Patent Description:
Most life science laboratory work is currently performed manually; using equipment that require full attention. Thus, research progress is slow, tedious, vulnerable to human errors and prone to significant experimental inconsistencies. Despite the rising demand, only limited automation has been developed so far for life science research.

The majority of known automation platforms serve only for semi-automation of laboratory protocols. Full automation of life-science laboratory procedures can be offered by large and expensive robotic installations; many of these are specialized and designed according to the needs of a particular laboratory. A small number of known systems do allow the full automation of some routine procedures, but only by using their reagent/bio-columns and consumable kits without the possibility of modifications required by the users.

Many devices in the field using robotic arms, such as the system described in patent application No. <CIT>, are not laboratory devices but only adjustable labware transferring systems that transfer labware to other devices at different positions. These devices do not include laboratory equipment such as liquid handlers or centrifuge which can be used for automation of life-science laboratory procedures. The current life-science automation systems provide some walk-away functionality by having stackers or towers where microtiter plates and other labware can be stored for a short period in room temperature, however none of these systems can offer <NUM>-hour unmonitored execution of more than one laboratory procedure.

Patent application No. <CIT> describes systems and methods for sample collection, sample preparation, assay, and/or detection. The disclosed device might include a cooling unit or a shared module being a small refrigeration. However, the application does not disclose any information about the cooling unit or the small refrigeration.

It is an object to provide an improved laboratory automation device and a method for its application. Further implementation forms are apparent from the dependent claims, the description, and the figures.

According to a first aspect, there is provided a laboratory automation device comprising a housing having a frame and at least two shelves, a centrifuge with at least two labware holding positions, the shelves holding a labware transferring system, the labware transferring system comprising a four-axis robotic arm and linear actuators configured to move and transfer labware within the device, the linear actuators comprising a loading unit and an automatic drawer unit for exporting and importing the labware; a freezer and a fridge configured to be loaded and unloaded by the loading unit; at least one three-axis liquid handling station, the liquid handling station comprising at least two pipettes, at least nine positions for labware, at least one waste collection unit, at least one tip box and at least one tip feeder configured to automatically refill said tip box. The laboratory device further comprises a microplate sealer, a temperature module, an incubation module, a magnetic module, an automated thermocycler, a monitoring system comprising sensors and/or cameras configured to monitor the movement of the labware transferring system. The laboratory device further comprises a controlling and scheduling system having a user interface designed to be remotely operated by a user to control the device and/or schedule procedures on the device, the controlling and scheduling system being connected to the monitoring system. The centrifuge, the freezer, the fridge, the liquid handling stations, the microplate sealer, the incubation module, the magnetic module, the temperature module and the automated thermocycler are connected via the labware transferring system.

The laboratory device further comprises an ice producing unit, the ice producing unit comprising an automated ice-bucket.

This solution provides a compact, autonomous and versatile device that allows walkaway automation for more than one laboratory procedure in <NUM> hours without human intervention. The microplate sealer allows storage of samples/consumables in sealed containers for a period of <NUM> hours or longer. The waste collection unit which can be connected to an external sewage system allows storage of waste for <NUM> hours or longer, but also allows the constant removal of waste. The tip feeder facilitates the non-stop refill of pipetting consumables for <NUM> hours or more, providing a steady supply. The fridge also facilitates autonomy, because any labware containing samples and/or reagents stable at <NUM>-<NUM> can be stored in the fridge for <NUM> hours or more and automatically retrieved any time needed. The freezer also facilitates autonomy, because any labware containing samples and/or reagents stable at -<NUM> can be stored in the freezer for <NUM> hours or more and automatically retrieved any time needed. The labware transferring system facilitates autonomy and versatility, because any labware can be automatically transferred to any incorporated parts without human intervention. Versatility is achieved since the centrifuge, the freezer, the fridge, the liquid handling stations, the microplate sealer, the incubation module, the magnetic module, the temperature module and the automated thermocycler are all physically connected via the labware transferring system. The housing is able to protect the user from the moving parts. The housing preferably encloses the centrifuge, the freezer, the fridge, the liquid handling stations, the microplate sealer, the incubation module, the magnetic module, the temperature module and the automated thermocycler. The device according to the first aspect can be programmed for <NUM>/<NUM> by the user and the device is able to execute different laboratory procedures autonomously. It is also possible to execute more laboratory procedures at the same time or after each other, without needing any intervention of the user. The controlling and scheduling system with the user interface facilitate cancelling or changing any step of the procedure <NUM>/<NUM>, remotely due to the monitoring system comprising sensors and/or cameras, without compromising the preservation of the consumables of the cancelled procedure due to fridge and freezer. The controlling and scheduling system also facilitates synchronization of robotic movements and allows initiation of any procedure at a different time point than the point of registration of procedure by the user into the system. The monitoring system comprising sensors and/or cameras allows monitoring of all robotic movements and produce analogue and digital information which is used by the controlling and scheduling system for autonomous self-correction, error monitoring and collision avoidance. The device according to the first aspect also allows the user to stay away, as the user does not need to be present when the laboratory process starts or finishes, since the device can store the treated samples, microplates, etc. for long time, i.e. <NUM> hours or more. The user staying away does not compromise the sample/reagent condition and integrity.

In a possible implementation form of the first aspect, the linear actuators comprise an elevator, an upper-deck slider and a lower-deck slider. The elevator has a vacuum gripper; the robotic arm also has a vacuum gripper; the device comprises an air pump system comprising air pumps for controlling said vacuum grippers; the upper-deck slider and the lower-deck slider are two-axis linear actuators. The upper-deck slider is configured to load and unload labware from the robotic arm and/or the elevator, the upper-deck slider having a camera attached to it. The lower-deck slider is configured to load and unload labware from the loading unit and/or the elevator. This facilitates the automatic transferring of any labware within the device between all essential parts of the device. Any reagent or sample needed during a laboratory process can be retrieved on demand and moved with the sliders to the location quickly, automatically, and autonomously.

In a further possible implementation form of the first aspect, the monitoring system comprises at least six cameras; at least one camera being mounted on the liquid handling station. This facilitates the monitoring and recording of the steps executed within the device and allows collision avoidance and error tracking. The cameras can record everything that happens in the device so that the user may monitor the process remotely and even watch the process multiple times.

In a further possible implementation form of the first aspect, any of the freezer and the fridge may enclose multiple shelves and any of them (the freezer, the fridge or both) may enclose an additional positioning unit. The positioning unit is configured to place labware at a predetermined position inside the freezer and/or the fridge and/or to move, e.g. rotate said shelves inside the freezer and the fridge. The shelves may move in a carousel-like movement. This facilitates storing any labware for a long period of time (<NUM> hours or longer), rearranging them any time necessary (according to temperature requirements, usage by different users etc.), and retrieving them automatically any time.

In a further possible implementation form of the first aspect, the device comprises a barcode scanner connected to the automatic drawer unit for reading barcodes on labware. This facilitates reading barcodes on the imported labware and thus facilitates an autonomous device that is able to automatically recognize the loaded labware.

In a further possible implementation form of the first aspect, the device comprises at least three shelves arranged above each other in the device; and the freezer, the fridge, the liquid handling station, the microplate sealer, the incubation module, the temperature module, the magnetic module, and the automated thermocycler are mounted at predetermined positions, preferably on the shelves; and the centrifuge has a metallic base. This facilitates the device being a compact device having a vertical arrangement, which allows smaller footprint.

In a further possible implementation form of the first aspect, ice producing unit is usually attached to the freezer. The automated ice-bucket can automatically fill the ice producing unit with crushed ice or iced-water. Thus, this implementation facilitates an autonomous device with automated production of ice.

In a further possible implementation form of the first aspect, the volume of the device is less than <NUM><NUM>, preferably less than <NUM><NUM>. This facilitates a relatively small, compact device that can be used at different locations, even at locations with less available free space. Furthermore, this also facilitates the device being movable.

According to a second aspect, there is provided a method for the application of an automated laboratory device according to the first aspect for performing a laboratory process, wherein the method comprises the steps:.

This solution provides a method that is able to execute different laboratory processes even at the same time without any human intervention. The method allows the complete stay-away of the user for <NUM> hours or longer. The performed laboratory process(es) can be composed of any combination of different series of liquid transferring/mixing steps with different volume within any labware, via pipetting and/or pump suction. Any combinations of procedures done by the mainstream equipment found in any research laboratory worldwide can be executed in this device as well. The identification step of the loaded labware can be done via a barcode scanner, via the user's registration number in the device through the user interface, and/or via the controlling and scheduling system. The identification step can be done at the same time with the loading, or before or after. The controlling and scheduling system facilitates the automatic execution of the laboratory process required by the user.

In a possible implementation form of the second aspect, the labware containing the sample is identified with a barcode scanner connected to the automatic drawer unit. This facilitates a quicker and more comfortable process for the user, since the barcode scanner can automatically recognize the loaded labware and can even start the corresponding process automatically.

In a further possible implementation form of the second aspect, the method further comprises the step of incubating the treated sample to a predetermined temperature and/or shaking the treated sample for up to <NUM> rpm for more than <NUM> second with the incubation module, and the laboratory process may be paused after any step for a period longer than <NUM> second for said heating or shaking of the sample with the incubation module. (Rpm means rotations per minute. ) This facilitates heating and rotational movement of the sample(s) inside the mounted labware, which are necessary steps in some laboratory procedures.

In a further possible implementation form of the second aspect, the method further comprises the steps:.

This allows performing several more laboratory procedures that include these steps. The temperature module facilitates the heating and cooling of samples within the labware.

In a further possible implementation form of the second aspect, the used labware and reagents are transferred to the waste collection unit via the linear actuators. This facilitates allows the constant removal of waste and thus an autonomous method that does not need human intervention for more than <NUM> hours.

In a further possible implementation form of the second aspect, the steps are monitored and recorded by the cameras within the device. This facilitates monitoring of all robotic movements and producing analogue and digital information to be used for autonomous self-corrections, error monitoring and collision avoidance by the controlling and scheduling system.

In a further possible implementation form of the second aspect, any of the steps are executed repeatedly without human supervision for a time period of <NUM> hours or longer; and the user is informed via the user interface by the controlling and scheduling system when the laboratory process is completed, and of any errors that occurred during the process. This facilitates the flexible and versatile use, controlling and scheduling of the device that can all be done remotely.

A preferred embodiment of the laboratory automation device that is illustrated in <FIG> and <FIG> comprises a housing having a frame <NUM> and at least three shelves <NUM>, <NUM>, <NUM> that hold the laboratory equipment of the device. In other embodiments other shelves can be included. The device may include a lower deck and an upper deck. In <FIG> and <FIG> shelf <NUM> is for the lower deck, shelf <NUM> is for the upper deck and shelf <NUM> is for the controlling and scheduling system and other units such as the power supply <NUM> and computer <NUM>. Shelf <NUM> is the roof in this embodiment. However, other arrangement is also possible, for example an embodiment where shelf <NUM> holds the controlling and scheduling system and other electronic and mechanical units; in this case, shelf <NUM> is not necessary. The shelves <NUM>, <NUM>, <NUM>, <NUM> are preferably metallic shelves and have <NUM> weight limit per shelf; the frame <NUM> is also metallic and it comprises horizontal, vertical and in-angle beams. The frame <NUM> holds the shelves <NUM>, <NUM>, <NUM>, <NUM> and all components mounted on the frame <NUM> or placed on the shelves <NUM>, <NUM>, <NUM>. The frame <NUM> may also hold covering panels <NUM> that are preferably metallic and may comprise windows and doors. In this case, the panels <NUM> are also part of the housing, but are optional. <FIG> illustrate such panels. The housing preferably encloses all important laboratory equipment such as a centrifuge <NUM>, a freezer <NUM>, a fridge <NUM>, the liquid handling station(s) <NUM>, <NUM>, a microplate sealer <NUM>, <NUM>, an incubation module <NUM>, <NUM> (incubation module meaning heating and shaking module), a magnetic module <NUM>, a temperature module (<NUM>, <NUM>), tip feeders (<NUM>, <NUM>) and an automated thermocycler <NUM>. The housing protects the user from the moving parts and allows the device being compact and minimizes contaminations. The housing may include led light strips <NUM> that can be attached to the shelves <NUM>, <NUM>, <NUM>, <NUM> for example. Preferably, the freezer <NUM>, the fridge <NUM>, the liquid handling station(s) <NUM>, <NUM>, the microplate sealer(s) <NUM>, <NUM>, the incubation module(s) <NUM>, <NUM>, the temperature module(s) <NUM>, <NUM>, the magnetic module <NUM>, and the automated thermocycler <NUM> are mounted at predetermined positions on the shelves <NUM>, <NUM>, <NUM>, <NUM>.

The volume of the device is less than <NUM><NUM>, preferably less than <NUM><NUM>, more preferably in the range of <NUM>-<NUM><NUM>. In a possible embodiment, it has the following size: height about <NUM>, width: about <NUM>-<NUM> (<NUM> in an embodiment), depth: <NUM>-<NUM> (<NUM> in an embodiment). In a preferred embodiment just like in <FIG> and <FIG> and <FIG>, the device has vertical arrangement. This means that the three shelves <NUM>, <NUM>, <NUM> are arranged above each other in the device so that the device only requires a small floor area. Preferably, the device is free standing and its weight is maximum <NUM>-<NUM>.

The laboratory automation device also comprises a robotic centrifuge <NUM> that has at least two labware holding positions, and the centrifuge <NUM> preferably has a separate metallic base <NUM>. This metallic base <NUM> can have heavy duty wheels. The centrifuge <NUM> is a universal table top or freestanding centrifuge, which is preferably refrigerated, is preferably able to precool the rotors during standstill, has a maintenance-free induction drive motor, two motorized lid locks, a stainless-steel bowl, an imbalance switch, a speed range up to <NUM> rpm, a maximum capacity of <NUM> x <NUM> down to microtubes with different adapters in the same bucket and a microcontroller controlling speed, gravitational field and time. Preferably, the centrifuge <NUM> also has a Spincontrol Universal with RS <NUM> as control unit, has various angle and swing-out rotors available, the rotors being lockable in <NUM> or <NUM> position and each rotor position identifiable.

2a-ef we can see the shelves <NUM>, <NUM>, <NUM> holding the different laboratory equipment in different views. The different laboratory equipment can however be arranged differently as well. The shelves <NUM>, <NUM>, <NUM> are also holding a labware transferring system that comprises a four-axis robotic arm <NUM> and linear actuators <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM> configured to move and transfer labware within the device. Most of the linear actuators <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM> are preferably two-axis actuators. The linear actuators comprise a loading unit <NUM> for loading and unloading the freezer <NUM> and the fridge <NUM>. The centrifuge <NUM>, the freezer <NUM>, the fridge <NUM>, the liquid handling station(s) <NUM>, <NUM>, the microplate sealer(s) <NUM>, <NUM>, the incubation module(s) <NUM>, <NUM>, the magnetic module <NUM> and the automated thermocycler <NUM> are all physically connected via the labware transferring system.

The freezer <NUM> typically has a target temperature of -<NUM>, a spark free safety interior, insulation, automated defrost, automated door opening, closing and lock, high/low temperature alarm. The fridge <NUM> typically has a target temperature of <NUM>-<NUM> a spark free safety interior, insulation, automated defrost, automated door opening, closing and lock, high/low temperature alarm. In a possible embodiment, either the fridge <NUM> or the freezer <NUM> or both can have up to <NUM> shelves: <NUM>-<NUM> width, <NUM>-<NUM> depth and <NUM>-<NUM> height each, that are fan circulated. The shelves can rotate in one embodiment, which is a movement, more particularly a carousel-like movement. In a possible embodiment, either the fridge <NUM> or the freezer <NUM> or both may enclose an additional positioning unit. This positioning unit can place labware containing sample(s) or reagent(s) at a predetermined position inside the freezer <NUM> and/or the fridge <NUM>. The positioning unit may be able to also move, for example rotate the shelves inside the freezer <NUM> and/or the fridge <NUM>, which rotation may be a carousel-like movement. In another possible embodiment, the shelves can rotate on the vertical axis and the loading unit <NUM> can rearrange any labware inside the freezer <NUM> and/or the fridge <NUM> to provide optimum temperature for all labware and to retrieve any labware any time.

The loading unit <NUM> is preferably a two-axis linear actuator for tube racks, microplates and other labware, it is capable of loading and unloading labware from the automated fridge <NUM> and freezer <NUM>, loading and unloading labware from the automatic drawer unit <NUM> and loading and unloading labware from lower-deck slider <NUM>. The loading unit <NUM> can comprise a vacuum gripper <NUM> and an air pump <NUM> for controlling the vacuum gripper <NUM>. The vacuum gripper <NUM> may comprise aluminum custom-made fingers.

The device comprises an ice producing unit <NUM>, which comprises an automated ice-bucket <NUM>. The automated ice-bucket <NUM> can store and produce ice and automatically fill the ice producing unit with crushed ice or iced-water any time when necessary. The ice producing unit <NUM> is preferably connected and attached to the freezer <NUM>.

The linear actuators also comprise an automatic drawer unit <NUM> for exporting out of the device and importing the labware into the device. The automatic drawer unit <NUM> may comprise a barcode scanner <NUM> for reading barcodes on labware. The automatic drawer unit <NUM> is a custom-made shelve that is capable of linear movements inside and outside the device, is able to import labware containing sample or reagent into the device by the users and export labware outside of the device to be picked up by users. The automatic drawer unit <NUM> is preferably on the lower deck.

The four-axis robotic arm <NUM> can have a minimum reach of <NUM> from its core, can comprise a camera <NUM> for calibrations, have a payload of up to <NUM>, and a maximum magnitude: rear arm limitations -<NUM>°- <NUM>°, forearm limitations -<NUM>°-<NUM>°.

Its other preferred features are as follows:.

The laboratory automation device also comprises at least one three-axis liquid handling station <NUM>, <NUM>. The preferred embodiment of the laboratory automation device that is illustrated in <FIG> and Figs. 2a-ef comprises two liquid handling stations <NUM>, <NUM>. However, the device can also comprise more than two liquid handling stations, for example three or four. The liquid handling station(s) <NUM>, <NUM> typically comprise at least two pipettes, the pipettes being <NUM>-<NUM>µL pipettes with <NUM> or <NUM> channels. The liquid handling station(s) <NUM>, <NUM> comprise at least nine positions for labware, two positions for tip boxes and at least one waste collection unit <NUM>, <NUM>. The waste collection unit(s) <NUM>, <NUM> is collecting used labware and/or solvents and is receiving trash via suction tubes from the disposal areas of the liquid handling station(s) <NUM>, <NUM>. In the illustrated embodiment each liquid handling stations <NUM>, <NUM> has a waste collection unit(s) <NUM>, <NUM>. They can receive for example used plasticware with or without liquid and inorganic liquids and can separate solids from liquid through a mesh. Liquids are drained both manually and automatically depending on the user requirements. The device may further include a trash bin <NUM> for organic solvents in which liquids can be drained both manually and automatically depending on the user requirements. The liquid handling station(s) <NUM>, <NUM> further comprises at least one tip box and at least one tip feeder <NUM>, <NUM>, <NUM>, <NUM> for automatically refilling the tip box. In the preferred embodiment where there are two liquid handling stations <NUM>, <NUM>, each of them comprises at least two tip boxes and two tip feeders. The liquid handling station(s) <NUM>, <NUM> may also comprise a tip calibrating system, marks for calibration, rails and frame, hardware controllers, HEPA filtration system (not shown in the figures) and led light strips <NUM> as germicidal UV lights on top.

The laboratory device of a preferred embodiment further comprises at least one heated microplate sealer <NUM>, <NUM> that can produce from room temperature up to <NUM> and keep the lid of labware heated at required temperatures. The microplate sealer <NUM>, <NUM> is able to seal and remove the seals of labware.

The laboratory device of a preferred embodiment further comprises at least one temperature module <NUM>, <NUM> that can have position for mounting tubes <NUM>µL - <NUM> or microplates (<NUM>-<NUM> well plates) or any other type of labware. The temperature module <NUM>, <NUM> can heat labware (containing samples for example) up to <NUM>, and cool them down to <NUM>.

The laboratory device of a preferred embodiment further comprises at least one incubation module <NUM>, <NUM> for heating and/or shaking that can have position for mounting tubes <NUM>µL - <NUM> or microplates (<NUM>-<NUM> well plates) or any other type of labware. The incubation module <NUM>, <NUM> is capable of rotational movement in the range of <NUM>-<NUM> rpm (rotations per minute) of the mounted labware and can also heat labware (containing samples for example) up to <NUM>, and cool them down to -<NUM> without shaking.

The preferred embodiment of the laboratory automation device that is illustrated in <FIG> and Figs. 2a-ef comprises two microplate sealers <NUM>, <NUM>, two temperature modules <NUM>, <NUM> and two incubation modules <NUM>, <NUM>. These can also be within the liquid handling station(s) <NUM>, <NUM>.

The laboratory device of a preferred embodiment further comprises an automated thermocycler <NUM> and a magnetic module <NUM>. The automated thermocycler <NUM> typically has a working volume range of <NUM>-<NUM>µL, can be able to open and close lids automatically and program lid temperatures up to <NUM> and program block temperatures in the range of <NUM>-<NUM>. The magnetic module <NUM> is able to engage and disengage strong magnets with labware, precipitate magnetic beads and can have adjustable plate brackets.

The laboratory device of a preferred embodiment further comprises a monitoring system comprising sensors and/or cameras <NUM>, <NUM>, <NUM> configured to monitor the movement of the labware transferring system. The monitoring system preferably comprises at least six cameras <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>. Preferably, at least one camera <NUM>, <NUM> is mounted on each liquid handling station <NUM>, <NUM>. Preferably, at least one camera is mounted on each deck. In a preferred embodiment there are two cameras <NUM>, <NUM> on the upper deck and two cameras <NUM>, <NUM> on the lower deck.

The laboratory device of a preferred embodiment further comprises a controlling and scheduling system. The controlling and scheduling system may comprise a software that is separated into two independent parts which exchange information between them: The Main Task Controller (Robotic Operating System (ROS) Node) which controls each hardware in subsystems, and the user interface which receives input from user. The Main Task Controller functionality is to keep track of the automated method execution and to orchestrate all the subsystems' controllers for method execution and provide collision avoidance. The Main Task Controller has all the required functionality and tools to control a variety of different hardware in a versatile and easily managed way, making the interfacing with multiple hardware devices and provides a messaging subsystem that allows high throughput distributed event management, so each subsystem's controller handles only the events that affect it, independently. The Main Task Controller connects to all the subsystems via USB or serial interface or other connection, and it can connect to the network either via a Wireless WiFi connection or via Ethernet. The user interface consists of the frontend of web applications. In a preferred embodiment the web applications are the User management, the Control Panel, and the Experiment Protocol Designer. The User management application provides all required functionality for the management of the user preferences and information (method procedure, notes, method specification etc.). The Control Panel application provides all the required functionality for the control, calibration of system and method execution and monitoring. The Experiment Protocol Designer application provides a way to create, structure and simulate the method to be automatically executed. The user interface receives user inputs and once the "Execute" command is given, the information is sent to the Main Task Controller which then coordinates the execution of the requested method. The user interface provides all the necessary functionality to the user to create, edit, save under his/her profile, or share a method, to calibrate the system, or to start, stop and monitor the experiment execution. The user interface can be remotely operated by a user to control the device and/or monitor the laboratory procedures handled by the device and/or schedule procedures on the device and/or review the errors and/or watch the recorded laboratory procedures and to calibrate the device. The purpose of the calibration is to tune all the subsystems so they can operate faultlessly and with the required precision. The calibration procedure can be broken apart to the calibration procedures of each of the subsystems.

The laboratory device can also comprise electrical and electronic control systems, such as wiring <NUM>, electrical boards <NUM>, power suppliers <NUM>, fuses <NUM> and a computer <NUM>. These are preferably held on a separate shelf from the laboratory equipment, on the upper shelf <NUM> or on shelf <NUM> or in electrical boards <NUM>.

The device may comprise a universal vacuum-manifold <NUM> for biotech column that holds columns with filters for isolation of biological material; the negative pressure causes liquid passage through column filters and the container of the universal vacuum-manifold <NUM> holds the flow through waste.

Most of the parts described above are depicted in <FIG> which show different details of the device. <FIG> illustrates the device according to a preferred embodiment and some parts of the device enlarged, focusing on the moving parts. We have illustrated the direction of movement of the moving elements in the device. Circular movement is shown by circular arrows and linear movement is shown by bilateral arrows. The moving parts on the lower deck are: elevator <NUM>, vacuum grippers <NUM>, <NUM> and <NUM>, automatic drawer unit <NUM>, door and shelves of freezer <NUM> and fridge <NUM>, loading unit <NUM> and lower-deck slider <NUM>, linear actuator <NUM> (of the lower-deck slider <NUM>), hatch of the centrifuge <NUM>. The moving parts on the upper deck are: four-axis robotic arm <NUM>, vacuum gripper <NUM> (of the robotic arm <NUM>), upper-deck slider <NUM>, elevator <NUM>, vacuum gripper <NUM> (of the elevator <NUM>).

In a possible embodiment, the linear actuators may comprise an elevator <NUM>, an upper-deck slider <NUM>, a linear actuator <NUM> and a drawer unit <NUM>. The elevator <NUM> may have a camera <NUM> attached to it for calibrations and a vacuum gripper <NUM>. The four-axis robotic arm <NUM> may also have a vacuum gripper <NUM>. The device may comprise an air pump system comprising air pumps <NUM>, <NUM> for controlling the vacuum grippers <NUM>, <NUM>, more particularly, for controlling the grippers' fingers movement on the four-axis robotic arm <NUM> and the elevator <NUM>. The upper-deck slider <NUM> is capable of linear movements in the upper deck of the device and is able to load and unload labware from the four-axis robotic arm <NUM> and/or the elevator <NUM>. The upper-deck slider <NUM> may also have a camera <NUM> attached to it for taking photos of tubes and microplates bottom site for user's reference.

The lower-deck slider <NUM> is able to load and unload labware from the loading unit <NUM> and/or the elevator <NUM>. The lower-deck slider <NUM> which is capable of linear movements in the lower deck of the device may have a linear actuator <NUM> for throwing labware in bins.

There can also be an air pump <NUM> for emptying the waste collection units <NUM>, <NUM> from any liquid handling stations <NUM>, <NUM> and an air pump <NUM> for the gripper on the loading unit <NUM>.

In a method for the application of the automated laboratory device according to our invention, the following steps are included.

The device can use any brand or type or volume of laboratory tips, tubes, microplates, microscope slides, cover slips, laboratory columns and/or other labware for the laboratory procedures that the device performs. The device can use also custom labware. The device can handle liquids that are viscous or not viscous and/or contain diluted inorganic and/or organic chemicals and/or magnetic or chemical beads and/or biological material in the form of tissue or cells or molecules (such as any type of DNAs, RNAs, proteins, enzymes, whole extracts, etc.) in any concentration.

The method may further comprise any of the steps as follows.

Some steps may be repeated multiple times. The steps executed can be monitored and recorded by the cameras <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM> within the device. For this purpose, photographs video and other electronic documentation of the process may take place in the form of error reporting, delays, timeline according to user requirements. The steps executed within the device can be repeated without human supervision for a time period of <NUM> hours or longer. This allows the user to walk away and stay away for <NUM> hours or longer or even for days. The user is informed via the user interface by the controlling and scheduling system when the laboratory process is completed and is informed of any errors that occurred during the process.

The method may further comprise the step of incubating the treated sample to a predetermined temperature and/or shaking the treated sample for up to <NUM> rpm for more than <NUM> second with the incubation module(s) <NUM>, <NUM>. The laboratory process can be paused automatically or by the user after any step for a period longer than <NUM> second for the heating and/or shaking or cooling of the sample with the incubation module(s) <NUM>, <NUM> and temperature modules <NUM>, <NUM> or for magnetic bead precipitation via magnetic module <NUM> or PCR reaction on thermal cycler (<NUM>).

During the method, collisions are avoided - typically due to the monitoring system and the controlling and scheduling system - between:.

The used labware and reagents are preferably transferred to the waste collection unit(s) <NUM>, <NUM> via the linear actuators <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>. Organic solvents can be transferred to trash bin <NUM> in a similar way.

If a life-science laboratory process requires the use of the centrifuge <NUM>, then the system will replicate the loading of the sample plate into an empty plate that will act as a counter weight. The counter weight plate can be prepared by using water instead of samples or reagents.

User can input remotely (without physical presence) all the required data via the user Interface and once the "Execute" command is given, backend sends the protocol to the Main Task Controller Node which then coordinates the execution of the laboratory protocol by the device. In the preferred embodiment where there are multiple liquid handling stations, multiple users may use the device even at the same time, for the same or different procedures.

The invention has multiple advantages. It provides stay-away automation, meaning that the user can not only walk away but also stay away for up to <NUM> hours or even longer during the use of the device. Thus, the device can increase productivity of the average user by increasing laboratory executing hours up to <NUM>% (<NUM> hours non-stop execution of laboratory work). The device increases consistency with robotic accuracy, maximizes efficiency by performing overlapping experiments, generates results in resource shortage cases, saves time for researchers which they can utilize in other important research tasks, offers extensive documentation with photos and video for monitoring and troubleshooting and eliminates waste of samples and reagents. The waste of samples and reagents is eliminated by more than <NUM>% according to our estimate. Due to less expensive liquid handling stations and robotic arm, the price of the device can be significantly lower. Another advantage is that it allows the use of any kind of reagents (depending on the choice of the user), and the reagents can be stored in the device and retrieved on demand. A further advantage is that the device is user-friendly, compact and autonomous, which achieve unrivalled levels of versatility by fully or semi-automating multiple procedures. Major advantage, beyond the current state of the art, is the ability of this device to be programmed by the user to perform endless variations and new laboratory procedures. Major advantage of the device is also its ability to holistically perform all steps of most laboratory procedures (full-automation, not semi-automation).

Under the word labware, we refer to any kind of labware such as microplates (<NUM>-<NUM> well plates) or laboratory tubes (<NUM>µL -<NUM>) or laboratory flasks or other glassware or plasticware vessels or microscope slides or cover slips or columns or custom-made laboratory consumables or custom-made components. It can be empty labware or a labware containing sample(s) or reagent(s).

Claim 1:
Laboratory automation device comprising:
- a housing having a frame (<NUM>) and at least three shelves (<NUM>, <NUM>, <NUM>, <NUM>),
- a centrifuge (<NUM>) with at least two labware holding positions,
- the shelves (<NUM>, <NUM>, <NUM>, <NUM>) holding a labware transferring system, the labware transferring system comprising a four-axis robotic arm (<NUM>) and linear actuators (<NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>) configured to move and transfer labware within the device, the linear actuators comprising a loading unit (<NUM>) and an automatic drawer unit (<NUM>) for exporting and importing the labware;
- a freezer (<NUM>) and a fridge (<NUM>) configured to be loaded and unloaded by the loading unit (<NUM>),
- at least one three-axis liquid handling station (<NUM>, <NUM>), the liquid handling station (<NUM>, <NUM>) comprising at least two pipettes, at least nine positions for labware, at least one waste collection unit (<NUM>, <NUM>), at least one tip box and at least one tip feeder (<NUM>, <NUM>, <NUM>, <NUM>) configured to automatically refill said tip box;
the laboratory device further comprising:
- a microplate sealer (<NUM>, <NUM>),
- a temperature module (<NUM>, <NUM>),
- an incubation module (<NUM>, <NUM>),
- a magnetic module (<NUM>),
- an automated thermocycler (<NUM>),
- a monitoring system comprising sensors and/or cameras (<NUM>, <NUM>, <NUM>) configured to monitor the movement of the labware transferring system; and
- a controlling and scheduling system having a user interface designed to be remotely operated by a user to control the device and/or schedule procedures on the device,
the controlling and scheduling system being connected to the monitoring system,
wherein the centrifuge (<NUM>), the freezer (<NUM>), the fridge (<NUM>), the liquid handling stations (<NUM>, <NUM>), the microplate sealer (<NUM>, <NUM>), the incubation module (<NUM>, <NUM>), the magnetic module (<NUM>), and the automated thermocycler (<NUM>) are connected via the labware transferring system, characterized in that the device comprises an ice producing unit (<NUM>), the ice producing unit (<NUM>) comprising an automated ice-bucket (<NUM>).