随着您实验室的需求扩大，将复杂工作流程的每个步骤自动化可实现价值的指数级增长。From increased walk-away time and throughput to reduced human error and improved lab safety, automation can keep routine work on track so that scientists can focus on more critical assay development challenges.
An enzyme-linked immunosorbent assay (ELISA) is one of the most popular methods for quantitation of target antigens, but it is also a time-consuming and labor-intensive process. ELISA 工作流程自动化可完成繁琐的样品制备、试剂移液和微孔板洗板步骤，无需您亲自操作，并可提高结果的可重复性。
Here we discuss key considerations for developing an integrated automated, high-throughput ELISA workcell. No matter where you are in your lab automation journey, these considerations are key to advancing your ELISA workﬂow solution.
How to develop an automated ELISA system
- Start with a simple, automated plate-handling system
- Add an automated incubator for cell-based assays
- Add an automated liquid handling system to remove manual preparing and pipetting
- Consider an automation-ready ELISA workcell
1. Start with a simple, automated plate handling system
Increase walk-away time by automating plate loading tasks with a sophisticated robotic arm, freeing you up to perform other tasks. This ﬁrst step in automation can help perform large-scale, plate-based assays efficiently by delivering microplates between an ambient hotel and a microplate washer and reader. The microplate washer automatically washes all wells of the assay plate, using the desired wash program to completely remove unbound reagents and eliminate background noise. The microplate reader then generates data following a preconfigured protocol that performs the necessary calculations on the data, delivering consistent results.
Here you can see the benefits of automating the manual task of plate loading at various steps of the workflow, especially at a large scale. After coating the plate and adding your samples, an integrated control software schedules an automated robotic arm to transfer plates from the ambient hotel to the microplate washer and back to the hotel. The process repeats after you add your reagents once again freeing you from manually loading and waiting for each plate to wash. Finally, you can add your substrates and let the robot feed the plates to the microplate reader and back to the hotel.
2。Add an automated incubator for cell-based assays
If you are running cell-based assays, you’ll also want to add an automation-friendly incubator that keeps your cells happy at 37°C with 5% CO2. This further increases your efficiency and walk-away time by removing that trek from instruments to incubator and back.
3。Add an automated liquid handling system to remove manual preparing and pipetting
As you continue your lab automation journey, the addition of an automated liquid handling system completely removes the burden of manually preparing and pipetting samples and assay reagents. The illustration below shows how automated liquid handling now replaces steps 2, 4, and 6 of human intervention, converting a labor-intensive ELISA into a truly walk-away workflow.
The robotic arm can be scheduled to deliver plates to and from the liquid handler, incubator, microplate washer, and reader of your automation setup in a method-specific way, completely freeing you from the lab bench. And, as your lab’s needs evolve, your workcell can be integrated with other instruments, like a plate sealer, seal remover, and plate shaker to further optimize your assay process.
4。Consider an automation-ready ELISA workcell
Here we demonstrate five workcells for an integrated solution that combines hardware and software for ELISA-based experiments, offering automation capabilities ranging from entry-level to advanced. No matter where you are at in your automation journey, these workflows can be tailored to your specific research needs according to sample size or sensitivity, as well as the need for increased throughput, efficiency, and walk-away time.
ELISA Workcell: Single-step instrument plate loader
Our entry-level system is a simple, compact, and user-friendly set-up called the ELISA Workcell. It consists of a SpectraMax® Microplate Reader, Peak Robotics S-LAB Plate Handler with the S-LAB software, and the AquaMax® 4000 Microplate Washer.
Perform plate-based assays on a large number of plates without having to manually feed them into your microplate washer and reader. Load up the plates that you need to run and walk away while the S-LAB software controls the robotic arm and delivers them to the instruments as scheduled. S-LAB plate handler operates in both a portrait or landscape positions, along with a 360-degree movement on the rotation axis.
ELISA Advanced Workcell: Future-proof automated plate loading
The ELISA Advanced Workcell is similar to the previous workcell except for an advanced, four-axis robotic arm, the PreciseFlex 400 (PF400) Sample Handler and the Genera scheduling software, as well as a plate hotel. The PF400 is designed to move along the Z-axis allowing for the flexibility of a vertical design setup. In addition to saving lab space by building upwards, this workcell helps future-proof your plate-based assay workflows. As your lab needs grow, this scalable set-up allows you to easily add instrumentation including incubators, cellular imagers, single-cell sorters, centrifuge, and more, expanding your options of automated workflows.
ELISA Advanced EC Workcell: Automated plate loading and incubation
ELISA Advanced Environmental Control (EC) Workcell suits customers needing an incubator for temperature and humidity control. The workcell has a similar composition to that of ELISA Advanced Workcell, now with the addition of the LiCONiC STX44 Automated CO2 Incubator for regulated environments. The Genera software controls the PF400 robot arm and handles samples as described in the ELISA workflow example. However, here we add the option of incubating the plates in an automated incubator, further increasing your efficiency by removing that walk from instruments to incubator and back.
ELISA HTS EC Workcell: Two-step instrument plate loader plus liquid handling
The ELISA HTS EC Workcell offers an automated liquid handler and allows the workcell to perform the manual tasks of sample preparation and reagent additions at designated times.
Components of this workcell include a SpectraMax Microplate Reader, AquaMax 4000 Microplate Washer, and LiCONiC STX44 Automated CO2 Incubator. The key addition to the workcell is the Microlab STARlet Robot Liquid Handler from Hamilton Robotics with integrated plate handling system and scheduling software.
HTS EC Workcell provides a significant advantage, particularly for large numbers of samples, which are subject to errors if handled manually. Besides reducing human errors, an automated liquid handling system will drastically reduce your hands-on time manually pipetting. 这可以执行多次测定，准确度更高，人工干预更少。
ELISA HTSx Workcell: Fully automated solution
ELISA HTSx WorkCell is the most advanced ELISA workcell in our portfolio, offering a complete, fully automated, walk-away solution. It works with a similar logic to the previous workcell but with a Microlab STAR Automatic Liquid Handler, which offers a much larger sample loading capacity. The system also contains multiple plate hotels, which can store up to 80 microplates.
The solution brings versatility to ELISAs. The STX44 Incubator is optional, depending on your need for non-ambient plate incubation temperatures or cell incubation. With an automated liquid handler, your presence is needed only at the initial loading step. No further manual intervention is required from then on, as the PF400 robot will carry out the transfer between workcell components so that assay steps can be performed at designated times.
Discuss your automated ELISA solution
Automation does not have to be overwhelming – there are a lot of flexibility and options available. Our five ready-made workcells for ELISA workflows offer automation solutions ranging from simple plate-loading capabilities to more advanced, completely automated workcells and the best part, it can be customized and built over time. Automating labor-intensive plate-based assays increases walkaway time, throughput, and reproducibility by reducing a researcher’s need to engage in common, repetitive, hands-on tasks.