JPH0430522Y2 - - Google Patents

Description

[Detailed description of the invention] (Industrial application field) This invention is an experimental device used for pharmacological experiments and toxicity experiments using animals such as mice and rats, especially for the in-vivo metabolic process of chemical substances and metabolites. This paper relates to a small animal metabolic experiment device for collecting metabolites in the exhaled breath of animals in order to investigate the dynamics of

(Prior Art) In order to calculate the balance of metabolites, it is necessary to separate, collect, and track the components excreted in the feces, urine, and breath of experimental animals.

Therefore, conventionally, experimental animals are housed in sealed cages and their feces, urine, and exhaled air are separated and collected (refer to Utility Model Publication No. 43011/1983). .

Although this method has definitely succeeded in separating and collecting feces and urine, the amount of sample collected for metabolites in exhaled breath is extremely small, so there are unresolved issues in collecting the entire amount. It was hot.

Therefore, the present inventor attempted to develop the device shown in FIG. 4 in an attempt to solve the above problem. This device (unpublished) is configured as follows. That is,
In Fig. 4, reference numeral 1 denotes a closed cage in which experimental animals are housed, and although cage 1 is not shown, it is equipped with a feeding section and a water supply section, and is also equipped with a mechanism for separately collecting feces and urine excreted by the animals. It is composed of Reference numeral 2 denotes an air pump, and the pump 2 is constructed by integrally forming an air supply pump 2a and an intake pump 2b in a double-barrel type. Reference numeral 3 denotes an air supply passage whose one end is connected to the upper end of the cage 1 and the other end is connected to the air supply pump 2a, and the gas (air) sent by the air supply pump 2a passes through the air supply passage 3 to the cage 1. be introduced within. Reference numeral 4 denotes a flow meter interposed in the air supply passage, which is equipped with a needle valve 4a, and is used to adjust the flow rate of air sent into the cage. Reference numeral 5 denotes a removal absorption bottle which is interposed in the air supply passage 3 between the flow meter 4 and the cage 1, and which absorbs and removes carbon dioxide in the air passing through the air supply passage 3 in advance. It contains an absorbent such as caustic soda. The carbon dioxide gas in the air supplied by the air pump 2a is absorbed and removed by an absorbent while passing through the absorption bottle 5, and is removed from the cage 1.
be introduced within.

Reference numeral 6 denotes an exhaust passage whose one end is connected to the lower end of the cage 1 and the other end is connected to the intake pump 2b, and the gas inside the cage 1 is sucked by the pump 2b through the exhaust passage 6 and discharged to the outside. It's becoming like that. Reference numeral 7 denotes a flow meter interposed in the exhaust passage 6, which is equipped with a needle valve 7a, and the flow meter 7 adjusts the flow rate of gas sucked from the cage 1. Reference numeral 8 denotes a sampling absorption bottle which is interposed in the exhaust passage 6 between the flow meter 7 and the cage 1 and which absorbs and collects metabolites in exhaled gas passing through the exhaust passage 6. The absorption bottle 8 contains an absorption liquid. (for example,
(monoethanolamine, etc.) is encapsulated. Metabolites in exhaled breath (such as carbon dioxide gas in exhaled breath) in the air sucked by the intake pump 2b are absorbed into the absorption liquid while passing through the collection absorption bottle 8,
collected.

Next, the method of use and operation of the above device will be explained. Experimental animals are housed in cage 1. Then, while driving the pump 2, the flow meter 4,
7, the intake air amount and exhaust air amount are adjusted to the same amount by operating the valves 4a and 7a. As a result, the amount of supply air sent into the cage 1 from the air supply pump 2a and the intake pump 2b
Therefore, the amount of exhaust gas absorbed from inside the cage 1 becomes the same amount. On the other hand, since the carbon dioxide in the gas (air) sent into the cage 1 from the air pump 2a has been removed in advance in the removal absorption bottle 5, the carbon dioxide is absorbed into the absorption liquid in the absorption bottle 8. gas is cage 1
Only those excreted in the exhaled air of animals inside the house are included.

(Problems to be solved by the invention) According to the above-mentioned device, it becomes possible to collect metabolites in exhaled breath of animals.

However, the above device has the following problems. That is, monoethanolamine (solution), which is commonly used as the above-mentioned absorbent, has the property of gradually increasing its viscosity as it absorbs water. Therefore, this monoethanolamine gradually increases in viscosity due to absorption of moisture-containing metabolites in exhaled breath, and gas permeability deteriorates in proportion to this viscosity. Therefore, initially the amount of air supplied to cage 1 and the amount of air exhausted from cage 1 were the same amount, that is, 100:100, but as time passes, the balance collapses and the amount of air exhausted gradually becomes smaller. As a result, the pressure inside the cage 1 gradually increases.

By the way, in this type of animal experiment, it is important to maintain the natural state as much as possible without stressing the experimental animal. As the pressure gradually increases, it not only causes negative effects such as stress on the animal, but also causes the pressure inside the cage to rise too much, causing gas to leak from the cage to the outside, making it impossible to collect all of the valuable exhaled breath sample into the absorption liquid. It disappears.

Therefore, one idea to solve the above problem is to use a sensor to constantly detect the pressure inside the cage 1 or the viscosity of the absorbent, and to adjust the suction pump in proportion to changes in the pressure or the viscosity of the absorbent. A method of automatically controlling the output so as to increase the displacement of 2b may be considered, but this method would make the device too large and increase the cost.

The present invention was devised in view of the above circumstances.

(Means for solving the problems) The present invention solves the above problems, and includes:
The contents of the invention will be explained below using FIGS. 1 to 3 corresponding to the embodiment.
an air supply passage 25 connected to the air supply passage 25; and an air supply pump 26 connected to the other end of the air supply passage 25 to supply gas (air) into the cage 11 through the air supply passage 25.
a, an exhaust passage 27 whose one end is connected to the cage 11, an intake pump 26b which is connected to the other end of the exhaust passage 27 and absorbs gas in the cage 11 through the exhaust passage 27, and the air supply passage 25. A removal absorption bottle 30 is inserted therein and absorbs and removes carbon dioxide from the gas sent into the cage 11.
, a collection absorption bottle 31 which is interposed in the exhaust passage 27 and which absorbs and collects exhaled metabolites in the gas absorbed from the cage 11 , and a removal absorption bottle from the air supply passage 25 . 30 and the above cage 11
It is characterized by comprising a relief valve 32 for adjusting a slight pressure difference, which is interposed in the air supply passage 25 between the air supply passages 25 and 25.

(Function) If the air supply and exhaust amounts by the air supply pump and the air supply pump are adjusted to the same amount and the pumps are driven, the amount of air supplied into the cage and the amount of air exhausted from the cage will be the same, so While the pressure inside the cage is maintained at the same pressure as the outside air pressure, the metabolites in the animal's breath are absorbed into the collection absorption bottle. As the moisture in exhaled breath is absorbed, the absorbent in the bottle gradually increases in viscosity, and gas permeability deteriorates in proportion to this viscosity. Therefore, the balance between the air supply amount and the exhaust amount is lost, and the exhaust amount gradually becomes smaller, and as a result, the inside of the cage becomes pressurized. When the inside of the cage becomes pressurized, the pressure inside the air supply passage will inevitably increase, so this pressure will act on the relief valve and open it, allowing the excess pressure to escape to the outside. The pressure also decreases and becomes the same as the outside pressure. In this way, the amount of supplied air is released to the outside and reduced by an amount commensurate with the reduction in the displacement amount, and as a result, the inside of the cage is always maintained at the same pressure as the outside air pressure.

(Embodiments) Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIGS. 1 to 3 show an experimental apparatus for small animal metabolism, etc., showing one embodiment of the present invention. In these figures, numeral 11 is a closed cage in which experimental animals such as mice and rats are housed and reared, and is made of transparent glass or plastic, and numeral 12 is a removably attached cage at the top opening of cage 11. It is a closed lid. The bottom of the cage 11 is formed into a funnel 13 shape. Reference numeral 14 denotes a bar-shaped stage formed in a grid shape, etc. The stage 14 is placed inside the cage 11 and placed above the funnel 13, and the experimental animal is housed on the stage 14. 15 is a conical spreader fixed to the center of the lower part of the stage 14, 16 is a manure separator attached to the lower end of the funnel 13, 17 is a feces collection bottle, and 18 is a urine collection bottle, in which the feces and urine excreted by the experimental animals are collected. stage 1
4 into the funnel 13, is spread by the spreader 5 and hits the inclined wall of the funnel 13,
Urine and feces are separated by a separator 16, and the urine and feces are collected into a urine collection bottle 18 and a feces collection bottle 17, respectively. 19 is a cooling bath, and 20 is a circulator, which is used to cool the excrement and urine in both the bins 17 and 18.

21 is a water supply section, and 22 is a feeding section, which is used to feed and water the animals in the cage 11.

Reference numeral 23 designates a liquid manometer whose lower end is connected to the airtight lid 12 of the cage 11. The upper end of the manometer 23 is open to the atmosphere and there is a U in the middle part.
A character portion 24 is formed. This manometer 23
is for detecting a change in the pressure inside the cage 11 based on the displacement of the liquid level in the U-shaped portion 24, that is, a state of equal pressure, negative pressure, or positive pressure with the external pressure.

Reference numeral 25 denotes an air supply passage whose one end is connected to the upper end of the cage 11, and 26 is an air pump. The pump 26 of the embodiment is constructed by integrating an air supply pump 26a and an intake pump 26b into a double unit. The other end of the air supply passage 25 is connected to an air supply pump 26a, and the gas (air) sent by the air supply pump 26a is configured to be introduced into the cage 11 through the air supply passage 25. be.

27 is an exhaust passage whose one end is connected to the lower end side of the cage 11, and the other end of the exhaust passage 27 is connected to the intake pump 26.
b, and is configured to suck the gas inside the cage 11 through the exhaust passage 27 by the suction pump 26b and discharge it to the outside of the pump 26b.

In the above case, the pump 26 includes an air supply pump 26a and an intake pump 26b as in the embodiment.
Instead of integrating the gas into a dual system, two separate pumps are used, one pump supplies gas into the cage 11, and the other pump supplies gas into the cage 11.
The configuration may be such that gas is sucked in and exhausted from the air. Furthermore, in the embodiment, one end of the air supply passage 25 is connected to the upper end of the cage 11, and one end of the exhaust passage 27 is connected to the lower end of the cage 11.
The connection positions of 5 and 27 to the cage 11 are basically the same even if they are reversed.

Reference numeral 28 denotes a flow meter that is equipped with a needle valve 28a and is interposed in the air supply passage 25, and is configured to adjust the flow rate of gas (air) supplied into the cage 11 by operating the valve 28a of the flow meter 28. has been done. Reference numeral 29 denotes a flow meter provided with a needle valve 29a and interposed in the exhaust passage 27. The flow meter 29 is configured to adjust the flow rate of gas sucked from the cage 11 by operating the valve 29a of the flow meter 29.

30 is interposed in the air supply passage 25 between the flow meter 28 and the cage 11, and is connected to the cage 1.
A removal absorption bottle 30a that absorbs and removes carbon dioxide from gas (air) sent into the trap 1, and in the embodiment, an absorption bottle 30a filled with caustic soda and an empty trap 3 are used.
Three absorption bottles 30c filled with 0b and soda lime are used, and each absorption bottle 30a, 30b, 3
While the gas (air) passes through 0c, carbon dioxide gas in the gas (air) is completely absorbed and removed. Note that the number of absorption bottles 30 can be increased or decreased as desired.

31 is interposed in the exhaust passage 27 between the flow meter 29 and the cage 11, and
1. In the embodiment, an absorption bottle 31a filled with monoethanolamine (solution) and two empty traps 31b and 31c are used. is used, and while the gas passes through the absorption bottle 31a, metabolites in exhaled breath in the gas are completely absorbed into an absorbent (monoethanolamine) and collected. In addition, also in this case, the number of absorption bottles 31 can be increased or decreased arbitrarily.

32 is interposed in the air supply passage 25 between the removal trap 30c of the air supply passage 25 and the cage 11 to allow gas to pass from the air supply passage 25 to the outside (outside the closed system). This relief valve 32 is a relief valve for adjusting a slight differential pressure.
It acts when the pressure inside the air supply passage 25 becomes slightly higher than the outside pressure, and releases the gas (pressure) inside the passage 25 to the outside to maintain the pressure inside the air supply passage 25 and the outside pressure at a constant pressure. It is configured. As shown in FIG. 2, the relief valve 32 of the embodiment has a fitting tube 33 protruding from the air supply passage 25, and the fitting tube 33 has a valve hole 3.
At the same time as fitting the valve pipe 34 which opened 5, the valve pipe 34
A valve plate 36a made of a thin rubber plate and a valve plate 36b made of thin water-absorbing paper are placed inside the valve plate 36a, 3.
A general-purpose check valve is used in which the valve 6b is held down by a holding piece 37. Therefore, the air supply passage 25
When the pressure inside the passage 25 is the same as atmospheric pressure, the valve hole 35 is closed by the valve plates 36a and 36b as shown in FIG. , the pressure inside the passage 25 acts to press the valve plates 36a and 36b, as shown in FIG.
The valve hole 35 is opened to release the pressure to the outside, and when the pressure inside the air supply passage 25 returns to the same pressure as the outside pressure, the valve hole 35 is closed again by the valve plates 36a and 36b.
In this way, the pressure within the air supply passage 25 is maintained at the same pressure as the outside air pressure.

Note that the above-mentioned relief valve 32 may have a structure other than that of the embodiment and may be appropriately selected and employed.

The experimental apparatus of this example was constructed as described above, and its usage and operation will now be explained.

An experimental animal is placed in a cage 11. At this time, since the amount of breath metabolites collected is extremely small, ¹⁴ C (carbon fluorine) is administered to the experimental animals as a labeling compound, if necessary. Then, while driving the pump 26, the flow meters 28, 2
9 to adjust the intake air amount and exhaust air amount to the same amount. As a result, the amount of supplied air sent into the cage 11 from the air supply pump 26a and the amount of exhausted air sucked from inside the cage 11 by the intake pump 26b become the same amount, and therefore the pressure inside the cage 11 is equal to the outside pressure. The pressure becomes the same. On the other hand, the gas (air) sent by the air pump 26a is sent to the absorption bottle 3.
When passing through the cage 11, carbon dioxide gas is absorbed and removed in advance in the absorption liquid, and air is supplied into the cage 11. Furthermore, since the gas in the cage 11 passes through the absorption bottle 31 and is sucked in, the metabolites in the exhaled air in this gas are absorbed into the monoethanolamine solution in the absorption bottle 31a, and the entire amount is collected.

In this way, the amount of air supplied into the cage 11 and the amount of air exhausted from the inside of the cage 11 are set to the same amount, that is,
The metabolites in the exhaled breath of the animal are absorbed into the collection absorption bottle 31 while maintaining the ratio of 100:100. At this time, as the moisture in the exhaled breath is absorbed, the monoethanolamine solution gradually increases in viscosity. Gas permeability deteriorates in proportion to this viscosity. Therefore, the balance between the amount of air supply and the amount of exhaust air is lost, and the amount of exhaust air gradually decreases, and as a result, the inside of the cage 11 becomes pressurized. When the inside of the cage 11 becomes pressurized, the pressure inside the air supply passage 25 also inevitably increases, so this pressure acts on the valve plates 36a and 36b.
is pressed to open the valve hole 35, so that the excess pressure inside the air supply passage 25 is released to the outside, so the pressure inside the air supply passage 25 and the cage 11 communicating with it gradually decreases, and becomes equal to the outside pressure. The pressure becomes the same. In this way, the air supply amount is reduced by an amount commensurate with the reduction in the displacement amount, and as a result, the inside of the cage 11 is always maintained at the same pressure as the outside air pressure.

(Effects of the invention) The invention is configured as described above, and the invention has the following effects.

(a) Metabolites in the breath of experimental animals can be reliably collected without leaking out of the closed system.

(b) Metabolic experiments can be performed on experimental animals in a closed system under normal pressure (atmospheric pressure).

[Brief explanation of the drawing]

Figures 1 to 3 show one embodiment of the experimental device for small animal metabolism, etc. according to the present invention. Figure 1 is an overall schematic layout, and Figure 2 is a longitudinal section showing an example of a relief valve. FIGS. 3A and 3B are explanatory views of the operation of the relief valve, and FIG. 4 is a schematic layout explanatory view showing the device before improvement. 11... Cage, 12... Sealing lid, 25... Air supply passage, 26... Air pump, 26a... Air supply pump, 26b... Intake pump, 27... Exhaust passage, 28, 29... Flow meter , 30... Absorption bottle for removal, 31... Absorption bottle for collection, 32...
Relief valve, 35...valve hole, 36a, 36b...valve plate.

Claims (1)

[Scope of Claim for Utility Model Registration] (1) (a) A closed cage for housing experimental animals, (b) An air supply passage connected to the cage at one end, (c) An air supply passage connected to the other end of the air supply passage. an air supply pump that supplies gas into the cage through an air passage; (d) an exhaust passage whose one end is connected to the cage; A suction pump that sucks in and exhausts it to the outside.
(f) A removal absorption bottle that is installed in the air supply passage and absorbs and removes carbon dioxide from the gas sent into the cage; (g) A removal absorption bottle that is installed in the exhaust passage and that Collection absorption bottle that absorbs and collects exhaled metabolites in the gas that is inhaled,
(H) A small animal metabolic experiment apparatus characterized by comprising an absorption bottle for removing the air supply passage and a relief valve for adjusting a slight pressure difference interposed in the air supply passage between the cages. . (2) The apparatus for experimenting with metabolism, etc. of small animals according to claim 1, wherein the air supply pump and the suction pump are integrated into a double-barrel system. (3) The small animal metabolism experiment apparatus according to claim 1, wherein the air supply pump and the suction pump are constructed separately.