WO2020016123A1 - Système de gestion de laboratoire - Google Patents

Système de gestion de laboratoire Download PDF

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Publication number
WO2020016123A1
WO2020016123A1 PCT/EP2019/068790 EP2019068790W WO2020016123A1 WO 2020016123 A1 WO2020016123 A1 WO 2020016123A1 EP 2019068790 W EP2019068790 W EP 2019068790W WO 2020016123 A1 WO2020016123 A1 WO 2020016123A1
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WO
WIPO (PCT)
Prior art keywords
computer system
substance
basic operation
batch
data
Prior art date
Application number
PCT/EP2019/068790
Other languages
German (de)
English (en)
Inventor
Marcus RHENIUS
Original Assignee
Bayer Business Services Gmbh
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Bayer Business Services Gmbh filed Critical Bayer Business Services Gmbh
Publication of WO2020016123A1 publication Critical patent/WO2020016123A1/fr

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Classifications

    • GPHYSICS
    • G16INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
    • G16HHEALTHCARE INFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR THE HANDLING OR PROCESSING OF MEDICAL OR HEALTHCARE DATA
    • G16H10/00ICT specially adapted for the handling or processing of patient-related medical or healthcare data
    • G16H10/40ICT specially adapted for the handling or processing of patient-related medical or healthcare data for data related to laboratory analysis, e.g. patient specimen analysis

Definitions

  • the present invention is concerned with performing processes in a laboratory.
  • the present invention comprises a method, a system and a computer program for carrying out processes in a laboratory.
  • a laboratory is a place to research or use scientific processes.
  • the term laboratory includes closed rooms (e.g. laboratory rooms, greenhouses) as well as open areas (e.g. in field experiments).
  • Processes that are carried out in a laboratory include experiments, process controls, quality controls, tests and measurements (especially calibrations) as well as the production and / or processing of chemical and / or biological substances.
  • L1MS laboratory information management system
  • L1S laboratory information system
  • LMS laboratory management system
  • laboratory management systems are described for example in EP2715626A1, US2003028501A and US2005273272A.
  • the areas for planning and / or evaluating processes are spatially separated from the areas for executing the processes.
  • One reason for this is that the execution area often deals with substances that can have a harmful impact on people and / or the environment, and the length of time in the execution area is reduced by the fact that work that does not require handling of harmful substances be moved to other areas (planning and / or evaluation area).
  • a first object of the present invention is a method comprising the following steps
  • Another object of the present invention is a system comprising
  • the at least one computer system and the device being connectable to one another directly or via a network
  • the input defining a
  • Process whereby the process definition includes:
  • Representation of the substance, the process plan and the process parameters comprises displaying an overview of the process on a screen of the at least one computer system
  • connection being used to establish a connection between the at least one computer system and the device Link the digital representation of the substance to a batch of the substance
  • Another object of the present invention is a computer program product comprising a program code which is stored on a data carrier and which causes a computer to carry out the following steps when the program code is loaded into the main memory of the computer:
  • the process parameter set comprising a digital representation of a substance, a process plan and process parameters
  • Receiving input from a user comprising:
  • a "process” is a directed sequence of events.
  • a process can be planned and carried out according to the planning.
  • a process in the sense of the present invention is carried out in a laboratory.
  • a laboratory is a place to research or use scientific processes.
  • the term laboratory includes closed spaces (e.g. laboratory rooms, greenhouses) as well as open spaces (e.g. in field experiments).
  • a laboratory is preferably an enclosed space in a building.
  • the process that is to be carried out is determined on a computer system.
  • the computer system for determining the process is preferably a stationary computer system. It is also conceivable that it is a mobile computer system or a computer system with mobile components.
  • a stationary computer system In contrast to a mobile computer system, a stationary computer system is a stationary computer system such as a desktop computer or a tower computer.
  • the term "stationary" should not be understood to mean that the computer system cannot be transported, but that a transportability, as is the case with mobile computer systems, is not necessary and not common.
  • stationary computer systems are equipped with monitors that have a screen size of at least 17 inches (to ensure comfortable work); Frequent transportation of such systems from one location to another (for example from the planning and / or evaluation area to the execution area) is impractical. In a stationary computer system, more value is placed on convenient and convenient usability than on portability.
  • the stationary computer system is also referred to as a workstation computer.
  • a mobile computer system is a computer system that a person can easily carry from one location to another location (for example from the planning and / or evaluation area to the execution area and / or vice versa).
  • Examples of mobile computer systems are tablet computers, handheld computers, smart watches, smartphones, smart glasses (data glasses).
  • a computer system with mobile components is a computer system in which components are designed such that a person can take them from one place to a place, while other components are not intended to be carried but rather remain in one place.
  • An example of a computer system with mobile components is a tablet computer which is connected to a larger monitor and / or to a mouse and / or to a keyboard and / or to a printer and / or the like (hereinafter also referred to as peripherals) can (e.g. via a docking station), the periphery usually remaining in one place to enable convenient working at the location, while the tablet computer can be carried by the person from one location to another location and at any location is operational without the periphery.
  • At least two computer systems are used to implement the invention; a stationary computer system that is used in the planning and / or evaluation area and a mobile computer system that is used in the execution area.
  • the system according to the invention can also comprise several computer systems. Depending on the particular step that is carried out, this can be a stationary or a mobile computer system; it can be the same computer system or different computer systems at different steps be used. All steps that are carried out in the execution area are preferably carried out with a mobile computer system, while all steps that are carried out in the planning and / or evaluation area are preferably carried out with a stationary or a mobile computer system, which is the mobile computer system can act the same computer system used in the execution area.
  • Entries and / or selections on a computer system are usually made by means of input means belonging to the computer system or to the periphery, such as a keyboard, a mouse, a touchscreen, a microphone, a scanner and the like.
  • Outputs usually take place in a computer system by means of output means belonging to the computer system or the periphery, such as a screen (monitor), a loudspeaker, a printer or the like.
  • Activities that are carried out in the execution area are those activities in which the at least one substance and / or a device is / are used to carry out a basic operation. Activities that are carried out in the planning and / or evaluation area are those activities in which neither a substance nor a device is used to carry out a basic operation.
  • a process in the sense of the present invention requires the definition of at least one substance.
  • the at least one substance is the object that is being processed.
  • a substance in the sense of the present invention is a chemical or biological substance or a mixture of substances.
  • the substance can also be a material sample or the like.
  • the substance is usually in a container.
  • the amount of the substance in the container is also referred to here as the batch of the substance. If the substance is not in a container, the real embodiment of the substance is also called a batch.
  • a digital representation of the substance is entered into the computer system and / or selected on the computer system.
  • a digital representation of a substance is, for example, the name of the substance, the (chemical) structural formula of the substance, a unique identifier (for example an identification number) of the substance or the like.
  • a substance is at least generically specified on the basis of the digital representation.
  • a process plan is entered into the computer system and / or selected on the computer system.
  • the process plan describes what should happen to the at least one substance.
  • the defined process plan is usually in the form of a description in text form or is created as text. However, it can also be available in the form of a graphic or be enriched by graphic elements. If the process is a chemical reaction (conversion) of a substance with another substance, it is recommended to use conventional reaction equations to define the process and / or to enrich the description of the process plan.
  • Process parameters are also entered into the computer system and / or selected or calculated on the computer system. Typical process parameters are, for example, the amount of the at least one substance, its purity, a temperature, a pressure, a speed, a time period and the like.
  • a process usually consists of a number of steps.
  • the definition of basic steps has become established in many areas.
  • Basic steps also called basic operations in the following, are often recurring operations that lead to a process (intermediate) result, are comparatively easy to describe and are characterized by a manageable number (usually less than 10) of parameters.
  • Examples of basic operations within the meaning of the present invention are: weighing, measuring, dissolving, mixing, stirring, heating, cooling, distilling off, evaporating, reacting (reacting), filtering, sieving, crushing, washing, extracting, drying, adding and the like ,
  • Stirring can be characterized, for example, by the stirrer to be used, a stirring speed and a stirring time. Homogenization of a mixture is achieved, for example, by stirring; the process (intermediate) result is a homogenized mixture.
  • the process plan includes a description of actions that are to be carried out with the at least one substance and that is primarily aimed at a person who is to carry out the corresponding actions in the laboratory (action description).
  • the main difference between an action description and a sequence of basic operations is that the basic operations represent separate, well-defined blocks that can be edited and / or edited independently of one another, while the action description describes the process in free form.
  • a process plan can also be a mixture of an action description and a sequence of basic operations.
  • the computer system is configured to transform the process plan into a sequence of basic operations based on an action description.
  • the computer system can be configured to search the action description for keywords and to generate a sequence of basic operations based on the identified keywords.
  • Such an automatically generated process can be displayed to a user who can change and / or add to the process.
  • the computer system is configured to generate a process parameter set from the information about the defined process.
  • the process parameter set comprises information about the at least one substance that is to be processed, about the process plan, ie the actions that are to be carried out on and / or with the at least one substance, and the process parameters.
  • the process parameter set is a digital data set that can be transmitted, for example, from a stationary computer system to a mobile computer system.
  • the Transmission preferably takes place via a network via which the two computer systems can be connected to one another. It is preferably a wireless network, preferably a radio network. However, a wired connection between the computer systems is also conceivable, via which the process parameter set (and the process results) can be transmitted from one computer system to the other computer system.
  • the substance, the process plan and the process parameters can be present in the process parameter set in the same digital representation in which they are also present on the stationary computer system and / or on the mobile computer system.
  • the data is usually available in compressed form in the process parameter set.
  • a preferred procedure includes that a person plans a process on a stationary workstation computer, and the planning data is then transferred (preferably automatically, possibly by pressing a virtual button) to a mobile computer system.
  • the mobile computer system is designed so that the person can (comfortably) take it to an execution area of the laboratory.
  • the computer system is configured to generate an overview of the defined process and to display this overview on a screen.
  • An overview of a process is a representation of the process, based on which a user can see what kind of process it is.
  • An overview can be a name in text form and / or a reaction equation in graphical form and / or the like or comprise the elements mentioned.
  • a description of the action is displayed as the process description, the person can select a basic operation from a virtual menu bar that is part of the description of the action and that is to be carried out as the next step.
  • a device with which the basic operation is carried out is usually required in addition to the at least one substance which is to be subjected to the basic operation.
  • devices for performing a basic operation are: scales, stirrers, heating devices, cooling devices, distillation systems, shakers, dosing devices, filtering devices, timepieces and the like.
  • a person links the digital representation of the at least one substance with a real batch of the substance and the basic operation to be carried out with a (real) device.
  • the computer system is informed with which batch of substance and with which device the process or a basic operation of the process is carried out.
  • the batch of the substance and the device each have a unique identifier.
  • the batch of the substance and the device can be clearly identified on the basis of their unique identifiers.
  • the unique identifier can be connected in machine-readable form to the substance or a container in which the substance is located, or to the device.
  • the unique identifier can be attached, for example, as an optically readable code (e.g. as a bar code or as a matrix code (e.g. QR code or data matrix code)) in the form of a label. It is also conceivable for an optically readable code to be printed, engraved, lasered, etched or otherwise inserted or attached. It is also conceivable to use RFID labels or comparable semiconductor memories which can be read by radio and in which the unique identifier is stored.
  • the device is registered in the same network as the computer system or a direct connection between the device and the computer system exists or can be established.
  • a person it is conceivable for a person to be shown, via the computer system, a list of devices which are connected directly or indirectly (via a network) to the computer system. From the list, the person can select a device for performing a basic operation.
  • the MAC address (media access control address) of the device functions as a unique identifier of the device.
  • the service set identifier (SS1D) of the device connected via WLAN functions as a unique identifier of the device.
  • the PAN-1D of the device connected via a ZigBee network functions as a unique identifier of the device.
  • the Bluetooth name of the device connected via Bluetooth functions as a unique identifier of the device.
  • the linking of the digital representation of the substance with the batch of the substance and the linking of the basic operation with the device serve to link between the virtual (digital), i.e. world represented in the computer system with the real (physically real) world.
  • the link is usually established by first selecting the digital representation (of the substance or the basic operation) and in a subsequent step the unique identifier of the corresponding real object being recorded using a suitable reading device (barcode scanner, camera, RFID reader or the like) , The reverse order of the steps is also conceivable.
  • the detected unique identifier is assigned to the corresponding digital representation in the computer system and this assignment is saved.
  • a database is preferably present, in which information about the object is stored for the respective unique identification of the real object (batch of substance, device).
  • Information that can be stored about a substance / a batch of a substance is, for example, batch name, date of manufacture, manufacturer, storage conditions, hazard warnings, quantity present, purity, contamination, shelf life, delivery time and / or the like.
  • Information that can be stored via a device is, for example, manufacturer, technical specifications, location, hazard warnings, maintenance times and / or the like.
  • Linking the digital representation of the substance with the batch of the substance can have the aim of capturing the batch of a substance with which a basic operation was carried out.
  • a batch name is therefore determined on the basis of the unique identifier and linked to the digital representation of the at least one substance.
  • a process result can be assigned to a defined batch. This can be advantageous if, for example, an unexpected result arises that raises questions for the clarification of which knowledge about the batch actually used is useful, for example because it turns out that the batch is contaminated.
  • the unique identifier of the substance is recorded, information on the substance is determined from a database on the basis of the unique identifier (eg substance name and / or structural formula), and it is determined whether the batch of the substance is from a chemical or biological point of view, the same substance acts as the digitally represented substance. It is conceivable that a person accidentally grabs the wrong substance. By recording the unique identifier and comparing data, it is therefore possible to recognize a wrongly selected substance and to alert the person to their mistake by means of a warning.
  • the unique identifier eg substance name and / or structural formula
  • the quantity of the real substance still available from the real substance is determined on the basis of the unique identifier of the real substance and compared with the quantity to be used in the basic operation according to the process plan. In the event that the amount of real substance still available is less than the amount to be used in the basic operation, a warning notice will be issued. It is also conceivable that the process plan is automatically adapted to the quantity still available. It is also conceivable that the quantity stored in the database is updated by subtracting the quantity to be used according to the process plan from the quantity currently stored in the database. It is also conceivable that such an update is only carried out after the real substance has been weighed out.
  • safety information is determined on the basis of the unique identification of the real substance from a database and compared with information in the process plan and / or with the process parameters in order to determine whether the intended actions and the process parameters are compatible with the substance. For example, it is conceivable that the substance decomposes above a temperature limit. If the substance is to be heated to a temperature above the temperature limit in accordance with the process plan and process conditions, the substance and the process plan / process parameters would not be compatible with one another. In such a case, a warning notice can be issued.
  • An analogous procedure can take place if an action according to the process plan provides for the contacting of two substances which, according to the safety information, should not be brought into contact under the planned conditions; for example because an uncontrollable reaction threatens.
  • technical specifications of the device are determined from a database on the basis of the unique identifier of the device, in order to compare this with information in the process plan and / or with the process parameters, and to determine whether the device is suitable for the planned actions ,
  • two substances should be stirred together at a stirring speed of at least 1500 revolutions per minute in order to achieve a homogeneous mixture. It is conceivable that the selected device achieves a maximum stirring speed of 1200 revolutions per minute. Based on the unique identifier, the maximum stirring speed of the stirrer is determined in a database and compared with the corresponding process parameter. If the maximum stirring speed is lower than the required stirring speed, a warning notice can be issued.
  • an amount of 1 mg of a substance should be weighed out.
  • a person selects a scale as a device with which the corresponding amount is to be weighed.
  • the accuracy of the balance is determined in a database. If the accuracy of the scale is below the required accuracy, a warning notice can be issued.
  • the scale can have an accuracy of 5 mg; such a scale is not suitable for weighing an amount of 1 mg; a warning notice can be issued.
  • the device for performing a basic operation is connected or connectable to the computer system via a network or directly. Through such a connection, data can be transmitted from the computer system to the device and / or data can be transmitted from the device to the computer system.
  • a connection between the device and the device also takes place together with the linkage of a basic operation with a device computer system.
  • process parameters are transmitted from the computer system to the device and / or process data are transmitted from the device to the computer system.
  • Transferring data between the device and the computer system has the advantage that the data does not have to be entered manually. In addition to an increase in efficiency, this also prevents incorrect entries.
  • the process plan provides for heating the at least one substance to a target temperature T.
  • the process parameter T can be transferred from the computer system to the device via the connection between the computer system and the device (for example a heater) be transmitted.
  • the device receives the set temperature T and sets it.
  • the amount of a substance should be weighed according to the process plan.
  • the result of the weighing can be transmitted from the device to the computer system via the connection between the computer system and the device.
  • process parameters are updated on the basis of transmitted process data.
  • a process parameter for example, a quantity of the at least one substance of 1 g is weighed out.
  • a person links the basic operation to a real device (e.g. a scale). The link creates a connection between the device and the computer system.
  • the basic operation is carried out by means of the device (for example filling the at least one substance into a weighing pan until the scale shows 1 g).
  • the device transfers process data to the computer system.
  • the computer system is configured in such a way that it compares the transferred process data with the process parameters.
  • the process plan provides a reaction between two substances A and B, each of which is to be weighed in at 1 g, and substance A has been weighed in at 1.04 g, it is conceivable that the required weights of the Substances A and B are set to 1, 04 g as a result of an update.
  • Another step of the method according to the invention is to carry out a basic operation with at least part of the batch of the substance with the aid of the device.
  • the execution can be done by the user. However, it is also conceivable that the execution is automated (i.e. without manual intervention by the user). It is also conceivable that one or more actions are carried out by the user and one or more actions take place automatically.
  • execution of the basic operation is tracked (monitored) by the computer system using the device.
  • the basic operation involves adding a quantity M of a substance A from a vessel G A TO a substance B in a vessel G B with the aid of a dosing unit.
  • the dosing is started; the computer system tracks the dosage, for example, followed by the temporal change in the amount of remaining in the vessel G A substance A and / or the amount of landed in the vessel G B B substance.
  • process (intermediate) results are recorded by the computer system for documentation purposes and / or for further processing and / or for evaluation.
  • a process result is a result of the whole process. Such a result can also be called the process end result.
  • An intermediate process result is the result of executing a basic operation.
  • process (intermediate) result means that a result can be a process result or an interim process result.
  • the acquisition of process (intermediate) results comprises two steps: the recording of process data and / or events and the generation of a result data record on the basis of the recorded information.
  • recording is understood to mean capturing, possibly processing and storing.
  • the detection can take place during the execution of a basic operation and / or afterwards. Recording can be continuous or sequential.
  • each event receives a time stamp; the timestamp indicates the point in time (or the time span) at which the event occurred.
  • Process (intermediate) results and / or events can be recorded, for example, by recording a digital video sequence with a camera, wherein the camera can be part of the computer system or can be connected to it. Digital image recordings (digital photos) are also possible. It is also conceivable that a user records observations by entering them into the computer system via an input means, e.g. via a microphone via voice message or a (virtual or real) keyboard via text message.
  • the process (intermediate) results are assigned to the respective basic operations and the higher-level process and are stored on the computer system and / or in a data memory which is connected to the computer system via a network. They can be called up later to edit them and / or to use them as a basis for planning further processes.
  • a user preferably inputs events via a microphone into the at least one computer system.
  • Speech recognition software is preferably installed, which converts the spoken words into written text.
  • Fig.l shows schematically an embodiment of the system according to the invention.
  • the system comprises a first computer system (10), a second computer system (20) and a device (30) for performing a basic operation.
  • the first and second computer systems are interconnected (represented by the dashed line). Via this connection, data can be transmitted from the first computer system (10) to the second computer system (20) and / or from the second computer system (20) to the first computer system (10).
  • the second computer system (20) and the device (30) are also connected to one another (represented by the dashed line). Via this connection, data can be transmitted from the second computer system (20) to the device (30) and / or from the device (30) to the second computer system (20).
  • the system comprises a first computer system (10), which is designed as a stationary computer system, a second computer system (20), which is designed as a mobile computer system, a first device (30a) for performing a basic operation, the first device ( 30a) is an agitator, and a second device (30b) for performing a basic operation, the second device (30b) being a balance.
  • the first computer system (10) is located in a planning and / or evaluation area (P); the Devices (30a, 30b) and the second computer system (20) are located in an execution area (A).
  • the system comprises a first computer system (10), which is designed as a stationary computer system, a second computer system (20), which is designed as a mobile computer system, a first device (30a) for performing a basic operation, which is an agitator, a second device (30b) for performing a basic operation, which is a balance, a data memory (60) and a server (50).
  • the system forms a network; the first computer system (10), the second computer system (20), the stirrer (30a), the balance (30b) and the data memory (60) are connected to the server (50).
  • the first computer system (10) can for example be connected to the server (50) via a LAN
  • the second computer system (20) can for example be connected to the server via a WLAN
  • the database (60) can for example be connected to the server (50) via a direct connection (e.g. USB).
  • the mixing device (30a) and the balance (30b) can be connected to the server (50), for example, via a connector, as is sold by the company cubuslab (https://www.cubuslab.com).
  • Fig. 4 shows an example of how a container (40) for a substance and a scale (30) can each be provided with a unique identifier.
  • An RFID tag (41) is attached to the container (40) and a unique identifier can be stored in its memory. The unique identifier can be read out with an appropriate RFID reader.
  • An optical code (31) is attached to the scale (30) (in the present example a QR code). The optical code comprises a unique identifier that can be read out with a corresponding reading device for optical codes (for example a camera).
  • FIG. 5 shows an example of a display on a screen of a computer system (20).
  • Four overviews (70a, 70b, 70c, 70d) of four processes are displayed.
  • Each of the overviews (70a, 70b, 70c, 70d) includes a process name (71a, 71b, 71c, 71d) and a reaction equation (72a, 72b, 72c, 72d).
  • a user can select one of the overviews, for example by touching the respective overview on a touchscreen.
  • the process plan (80) comprises a process name (81), a reaction equation (82) and an action description (83).
  • the process plan (80) comprises a process name (81), a reaction equation (82) and a sequence (84) of basic operations. It is conceivable that the sequence of basic operations was generated automatically from the action description (83) from FIG. 6 or a similar action description.
  • FIG. 8 shows an example of a further display on a screen of a computer system (20).
  • an overview (70) of a process is shown in the form of a reaction equation.
  • Digital representations (85a, 85b, 85c, 85d) of the substances used in the process are shown on the left.
  • the digital representations are chemical structural formulas (85a, 85b) and chemical formulas (85c, 85d). Names (1PAC names, trivial names) of the substances and / or other representations would also be conceivable.
  • a button eg 86b
  • the process of linking a digital representation of a substance with a batch of the substance is initiated.
  • instructions (87) appear on the screen after the button (86b) has been selected, which the user must execute : the The user is asked to place a camera, which is part of the computer system (20), in front of the optical code (41).
  • the optical code (41) is applied to a label of the substance container (40).
  • the computer system (20) is configured to recognize and read out the optical code (41) which is imaged on the camera sensor.
  • the optical code (41) comprises a unique identifier. When reading the optical code (41), the unique identifier of the substance that is in the container (40) is detected.
  • a separate reading device for optical codes is used, which is connected to the mobile computer system (20), for example via Bluetooth.
  • the information that the batch of the substance with the corresponding unique identifier is used in the process is stored in a memory of the computer system (20).
  • information about the substance / batch can be determined from a database (60) to which the computer system (20) is connected via a network or directly (represented by the dashed line).
  • the computer system (20) can use the information to check whether the substance in the container (40) is really the substance that is to be used in the process and its digital representation (85b) on the screen of the computer system (20 ) is displayed (the "desired substance"). If the computer system (20) detects that it is not the desired substance, the computer system (20) can display a message on the screen.
  • FIG. 9 shows an example of a further display on a screen of a computer system (20).
  • a list (90) of basic operations managed by the computer system (20) is displayed.
  • a user can select the corresponding entry by touching an entry in the list. With this selection, the user signals to the computer system (20) that the user wants to carry out the corresponding basic operation as the next step.
  • FIG. 10 shows an example of a further display on a screen of a computer system (20).
  • a user After a user has selected a basic operation from a list of basic operations in FIG. 9, he can check, supplement and / or correct the parameters for executing the basic operation.
  • the user is shown that the substances ethanol and sulfuric acid should be heated together to a temperature of 115 ° C.
  • the user can add further substances to this basic operation by means of "drag and drop". He can change the entry of the temperature in the temperature field. He can enter a period (t) of how long the substances should be kept at the temperature of 115 ° C.
  • FIG. 11 shows an example of a further display on a screen of a computer system (20).
  • a user After a user has selected a basic operation from a list of basic operations in FIG. 9, he can link the basic operation to a device for performing a basic operation. It is conceivable for the user to be shown a list of devices with which the basic operation can be carried out and which are connected directly or indirectly (via a network) to the computer system (20). In the present case, the user can tap a virtual button (86b) to initiate a link to a device.
  • a message (87) appears with instructions to the user: he is asked to hold the camera of the computer system (20) in front of the optical code (31) of the device (30) to be linked, or one with the computer system (eg via Bluetooth) connected reader to use for optical codes.
  • the computer system (20) or the optical reading device is configured to recognize and read out the optical code imaged on the respective (camera) sensor.
  • the optical code (31) comprises a unique identifier, on the basis of which the device can be identified. Under the unique identifier, information about the device can be stored in a database (60) to which the computer system (20) is connected directly or indirectly (via a network).
  • the identifier of the device is stored in a memory of the computer system (20) together with the information that the basic operation of the process is carried out with the device (30). It is conceivable that the link establishes a connection between the device (30) and the computer system (20), via which data and / or control signals can be transmitted.
  • FIG. 12 shows schematically in the form of a flow chart an embodiment of the method according to the invention.
  • the method (100) comprises the following steps
  • FIG. 13 shows schematically in the form of a flow chart a further embodiment of the method according to the invention.
  • the method (200) comprises the following steps
  • FIG. 14 shows schematically in the form of a flow chart a further embodiment of the method according to the invention.
  • the method (300) comprises the following steps

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  • Health & Medical Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Epidemiology (AREA)
  • General Health & Medical Sciences (AREA)
  • Medical Informatics (AREA)
  • Primary Health Care (AREA)
  • Public Health (AREA)
  • Automatic Analysis And Handling Materials Therefor (AREA)

Abstract

La présente invention porte sur la mise en oeuvre de processus dans un laboratoire. La présente invention concerne un procédé, un système et un programme informatique pour mettre en oeuvre des processus.
PCT/EP2019/068790 2018-07-20 2019-07-12 Système de gestion de laboratoire WO2020016123A1 (fr)

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EP18184603 2018-07-20

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Cited By (1)

* Cited by examiner, † Cited by third party
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EP3975191A1 (fr) 2020-09-28 2022-03-30 Sartorius Lab Instruments GmbH & Co. KG Procédé de support d'un utilisateur de laboratoire biotechnologique

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EP0796654A2 (fr) * 1996-03-22 1997-09-24 Warner-Lambert Company Système de gestion d'information pour synthèses multiples simultanées automatisées
US20030028501A1 (en) 1998-09-17 2003-02-06 David J. Balaban Computer based method for providing a laboratory information management system
US20040003000A1 (en) * 2001-01-29 2004-01-01 Smith Robin Young Systems, methods and computer program products for determining parameters for chemical synthesis
WO2003102854A2 (fr) * 2002-06-04 2003-12-11 Applera Corporation Systeme et procede de commande en circuit ouvert et de suivi d'instruments biologiques
US20050273272A1 (en) 2004-04-22 2005-12-08 Applera Corporation, A Delaware Corporation System and method for laboratory-wide information management
US20070050092A1 (en) * 2005-08-12 2007-03-01 Symyx Technologies, Inc. Event-based library process design
WO2008024471A2 (fr) 2006-08-24 2008-02-28 Kevin Lloyd Gestion d'informations de laboratoire utilisant une identification par radio fréquence
US20080134073A1 (en) * 2006-12-01 2008-06-05 Stefano Bergantino Method for controlling and/or monitoring data processing device and computer program
US20140094947A1 (en) * 2008-09-29 2014-04-03 Fisher-Rosemount Systems, Inc. Recipe command steps and recipe inputs from external logic
WO2010086862A1 (fr) * 2009-02-01 2010-08-05 Sparklix Ltd. Carnet de laboratoire électronique complet
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US20130145046A1 (en) 2011-12-02 2013-06-06 Slava Rivkin System for communicating between a plurality of remote analytical instruments
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US20180032954A1 (en) * 2016-07-29 2018-02-01 Abbott Laboratories System and method for inventory sharing in a laboratory management system

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP3975191A1 (fr) 2020-09-28 2022-03-30 Sartorius Lab Instruments GmbH & Co. KG Procédé de support d'un utilisateur de laboratoire biotechnologique

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