JP5563637B2 - Automatic bacteria test method - Google Patents

Description

  The present invention relates to an automatic bacteria testing apparatus and method capable of automatically testing various bacteria, particularly general bacteria and E. coli.

Bacteria tests (general bacteria, E. coli) performed in tap water, well water, pool water, etc. are all performed manually. Conventionally used methods for testing general bacteria and methods for testing E. coli are shown below.
First, the inspection method of general bacteria is performed in the following procedures.
(1) Place the sampling bottles on a sterilized desk.
(2) Write the sample identification number on the lid of the sampling bottle.
(3) Place the sterilized petri dish in front of the sampling bottle arranged on the desk.
(4) Write the sample identification number on the petri dish.
(5) Place the sterilized chip on the sample dispenser, open the lid of the sample collection bottle, take 1 mL of the sample with the sample dispenser, and put it in the petri dish.
(6) Put a sterilized medium (about 45 ° C) in a petri dish.
(7) Stir the petri dish to mix the sample and the medium.
(8) Leave until the medium is solidified.
(9) After the medium has hardened, invert the petri dish.
(10) Place the inverted petri dish in a 36 ° C. incubator and culture.
(11) After 22-24 hours, remove from the incubator and count the number of bacteria.

On the other hand, the inspection method of E. coli is performed according to the following procedure.
(1) Place the sampling bottles on a sterilized desk.
(2) Write the sample identification number on the lid of the sampling bottle.
(3) Write the sample identification number in the E. coli test container that already contains the E. coli test medium.
(4) Place 100 mL of the sample in the sampling bottle into a container dedicated for E. coli testing.
(5) Place in a 36 ° C. incubator and incubate.
(6) After 24 hours, take out from the incubator, apply ultraviolet light, and determine whether E. coli is detected or not based on the presence or absence of fluorescence.

However, the above-described conventional inspection method has the following problems.
(1) Since it is manual work, it has a great deal of time and labor.
(2) Since it is a manual work, the sample may be exogenously contaminated (bacteria present in the air fall on the culture medium or petri dish, or bacteria that humans have attached), and the analysis cannot be performed with high accuracy. There is.
(3) A human error may occur due to a sample mistake by a person or an incorrect entry of a sample identification number.
(4) An analysis error occurs by a person.
(5) It is not performed by a certain analysis method.

  On the other hand, a method for detecting bacteria using an adsorbent capable of specifically adsorbing to bacteria has also been proposed (Patent Document 1).

JP 2002-125695 A

  An object of the present invention is to automatically and efficiently test a plurality of types of bacteria (for example, bacterial tests (general bacteria and E. coli) performed in tap water, well water, pool water, etc.). Another object of the present invention is to provide an automatic bacteria testing apparatus and method capable of testing without human error.

The invention according to claim 1 is a sample sample container storage chamber storing a plurality of sample sample bottles with screw caps each storing a sample sample, and a part of the sample sample taken out from the sample sample container storage chamber. A first bacterial culture device for culturing Escherichia coli having a first bacterial culture medium injecting section for injecting a first bacterial culture medium into the sample specimen bottle taken out, and a first bacterial culture section;
Bacterial culture container storage chamber storing a plurality of empty bacterial culture petri dishes, and a second bacterial sample specimen injection for injecting a second bacterial sample specimen into the bacterial culture petri dish taken out of the bacterial culture container storage chamber and parts, it comprises a second bacteria culture media injection unit for injecting a second bacteria culture media to the bacterial culture in a petri dish, a second bacterial culture apparatus for culturing common bacteria and a second bacterial culture unit a bacterial culture device,
Before injecting the first bacterial culture medium into the sample specimen bottle, a part of the sample specimen is taken out from the sample specimen bottle, and a part of the sample specimen is used as the second bacterial sample specimen in the petri dish for bacterial culture. It is equipped with a mechanism for taking out and injecting some sample specimens,
The partial sample specimen extraction / injection mechanism opens the sample specimen bottle before taking out a part of the sample specimen, and after injecting the first bacterial culture medium into the sample specimen bottle from which the sample specimen has been taken out, A lid opening / closing mechanism for closing the sample specimen bottle is provided,
The lid opening / closing mechanism includes: a container mounting table on which an upper surface of the sample specimen bottle can be mounted; a lid gripping tool that is disposed above the container mounting table and grips and fixes the lid of the sample specimen bottle; Bacterial culture apparatus having a container body rotating mechanism that rotates with respect to the lid gripping tool together with the container mounting table
A bacterial test method for detecting bacteria after culturing bacteria using
Bacteria culture using the bacterial culture apparatus,
A culture medium for first bacteria is injected into the sample specimen bottle taken out from the specimen specimen container storage chamber containing a plurality of specimen specimen bottles with screw caps each containing a specimen specimen, and the first bacteria composed of Escherichia coli are cultured. A first bacterial culture step;
A sample specimen for the second bacteria is injected into the petri dish for bacterial culture taken out from the container chamber for storing the bacterial culture containing a plurality of empty bacterial culture dishes, and the second bacterial medium is injected into the petri dish for bacterial culture. A second bacterial culture step of culturing a second bacterium composed of general bacteria,
Before injecting the first bacterial culture medium into the sample specimen bottle, a part of the sample specimen is taken out from the open specimen specimen bottle, and a part of the sample specimen is placed in the bacterial culture dish for the second bacteria. Injecting as a sample specimen, the medium for the first bacteria is injected into the opened sample specimen bottle,
The detection of bacteria is
After the first bacterial culture step and the second bacterial culture step, a first bacterial detection step for confirming the presence or absence of fluorescence and a second bacterial detection step for confirming the number of bacteria are provided.
Bacteria test method for tap water, well water or pool water
It is about.

  The invention according to claim 2 is the invention according to claim 1, wherein the sample specimen container storage chamber constituting the first bacterial culture apparatus, the first culture medium injecting section, and the first bacterial culture section. Are arranged in series.

  The invention according to claim 3 is the invention according to claim 1 or 2, wherein the bacteria culture container storage chamber constituting the second bacteria culture device, the second bacteria sample specimen injection section, The second bacterial culture sections are arranged in series.

The invention according to claim 4, in the invention described in claims 1 to 3, before Symbol some sample specimen removal injection mechanism includes a sample dispenser from the bottle body of the open lid state retrieve a portion of the sample under examination And a specimen dispenser transfer mechanism for transferring the specimen dispenser between an upper position of the lid opening / closing mechanism and an upper position of the second bacterial sample injection section.

The invention according to claim 5, in the invention described in any one of 1 to 4, the identification code on the sample specimen bottle is applied in the vicinity of the sample under examination bottle, distribution code reader for decrypting the identification code It was set up.

The invention according to claim 6 is the invention according to any one of claims 1 to 5 , wherein the first bacterial culture section has a box-shaped structure, and is arranged on the side facing the culture medium injection section for the first bacteria. A plurality of tray insertion windows are formed on the rear wall at intervals in the vertical direction, and a tray extraction opening / closing door is formed on the front wall of the first bacterial culture section that is opposite to the rear wall. It is characterized by that.

The invention according to claim 7 is the invention according to any one of claims 1 to 6 , wherein the second bacterial culture part has a box-shaped structure, and is on the side facing the sample specimen injection part for the second bacteria. It has a rear wall, a plurality of tray insertion windows are formed on the rear wall at intervals in the vertical direction, and a tray removal opening / closing door is formed on the front wall of the second bacterial culture section opposite to the rear wall It is characterized by that.

  In another aspect of the invention, a first bacterial culture medium is injected into the sample specimen container taken out from the specimen specimen container storage chamber containing a plurality of specimen specimen containers each containing a specimen specimen, and the first bacteria comprising Escherichia coli. A first bacterial culture step of culturing
  A sample specimen for the second bacteria is injected into the petri dish for bacterial culture taken out from the container chamber for storing the bacterial culture containing a plurality of empty bacterial culture dishes, and the second bacterial medium is injected into the petri dish for bacterial culture. A second bacterial culture step of culturing a second bacterium composed of general bacteria,
  Before injecting the first bacterial culture medium into the sample specimen container, a part of the sample specimen is taken out from the sample specimen container, and a part of the sample specimen is injected into the bacterial culture petri dish as the second bacterial sample specimen. A culture process designed to
  After the first bacterial culture step and the second bacterial culture step, an inspection step comprising a first bacterial detection step for confirming the presence or absence of fluorescence and a second bacterial detection step for confirming the number of bacteria, respectively.
The present invention relates to a method for testing bacteria.

According to the invention of claim 1, before injecting the first bacterial culture medium into the sample specimen bottle, a part of the sample specimen is taken out from the sample specimen bottle, and a part of the sample specimen is placed in the petri dish for bacterial culture. 2 Injected as a sample for bacteria. Therefore, for example, both culture and inspection of E. coli and culture and inspection of general bacteria can be performed automatically, a large amount of sample specimens can be processed in a short time, and the processing efficiency can be remarkably improved. It is possible to inspect under the same conditions, and there is no error in the analysis method.
According to the second aspect of the present invention, the sample specimen container storage chamber, the first bacterial culture injecting section, and the first bacterial culture section that constitute the first bacterial culture apparatus are arranged in series. From the surface, the overall configuration of the apparatus can be made compact.

  According to the invention according to claim 3, the bacterial culture container storage chamber, the second bacterial sample injection portion, and the second bacterial culture portion that constitute the second bacterial culture device are arranged in series, Also from this aspect, the overall configuration of the apparatus can be made compact.

According to the invention of claim 4, part sample specimen removal injection mechanism includes a cover opening and closing mechanism, and the sample dispenser to take out the part from the bottle body of open lid state of the sample analyte, the upper cover opening and closing mechanism specimen dispenser A specimen dispenser transfer mechanism for transferring between the position and the position above the second specimen sample injection part for bacteria is provided. Accordingly, a part of the sample specimen can be easily and reliably removed from the bottle body, and a part of the removed sample specimen can be easily and reliably transferred to the second bacterial sample specimen injection section.

According to the first aspect of the present invention, the lid opening / closing mechanism includes a container placing table on which the sample specimen container can be placed, and a lid that is disposed above the container placing table and holds and fixes the lid of the sample specimen container. The gripping tool and a container body rotating mechanism that rotates the container body with respect to the lid gripping tool together with the container mounting table are provided. Therefore, the lid opening / closing mechanism can be used not only for the opening / closing operation of the sample specimen container but also for transferring the specimen specimen container, and the configuration of the partial specimen extraction / injection mechanism can be made compact.

According to the invention of claim 5, the identification code on the sample specimen bottle is applied, in the vicinity of the sample analyte bottle has a configuration which is disposed a code reader for decrypting the identification code. Therefore, for example, by reading a two-dimensional code such as QR code (registered trademark) and correlating the sample identification number with the position of the sample collection bottle and the petri dish for bacterial culture, human errors such as sample mistakes by humans are eliminated. .

According to the invention of claim 6 , the first bacterial culture section has a box-type structure, has a rear wall on the side facing the first bacterial culture medium injection section, and puts a plurality of trays in the rear wall. The windows are formed at intervals in the vertical direction, and a tray extraction opening / closing door is formed on the front wall of the first bacterial culture section opposite to the rear wall. Therefore, from the first bacterial culture injecting section, the sample specimen bottle is moved along the continuous and linear operation line through the tray insertion window provided on the rear wall of the first bacterial culture section. It can be put into the department. Furthermore, since the opening / closing door for taking out the tray provided on the front wall of the first bacterial culture unit is formed in alignment with the tray insertion window provided on the rear wall of the first bacterial culture unit, the same is applied after the culture period. In addition, a plurality of sample specimen bottles can be easily taken out by opening the tray taking-out opening / closing door along a continuous and linear operation line.

According to the invention which concerns on Claim 7, the 2nd bacteria culture part has a box-type structure, it has a rear wall in the side which opposes the sample specimen injection | pouring part for 2nd bacteria, and several tray is provided in a rear wall. An input window is formed at intervals in the vertical direction, and a tray take-out opening / closing door is formed on the front wall of the second bacterial culture section opposite to the rear wall. Therefore, the bacterial culture petri dish is continuously and linearly charged into the second bacterial culture section from the second bacterial sample specimen injection section through the tray insertion window provided on the rear wall of the second bacterial culture section. can do. Furthermore, since the tray removal opening / closing door provided on the front wall of the second bacterial culture unit is formed in a state aligned with the tray insertion window provided on the rear wall of the second bacterial culture unit, after the culture period, a plurality of The petri dish for bacterial culture can be easily taken out by opening the tray door.
According to the invention according to claim 1, since one of the first bacteria and the second bacteria is Escherichia coli and the other is a general bacteria, it can be applied to a bacterial test performed in tap water, well water, pool water, or the like. it can.

1 is a perspective view of an automatic bacterial test analyzer according to an embodiment of the present invention. It is the arrow view seen from the FIG. 1A-A line. It is the arrow view seen from FIG. 1B-B line. It is sectional drawing by the FIG. 1C-C line. It is a cross-sectional view showing that the partial sample extraction and injection mechanism, the petri dish sample injection portion and the agar medium collection injection portion are on the same line. It is a top view which shows that a partial sample extraction / injection mechanism, a petri dish sample injection part, and an agar medium collection injection part are on the same line. It is explanatory drawing which shows the state which takes out one sample sample bottle from the tray which arranged the some sample sample bottle. It is explanatory drawing which shows the state which removes a lid | cover from a sample sample bottle and reads two-dimensional codes, such as QR code (trademark) provided in the outer peripheral surface of the bottle main body. It is explanatory drawing which shows the state which takes out a chip | tip from a chip | tip storage container. It is explanatory drawing of the control system for controlling operation | movement of the automatic bacteria test analyzer concerning one Example of this invention. It is a flowchart of an E. coli test. It is a flowchart of a general bacteria test.

First, the overall configuration of the automatic bacterial test analyzer according to the present embodiment will be described with reference to FIG. In this embodiment, an example is shown in which the first bacteria are Escherichia coli and the second bacteria are general bacteria.
As shown in FIG. 1, the automatic bacterial test analyzer 10 includes an Escherichia coli culture device 12 (first bacterial culture device) and a general bacterial culture device 14 (second bacterial culture device) arranged in parallel. Moreover, although not shown in figure, the bacteria detection apparatus which can each detect a 1st bacteria and a 2nd bacteria is arrange | positioned downstream from the colon_bacillus | E._coli culture apparatus 12 and the general bacteria culture apparatus 14. FIG. The automatic bacterial test analyzer 10 is preferably installed in a closed booth, and the closed booth is preferably formed of a transparent material so that the operation of the automatic bacterial test analyzer 10 can be visually recognized from the outside.

  The E. coli culture apparatus 12 includes a sample sample bottle storage chamber 18 that stores a plurality of sample sample bottles 16 (sample sample containers) each storing a sample sample, and a sample sample bottle 16 taken out from the sample sample bottle storage chamber 18. It has a medium injection part 20 (first bacterial medium injection part) for injecting the Escherichia coli medium one by one and an incubator 23 constituting the E. coli culture part. The sample specimen bottle storage chamber 18, the culture medium injecting unit 20, and the incubator 23 are arranged in series. Further, between the culture medium injecting unit 20 and the incubator 23, a bottle rocking device 19 and a loading robot 21 for loading the sample specimen bottle 16 into the incubator 23 in a stacked state are disposed. As will be described later, the loading robot 21 is also used as a loading device for loading the petri dish 24 into the incubator 30 of the general bacterial culture apparatus 14. And the general bacterial culture apparatus 14.

  On the other hand, the general bacterial culture apparatus 14 generally injects a sample for general bacteria into a petri dish storage chamber 26 storing a plurality of empty petri dishes 24 (bacterial culture containers) and the petri dish 24 taken out from the petri dish storage chamber 26. A bacterial sample injection unit 28 (second bacterial sample specimen injection unit), a culture medium injection unit 29 (second bacterial culture medium injection unit) for injecting a general bacterial culture medium into the petri dish 24, and a general bacterial culture unit And an incubator 30. The petri dish storage chamber 26, the general bacteria sample injection section 28, and the incubator 30 are arranged in series (on a straight line). Between the culture medium injecting unit 29 and the incubator 30, a petri dish cooling unit 31, a petri dish reversing unit 33, and a feeding robot 21 for feeding the petri dish 24 into the incubator 30 in a stacked state are disposed. Yes.

  In the automatic bacteria test / analysis apparatus 10 having the above-described configuration, the present invention includes an Escherichia coli culture apparatus 12 and a general bacteria culture apparatus 14 arranged in parallel, and between the Escherichia coli culture apparatus 12 and the general bacteria culture apparatus 14. Further, a partial sample specimen extraction / injection mechanism 32 is provided for taking a part of the sample specimen from the sample specimen bottle 16 used in the E. coli culture apparatus 12 and injecting it into the petri dish 24 as a sample for general bacteria. Specifically, a partial sample extraction / injection mechanism 32 is disposed upstream of the medium injection unit 20 of the E. coli culture apparatus 12. Note that the partial sample extraction / injection mechanism 32 may be arranged not on the upstream side of the culture medium injection unit 20 of the E. coli culture apparatus 12 but on the downstream side.

Next, the configuration of each part of the E. coli culture apparatus 12 will be described.
As shown in FIGS. 1 and 2, a plurality of trays 34 each storing a plurality of sample specimen bottles 16 are arranged in a stacked state in the sample specimen bottle storage chamber 18. A tray lifting mechanism 36 is disposed below the sample specimen bottle storage chamber 18, and a tray transfer mechanism 38 including a belt conveyor is disposed on the downstream side of the tray lifting mechanism 36. By driving the tray lifting and lowering mechanism 36 and the tray transfer mechanism 38 with the above-described configuration, a part of the sample 74 is taken out of the tray 74 that houses a plurality of sample sample bottles 16 each enclosing a sample sample. It can be transferred to the injection mechanism 32.

As shown in FIGS. 1, 2, 4, and 7, the sample specimen bottle 16 includes a bottle body 40 and a lid 42 that is screwed to the bottle body 40.
As shown in FIGS. 2 and 4, the partial sample extraction / injection mechanism 32 includes an intermediate portion of a tray transfer mechanism 38 formed of a belt conveyor and a lift and carrier bed provided in the general bacterial culture apparatus 14 described later. A lid opening / closing mechanism 44 interposed between the tray transfer mechanism 78, a sample dispenser 46 for taking out a part of the sample body from the bottle body 40 in the opened state, and injecting it into the petri dish 24 as a sample for general bacteria, The specimen dispenser 46 is transferred in the left-right direction between the lid opening / closing position and the upper position of the chip storage container 69 and between the lid opening / closing position and the general sample specimen injection unit 28 provided in the general bacterial culture apparatus 14. A specimen dispenser transfer mechanism 48 including a ball screw.

As shown in FIGS. 1, 2, 4, and 8, the lid opening / closing mechanism 44 includes a bottle mounting table 50 on which a sample specimen bottle 16 can be placed, and a tray transfer mechanism 38 by a specimen dispenser transfer mechanism 48. A lid gripper 52 that can reciprocate between the bottle mounting table 50 and can grip and fix the lid 42 of the sample specimen bottle 16, and the bottle body 40 together with the bottle mounting table 50 with respect to the lid gripping tool 52. A bottle body rotating mechanism 54 capable of rotating. After the lid 42 of one sample specimen bottle 16 is gripped by the lid gripping tool 52 from the plurality of sample specimen bottles 16 arranged in the tray 34 on the tray transfer mechanism 38, the sample specimen bottle 16 is placed on the bottle mounting table 50. When the sample specimen bottle 16 is rotationally driven in one direction together with the bottle mounting table 50 by the bottle main body rotation mechanism 54 with the lid 42 fixed by the lid gripping tool 52, the bottle main body 40 is moved relative to the lid 42. Can be rotated. Thereby, the screwing of the lid 42 is released, the lid 42 can be removed from the bottle body 40, and the sample specimen bottle 16 can be opened. Further, a part of the sample body is taken out from the bottle body 40 in the opened state by using the sample dispenser 46, the sample dispenser transfer mechanism 48 is driven, and the sample dispenser 46 is provided in the general bacterial culture apparatus 14 from the lid opening / closing position. Then, the sample is transferred to the general sample specimen injection unit 28 and a sample dispenser 46 injects a part of the sample specimen into the petri dish 24 in the general sample specimen injection unit 28. Further, in the step after injecting the Escherichia coli medium into the bottle main body 40 by the medium injection unit 20 described later, when the sample specimen bottle 16 is rotationally driven together with the bottle mounting table 50 by the bottle main body rotation mechanism 54, the lid 42. Is screwed onto the bottle body 40 and attached. Thereafter, the sample specimen bottle 16 is returned to the original position in the tray 34 on the tray transfer mechanism 38.
Further, as shown in FIGS. 4 and 8, the outer peripheral surface of the sample specimen bottle 16 includes a QR code (registered trademark) that is an identification symbol indicating the contents of the sample specimen enclosed in the sample specimen bottle 16. A two-dimensional code 55 is affixed, and a code reader 57 for decoding the two-dimensional code 55 is disposed in the vicinity of the sample specimen bottle 16.

  As shown in FIG. 8, the lid gripping tool 52 includes a clamp 56 that detachably grips the lid 42 of the sample specimen bottle 16, a lift cylinder 58 that is attached to the lower end of the clamp 56, and a lift dispenser cylinder 58 that is a specimen dispenser transfer mechanism. 48 and a mounting base 62 for mounting to 48.

As shown in FIG. 8, a specimen dispenser 46 has a pipette 66 that can be moved up and down, and a mount base for attaching the pipette 66 to the specimen dispenser transfer mechanism 48 described above. 68. The mounting base 68 is attached to the sample dispenser transfer mechanism 48 in a state separated from the lid opening / closing mechanism 44 in the left-right direction. In order to attach the tip 64 to the tip of the sample dispenser 46, the sample dispenser 46 is placed on the tip storage container 69 disposed on one side of the tray transfer mechanism 38 as shown in FIG. The pipette 66 is lowered, and one chip 64 from the plurality of chips 64 in the chip storage container 69 is attached to the tip of the pipette 66. The chip storage container 69 is placed on the chip transfer table 81, and moves the chip transfer table 81 along the longitudinal direction of the E. coli culture apparatus 12, and the sample dispenser transfer mechanism 48 is orthogonal to the longitudinal direction. By moving in the direction (left-right direction), all the chips 64 in the chip storage container 69 can be detachably attached to the tip of the pipette 66. Further, as shown in FIG. 8, the tip 64 can be easily detached from the pipette 66 by driving a known detachment mechanism (not shown) by the advance / retreat cylinder 51 attached to the attachment base 68. The detached chip 64 is collected through a collection chute 53 into a collection container (not shown).
Here, the reason why the tip 64 is detachably attached to the tip of the pipette 66 is that when the same pipette is used for a plurality of sample specimens, there is a possibility that a plurality of sample specimens may be mixed, and that fear is avoided. This is because it is necessary to replace the tip of the pipette every time a part of the sample body is taken out from the bottle body 40.
The chip storage container 69 is provided with a sterilization lamp 71 for sterilizing the chip 64.

  As shown in FIGS. 1, 2 and 4, the culture medium injecting section 20 is disposed adjacent to the culture medium tank 70 filled with the E. coli culture medium and the lid opening / closing mechanism 44, and a part of the dispensing end thereof is a sample specimen. A medium injection nozzle 72 that is movable between an injection position located above the sample specimen bottle 16 on the bottle mounting table 50 in the extraction / injection mechanism 32 and a standby position that is spaced from the injection position; An advancing / retreating cylinder 90 for advancing and retracting the nozzle 72 and a culture medium supply pipe 75 for connecting the injection nozzle 72 and the culture medium tank 70 in communication are provided. With the configuration described above, the E. coli medium can be injected into the sample specimen bottle 16 in the open state.

  As shown in FIG. 2, the incubator 23 has a box-type structure, and a plurality of trays 34 each storing a plurality of sample specimen bottles 16 are accommodated therein in a vertically stacked state. A space 93 is formed, and a placement roller 96 is arranged in each storage space 93, and the tray 34 is placed on the placement roller 96. The incubator 23 has a rear wall 94 on the side facing the culture medium injecting section 20, and a plurality of tray insertion windows 95 are aligned with the storage space 93 at intervals in the vertical direction on the rear wall 94. It is formed in a state. On the other hand, on the front wall 97 of the incubator 23 on the opposite side of the rear wall 94, a single tray take-out opening / closing door 99 is formed over the substantially entire height of the incubator 30 so as to align with the tray insertion window 95. In this embodiment, as shown in FIG. 2, the incubator 23 includes an opening / closing plate 132 having a tray insertion window (not shown) at the same height as the tray insertion window 95. By moving 132 up and down with a lifting cylinder 134. By aligning the tray input window with the tray input window 95 described above, the tray 34 can be stored in each storage space 93, and the tray input window 95 can be closed by setting the tray input window to the non-aligned state.

  The feeding robot 21 disposed between the culture medium injecting unit 20 and the incubator 23 is a ball screw (not shown) between the left and right side walls of the rectangular support base 100 that supports the Escherichia coli culture device 12 and the general bacterial culture device 14. The moving table 102 includes a moving table 102, a vertical support frame 104 erected on the upper surface of the moving table 102, and a tray transfer table 106 including a belt conveyor attached to the vertical support frame 104 so as to be movable up and down.

  By configuring the incubator 23 and the loading robot 21 as described above, the tray 34 for storing the plurality of sample specimen bottles 16 into which E. coli has been injected by the medium injecting unit 20 can be moved from the medium injecting unit 20 to the moving table 102 and the incubator. Through the tray insertion window 95 provided on the rear wall 94 of the apparatus 23, it can be input into the incubator 23 along a continuous and linear operation line. Further, since the tray take-off opening / closing door 99 provided on the front wall 97 of the incubator 23 is formed so as to be aligned with the tray insertion window 95 provided on the rear wall 94 of the incubator 30, similarly after the culture period, A plurality of sample specimen bottles 16 can be easily taken out by opening the tray taking-out opening / closing door 99 along a continuous and linear operation line.

Next, the structure of each part of the general bacterial culture apparatus 14 will be described.
As shown in FIGS. 1 and 3, a plurality of trays 74 each storing a plurality of empty petri dishes 24 are arranged in a plurality of stages in the petri dish storage chamber 26. A sterilization lamp 77 is disposed above the petri dish storage chamber 26. A tray elevating mechanism 76 is disposed below the petri dish storage chamber 26, and a tray transfer mechanism composed of a lift and carrier bed is disposed between the petri dish elevating mechanism 76 and the general bacteria sample injection unit 28. 78 is disposed. By driving the tray lifting mechanism 76 and the tray transfer mechanism 78 with the above-described configuration, the tray 74 storing a plurality of empty petri dishes 24 can be transferred to the general bacteria sample injection unit 28 for each stage.

  The general bacteria sample injection section 28 for injecting a sample for general bacteria into the petri dish 24 is substantially composed of a swinging table 80 that constitutes a part of the tray transfer mechanism 78. In addition, a tray 74 for storing a plurality of empty petri dishes 24 is transferred from the petri dish storage chamber 26. Further, as described above, a part of the sample body taken out from the open bottle body 40 is injected into the petri dish 24 as a sample for general bacteria by the sample dispenser 46.

As shown in FIG. 4, the medium injecting unit 29 sucks and injects the agar medium into the petri dish 24 by agar medium container 82 (general bacteria medium container), hot stirrer 83 that stirs the agar while heating it. A pipette 84 that can be moved up and down (moved up and down by the lifting mechanism 130), a lid opening and closing mechanism 86 that attaches and detaches the lid 25 of the petri dish 24, a pipette 84 and the lid opening and closing mechanism 86 are attached at a predetermined interval. And a traversing mechanism 88 formed of a ball screw that can traverse with the petri dish 24. The lid opening / closing mechanism 86 includes an elevating rod 126 and a vacuum suction pad 128 attached to the lower end of the elevating rod 126. With the configuration described above, the agar medium can be injected into the petri dish 24 into which the sample for general bacteria has already been injected, and then the lid opening / closing mechanism 86 is driven to close the lid 25 of the petri dish 24. Here, since the petri dish 24 that accommodates a part of the sample specimen and the agar medium is placed on the swing table 80, the sample body can be uniformly dispersed in the agar medium.
In this embodiment, as shown in FIGS. 5 and 6, the petri dish injection position and the agar medium collection injection position are placed on the same line in the same line L1 as the sample bottle collection position, thereby saving space. In addition, the specimen and the petri dish 24 can be easily associated with each other. That is, as shown in FIG. 6, the four petri dishes 24 forming one row in the tray 74 correspond to the four sample specimen bottles 16 forming one row in the tray 34 in a one-to-one relationship. It is not necessary to provide a separate identification display on the petri dish 24.

  As shown in FIG. 3, the incubator 30 has a box-type structure, and a storage space 110 in which a plurality of trays 74 each storing a plurality of petri dishes 24 can be stored in a vertically stacked state. The placement roller 112 is disposed in each storage space 110, and the tray 74 is placed on the placement roller 112. The incubator 30 has a rear wall 114 on the side facing the general bacteria sample injection portion 28, and a plurality of tray insertion windows 116 are spaced apart in the vertical direction on the rear wall 114, and the storage space 110. It is formed in a state consistent with. On the other hand, on the front wall 118 of the incubator 30 on the side opposite to the rear wall 114, a single tray take-out opening / closing door 120 is formed over the substantially entire height of the incubator 30 so as to align with the tray insertion window 116. In this embodiment, as shown in FIG. 3, the incubator 30 includes an opening / closing plate 122 having a tray insertion window (not shown) at the same height as the tray insertion window 116. By moving 122 up and down with a lifting cylinder 124. By aligning the tray input window with the tray input window 116 described above, the tray 74 can be stored in each storage space 110, and the tray input window 116 can be closed by setting the tray input window to the non-aligned state.

  By configuring the incubator 30 and the above-described feeding robot 21 as described above, a tray 74 for storing a plurality of petri dishes 24 into which general bacteria and agar are injected in the general bacteria sample injection unit 28 is used. The injection unit 28 can continuously and linearly enter the incubator 30 through the tray 102 and the tray insertion window 116 provided on the rear wall 114 of the incubator 30. Furthermore, since the tray extraction opening / closing door 120 provided on the front wall 118 of the incubator 30 is formed in alignment with the tray insertion window 116 provided on the rear wall 114 of the incubator 30, a plurality of petri dishes are used after the culture period. 24 can be easily removed by opening the tray extraction opening / closing door 120.

FIG. 10 illustrates a control system used in the automatic bacterial test analyzer 10 according to the present invention.
An operation in which various switches such as an operation start switch, an operation stop switch, and a display unit for indicating an operation status are attached to the input side of a control device 206 incorporating a CPU (Central Processing Unit) 200, ROM 202, RAM 204, and the like. A panel 208 is connected, and the various devices and various mechanisms described above are connected to the output side of the control device 206 via a drive circuit (not shown).
Therefore, the control device 206 performs the operation of the automatic bacteria test analyzer 10 according to the present invention based on a predetermined operation program using various operation signals from the operation panel 208 and various detection signals from various sensors. It can be done automatically.

Hereinafter, an automatic bacterial test analysis method using the automatic bacterial test analyzer 10 according to the present invention will be described with reference to FIGS.
[Inspection of E. coli] (Fig. 11)
(1) The tray 34 in which a plurality of sample sample bottles 16 are arranged is taken out from the sample bottle storage chamber 18 and transferred to the partial sample sample extraction / injection mechanism 32 (step S1).
(2) The sample specimen bottles 16 are taken out one by one from the tray 34 by the partial sample specimen extraction / injection mechanism 32 and placed on the bottle mounting table 50 (step S2).
(3) Remove the lid 42 from the sample specimen bottle 16 (step S3). (This opening operation is performed by fixing the lid 42 of the sample specimen bottle 16 and rotating the bottle body 40.)
(4) The Escherichia coli medium is injected into the sample specimen bottle 16 in the open state (step S4).
(5) The lid 42 is attached to the sample specimen bottle 16 (step S5).
(6) The sample specimen bottle 16 is returned to the original position in the original tray 34 (step S6).
(7) The tray 34 is rocked by the bottle rocking device 19 (step S7).
(8) The tray 34 on which the sample specimen bottle 16 is placed is transferred into the incubator 23 and cultured (step S8).
(9) After 24 hours, the sample specimen bottle 16 is taken out from the incubator 23 and the presence or absence of fluorescence is confirmed (step S9).

[Examination of general bacteria] (Fig. 12)
(1) The tray 74 on which a plurality of empty petri dishes 24 are arranged is taken out from the petri dish storage chamber 26 and transferred to the general bacteria sample injection section 28 (step S101).
(2) Remove the lid 25 of the petri dish 24 (step S102).
(3) The two-dimensional code 55 such as QR code (registered trademark) provided around the bottle main body 40 is read between the step S3 and the step S5 in the above-described E. coli inspection, and is associated with the petri dish 24 for general bacteria. Is performed (step S103).
(4) A part of the sample specimen is taken out from the specimen specimen bottle 16 by the specimen dispenser 46 and injected into the petri dish 24 (step S104).
(5) An agar medium is injected into the petri dish 24 (step S105).
(6) After the lid 25 is again put on the petri dish 24, the petri dish 24 is swung (step S106).
(7) The petri dish 24 is inverted (step S107).
(8) The tray 74 on which the petri dish 24 is placed is transferred into the incubator 23 and cultured (step S108).
(9) After 22 to 24 hours have elapsed, the tray 74 is removed from the incubator 23, and the number of general bacteria in each petri dish 24 is counted (step S109).

  The present invention has been specifically described above with reference to the examples. However, the present invention is not limited to the configuration of the automatic bacterial test analyzer described in the examples, and All other embodiments and modification examples are included without departing from the gist of the invention described in the above. For example, the Escherichia coli culture device and the general bacterial culture device that constitute the automatic bacterial test analyzer operate It goes without saying that each program can be operated independently by changing a part of the program. Further, it is possible to further provide an apparatus similar to the second bacterial culture apparatus and to culture and inspect three or more kinds of bacteria.

10: Automatic bacteria test analyzer 12: E. coli culture device (first bacterial culture device)
14: General bacterial culture device (second bacterial culture device)
16: Sample specimen bottle (sample specimen container)
18: Sample specimen bottle storage chamber 19: Bottle swinging device 20: Medium injecting section (first bacteria medium injecting section)
21: Input robot 23: Incubator 24: Petri dish (bacteria culture vessel)
25: Lid 26: Petri dish storage chamber 28: Sample injection part for general bacteria (sample specimen injection part for second bacteria)
29: Medium injection part (second bacterial medium injection part)
30: Incubator 31: Petri dish cooling unit 32: Partial sample extraction / injection mechanism 33: Petri dish reversing unit 34: Tray 36: Tray lifting mechanism 38: Tray transfer mechanism 40: Bottle body 42: Lid 44: Lid opening / closing mechanism 46: Sample Dispenser 48: Specimen dispenser transfer mechanism 50: Bottle mounting table 51: Advance / retreat cylinder 52: Lid gripper 53: Collection chute 54: Bottle main body rotation mechanism 55: Two-dimensional code 56: Clamp 57: Code reader 58: Elevating cylinder 62: Installation Base 64: Tip 66: Pipette 68: Mounting base 69: Chip storage container 70: Medium tank 71: Sterilization lamp 72: Medium injection nozzle 74: Tray 75: Medium supply pipe 76: Tray lifting mechanism 77: Sterilization lamp 78: Tray Transfer mechanism 80: Swing table 81: Chip transfer table 82: Agar medium container 83: Hot Stirrer 84: Pipette 86: Lid opening / closing mechanism 88: Traverse mechanism 90: Advance / retract cylinder 93: Storage space 94: Rear wall 95: Tray insertion window 96: Loading roller 97: Front wall 99: Opening / closing door 100 for taking out the tray 100: Rectangular support Table 102: Moving table 104: Vertical support frame 106: Tray transfer table 110: Storage space 112: Loading roller 114: Rear wall 116: Tray loading window 118: Front wall 120: Opening door 122 for taking out the tray 122: Opening / closing plate 124 : Lifting cylinder 126: Lifting rod 128: Vacuum suction pad 130: Lifting mechanism

Claims (7)

A sample sample container storage chamber storing a plurality of sample lid bottles with screw caps each storing a sample sample, and the sample sample bottle extracted from the sample sample container storage chamber and a part of the sample sample extracted A first bacterial culture device for culturing Escherichia coli having a first bacterial culture medium injecting section for injecting a first bacterial culture medium, and a first bacterial culture section;
Bacterial culture container storage chamber storing a plurality of empty bacterial culture petri dishes, and a second bacterial sample specimen injection for injecting a second bacterial sample specimen into the bacterial culture petri dish taken out of the bacterial culture container storage chamber and parts, it comprises a second bacteria culture media injection unit for injecting a second bacteria culture media to the bacterial culture in a petri dish, a second bacterial culture apparatus for culturing common bacteria and a second bacterial culture unit a bacterial culture device,
Before injecting the first bacterial culture medium into the sample specimen bottle, a part of the sample specimen is taken out from the sample specimen bottle, and a part of the sample specimen is used as the second bacterial sample specimen in the petri dish for bacterial culture. It is equipped with a mechanism for taking out and injecting some sample specimens,
The partial sample specimen extraction / injection mechanism opens the sample specimen bottle before taking out a part of the sample specimen, and after injecting the first bacterial culture medium into the sample specimen bottle from which the sample specimen has been taken out, A lid opening / closing mechanism for closing the sample specimen bottle is provided,
The lid opening / closing mechanism includes: a container mounting table on which an upper surface of the sample specimen bottle can be mounted; a lid gripping tool that is disposed above the container mounting table and grips and fixes the lid of the sample specimen bottle; container body rotation mechanism and Yusuke that bacterial culture device to rotate relative to said lid gripping device together with the container placing table
A bacterial test method for detecting bacteria after culturing bacteria using
Bacteria culture using the bacterial culture apparatus,
A culture medium for first bacteria is injected into the sample specimen bottle taken out from the specimen specimen container storage chamber containing a plurality of specimen specimen bottles with screw caps each containing a specimen specimen, and the first bacteria composed of Escherichia coli are cultured. A first bacterial culture step;
A sample specimen for the second bacteria is injected into the petri dish for bacterial culture taken out from the container chamber for storing the bacterial culture containing a plurality of empty bacterial culture dishes, and the second bacterial medium is injected into the petri dish for bacterial culture. A second bacterial culture step of culturing a second bacterium composed of general bacteria ,
Before injecting the first bacterial culture medium into the sample specimen bottle, a part of the sample specimen is taken out from the open specimen specimen bottle, and a part of the sample specimen is placed in the bacterial culture dish for the second bacteria. Injecting as a sample specimen, the medium for the first bacteria is injected into the opened sample specimen bottle ,
The detection of bacteria is
Tap water, characterized by comprising after said first bacterial culture step and the second bacterial culture step, each second bacteria detection process to verify the number of first bacterium detection step and bacteria to verify the presence or absence of fluorescence, Bacteria test method for well water or pool water . In the bacterial culture apparatus, the sample specimen container storage chamber, the first bacterial culture injecting section, and the first bacterial culture section constituting the first bacterial culture apparatus are arranged in series. The method for testing bacteria according to claim 1. In the bacterial culture apparatus, the bacterial culture container storage chamber, the second bacterial sample injection section, and the second bacterial culture section that constitute the second bacterial culture apparatus are arranged in series. The method for testing bacteria according to claim 1 or 2. In the bacterial culture apparatus, the partial sample specimen extraction / injection mechanism includes a specimen dispenser that extracts a part of the specimen specimen from the open bottle body, the specimen dispenser at a position above the lid opening / closing mechanism, and the second position. 4. The method for testing bacteria according to claim 1, further comprising a sample dispenser transfer mechanism for transferring between the sample sample injection part for bacteria and an upper position of the sample sample injection unit. 5. The bacterial culture apparatus according to claim 1, wherein an identification code is assigned to the sample specimen bottle, and a code reader for decoding the identification code is disposed in the vicinity of the sample specimen bottle. The method for testing bacteria according to crab. In the bacterial culture apparatus, the first bacterial culture section has a box-shaped structure, has a rear wall on the side facing the first culture medium injection section, and has a plurality of tray insertion windows on the rear wall. 6. The tray extraction opening / closing door is formed on the front wall of the first bacterial culture section that is formed at an interval in the vertical direction and that is opposite to the rear wall. 6. Bacteria testing method . In the bacterial culture apparatus, the second bacterial culture section has a box-shaped structure, has a rear wall on the side facing the second bacterial sample specimen injection section, and a plurality of tray insertion windows on the rear wall. 7. A tray take-out opening / closing door is formed on the front wall of the second bacterial culture section that is spaced apart in the vertical direction and is opposite to the rear wall. The bacterial test method described.

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