JPH0325598Y2 - - Google Patents

Description

[Detailed Description of the Invention] Technical Field The present invention relates to a culture device for microscopic observation, which is fixedly disposed on the stage of the microscope so that the cultured specimen can be observed under the microscope while kept at an appropriate temperature. .

Prior Art In conventional culture apparatuses for microscopic observation, the culture specimens in the culture observation container are kept warm by blowing warm air into the heat insulation box using a fan to heat the culture observation container and its surroundings. By heating,
It was being done. However, this method has the following drawbacks: (1) Since the indoor air is heated with a heater and then a fan is used to blow warm air into the insulated box, it may be harmful to the culture specimens to be observed. (2) When blowing hot air into the heating box, the response time for the culture specimen to reach the specified temperature is long because the heat capacity of the air is small. When using time-based program control, it takes a very long time and sufficient performance cannot be obtained; (3) Since a fan is used to blow warm air into the insulating box, dust inside the insulating box flies up and sticks to the culture specimens. (4) When using an open culture observation container, water vapor evaporated from the culture solution in the culture observation container will adhere to the inner surface of the insulated box and cause cloudiness, which will hinder observation; It has drawbacks.

Purpose In view of the above points, this invention prevents dust from being introduced into the insulating box through the fan, prevents dust from flying up inside the insulating box, and reduces the response time of temperature control to a predetermined temperature of the culture specimen. To provide a culture device for microscopic observation which has a short length and which prevents clouding on the inner surface of a heat-insulating box even when an open culture observation container is used.

Overview This purpose is to define a first space that surrounds a microscope stage, at least a part of which is configured as a heat generating part, and a culture observation container placed on the top surface of the heat generating part of the stage. a first heat insulating box that is heated, a second heat insulating box defining a second space surrounding the first heat insulating box together with the first heat insulating box, and heating the second space; The present invention is solved by a culture device for microscopic observation, characterized in that it is equipped with a heating means for

Further, preferably, the present apparatus includes a temperature control device for feedback controlling the temperature of the heat generating part by detecting the temperature of the heat generating part of the stage and comparing the detected temperature with a set temperature.

EXAMPLES The present invention will be explained below using examples shown in the drawings. Figure 1 shows an example in which the present invention is applied to an inverted microscope, 1 is an inverted microscope, and 2 is a culture device according to the present invention. It is. This culture device 2 is further shown in detail in FIGS. 2 and 3,
Reference numeral 3 denotes a stage for the microscope 1, which includes a portion 3a configured as a heat generating portion, and a portion 3 to which the portion 3a is removably attached and movable in a direction perpendicular to the plane of the paper.
It has b. Reference numeral 4 designates an airtight first insulating box defining a first space 6 surrounding the culture observation container 5 placed on the top surface of the stage portion 3a; It is composed of a peripheral wall 4a and a lid 4b which are fixedly arranged by screws 7, and the peripheral wall 4b is used for injecting gas such as CO ₂ when a culture specimen to be observed requires gas, for example. The lid 4b has a hole 4c into which the tip of the lens barrel of the condenser lens 9 of the microscope 1 can fit, and whose lower end is closed by a transparent member 10. , a plurality of holes 4d (four in the drawing) each of which can be opened and closed by a lid 11 for injecting a reagent or inserting a temperature sensor, a humidity sensor, etc., and a hole 4d in the lid 4b so as to surround the culture observation container 5. It has a flange portion 4e provided on the lower surface outside the hole 4d, and is configured to slide airtightly against the upper edge of the peripheral wall 4a. 12 is a cord for supplying power to the heat generating part of the stage part 3a, and is connected to the temperature control device 14 via the connector 13; 15 is a temperature sensor disposed on the upper surface of the stage part 3a; The cord is likewise connected to temperature control device 14. Reference numeral 16 denotes an airtight second heat insulation box that defines a second space 17 surrounding the first heat insulation box 4. A peripheral wall 16a is fixedly disposed on the upper surface of the stage portion 3b by fixing with a fastener 18, etc., and a condenser lens 9 of the microscope 1 is fixed to the peripheral wall 16a and located in the center. A lid 16b having a hole that is sufficiently large compared to the diameter of the lens barrel, and a sliding member 16c that is slidably placed on the lid 16b and has a hole in the center into which the condenser lens 9 can fit. The surrounding wall 16a has a tube 2 connected to a hot air fan 19 to blow hot air into the second space 17.
0 as shown in the figure. Note that 22 is an objective lens of the inverted microscope 1, and 23 is an annular water container.

Since the present embodiment is constructed as described above, the culture observation container 5 containing the culture specimen to be observed is first placed on the portion 3a of the stage 3 of the microscope 1, which is configured as a heat generating part. However, in the case of a culture specimen that requires humidity, the water container 23 is filled with water and placed on the stage portion 3a in the same manner. Next, input the set temperature using the temperature control device 14 and set the temperature on the stage 3.
a, the heat generated by the section 3a directly heats the culture observation container 5 containing the culture specimen, and the air in the first warming box 6 is heated by the heat transfer of natural convection, thus allowing the culture to proceed. The specimen is kept warm. At this time, warm air is blown into the second space 17 from the hot air fan 19 via the tube 20,
As a result, the second space 17 is heated, and by heating the first insulating box 4 until its inner surface temperature becomes higher than the air temperature in the first space 6, the culture specimen is heated. Alternatively, the water vapor evaporated from the water in the water container 23 does not condense on the inner surface of the first heat insulation box 4. In addition, since the condenser lens 9 is fitted into the hole 4c of the lid 4b of the first heat-insulating box 4, when the stage 3 is moved, the lid 4b of the first heat-insulating box 4 that moves together with the stage 3 is moved. By sliding against the peripheral wall 4a, its position does not change. Therefore, the hole 4d provided in the lid 4b always faces the focal point on the optical axis as shown in the figure, and even if the stage 3 is moved, reagents can always be injected toward the observation position. However, the holes 4d may be formed in other directions as necessary. In addition, the observation range of the culture specimen is such that when the stage 3 is moved to the limit position as shown in FIG. Since it is locked by the flange portion 4e provided on the stage 3, it moves by a distance l relative to the stage 3. Therefore, if the diameter of the center hole in the part 3a of the stage 3 is A, then φ{A+
2l}.

FIG. 5 shows a second embodiment of the present invention,
Components that are the same as those in the embodiment shown in FIG. The lid 30a is fixed to the peripheral wall 30b and has a hole in the center into which the condenser lens 9 of the microscope 1 can fit, and the lid 30a is fixed to the peripheral wall 30b, and has a hole in the center into which the condenser lens 9 of the microscope 1 can be fitted. A heater 32 is disposed within a second space 31 defined between the two.
The second space 31 is heated in the same way as the second space 17 in the first embodiment by energizing the heater 32.

Effects of the invention As described above, according to the invention, the response time is short because the cultured specimen is directly heated by the mounting stage, and the space surrounding the cultured specimen is sealed, causing harmful Dust is not carried around the cultured specimens, dust inside the insulated box is not stirred up, and therefore no harmful dust is attached to the cultured specimens, and the inner surface of the first insulated box is not clouded. Since it is located on the top surface of the stage, it does not interfere with the conversion of the revolver or the operation of the correction ring of the objective lens. Furthermore, even if the observation position is moved, reagents can always be injected toward the observation position, and a wide observation range can be obtained by changing the relative position of the cultured specimen and the stage. Since reagents are injected and culture specimens are adjusted without opening the lid, the CO ₂ concentration and temperature-controlled air inside the insulated box will not escape, and dust will not enter. Furthermore, in the case of the second embodiment, even if the stage is moved, the insulating box does not move, so the cord of the heater will not be pulled due to movement, and the observation field of view will not be moved inadvertently. Since the second space is heated by the heater, vibrations that may be harmful to the culture specimen do not occur.

[Brief explanation of the drawing]

Fig. 1 is a schematic side view of an inverted microscope to which the present invention is applied, Fig. 2 is a sectional view showing a first embodiment of the culture device according to the present invention, and Fig. 3 is a line taken along the - line of the embodiment of Fig. 2. A cross-sectional view, FIG. 4 is a view similar to FIG. 2 showing a state in which the stage has been moved to the limit position, and FIG. 5 is a view showing a second embodiment of the present invention. 1...Inverted microscope, 2...Culture device, 3...
Loading stand, 4... First heat insulation box, 5... Culture observation container, 6... First space, 7... Screw, 8, 20...
...Tube, 9...Condenser lens, 10...
Transparent member, 11...lid, 12...cord, 13...
... Connector, 14 ... Temperature control device, 15 ... Temperature sensor, 16 ... Second heat insulation box, 17 ... Second space, 18 ... Fastener, 19 ... Warm air fan,
21...Mounting port, 22...Objective lens, 23...
water container.

Claims (1)

[Scope of Claim for Utility Model Registration] (1) A microscope main body, a movable microscope stage whose at least a portion is configured as a heat generating part, and a microscope mounted on the top surface of the heat generating part of the stage. a first heat-insulating box defining a first space surrounding the culture observation container; and a second space surrounding the first heat-insulating box defined together with the first heat-insulating box. 1. A culture device for microscopic observation, comprising: a second heat-insulating box; and heating means for heating the second space. (2) The culture device for microscopic observation according to claim 1 of the utility model registration, characterized in that the second heat-insulating box is detachably fixed to the microscope body.