LII:Considerations in the Automation of Laboratory Procedures
Title: Considerations in the Automation of Laboratory Procedures
Author for citation: Joe Liscouski
License for content: Creative Commons Attribution 4.0 International
Publication date: January 2021
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This article should be considered a work in progress and incomplete. Consider this article incomplete until this notice is removed. |
Introduction
Scientists have been dealing with the issue of laboratory automation for decades, and during that time the meaning of those words has expanded from the basics of connecting an instrument to a computer, to the possibility of a fully integrated informatics infrastructure beginning with sample preparation and continuing on to the laboratory information management system (LIMS), electronic laboratory notebook (ELN), and beyond. Throughout this evolution there has been one underlying concern: how do we go about doing this?
The answer to that question has changed from a focus on hardware and programming, to today’s need for a lab-wide informatics strategy. We’ve moved from the bits and bytes of assembly language programming to managing terabytes of files and data structures.
The high-end of the problem—the large informatics database systems—has received significant industry-wide attention in the last decade. The stuff on the lab bench, while the target of a lot of individual products, has been less organized and more experimental. Failed or incompletely met promises have to yield to planned successes. How we do it needs to change. This document is about the considerations required when making that change. The haphazard "let's try this" method has to give way to more engineered solutions and a realistic appraisal of the human issues, as well as the underlying technology management and planning.
Why is this important? Whether you are conducting intense laboratory experiments to produce data and information or making chocolate chip cookies in the kitchen, two things remain important: productivity and the quality of the products. In either case, if the productivity isn’t high enough, you won’t be able to justify your work; if the quality isn’t there, no one will want what you produce. Conducting laboratory work and making cookies have a lot in common. Your laboratories exist to answer questions. What happens if I do this? What is the purity of this material? What is the structure of this compound? The field of laboratories asking these questions is extensive, basically covering the entire array of lab bench and scientific work, including chemistry, life sciences, physics, and electronics labs. The more efficiently we answer those questions, the more likely it will be that theselabs will continue operating and, that you’ll achieve the goals your organization has set. At some point, it comes down to performance against goals and the return on the investment organizations make in lab operations.
In addition to product quality and productivity, there are a number of other points that favor automation over manual implementations of lab processes. They include:
• lower costs per test; • better control over expenditures; • a stronger basis for better workflow planning; • reproducibility; • predictably; and • tighter adherence to procedures, i.e., consistency.
Lists similar to the one above can be found in justifications for lab automation, and cookie production, without further comment. It’s just assumed that everyone agrees and that the reasoning is obvious. Since we are going to use those items to justify the cost and effort that goes into automation, we should take a closer look at them.
Lets begin with reproducibility, predictability, and consistency, very similar concerns that reflect automation’s ability to produce the same product with the desired characteristics over and over. For data and information, that means that the same analysis on the same materials will yield the same results, that all the steps are documented and that the process is under control. The variability that creeps into the execution of a process by people is eliminated. That variability in human labor can result from the quality of training, equipment setup and calibration, readings from analog devices (e.g., meters, pipette meniscus, charts, etc.), there is a long list of potential issues.
Concerns with reproducibility, predictability, and consistency are common to production environments, general lab work, manufacturing, and even food service. There are several pizza restaurants in our area using one of two methods of making the pies. Both start the preparation the same way, spreading dough and adding cheese and toppings, but the differences are in how they are cooked. Once method uses standard ovens (e.g., gas, wood, or electric heating); the pizza goes in, the cook watches it, and then removes it when the cooking is completed. This leads to a lot of variability in the product, some a function of the cook’s attention, some depending on requests for over or under cooking the crust. Some is based on "have it your way" customization. The second method uses a metal conveyor belt to move the pie through an oven. The oven temperature is set as is the speed of the belt, and as long as the settings are the same, you get a reproducible, consistent product order after order. It’s a matter of priorities. Manual verses automated. Consistent product quality verses how the cook feels that day. In the end, reducing variability and being able to demonstrate consistent, accurate, results gives people confidence in your product.
Lower costs per test, better control over expenditures, and better workflow planning also benefit from automation. Automated processes are more cost-efficient since the sample throughput is higher and the labor cost is reduced. The cost per test and the material usage is predictable since variability in components used in testing is reduced or eliminated, and workflow planning is improved since the time per test is known, work can be better scheduled. Additionally, process scale-up should be easier if there is a high demand for particular procedures. However there is a lot of work that has to be considered before automation is realizable, and that is where this discussion is headed.
How does this discussion relate to previous work?
This work follows on the heels of two previous works:
- Computerized Systems in the Modern Laboratory: A Practical Guide (2015): This book presents the range of informatics technologies, their relationship to each other, and the role they play in laboratory work. It differentiates a LIMS from an ELN and scientific data management system (SDMS) for example, contrasting their use and how they would function in different lab working environments. In addition, it covers topics such as support and regulatory issues.
- A Guide for Management: Successfully Applying Laboratory Systems to Your Organization's Work (2018): This webinar series complements the above text. It begins by introducing the major topics in informatics (e.g., LIMS, ELN, etc.) and then discusses their use from a strategic viewpoint. Where and how do you start planning? What is your return on investment? What should get implemented first, and then what are my options? The series then moves on to developing an information management strategy for the lab, taking into account budgets, support, ease of implementation, and the nature of your lab’s work.
The material in this write-up picks up where the last part of the webinar series ends. The last session covers lab processes, amd this picks up that thread and goes into more depth concerning a basic issue: how do you move from manual methods to automated systems?
Productivity has always been an issue in laboratory work. Until the 1950s, a lab had little choice but to add more people if more work needed to be done. Since then, new technologies have afforded wider options, including new instrument technologies. The execution of the work was still done by people, but the tools were better. Now we have other options. We just have to figure out when, if, and how to use them.
Before we get too far into this ...
About the author
Initially educated as a chemist, author Joe Liscouski (joe dot liscouski at gmail dot com) is an experienced laboratory automation/computing professional with over forty years experience in the field, including the design and development of automation systems (both custom and commercial systems), LIMS, robotics and data interchange standards. He also consults on the use of computing in laboratory work. He has held symposia on validation and presented technical material and short courses on laboratory automation and computing in the U.S., Europe, and Japan. He has worked/consulted in pharmaceutical, biotech, polymer, medical, and government laboratories. His current work centers on working with companies to establish planning programs for lab systems, developing effective support groups, and helping people with the application of automation and information technologies in research and quality control environments.
