DE202020105990U1 - Parasite in-vitro breeding facility that enables real-time image recording - Google Patents

Abstract

Parasite in-vitro cultivation device in which real-time image recording can be made possible, characterized in that it comprises an upside-down biomicroscope (4), on the object table (1) of which a cultivation box (2) is provided for cultivating parasites , wherein a light source assembly (6) for providing a light source for the interior of the grow box (2) is provided above the object table (1) via a support mechanism, wherein at the top of the grow box (2) a through hole (11) for leading through the lowest Area of the light source assembly (6) is provided, via which through hole (11) the lowermost area of the light source assembly (6) protrudes into the grow box (2), the circumference of the light source assembly (6) being tightly connected to the inner wall of the through hole (11) , the lowermost area of the grow box (2) being transparent, with an objective (8) of the upside-down biomicroscope s (4) is arranged directly below the object table (1), a camera assembly (5) for capturing an image viewed through the objective (8) being provided on an eyepiece of the upside-down biomicroscope (4), on the inner wall of the breeding box (2) a temperature control assembly (7) is provided for controlling the temperature inside the breeding box (2) and a sealed box door (10) is detachably provided on a side wall of the breeding box (2).

Description

AREA OF USED PATTERN

The present utility model relates to the field of in-vitro breeding of parasites, in particular a parasite in-vitro breeding device in which real-time image recording can be made possible.

STATE OF THE ART

Parasites refer to disease-causing lower eukaryotes that can serve as both pathogens and media for disease transmission. In medical studies, some parasites are bred as test subjects in order to promote knowledge of the habits and pathology of the parasites, which makes an essential contribution to the medical field. The breeding of parasites must take place in a breeding box. Since the breeding of parasites requires a constant environment, it is not desirable to take parasites during breeding for observation by means of a microscope, so that it is not possible to record real-time images during the breeding of parasites.

MODEL DISCLOSURE

The present utility model is based on the object of providing a parasite in-vitro breeding facility in which real-time image recording is made possible, with which observation and image recording of the growth and development state of the parasites can be realized in real time during breeding.

According to the present utility model, the object is achieved by the following configuration: A parasite in-vitro breeding device, in which real-time image recording can be made possible, comprises an upside-down biomicroscope, on the object table of which a breeding box is provided for breeding parasites , a light source assembly for providing a light source for the interior of the grow box is provided above the object table via a support mechanism, a through hole being provided in the uppermost area of the grow box for passing the lowermost area of the light source assembly, via which through hole the lowermost area of the light source assembly in the grow box protrudes, the circumference of the light source assembly being tightly connected to the inner wall of the through hole, the lowermost area of the grow box being transparent, with an objective of the upside-down biomicroscope ops is arranged directly below the object table, with a camera assembly for capturing an image viewed through the lens being provided on an eyepiece of the upside-down biomicroscope, with a temperature control assembly being provided on the inner wall of the grow box for controlling the temperature inside the grow box and on a Side wall of the breeding box a sealed box door is detachably provided.

The present utility model is advantageously characterized in that, in the present utility model, the temperature inside the cultivation box is controlled via the temperature control assembly, with an image of the growth and development of parasites in a closed cultivation box being captured in real time via a connection between the camera assembly and the microscope with which the growth and development of parasites can be monitored in a more scientific and non-invasive manner in order to describe the growth and development status of the parasites in individual stages.

On the basis of the above configuration, the following developments are conceivable for the present utility model.

It is further provided that the inner wall of the through hole is provided with a sealing ring, the outer jacket wall of which is tightly and firmly connected to the inner wall of the through hole, the lowermost area of the light source assembly passing through a central hole in the sealing ring and bearing tightly against the inner wall of the sealing ring .

With the above development it is advantageously achieved that by providing the sealing ring, a tight fit of the light source assembly can be ensured on the through-hole in order to avoid the impairment of the growth of the parasites by connecting the interior of the breeding box to the external environment.

It is further provided that the support mechanism comprises a standing column, which is permanently provided on the object table, and a connecting column, the lowermost area of which is inserted in the standing column, a mounting hole connected to its lowermost area being provided within the standing column, the lowermost area of the connecting column in the mounting hole is inserted and is locked via a first locking bolt provided on the side wall of the column, while a horizontal support rod is provided at the uppermost area of the connecting column, and the light source assembly is fixedly arranged on the horizontal support rod and is located directly above the through hole is located.

With the above development it is advantageously achieved that the connecting column is first lifted before assembly so that the light source assembly is separated from the uppermost area of the grow box, after which the connecting column is locked via the first locking bolt in order to prevent the connecting column from shifting downwards and thus to provide sufficient space to accommodate the grow box. After attaching the grow box, the first locking bolt is released so that the connecting column and the light source assembly connected to the connecting column via the horizontal support rod move downwards and the light source assembly is inserted into the through-hole, after which the connecting column is locked via the first locking bolt, so that afterwards an image recording of the breeding of parasites can be made.

It is also provided that an annular recess is provided in the upper region of the connecting column, in which a rotary sleeve is pushed, on the outer wall of which a second locking bolt is provided for locking the rotary sleeve, and one end of the horizontal support rod with the outer jacket wall of the Rotary sleeve is firmly connected.

With the above development it is advantageously achieved that by providing the annular recess and the rotating sleeve, a rotation of the light source assembly is made possible in the horizontal direction in order to provide sufficient space for attaching the breeding box.

It is further provided that a receiving recess for receiving the breeding box is provided on the upper surface of the object table, in which receiving recess the lowermost area of the breeding box is arranged.

With the above development it is advantageously achieved that the provision of the receiving recess enables the positioning for the arrangement and the fastening of the breeding box.

It is further provided that a mounting space for attaching the light source assembly is provided on the object table, which mounting space is arranged directly below the receiving recess, the receiving recess and the mounting space being connected to one another via a mounting hole, and the object table on both sides with one to the mounting space connected opening is provided.

With the above development it is advantageously achieved that the use and maintenance of the objective are facilitated by providing the opening.

It is further provided that the device further comprises a display which is in communication with the camera assembly and is used to display a real-time image recorded by the camera assembly.

With the above development it is advantageously achieved that, by providing the display, an image captured by the camera assembly can be extracted in real time in order to find out the breeding status of the parasites in real time.

It is further provided that the device further comprises a carbon dioxide concentration detection sensor for monitoring the carbon dioxide concentration within the grow box.

With the above development it is advantageously achieved that the carbon dioxide concentration within the breeding box can be monitored in real time with the carbon dioxide concentration detection sensor.

It is further provided that the device further comprises a control device, an air inlet for connecting to an external carbon dioxide source being provided on a side wall of the breeding box, on which air inlet a flow-through solenoid valve is provided, and wherein the control device with the flow-through solenoid valve and the Carbon dioxide concentration detection sensor is electrically connected.

With the above development it is advantageously achieved that the control device opens or closes the flow solenoid valve as a function of a carbon dioxide concentration within the grow box detected by the carbon dioxide concentration detection sensor, in order to supply the interior of the grow box with carbon dioxide if necessary supply.

Figure list

• 1 shows a schematic structural representation of an embodiment of the present utility model.

1.

Objekttisch,

2.

Zuchtkasten,

3.

Durchfluss-Elektromagnetventil,

4.

Auf dem Kopf stehendes Biomikroskop,

5.

Kamerabaugruppe,

6.

Lichtquellenbaugruppe,

7.

Temperatursteuerbaugruppe,

8.

Objektiv,

9.

Kohlendioxid-Konzentration-Erfassungssensor,

10.

Abgedichtete Kastentür,

11.

Durchgangsbohrung,

12.

Dichtring,

13.

Stehsäule,

14.

Verbindungssäule,

15.

Montagebohrung,

16.

Erster Verriegelungsbolzen,

17.

Horizontal-Stützstange,

18.

Ringförmige Aussparung,

19.

Drehhülse,

20.

Zweiter Verriegelungsbolzen,

21.

Aufnahmeausnehmung,

22.

Montageraum,

23.

Verbindungsbohrung.

The individual reference symbols are used for the following parts:

1.

Object table,

2.

Breeding box,

3.

Flow solenoid valve,

4th

Upside down biomicroscope,

5.

Camera assembly,

6th

Light source assembly,

7th

Temperature control module,

8th.

Lens,

9.

Carbon dioxide concentration detection sensor,

10.

Sealed box door,

11.

Through hole,

12.

Sealing ring,

13th

Standing column,

14th

Connecting column,

15th

Mounting hole,

16.

First locking bolt,

17th

Horizontal support rod,

18th

Annular recess,

19th

Rotating sleeve,

20th

Second locking bolt,

21st

Receiving recess,

22nd

Assembly room,

23.

Connecting hole.

EMBODIMENTS OF THE PATTERN OF USE

In the following, the principle and the features of the present utility model are described with reference to the accompanying drawings, the examples mentioned merely serving to explain the utility model without restricting the scope of the utility model.

How out 1 results, the present embodiment includes an upside down biomicroscope 4th , on its stage 1 a breeding box 2 intended for the breeding of parasites. Above the object table 1 is a light source assembly via a support mechanism 6th for providing a light source for the interior of the grow box 2 intended. At the top of the grow box 2 is a through hole 11 for leading through the lowest area of the light source assembly 6th provided through which through hole 11 the lowest area of the light source assembly 6th in the breeding box 2 protrudes. The scope of the light source assembly 6th is with the inner wall of the through hole 11 tightly connected. The lowest area of the grow box 2 is transparent. One lens 8th of the upside down biomicroscope 4th is immediately below the stage 1 arranged. On an eyepiece of the upside-down biomicroscope 4th is a camera assembly 5 for capturing one through the lens 8th viewed image provided (the camera assembly provided in the biomicroscope 5 belongs to conventional technical means in this field and a detailed description of their concrete structure is not given here). On the inside wall of the grow box 2 is a temperature control module 7th to control the temperature inside the grow box 2 provided (the temperature control module 7th belongs to conventional techniques in the field and typically includes a controller, a temperature sensor, and an electric heater. The controller is electrically connected to the sensor and the electric heater. The heating temperature of the electrical heater is controlled as a function of a temperature detected by the sensor, in order to enable constant temperature regulation, as in the case of the temperature control module 7th from the existing patent specification with patent number 201720790374.7). On one side wall of the breeding box is a sealed box door 10 removable provided. One side of the sealed box door 10 is hinged to a side wall of the grow box 2 connected, while the other side is connected to the side wall of the grow box via a snap lock 2 connected is. When the sealed box door 10 the side opening of the breeding box 2 locked, the sealed box door 10 and sealed the peripheral wall of the opening. The embodiment further includes a carbon dioxide concentration detection sensor 9 for monitoring the carbon dioxide concentration inside the grow box 2 . With the carbon dioxide concentration detection sensor 9 can reduce the carbon dioxide concentration inside the grow box 2 monitored in real time. The exemplary embodiment also includes a control device. The control unit is with the temperature control assembly 7th and the carbon dioxide concentration detection sensor 9 connected to monitor temperature and carbon dioxide concentration in real time. Through the temperature control assembly 7th the temperature inside the grow box 2 regulated and via a flow solenoid valve 3 that connects to the inside of the grow box 2 controls, the inside of the grow box is created by a source of carbon dioxide 2 supplied with carbon dioxide. Via the temperature control module 7th the temperature inside the grow box 2 controlled. Via a connection of the camera assembly 5 with the microscope 4th becomes a picture of the growth of parasites in the closed breeding box 2 captured in real time, which allows parasite growth to be monitored in a more scientific and non-invasive way to provide images of the To record the growth status of the parasites in individual stages.

In the present embodiment is at the top of the grow box 2 a through hole 11 for leading through the lowest area of the light source assembly 6th provided through which through hole 11 the lowest area of the light source assembly 6th in the breeding box 2 is introduced. The outer peripheral wall of the light source assembly 6th lies close to the inner wall of the through hole 11 at. The inner wall of the through hole is concrete 11 with a sealing ring 12 provided, the outer shell wall with the inner wall of the through hole 11 is tightly and firmly connected. With the specific connection of the sealing ring 12 with the inner wall of the through hole 11 it can be an adhesive connection or a locking connection via a locking groove. The lowest area of the light source assembly 6th goes through a central hole in the sealing ring 12 through and lies close to the inner wall of the sealing ring 12 at. By inserting the lowest part of the light source assembly 6th in the breeding box 2 will provide a light source for the grow box 2 facilitated. By providing the sealing ring 12 can seal the light source assembly 6th at the through hole 11 be ensured so as to interfere with the growth of the parasites by connecting the inside of the grow box 2 to avoid with the external environment.

Preferably the support mechanism comprises one on the stage 1 fixed column 13th and a connecting column 14th , whose lowest area is in the standing column 13th is introduced. Inside the standing column 13th is a mounting hole connected to its lowest area 15th intended. The lowest area of the connecting column 14th is in the mounting hole 15th and is inserted via one on the side wall of the standing column 13th provided first locking bolt 16 locked while at the top of the connecting pillar 14th a horizontal support rod 17th is provided. The camera assembly 5 is on the horizontal support rod 17th fixed and is located directly above the through hole 11 . Before assembly, the connecting pillar is first 14th raised, after which the first locking bolt 16 the connecting pillar 14th is locked to a displacement of the connecting column 14th to prevent downward and thus sufficient space to attach the breeding box 2 to provide. After attaching the grow box 2 becomes the first locking bolt 16 released so that the connecting column 14th and the one over the horizontal support rod 17th with the connecting column 14th connected light source assembly 6th move down and the bottom section of the light source assembly 6th into the through hole 11 is inserted, after which the first locking bolt 16 the connecting pillar 14th is locked so that an image recording of the breeding of parasites can then be performed.

On the basis of the above configuration, the following development is also possible for the present exemplary embodiment: On the one in the mounting hole 15th introduced part of the connecting column 14th a vertically arranged rack is provided and on the standing column 13th is one in the mounting hole 15th introduced rotary handle provided rotatably, its in the mounting hole 15th arranged end is in engagement with the rack via a gear. The connecting column is set by turning the twist grip 14th offset in displacement up and down, bringing the light source assembly 6th is set in motion up and down. Furthermore, the rotary handle can be replaced by a servomotor, the output end of which is in the mounting hole 15th is inserted and is in engagement with the rack via a gear. The movement of the connecting column is controlled by the servomotor 14th and the microscope 4th electrically controlled up and down.

In the present embodiment it is provided that on the upper surface of the stage 1 a receiving recess 21st to accommodate the grow box 2 is provided in which receiving recess 21st the lowest area of the grow box 2 is arranged. By providing the receiving recess 21st can positioning for arranging and securing the grow box 2 are made possible. At the stage 1 is an assembly room 22nd to accommodate the light source assembly 6th intended. Specifically, a side edge of the object table extends 1 inside the object table 1 to create a side recess to serve as a mounting space 22nd to form, so that an opening connected to the mounting space is formed on a side surface of the stage for attachment, use and maintenance of the lens 8th to facilitate. The assembly room 22nd is immediately below the receiving recess 21st arranged. The receiving recess 21st and the assembly room 22nd are via a connecting hole 23 connected with each other. The embodiment further includes a display associated with the camera assembly 5 is in communication connection and for displaying a by the camera assembly 5 recorded image. By providing the display, the camera assembly 5 The captured image can be extracted in real time to find out the breeding status of the parasite in real time.

On the basis of the above exemplary embodiment, the following further development is also possible for the present application: On the upper region of the connecting column 19th is an annular recess 18th provided in which a rotating sleeve 19th is pushed, on the outer wall of a second locking bolt 20th to lock the rotating sleeve 19th is provided. One end of the horizontal support rod 22nd is with the outer jacket wall of the rotating sleeve 19th firmly connected.

On the basis of the above embodiment, the following further development is also possible for the present application: At the lowest area of the breeding box 2 there are scales for measuring the length of parasites. After a culture dish or a culture bottle has been placed at a corresponding point on the scales, an image of the scales can be made in the by the camera assembly 5 captured images are captured so that the length of the parasites can be measured by observing the scales. Furthermore, measurement scales can be provided on the display screen, over which the length of the parasites in the image shown on the display, which is generated by the camera assembly 5 is detected, is measured.

In the description of the present utility model, it goes without saying that the terms "central", "length", "top", "bottom", "front", "rear", "left", "right", "vertical", " horizontal "," uppermost "," inside "," outside "," circumference "," circumferential direction "etc. are used in relation to the representation in the respective illustration in order to merely describe the utility model and, if necessary, to simplify the description . In other words, these terms are not used either implicitly or explicitly to indicate the positioning or the design and operation of the relevant system or the relevant element in a predetermined positioning, so that there is no restriction of the utility model here.

In the description of the present utility model, the term “several” refers to a number of at least two, for example two or three etc., unless otherwise stated.

In the present utility model, the terms “attach”, “interconnected”, “connect”, “fasten” or the like are to be understood in a broader sense, unless expressly stated and defined otherwise. So it can e.g. be a fixed, a detachable or a one-piece connection as well as a mechanical and also an electrical connection. In addition, direct connections, indirect connections or connections produced via an intermediate piece as well as internal connections between two elements or interactions between two elements are also conceivable, unless expressly defined otherwise. As an average specialist in this field, one can proceed from the facts in order to determine what meaning the terms mentioned should have according to the present utility model.

In the description, the explanation with reference to the terms such as “an exemplary embodiment”, “some exemplary embodiments”, “examples”, “specific examples” or “some examples” should be interpreted in such a way that specific features, structures, materials or properties that are explained on the basis of the exemplary embodiment or the example, are included in at least one exemplary embodiment or example of the present utility model. In the present description, the mention of the above terms does not necessarily refer to the same exemplary embodiment or example. Furthermore, the specific features, structures, materials or properties described can be combined with one another in a suitable manner within the scope of any one or more exemplary embodiments or examples. In addition, experts in this field can combine and merge various exemplary embodiments or examples explained in the description and their features with one another, provided that there is no contradiction.

So far, preferred exemplary embodiments have been described, which in no way serve to restrict the present utility model. Any modifications, equivalent substitutions and improvements within the framework of the basic ideas and principles of the utility model should be covered by the scope of protection of the utility model.

Claims (9)

Parasite in-vitro cultivation device in which real-time image recording can be made possible, characterized in that it comprises an upside-down biomicroscope (4), on the object table (1) of which a cultivation box (2) is provided for cultivating parasites , wherein a light source assembly (6) for providing a light source for the interior of the grow box (2) is provided above the object table (1) via a support mechanism, wherein at the top of the grow box (2) a through hole (11) for leading through the lowest Area of the light source assembly (6) is provided, via which through hole (11) the lowermost area of the light source assembly (6) protrudes into the grow box (2), the circumference of the light source assembly (6) being tightly connected to the inner wall of the through hole (11) , the lowermost area of the breeding box (2) being transparent, with an objective (8) of the upside-down biomicroscope ps (4) is arranged immediately below the stage (1), with one The eyepiece of the upside-down biomicroscope (4) has a camera assembly (5) for capturing an image viewed through the lens (8), with a temperature control assembly (7) on the inner wall of the grow box (2) for controlling the temperature inside the grow box (2) is provided and a sealed box door (10) is detachably provided on a side wall of the grow box (2). Parasite in-vitro breeding facility, which enables real-time image recording, according to Claim 1 , characterized in that the inner wall of the through hole (11) is provided with a sealing ring (12), the outer jacket wall of which is tightly and firmly connected to the inner wall of the through hole (11), the lowermost region of the light source assembly (6) being connected by a central one Hole of the sealing ring (12) passes and lies tightly against the inner wall of the sealing ring (12). Parasite in-vitro breeding facility, which enables real-time image recording, according to Claim 2 , characterized in that the support mechanism comprises a standing column (13) fixedly provided on the object table (1) and a connecting column (14), the lowermost area of which is inserted into the standing column (13), one with a column inside the standing column (13) its lowermost area connected mounting hole (15) is provided, the lowermost area of the connecting column (14) is inserted in the mounting hole (15) and is locked via a first locking bolt (16) provided on the side wall of the upright column (13), while on a horizontal support rod (17) is provided in the uppermost region of the connecting column (14), and the light source assembly (6) is fixedly arranged on the horizontal support rod (17) and is located directly above the through-hole (11). Parasite in-vitro breeding facility, which enables real-time image recording, according to Claim 3 , characterized in that an annular recess (18) is provided in the upper region of the connecting column (14), in which a rotary sleeve (19) is pushed, on the outer wall of which a second locking bolt (20) is provided for locking the rotary sleeve (19) is, and wherein one end of the horizontal support rod (17) is firmly connected to the outer jacket wall of the rotary sleeve (19). Parasite in-vitro breeding facility that enables real-time image recording, according to one of the Claims 1 to 4th , characterized in that a receiving recess (21) for receiving the breeding box (2) is provided on the upper surface of the object table (1), in which receiving recess (21) the lowermost area of the breeding box (2) is arranged. Parasite in-vitro breeding facility, which enables real-time image recording, according to Claim 5 , characterized in that a mounting space (22) for receiving the objective (8) is provided on the object table (1), which mounting space (22) is arranged directly below the receiving recess (21), the receiving recess (21) and the mounting space (22) are connected to one another via a connecting bore (23), and the specimen table (1) is provided on both sides with an opening connected to the assembly space (22). Parasite in-vitro breeding facility that enables real-time image recording, according to one of the Claims 1 to 4th , characterized in that it further comprises a display which is in communication with the camera assembly (5) and is used to display a real-time image recorded by the camera assembly (5). Parasite in-vitro breeding facility that enables real-time image recording, according to one of the Claims 1 to 4th characterized in that it further comprises a carbon dioxide concentration detection sensor (9) for monitoring the carbon dioxide concentration inside the grow box (2). Parasite in-vitro breeding facility, which enables real-time image recording, according to Claim 8 , characterized in that it further comprises a control device, with an air inlet for connecting to an external carbon dioxide source being provided on a side wall of the breeding box (2), on which air inlet a flow solenoid valve (3) is provided, and wherein the control device with the Flow solenoid valve (3) and the carbon dioxide concentration detection sensor (9) is electrically connected.

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