JP2016189760A - Environment control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an environment control device for controlling a rearing environment of laboratory animals.SOLUTION: The environment control device includes an air blower and a temperature regulator for each rearing cage. Further the environment control device includes one or multiple of a humidity regulator, a light quantity regulator, an introduced fresh air filter, and an exhausted inside air filter. The environment control device also includes a communication function so as to improve accuracy and efficiency of animal tests.SELECTED DRAWING: Figure 1

Description

  The present invention relates to environmental control of animal breeding, particularly small animal breeding.

In animal experiments, ammonia, such as bacteria and excrement of laboratory animals, affects laboratory animals, and as a result, affects the accuracy of experiments, as well as humans performing experiments. Therefore, the air cleanliness in the laboratory as well as in the cage (raft) for breeding laboratory animals is very important.
Therefore, a plurality of cages for animal experiments are generally arranged in a closed rack having a centralized intake / exhaust function, and are managed so that the inside of the cage is always kept clean.

As prior art, a cage is arranged so that the inside of the cage is cleaned in a room in which temperature and airflow are controlled, such as Japanese Patent Application Laid-Open No. 08-140515 and Japanese Utility Model Application Laid-Open No. 07-039398, or Japanese Patent Application Laid-Open No. 08-242718. Some filters are designed to block dust inside and outside the cage.
There is also a method to improve workability and controllability of air flow in individual cages like NEXGEN at http://www.allentowninc.com/.

Japanese Patent Laid-Open No. 08-140515 Japanese Utility Model Publication No. 07-039398 Japanese Patent Laid-Open No. 08-242718

http://www.allentowninc.com/ Translation of "Guidelines for the management and use of laboratory animals" Translation: Naoko Kagiyama, Kazuo Owada, Satoshi Kunida, Takatoshi Kuhara, Tsutomu Kurosawa ISBN 978-4-904419-23-6 “Mouse / Rat's Q & A” Nakagama Sai, Kitada Kazuhiro, Shiroishi Toshihiko ISBN 978-4-7581-0715-0

In the accuracy and reproducibility of animal experiments, the air cleanliness is important as described above, but the breeding environment is required to be in a certain condition. Depending on the type of experimental animal, for example, the temperature is required to be minimal within a range of 16 to 29 degrees Celsius and a relative humidity of 30 to 70% (translation: Naoko Kagiyama, Kazuo Owada, Satoshi Kunida, Takatoshi Kuhara and Tsutomu Kurosawa “Guidelines for the management and use of experimental animals” ISBN 978-4-904419-23-6).

In addition, there is a standard for ventilation conditions, and it is required that the number of ventilations per hour is 8 times or more and the flow velocity is 0.2 m or less per second (Nakagama Sai, Kazuhiro Kitada, Toshihiko Shiroishi "Q & A about mouse / rat" ISBN 978-4-7581-0715-0). In order to cope with such a standard, for example, there is a method for eliminating a non-uniform air volume generated by concentrated exhaust, as shown in Japanese Utility Model Laid-Open No. 07-039398.

However, the conventional system requires a complicated design that makes the air flow uniform according to the rack shape, etc., and the airflow in each cage is strictly controlled. There is no way to confirm. In addition, since a complicated flow path for intake and exhaust is required, the equipment tends to be large. On the other hand, in terms of temperature, there is a temperature difference between a cage close to the fan and a cage far from the fan. In addition, the calorific value varies depending on the number of breeds of each cage and the type of experimental animal, and it is impossible to precisely control the whole by centralized intake / exhaust management. Furthermore, it is necessary to control the temperature of the room and the entire rack, resulting in poor energy efficiency.

Therefore, the present inventor made the present invention in order to solve these problems.

The environmental control device of the present invention
“It controls the environment of the animal containment space (the space that contains animals)
The animal storage space is equipped with a blower and a temperature controller,
It is possible to control the temperature in the animal storage space, introduce outside air into the animal storage space, or discharge the inside air from the animal storage space. ''
It is characterized by that.

In addition, the environmental control apparatus of the present invention
“One or more of a humidity controller, a light amount controller, an introduced outside air filter, and a discharged inside air filter are further provided.”
It is characterized by that.

Furthermore, the environmental control apparatus of the present invention is
“A) Operating sound is 60 dB or less, B) Temperature control range is 18 to 28 degrees Celsius, C) Humidity control range is 30 to 70% relative humidity, D) Light quantity control range is 150 to illuminance. E) satisfying one or more of conditions A to E of 300 lux, E) The wind speed in the animal housing space is 0.2 m or less per second, and the exchange of the inside air in one hour is eight or more times "
It is characterized by that.

The environmental control device of the present invention
"The temperature controller is a thermoelectric element"
It is characterized by that.

In addition, the environmental control apparatus of the present invention
"For pets or animal animals"
It is characterized by that.

Furthermore, the environmental control apparatus of the present invention is
"Has a communication function"
It is characterized by that.

The environmental control device of the present invention
"Powered wirelessly"
It is characterized by that.

In addition, the environmental control apparatus of the present invention
"For animals for animal experiments and has a function of controlling a device attached to a laboratory animal"
It is characterized by that.

According to the present invention, it is possible to perform environmental control with high accuracy for each animal cage.

It is a conceptual diagram of this invention. It is a figure explaining the condition which introduces cold wind to a cage. It is a figure explaining the condition which introduces warm air to a cage.

Hereinafter, in describing the present invention, it is assumed that a mouse is assumed as an animal experimental animal and that the mouse is applied to breeding and experiments.

FIG. 1 illustrates the basic concept of the present invention.
The cage (Cage) is a space for accommodating animals for animal experiments, and the animal accommodating space in the claims corresponds to this.
In FIG. 1, since it is simply shown as a conceptual diagram for easy understanding, there is only one mouse in the cage, but in reality, multiple mice may be accommodated in one cage.

In order to introduce air into the cage from the outside, a blower is provided. The blower introduces outside air from the outside of a room with a cage (for example, a laboratory or a breeding room) and sends it into the cage.
The outside air sent out from the blower is sent into the cage through the temperature controller. The temperature controller is configured by, for example, a thermoelectric conversion element (TED).

The blower and the temperature controller are controlled by a controller. The control unit communicates with the control terminal (Host). An instruction (Control Command) is transmitted from the control terminal to the control unit, and data (Measurement data) measured by a measuring device (not shown) is transmitted from the control unit to the control terminal. For these communications, USB, RS-232C, GP-IB, which are wired data communication schemes, and WiFi, Bluetooth (registered trademark), ZigBee (registered trademark), which are wireless data communication schemes, can be used. However, there is no particular limitation.
The measuring device measures the cage environment. For example, temperature, humidity, illuminance, volume, outside air introduction (ventilation) flow rate in the cage, and the like.

Data (environment data) measured for the environment in these cages is accumulated in a storage device (not shown) provided in the control unit. When a certain amount of environmental data is stored in the storage device, the environmental data is transmitted from the control unit to the control terminal. Alternatively, the environmental data is transmitted at regular time intervals, or if there is a request from the control terminal even before a predetermined amount of data is accumulated, the environmental data accumulated at that time is transmitted to the control terminal. With this configuration, it is possible to operate independently and continuously to save power for a certain period of time, and it is possible to monitor the state of the cage from the control terminal in real time.
This environmental data is treated as a time-series log, and is important for verifying the relationship between the experimental animal environment and the experimental results. In particular, in precise animal experiments where minute differences occur, the certainty of the experimental results can be supported by environmental data.

With this configuration, environmental control can be performed even with one cage. It is also possible to perform parallel control by providing a plurality of cages. The number of cages can be increased up to the maximum number that can be managed by the control terminal, and parallel control can be performed independently.

FIG. 2 is a view for explaining the introduction of air into the cage.
First, fresh air is sent to a temperature regulator by a blower. As described above, the temperature regulator is constituted by a thermoelectric conversion element (TED). In the thermoelectric conversion element, heating and cooling can be set reversibly by applying a voltage.

For example, when it is determined by the measuring instrument described above that the temperature in the cage (Cage) is higher than a certain level and cooling is necessary, the controller (Controller) causes the thermoelectric conversion element to “air introduced into the cage”. The voltage is set so that “is cooled”.
As a result, cool air (Cool Fresh Air) is supplied into the cage, and the temperature in the cage can be lowered. At this time, heating is simultaneously generated in the thermoelectric conversion element. The heat generated here is discarded to the outside as heat exhaust (Hot Exhaust).

FIG. 3 is substantially the same as FIG. 2, except that it is warm air that is introduced into the cage.
First, fresh air is sent to a temperature regulator by a blower. The temperature regulator is composed of a thermoelectric conversion element (TED), and the thermoelectric conversion element can be reversibly set by heating and cooling by applying a voltage as described above.

When it is determined by the above-described measuring device that the temperature in the cage (Cage) is below a certain level and heating is necessary, the controller (Controller) causes the thermoelectric conversion element to “heat the air introduced into the cage. The voltage is set to
As a result, warm air (Warm Fresh Air) is supplied into the cage, and the temperature in the cage can be raised. At this time, the thermoelectric conversion element is also cooled at the same time. The cold air generated here is discarded as cold exhaust (Cold Exhaust).

In this way, the temperature in the cage can be controlled within an arbitrary range by switching the temperature of the outside air introduced while measuring the temperature in the cage.

When introducing the outside air, dust or microorganisms may be mixed in the gas. Therefore, it is preferable to provide a filter (filter) at the outside air intake of the blower.
Similarly, since things that have an unfavorable effect on the surroundings, such as mouse excreta, are accumulated in the cage, it is more preferable that a filter is provided in the cage outlet (not shown) as well.

In addition, a humidity measuring device / humidity adjusting device, illuminance measuring device / light quantity adjusting device, volume measuring device, etc. (not shown) may be additionally provided and operated in a linked manner.
By adopting this configuration, it is possible to maintain the environment so as to satisfy the conditions described in the claims, and set the environment under the conditions described in Non-Patent Document 2 and Non-Patent Document 3 described above. Easy to do.

Moreover, you may make it communicate wirelessly between the above-mentioned control part and control terminal.
When this configuration is adopted, it is not necessary to connect a communication line for each cage, and the constraint conditions for the installation of the cage are relaxed. Specifically, if the communication line is constantly connected, the communication line that can be connected at the same time will not be restricted. If the communication line is connected as necessary, the man-hour for connecting the communication line Can be reduced.

In addition, from the viewpoint that the cable connection operation may cause anxiety to the mouse in the cage (unpleasant vibration at the time of connection or the cable that crawls around the cage is misrecognized by a specific creature such as a snake) Wireless communication is suitable for improving the accuracy of animal experiments.

Furthermore, the power consumed by the cage (necessary for the control unit, blower, thermoelectric conversion element, various measuring devices, and various regulators) may be wirelessly fed. This further relaxes the constraints on cage installation and allows the cage to be moved while the cage is operating in a space within the power supply range, thereby improving the efficiency of animal experiments. Is possible.

In addition, when the experimental device is mounted on the mouse in the cage, it is particularly preferable that the experimental device can be controlled from the control unit of the cage. For example, when experimenting with a new drug using a wearable drug solution injection device, especially when injecting a very small amount of drug solution intermittently for a long time, there is a boundary between the breeding of mice (life) and the experiment. When it is not possible to divide clearly and a similar experiment is performed on a large number of mice, it is practically impossible for a human to inject a very small amount of a chemical solution manually.

In that respect, according to the above-described method, the mouse can conduct the experiment while sending the usual breeding (life). Humans only need to perform chemical replenishment work when the remaining amount of chemicals in the infusion device is low, and it is possible to significantly reduce the number of man-hours for animal experiments and to eliminate the introduction of errors due to manual labor. A significant improvement in the accuracy of the results can be expected at the same time.

More preferably, the power supply of the wearable experimental apparatus is also used as a wireless power supply for the power consumption of the cage. Similarly, it is more preferable that communication between the wearable experimental apparatus and the cage control unit is performed wirelessly. By adopting this configuration, no cable-like wired objects are connected to the cage, and it can be handled as a completely independent individual cage, dramatically increasing the degree of freedom in installation and movement. To do.

Moreover, the cage by the environmental control apparatus of this invention produces the further secondary effect. For example, since environmental control is possible for each cage, a plurality of environmental tests can be performed in a short time by simultaneously operating a plurality of cages having different environment settings.

In addition, it becomes possible to detect the mutual influence of cages. For example, when an experimental animal becomes an unexpected abnormal state (abnormal behavior, abnormal vocalization, incontinence, etc.), it is inevitable that the experimental animal in a neighboring cage is affected. In such a state, by controlling the introduction of a sedative such as anesthetic gas into the cage, the abnormal experimental animal can be eased and the influence on other experimental animals can be eliminated. .

Up to this point, the description has been given assuming a mouse as an animal, but the present invention is not limited to this. Other animals such as rabbits, guinea pigs and rats may be used. In addition, it can be applied to the growth and experiment of microorganisms and plants.

In addition, the present invention has been described above assuming an animal for animal experiments. However, the present invention is not limited to this. It can also be used for the treatment, breeding and breeding of pet animals and pet hotels (temporary underwriting for pet animals).

The present invention has been described with reference to preferred embodiments. However, the present invention is not limited to these embodiments, and many modifications can be made without departing from the spirit of the invention. Of course.

Cage environmental control can be performed using a mass-produced blower and a temperature controller, which has the effect of improving the efficiency of work such as animal experiments.

Claims (8)

An apparatus for controlling the environment of an animal storage space (space for storing animals),
The animal housing space is provided with a blower and a temperature controller,
Temperature control in the animal storage space, introduction of outside air into the animal storage space or discharge of internal air from the animal storage space is possible.
An environmental control device characterized by that. 2. The environmental control apparatus according to claim 1, further comprising one or more of a humidity controller, a light amount controller, an introduced outside air filter, and a discharged inside air filter. apparatus. The environment control device according to claim 2,
A) Operating sound is 60 dB or less B) Temperature control range is 18 to 28 degrees Celsius C) Humidity control range is 30 to 70% relative humidity D) Light quantity control range is 150 to 300 lux in illuminance E) An environment satisfying one or more of the conditions A to E in which the wind speed in the animal housing space is 0.2 m or less per second and the exchange of the inside air within one hour is eight or more times Control device. The environmental control device according to claim 1, wherein the temperature controller is a thermoelectric element. 5. The environment control apparatus according to claim 1, wherein the environment control apparatus is for a pet animal or animal experiment animal. 6. The environment control apparatus according to claim 5, wherein the environment control apparatus has a communication function. The environment control device according to claim 6, wherein power is supplied wirelessly. 8. The environment control device for animal experimental animals according to claim 7, wherein the environment control device has a function of controlling a device to be attached to the laboratory animal.