JP2021065821A - Controller, program, and solid-phase synthesis apparatus - Google Patents

Abstract

To provide a controller of a solid-phase synthesis apparatus, a program, and a solid-phase synthesis apparatus which contribute to a larger size of a solid-phase synthesis apparatus in a limited space.SOLUTION: A controller of a solid-phase synthesis apparatus, in which the solid-phase synthesis apparatus comprises: a plurality of chemical liquid containers 51 to 57, 61 to 65 which store each chemical liquid; and a reaction vessel 40 which allows a plurality of chemical liquid and material to react, in which the controller is equipped with a first UI screen generation part and an operation control part, the first UI screen generation part is constituted so as to generate a first UI screen for determining arrangement of the chemical liquid container. Herein, the first UI screen has a plurality of two-dimensionally arrayed cells, indicates an arranging place of the chemical liquid containers where cells arrayed in one out of the same array and row can be simultaneously arranged, and the operation control part controls the solid-phase synthesis apparatus so as to send chemical liquid from the chemical liquid containers to the reaction vessel 40 on the basis of the arrangement of the chemical liquid containers determined by using the first UI screen.SELECTED DRAWING: Figure 2

Description

The present invention relates to a control device, a program, and a solid phase synthesizer.

A synthesizer is used to selectively send a plurality of types of solutions for chemical synthesis (for example, Patent Document 1). Then, such a synthesizer has a control device and a device main body, and the device main body is controlled by the control device (computer).

JP-A-2018-167158

Among such synthesizers, a solid-phase synthesizer (for example, a peptide synthesizer) that uses a resin to cause a synthesis reaction on the resin surface is known. In the solid-phase synthesizer, the synthesis work must be performed in an explosion-proof area from the viewpoint of safety, and the area of the explosion-proof area is also limited by safety standards. Therefore, if the solid-phase synthesizer is enlarged for the purpose of performing a large amount of synthesis at one time, all the chemical containers cannot be arranged in the explosion-proof area.

The present invention has been made in view of such circumstances, and provides a control device, a program, and a solid-phase synthesizer for a solid-phase synthesizer that contributes to an increase in the size of the solid-phase synthesizer in a limited space. The purpose.

According to one aspect of the present invention, which is a control device for a solid-phase synthesizer, the solid-phase synthesizer comprises a plurality of chemical solution containers for storing each chemical solution and a reaction vessel for reacting a plurality of chemical solutions and raw materials. The control device includes a first UI screen generation unit and an operation control unit, and the first UI screen generation unit is configured to generate a first UI screen for determining the arrangement of the chemical solution container. Here, the first UI screen shows the arrangement location of the chemical solution container which has a plurality of cells arranged two-dimensionally and in which the cells arranged in one of the same rows and columns can be arranged at the same time, and the operation control unit. Provides a device that controls the solid-phase synthesizer so that the chemical solution is sent from the chemical solution container to the reaction vessel based on the arrangement of the chemical solution container determined by using the first UI screen. To.

By using such a control device, the synthesis reaction can be efficiently performed even if a large-sized solid-phase synthesizer in which the place where the chemical solution container is arranged is implemented. It has the above-mentioned advantageous effects.

It is a figure which shows the hardware structure of the solid phase synthesis apparatus 1 which concerns on this embodiment. It is a figure which shows the hardware composition of the apparatus main body 2. It is a block diagram which shows the hardware composition of the control device 3. It is a functional block diagram which shows the function of the control device 3 (control unit 33). An example of the first UI screen G1 generated by the first UI screen generation unit 332 is shown. An example of editing from the state of FIG. 5 is shown. An example of the second UI screen G2 generated by the second UI screen generation unit 335 is shown. It is an activity diagram which shows the process flow of the control device 3 which concerns on this embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The various features shown in the embodiments shown below can be combined with each other. In particular, in the present specification, the "part" may include, for example, a combination of hardware resources implemented by circuits in a broad sense and information processing of software that can be concretely realized by these hardware resources. .. Further, in this embodiment, various information is handled, and these information are represented by high and low signal values as a bit set of binary numbers composed of 0 or 1, and communication / calculation is executed on a circuit in a broad sense. Can be done.

A circuit in a broad sense is a circuit realized by at least appropriately combining a circuit, a circuit, a processor, a memory, and the like. That is, an integrated circuit for a specific application (Application Special Integrated Circuit: ASIC), a programmable logic device (for example, a simple programmable logic device (Simple Programmable Logical Device: SPLD), a composite programmable logic device (Complex Programg)). It includes a programmable gate array (Field Programmable Gate Array: FPRA) and the like.

1. 1. Hardware Configuration Section 1 describes the hardware configuration according to this embodiment.

1-1. Solid-phase synthesizer 1
FIG. 1 is a diagram showing a hardware configuration of the solid phase synthesizer 1 according to the present embodiment. FIG. 2 is a diagram showing a hardware configuration of the device main body 2.

As shown in FIG. 2, the solid-phase synthesizer 1 includes an apparatus main body 2 and a control apparatus 3. In particular, the apparatus main body 2 includes a plurality of chemical solution containers for storing each chemical solution and a reaction container 40 for reacting the plurality of chemical solutions and raw materials. The control device 3 is configured to control the operation of the device main body 2. Hereinafter, each component will be described in more detail.

1-2. Device body 2
The apparatus main body 2 according to the present embodiment includes a synthesis unit 4, a first container unit 5, and a second container unit 6. The synthesis unit 4 and the first container unit 5 are connected by a first pipe group 7 including a plurality of liquid feeding pipes 71 to 77. The synthesis unit 4 and the second container unit 6 are connected by a second pipe group 8 including a plurality of liquid feeding pipes 81 to 85.

The synthesis unit 4 includes a reaction vessel 40, a first measuring instrument 41, and a second measuring instrument 42. The reaction vessel 40 and the first measuring instrument 41 are connected by a first chemical solution supply pipe 45. The reaction vessel 40 and the second measuring instrument 42 are connected by a second chemical solution supply pipe 46. As a result, the chemical solution is supplied to the reaction vessel 40 from the first measuring instrument 41 or the second measuring instrument 42.

The first measuring instrument 41 is connected to the first container unit 5 via the first piping group 7, and the second measuring instrument 42 is connected to the second container unit 6 via the second piping group 8. The first container unit 5 includes a plurality of chemical liquid containers 51 to 57. The chemical liquid contained in each of the chemical liquid containers 51 to 57 is individually sent to the first measuring instrument 41 through the liquid feeding pipes 71 to 77 of the first pipe group 7. The second container unit 6 includes a plurality of chemical liquid containers 61 to 65. The chemicals contained in the chemical containers 61 to 65 are individually sent to the second measuring instrument 42 through the liquid feeding pipes 81 to 85 of the second pipe group 8. The first measuring instrument 41 and the second measuring instrument 42 constitute a liquid feeding destination container to which the chemical liquid is fed.

That is, the chemicals contained in the chemical containers 51 to 57 of the first container unit 5 are sent to the first measuring instrument 41 through the first piping group 7, weighed by the load cell, and then sent to the reaction vessel 40. Similarly, the chemicals contained in the chemical containers 61 to 65 of the second container unit 6 are sent to the second measuring instrument 42 through the second piping group 8, weighed by the load cell, and then sent to the reaction vessel 40. .. As described above, the solid-phase synthesizer 1 includes a plurality of chemical solution containers for storing each chemical solution and a reaction vessel 40 for reacting the plurality of chemical solutions and raw materials.

With such a configuration, the raw material and a plurality of chemical solutions can be sent to the reaction vessel 40 and stirred to cause a production reaction. Since the quantities of the chemical liquid containers 51 to 57 in the first container unit 5 and the chemical liquid containers 61 to 65 in the second container unit 6 are limited, if it is desired to use a chemical liquid in excess of this quantity in the synthetic reaction, It is necessary to change the contents or containers of the chemical liquid containers 51 to 57 and the chemical liquid containers 61 to 65.

1-3. Control device 3
FIG. 3 is a block diagram showing a hardware configuration of the control device 3. The control device 3 of the solid-phase synthesizer 1 includes a communication unit 31, a storage unit 32, a control unit 33, a display unit 34, and an input unit 35, and these components are the communication bus in the control device 3. It is electrically connected via 30. Each component will be further described.

<Communication unit 31>
Although wired communication means such as USB, IEEE1394, Thunderbolt, and wired LAN network communication are preferable, the communication unit 31 performs wireless LAN network communication, mobile communication such as LTE / 3G, Bluetooth (registered trademark) communication, and the like as necessary. May be included. That is, it is more preferable to carry out as a set of these plurality of communication means. The control device 3 is connected to the device main body 2 via a communication unit 31, and is configured to control the operation of the device main body 2.

<Memory unit 32>
The storage unit 32 stores various information defined by the above description. This is, for example, as a storage device such as a solid state drive (SSD), or a random access memory (Random Access Memory:) that stores temporarily necessary information (arguments, arrays, etc.) related to program operations. It can be implemented as a memory such as RAM). Moreover, these combinations may be used. In particular, the storage unit 32 stores various programs and the like related to the control device 3 executed by the control unit 33.

<Control unit 33>
The control unit 33 processes and controls the overall operation related to the control device 3. The control unit 33 is, for example, a central processing unit (CPU) (not shown). The control unit 33 realizes various functions related to the control device 3 by reading a predetermined program stored in the storage unit 32. Specifically, it corresponds to a display control function, a UI screen generation function, an operation control function, and the like. That is, the information processing by the software (stored in the storage unit 32) is specifically realized by the hardware (control unit 33), so that the reception unit 330, the display control unit 331, the first UI screen generation unit 332, It can be executed as a replacement unit 333, an empty cell insertion unit 334, a second UI screen generation unit 335, and an operation control unit 336. These will be described in more detail in Section 2.

Although it is described as a single control unit 33 in FIG. 2, it is not actually limited to this, and it may be implemented so as to have a plurality of control units 33 for each function. Moreover, it may be a combination thereof.

<Display unit 34>
The display unit 34 may be included in the housing of the control device 3, or may be externally attached, for example. The display unit 34 displays a screen of a graphical user interface (GUI) that can be operated by the user. For example, it is preferable to use display devices such as a CRT display, a liquid crystal display, an organic EL display, and a plasma display properly according to the type of the control device 3. The display device can selectively display the display screen in response to the control signal of the display control unit 331 in the control unit 33. For example, the first UI screen G1, the second UI screen G2, and the like can be visually displayed by the user.

<Input unit 35>
The input unit 35 may be included in the housing of the control device 3 or may be externally attached. For example, the input unit 35 may be implemented as a touch panel integrally with the display unit 34. If it is a touch panel, the user can input a tap operation, a swipe operation, and the like. Of course, instead of the touch panel, a switch button, a mouse, a QWERTY keyboard, or the like may be adopted. The input is transferred as a command signal to the control unit 33 via the communication bus 30, and the control unit 33 can execute a predetermined control or calculation as needed. That is, the user can give an instruction to the control device 3 by using the input unit 35.

In particular, the user can determine the arrangement of a plurality of chemical solution containers for storing each chemical solution while looking at the first UI screen G1 displayed on the display unit 34 using the input unit 35. Further, the user can determine the operation to be executed by the solid-phase synthesizer 1 while looking at the second UI screen G2.

2. Functional configuration Section 2 describes the functional configuration according to this embodiment. FIG. 4 is a functional block diagram showing the functions of the control device 3 (control unit 33).

Regarding the above-mentioned control unit 33, the control device 3 of the solid-phase synthesis device 1 includes a reception unit 330, a display control unit 331, a first UI screen generation unit 332, a replacement unit 333, an empty cell insertion unit 334, and the like. It includes a 2UI screen generation unit 335 and an operation control unit 336. Hereinafter, each component will be further described.

[Reception Department 330]
In the reception unit 330, information processing by software (stored in the storage unit 32) is specifically realized by hardware (control unit 33). The reception unit 330 is configured to receive an instruction input by the user via the input unit 35.

In particular, the reception unit 330 is configured to receive an input instruction for determining the arrangement of a plurality of chemical solution containers for storing each chemical solution to be sent. Further, the reception unit 330 is configured to receive an input instruction for determining an operation to be executed by the solid-phase synthesizer 1.

[Display control unit 331]
In the display control unit 331, information processing by software (stored in the storage unit 32) is specifically realized by hardware (control unit 33). The display control unit 331 determines the screen to be displayed on the display unit 34. For example, the display control unit 331 can display the first UI screen G1 and the second UI screen G2, and a plurality of chemical solution containers for storing each chemical solution that can be input to the first UI screen G1 and the second UI screen G2 on the display unit 34 so that the user can visually display them.

[1st UI screen generator 332]
In the first UI screen generation unit 332, information processing by software (stored in the storage unit 32) is specifically realized by hardware (control unit 33). The first UI screen generation unit 332 is configured to generate the first UI screen G1 for determining the arrangement of a plurality of chemical liquid containers for storing each chemical liquid to be sent. FIG. 5 shows an example of the first UI screen G1 generated by the first UI screen generation unit 332.

The first UI screen G1 has a plurality of cells C arranged two-dimensionally, and indicates an arrangement location of a chemical solution container in which cells C arranged in one of the same rows and columns can be arranged at the same time. In this example, the chemicals 1 to 4 described in cells C arranged in the same row i are set to be able to be arranged at the same time, and the chemical solutions 5 to 8 described in cells C arranged in the same row ii are set to be able to be arranged simultaneously. It is set that the chemical solutions 9 and 10 described in cell C arranged in the same row iii can be arranged at the same time. In addition, the upper part of the chemical solution shows the order of sending the solution. Such an order may be configured to be settable on the first UI screen G1, or may be set on another UI (not shown).

A1 to A7 described in the heading line indicate the location of the chemical solution container. A1 to A7 correspond to, for example, the placement locations of the chemical liquid containers 51 to 57. Check boxes A1 to A7 are provided at the upper part of the first UI screen G1, and the user can check the arrangement location to be used. In this example, since A1 to A4 are checked, A1 to A4 are used as the placement location.

As described in [Problems to be Solved by the Invention], if the solid-phase synthesizer 1 is enlarged, the arrangement locations of a plurality of chemical liquid containers for storing each chemical liquid to be sent are limited. Since the present embodiment has a configuration in which the placement location of the chemical solution container can be visually confirmed in advance, it is advantageous that the solid-phase synthesizer 1 can be efficiently used even in a limited placement location. It works.

It is preferable to determine the specific arrangement of the chemical solution container in consideration of the number of cleanings of the first piping group 7 and the second piping group 8 and the like. For example, when there is a possibility of using the same chemical solution, it is preferable to arrange them in the same row. In editing the specific arrangement location, the user can use the replacement of the cell C by the replacement unit 333 and the insertion of the empty cell C0 by the empty cell insertion unit 334, which will be described next. FIG. 6 shows an example when editing is performed from the state of FIG.
[Replacement section 333]
In the replacement unit 333, information processing by software (stored in the storage unit 32) is specifically realized by hardware (control unit 33). The replacement unit 333 is configured to be able to replace any two cells C among the plurality of cells C on the first UI screen G1.

When the user selects two cells C to be replaced and presses the replacement button B1, the two selected cells C are replaced. For example, in the example shown in FIG. 6, the result of replacing the chemical solution 2 and the chemical solution 3 from the state shown in FIG. 5 is shown.

[Empty cell insertion part 334]
In the empty cell insertion unit 334, information processing by software (stored in the storage unit 32) is specifically realized by hardware (control unit 33). The empty cell insertion unit 334 is configured so that the empty cell C0 can be inserted into a plurality of cells C two-dimensionally arranged on the first UI screen G1. Here, the empty cell C0 indicates an arrangement location that is not intentionally used. Specifically, when the user presses the empty cell insertion button B2, the empty cell C0 is inserted.

By the way, in the present embodiment, the insertion of the empty cell C0 may include not only inserting the empty cell C0 between two consecutive cells C but also replacing one cell C with the empty cell C0. For example, in the example shown in FIG. 6, an empty cell C0 is inserted between the chemical solution 6 and the chemical solution 7. Along with this, the positions of cells C of the chemical solutions 7 to 10 are shifted one by one. When the user presses the empty cell deletion button B3, the empty cell C0 may be deleted.

[2nd UI screen generator 335]
In the second UI screen generation unit 335, information processing by software (stored in the storage unit 32) is specifically realized by hardware (control unit 33). The second UI screen generation unit 335 is configured to generate the second UI screen G2 for determining the operation to be executed by the solid phase synthesizer 1. FIG. 7 shows an example of the second UI screen G2 generated by the second UI screen generation unit 335.

The operation to be executed by the solid-phase synthesizer 1 includes, for example, how much and how much liquid is sent from which chemical liquid container. Specifically, the user presses the read button in the operation list edit of the second UI screen G2, and in the function edit on the right side of the second UI screen G2, the user is stored in the chemical solution container whose arrangement is determined on the first UI screen G1. Determine the operation such as the weight of the chemical solution to be sent and the time to send the liquid.

Here, in the present embodiment, the arrangement of the chemical solution container determined by using the first UI screen G1 is automatically reflected on the second UI screen G2. For example, in FIG. 7, when the operation “condensation” is selected and read, the function “A bottle feeding” reflects A3, which is the arrangement set on the first UI screen G1 in the function list editing. By automatically reflecting the arrangement of the chemical solution container in this way, the user does not have to re-enter the arrangement location of the chemical solution container determined on the first UI screen G1 on the second UI screen G2. That is, it has an advantageous effect of contributing to more efficient work.

[Motion control unit 336]
In the operation control unit 336, information processing by software (stored in the storage unit 32) is specifically realized by hardware (control unit 33). The operation control unit 336 controls the solid-phase synthesizer 1 so as to send the chemical solution from the chemical solution container to the reaction vessel 40 based on the arrangement of the chemical solution container determined by using the first UI screen G1. More specifically, the motion control unit 336 transfers the chemical solution from the chemical solution container based on the operation determined using the second UI screen G2 in which the arrangement of the chemical solution container determined by using the first UI screen G1 is reflected. The solid-phase synthesizer 1 is controlled so as to send the solution to the reaction vessel 40.

3. 3. Process flow of the control device 3 Section 3 describes the process flow of the control device 3 described above. FIG. 8 is an activity diagram showing a processing flow of the control device 3 according to the present embodiment. Hereinafter, each activity in FIG. 8 will be described.

[from here]
(Activity A01)
The user uses a UI (not shown) to determine the sequence of the drug solution to be used in the synthesis.

(Activities A02a, A02b)
Subsequently, the first UI screen G1 is displayed on the display unit 34. Specifically, the reception unit 330 accepts the user's input, subsequently, the first UI screen generation unit 332 generates the first UI screen G1, and the display control unit 331 displays this on the display unit 34. Using this, the user performs an editing operation to determine the arrangement of the drug solution container. Specifically, the user may replace any two cells C among the plurality of cells C arranged in two dimensions (A02a), or empty cells in the plurality of cells C arranged in two dimensions. C0 may be inserted (A02b).

(Activity A03)
Subsequently, the second UI screen G2 is displayed on the display unit 34. Specifically, the reception unit 330 accepts the user's input, subsequently, the second UI screen generation unit 335 generates the second UI screen G2, and the display control unit 331 displays this on the display unit 34. Using this, the user determines the operation to be executed by the solid-phase synthesizer 1. For example, the weight of each chemical solution to be sent by the user, the time to send the solution, and the like are input.

(Activity A04)
Based on the operation determined using the second UI screen G2, the solid-phase synthesis apparatus 1 is controlled to perform solid-phase synthesis so that the chemical solution is sent from the chemical solution container to the reaction vessel 40.
[to this point]

According to such a method, it is possible to efficiently determine the arrangement of a plurality of chemical solution containers for storing each chemical solution to be sent.

4. Modification Example Section 4 describes a modification of the present embodiment. That is, the following aspects may be adopted.
(1) The first UI screen G1 and the second UI screen G2 are examples, and are not limited to this form.
(2) The contents stored in the storage unit 32 may be synchronized with an external shared server or the like and used for the solid-phase synthesizer 1 located at another location.
(3) The control device 3 may further include an optimization example presentation unit (not shown). The optimization example presentation unit may be configured to present an optimization example of the arrangement of the chemical solution container on the first UI screen G1 based on the type and order of the chemical solution to be sent.
(4) A program that causes the computer to function as the control device 3 may be provided. This program may be pre-installed, may be installed after the fact, such a program may be stored in an external storage medium, or may be operated by cloud computing.

5. Conclusion As described above, according to the present embodiment, the control device, program, and solid-phase synthesizer of the solid-phase synthesizer that contributes to the increase in size of the solid-phase synthesizer can be implemented in a limited space.

It may be provided in each of the following aspects.
The control device further includes a replacement unit, which is configured to be capable of replacing two selected cells among the plurality of cells on the first UI screen.
The control device further includes an empty cell insertion unit, and the empty cell insertion unit is configured so that an empty cell can be inserted into the plurality of cells arranged two-dimensionally on the first UI screen. Indicates the placement location that is not intentionally used.
The control device further includes a second UI screen generation unit, and the second UI screen generation unit is configured to generate a second UI screen for determining an operation to be executed by the solid-phase synthesizer. The arrangement of the chemical solution container determined using the screen is automatically reflected on the second UI screen.
The control device further includes an optimization example presentation unit, and the optimization example presentation unit provides an optimization example of the arrangement of the chemical solution container on the first UI screen based on the type and order of the chemical solution to be sent. What is configured to present.
A program that causes a computer to function as the control device.
It is a solid-phase synthesizer and includes an apparatus main body and a control device. The apparatus main body includes a plurality of chemical solution containers for storing each chemical solution and a reaction vessel for reacting a plurality of chemical solutions and raw materials, and the control thereof. The device is the control device, which is configured to control the operation of the device body.
Of course, this is not the case.

Finally, various embodiments of the present invention have been described, but these are presented as examples and are not intended to limit the scope of the invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the gist of the invention. The embodiment and its modifications are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and the equivalent scope thereof.

1: Solid phase synthesizer 2: Device main body 3: Control device 30: Communication bus 31: Communication unit 32: Storage unit 33: Control unit 330: Reception unit 331: Display control unit 332: First UI screen generation unit 333: Replacement unit 334: Empty cell insertion unit 335: Second UI screen generation unit 336: Operation control unit 34: Display unit 35: Input unit 4: Synthesis unit 40: Reaction vessel 41: First measuring instrument 42: Second measuring instrument 45: First Chemical solution supply pipe 46: Second chemical solution supply pipe 5: First container unit 51: Chemical solution container 52: Chemical solution container 53: Chemical solution container 54: Chemical solution container 55: Chemical solution container 56: Chemical solution container 57: Chemical solution container 6: Second container unit 61: Chemical solution container 62: Chemical solution container 63: Chemical solution container 64: Chemical solution container 65: Chemical solution container 7: First piping group 71: Liquid feeding pipe 72: Liquid feeding piping 73: Liquid feeding piping 74: Liquid feeding piping 75: Liquid feeding pipe 76: Liquid feeding pipe 77: Liquid feeding pipe 8: Second pipe group 81: Liquid feeding pipe 82: Liquid feeding pipe 83: Liquid feeding pipe 84: Liquid feeding pipe 85: Liquid supply piping B1: Replacement button B2: Empty cell insert button B3: Empty cell delete button C: Cell C0: Empty cell G1: 1st UI screen G2: 2nd UI screen

Claims (7)

It is a control device for solid-phase synthesis equipment.
The solid-phase synthesizer includes a plurality of chemical solution containers for storing each chemical solution and a reaction vessel for reacting a plurality of chemical solutions and raw materials.
This control device includes a first UI screen generation unit and an operation control unit.
The first UI screen generation unit is configured to generate a first UI screen for determining the arrangement of the chemical solution container, wherein the first UI screen has a plurality of cells arranged two-dimensionally and is the same. Indicates the location of the chemical container in which the cells arranged in one of the rows and columns of the above can be arranged at the same time.
The operation control unit controls the solid-phase synthesizer so as to send the chemical solution from the chemical solution container to the reaction vessel based on the arrangement of the chemical solution container determined using the first UI screen. thing. In the control device according to claim 1,
With a replacement section
The replacement unit is configured so that two selected cells among the plurality of cells on the first UI screen can be replaced. In the control device according to claim 1 or 2.
An empty cell insertion unit is further provided, and the empty cell insertion unit is configured so that an empty cell can be inserted into the plurality of cells arranged two-dimensionally on the first UI screen, and the empty cell is intentionally referred to here. An indication of the location that is not used. In the control device according to any one of claims 1 to 3.
Further equipped with a second UI screen generator
The second UI screen generation unit is configured to generate a second UI screen for determining an operation to be executed by the solid-phase synthesizer, and the arrangement of the chemical solution container determined by using the first UI screen is described. It is configured to be automatically reflected on the 2nd UI screen. In the control device according to any one of claims 1 to 4.
Further equipped with an optimization example presentation section,
The optimization example presentation unit is configured to present an optimization example of the arrangement of the chemical solution container on the first UI screen based on the type and order of the chemical solution to be sent. It ’s a program
A computer that functions as a control device according to any one of claims 1 to 6. It is a solid phase synthesizer
Equipped with a device body and a control device,
The apparatus main body includes a plurality of chemical solution containers for storing each chemical solution and a reaction container for reacting a plurality of chemical solutions and raw materials.
The control device is the control device according to any one of claims 1 to 6.
A device configured to control the operation of the device body.

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