorsi, superficial gluteus dorsi and spinal column muscles of the back of a mouse or rat, and trunk trunk muscle The embedded microchip is difficult to move in the body, and accurate in-vivo information can be continuously measured.
Further, by utilizing the habit that a mouse or a rat enters a cylindrical object, the in-vivo information transmitted from the microchip is transferred to the cylindrical probe with a cylindrical probe having a size that allows the mouse or rat to enter. Alternatively, when the rat is received and transmitted to the analysis device after analysis, the transmission distance of the in-vivo information transmitted from the microchip embedded in the mouse or the like that has entered the cylindrical probe is shortened. And since the said information can be received reliably from a short distance, in-vivo information can be measured accurately.
Thus, according to the present invention, accurate in-vivo information of the mouse or rat can be measured without inhibiting the activity of the normal state (wakefulness) of the mouse or rat kept in the cage. Therefore, the present invention is useful as a method for measuring in-vivo information of, for example, a transgenic mouse or a transgenic rat in which a heterologous gene is incorporated and expressed.
In addition, since a mouse or rat with a microchip equipped with a device for detecting in-vivo information embedded in the back can continuously and accurately measure in-vivo information while being reared normally, This is useful in field research.

Hereinafter, the method for measuring in-vivo information of a mouse or rat according to the present invention will be described by taking as an example the case of measuring in-vivo information of a mouse.
As shown in FIG. 1, the measurement method of the present invention is a microchip including at least a device for detecting in-vivo information and a transmitting means for transmitting in-vivo information detected by the device to the outside wirelessly. Using the mouse 11 with 1 embedded in the back, the in-vivo information of the mouse 11 is transmitted from the microchip 1 to an analyzer provided outside in the state normally raised in the cage 14 (wakefulness state). Do. In the measuring method shown in FIG. 1, a signal is transmitted to an external device composed of a measuring instrument 8, an application system 9, and a server system 10 through a probe 12 for reliably receiving in-vivo information transmitted from the microchip 1 as a signal. It is transmitted to the analysis device to analyze in-vivo information. Here, the measuring instrument 8 is a device for supplying power to the microchip 1 and transmitting and receiving signals, and the application system 9 controls the in-vivo information of the mouse 11 transmitted from the microchip 1, and information The server system 10 is a device for accumulating the in-vivo information and creating a database. In the measurement method shown in FIG. 1, the analysis device provided outside is configured from a measuring instrument, an application system, and a server system. However, the analysis device provided outside in the present invention is not necessarily configured in this way. It doesn't have to be.

FIG. 2 shows another example of the measurement method of the present invention, in which a probe for reliably receiving in-vivo information transmitted from a microchip as a signal is formed in a cylindrical shape that allows a mouse to enter, The in-vivo information transmitted from the microchip 1 embedded in the back of the mouse 11 entering the inside of the cylindrical probe 13 is received by the cylindrical probe 13 and then transmitted to the analysis device for analysis. Is the method.
The mouse 11 is inserted into the cylindrical probe 13 using the habit of the mouse or rat entering the inside, looking into the hole, and transmitted from the microchip 1 embedded in the back of the mouse 11 entering the inside. If the in-vivo information is received by the cylindrical probe 13, the transmission distance of the in-vivo information can be shortened, so that the information can be reliably received from a short distance and transmitted to the external analyzer. Therefore, in-vivo information can be measured with high accuracy. Further, if food, water, or the like is placed in the cylindrical probe 13 every predetermined time and the mouse 11 enters the cylindrical probe 13 every predetermined time to measure in-vivo information, the information is measured every predetermined time. Can be easily measured.
1 and 2 show the measurement method in which the probe and the analyzer provided outside are separate from each other, for example, the probe and the measuring instrument may be integrated. In the measurement method, the in-vivo information transmitted from the microchip provided on the back of the mouse is transmitted to the analysis device via the probe. However, the measurement method of the present invention includes the measurement method described above. However, the in-vivo information may be transmitted directly from the microchip to an analyzer provided outside without providing a probe.

For example, as shown in FIG. 3, the microchip 1 is made of quartz glass or resin having a short side of 0.5 mm to 2 mm and a long side of 5 mm to 15 mm, or a cylindrical body subjected to biocompatible treatment. Electrodes 2 that are devices for detecting cardiac information (myocardial action potential) are provided at both ends. The electrode 2 detects a series of action potentials when the myocardium contracts and dilates, and serves to create an electrocardiogram (ECG) such as a QRS wave. At the same time, the instantaneous heartbeat (bpm) is calculated from the interval between the R wave and R wave of the electrocardiogram and the RR interval data.
In addition to the electrode 2, the microchip 1 can be provided with a device for detecting in-vivo information other than the heart information such as the temperature sensor 3 as a signal.

In addition to the device for detecting in-vivo information such as the electrodes 2 provided at both ends of the cylindrical body and the temperature sensor 3 mounted on the substrate 7, the microchip 1 is provided inside the cylindrical body, A power storage capacitor 5 and a plurality of circuits 6 such as a sensor signal preamplifier, a sensor signal processing circuit, an energy supply circuit, a solid identification code RW circuit, and a sensor signal processing circuit are mounted on a substrate 7, and further, depending on the device. A signal transmitting / receiving antenna and an energy supply antenna 4 can be provided as transmitting means for transmitting the detected in-vivo information to the outside wirelessly.
For example, the microchip 1 shown in FIG. 3 detects the action potential of the mouse myocardium as an electrical signal with the electrode 2, amplifies the detected electrical signal with a sensor signal preamplifier, and processes the amplified signal with a sensor signal processing circuit. Thereafter, the in-vivo information is transmitted by transmitting a signal to the outside from the signal transmitting / receiving antenna 4 as a transmitting means.
Further, the microchip 1 is continuously supplied with energy from the outside via the energy supply antenna 4, and this energy is processed so as to become a power source in the energy supply circuit and stored in the capacitor 5. The power supply such as is not mounted, it is miniaturized. For this reason, even if the microchip 1 is embedded in the back of the mouse, the burden on the mouse is reduced, so that in-vivo information of the mouse can be continuously measured for a long period of time.

In addition, by embedding the microchip in the back of the mouse, the number of signals detected from organs other than the heart is reduced and noise is reduced, so that heart information can be accurately measured. Further, when the microchip is embedded in the back of the mouse, there is an advantage that the organ of the mouse is not damaged compared to the case where the microchip is embedded in the abdominal cavity of the mouse.
It is preferable that the back portion is between at least one muscle selected from trapezius, latissimus dorsi, superficial gluteus dorsi and standing spine and trunk skin muscles. When a microchip is embedded in the body of the mouse, the microchip is difficult to move in the body, and the action potential of the myocardium can be detected in a stable state, and heart information can be accurately measured. It is.

(Example)
Using a commercially available implanter equipped with an insertion needle between the trapezius muscle and trunk skin muscle of a mouse, using a microchip having an electrode which is a device for measuring cardiac information schematically shown in FIG. The electrical signal obtained from the embedded microchip was processed using an analyzer with the system shown in the schematic configuration of FIG. 1, and the electrocardiogram with high measurement accuracy shown in FIG. 4 was obtained. The heart rate could also be measured with high accuracy.

(Comparative example)
The same microchip as in the above example was embedded in the abdominal cavity of a mouse, and the electrical signal obtained from the microchip was processed using the same system as in the above example. Could not do.

In this way, when the heart information is measured by embedding a microchip between the back of the mouse, especially between the trapezius and trunk skin muscles, it is normally raised without disturbing daily behavior It was confirmed that heart information such as accurate electrocardiogram and heart rate of the mouse in the state can be measured. In addition, instead of between the trapezius muscle and the trunk skin muscle, the microchip is used between the latissimus dorsi muscle and the trunk skin muscle, between the shallow gluteus muscle and the trunk skin muscle, the erection spine muscle and the trunk skin muscle. When the heart information such as the electrocardiogram and the heart rate is measured by the same in-vivo information measuring method as in the above embodiment, accurate heart information can be obtained continuously as in the above embodiment. I was able to. Moreover, the same result was able to be obtained even if it conducted the same experiment using the rat instead of the mouse.
In contrast, when the microchip is embedded in the abdominal cavity near the heart of a mouse, where the myocardial action potential is presumed to be easily measured, signals from action potentials of organs other than the heart, such as the lungs and digestive organs, and the diaphragm As a result, it was found that the obtained heart information has a large variation and accurate heart information cannot be measured. Furthermore, if the microchip is embedded in the abdominal cavity of a mouse, not only the internal organs of the mouse may be damaged, but the microchip may move in the body, and the position of the microchip embedded in the body It was found that there was a problem that the data obtained depending on the direction.

  The present invention provides a method for measuring in-vivo information capable of accurately measuring in-vivo information of a mouse or rat in a normally bred state (awake state) without inhibiting daily behavior, and the in-vivo information. This is effective in that a mouse or rat that can be measured can be provided.

It is explanatory drawing of one aspect of the measuring method of the in-vivo information of the mouse | mouth or rat of this invention. It is explanatory drawing of the other aspect of the measuring method of the in-vivo information of the mouse | mouth or rat of this invention. It is explanatory drawing which shows schematic structure of the one aspect | mode of a microchip. It is the electrocardiogram measured with the measuring method of the in-vivo information of the mouse | mouth of this invention in an Example.

Explanation of symbols

1 Microchip 2 Electrode (device)
3 Temperature sensor (device)
4 Signal transmission / reception antenna and energy supply antenna (transmission means)
5 Capacitor 6 Circuit 7 Board 8 Measuring Instrument 9 Application System 10 Server System 11 Mouse 12 Probe 13 Tubular Probe 14 Cage

Claims (8)

  A microchip having at least a device for detecting in-vivo information and a transmitting means for transmitting in-vivo information detected by the device to the outside wirelessly is embedded in the body of a mouse or rat, and the microchip is A method for measuring in-vivo information of a mouse or rat by analyzing transmitted in-vivo information with an analyzer provided outside, wherein the microchip is embedded in the back of the mouse or rat.   The measurement method according to claim 1, wherein the in-vivo information is at least heart information.   The measurement method according to claim 1 or 2, wherein the back portion is between at least one muscle selected from trapezius, latissimus dorsi, superficial gluteus dorsi, and standing spine muscle and trunk cutaneous muscle.   The measurement method according to claim 1, wherein the mouse or rat is a transgenic mouse or a transgenic rat.   The in-vivo information transmitted from the microchip is received by a cylindrical probe of a size that allows mouse or rat to enter, and is received when the mouse or rat enters the cylindrical probe and then transmitted to the analysis device for analysis. The measuring method according to claim 1, wherein:   A mouse or rat comprising a microchip including at least a device for detecting in-vivo information and a transmitting means for transmitting in-vivo information detected by the device to the outside wirelessly.   The mouse or rat according to claim 6, wherein the device is a device for detecting at least cardiac information.   The mouse or rat according to claim 6 or 7, wherein the back part is between at least one muscle selected from trapezius, latissimus dorsi, superficial gluteus dorsi, and standing spine muscle and trunk cutaneous muscle.