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==Sandbox begins below==
==Sandbox begins below==
Material testing can focus on specific industries (e.g., automotive, construction, and pharmaceutical), products (e.g., car seats, asphalt, and medical devices), or raw materials (e.g., steel, gravel, and zirconia ceramic).


==1. Introduction to LIMS and LIMS acquisition==
About chemical testing of raw materials https://a2la.org/accreditation/chemical-testing/
Your [[laboratory]] was created to carry out specific tasks, to do work that its parent organization needed to conduct its work and reach its business goals. The lab's biggest output is analytical results of tests it conducts, and it's imperative those analytical results are accurate, timely, and unaltered. Today, lab's more than ever depend on a [[laboratory information management system]] (LIMS) to better meet those requirements.


The point of this guide is to give you the background you need to better make a case to your organization's management and key stakeholders for acquiring and deploying a LIMS. While pursuing this topic, we're going to make a couple of simple assumptions. We'll assume that your organization's senior management may not understand what goes on in your lab and how it carries out its work. We'll also assume they have a lot of things to contend with in their roles, giving them limited time to fully understand your lab's needs and the tools required to help it succeed. You want to make the explanation and justification for LIMS acquisition and deployment as easy and succinct as possible while at the same time demonstrating that this is the right decision.
Material testing domains:
* Aerospace
**Adhesives
**Composites
**Fasteners
**Paints and primers
**Sealants
**Etc.
*Automotive
**Adhesives
**Coatings
**Foams
**Lighting and high-visibility solutions
**Plastics
**Seating
**Etc.
*Carbon
**Activated carbon
**Coal tar
**Etc.
*Coatings, linings, and sealants
**Ceramic coatings
**Metal coatings
**Pipe linings
**Thermal sprays
**Etc.
*Construction and engineering
**Asphalt
**Brick and tile
**Fasteners
**Fenestration and glazing products (i.e., windows, doors, glass)
**Geosynthetics
**Plumbing
**Soil
**Etc.
* Insulation, foam, and composites
**Fiberglass
**Flexible and laminate urethane foam composite
**Polyester resins
**Etc.
*Lubricants and thickeners
**Metallic stearates
**Powdered metal
**Pre-formed grease thickeners
**Etc.
* Medical devices
**Ceramics
**Metals
**Screws
**Etc.
*Metals
**Aluminum
**Castings
**Copper
**Rebar
**Steel
**Tubing
**Welds
**Zinc
**Etc.
* Packaging and labeling
**Cardboard
**Label adhesives
**Pharmaceutical packaging
**Sterile barrier materials
**Etc.
* Paints and oils
**Interior/Exterior paints
**Organic coatings
**Paint on parts
**Transformer oil
**Etc.
* Paper
**Cellulose paper tape
**Crepe paper and tubes
**Kraft paper
**Pressboard
**Etc.
*Polymers and plastics
**Biopolymers
**Condoms and gloves
**Payment cards
**O-rings
**[https://www.sciencedirect.com/science/article/pii/S1751616121005105 Silicone-based biological tissue mimics]
**Thermoplastic resins
**Etc.
* Raw materials
**Food and beverage ingredients
**Elemental material
**Pharmaceutical ingredients
**Etc.
* Reference materials
**Cannabinoids
**Coals and cokes
**Elemental gasses
**Isotope reference material
**Organic analytical reference material
**Pesticides
**Etc.
*Rubbers
**Bump stops
**Gloves
**Neoprene
**Silicone
**Tires
**Etc.
*Electronics and energy devices
**Batteries
**Semiconductors
**Solar panels
**Transformers
**Etc.
*Textiles
**Carpet
**Drapery
**Non-woven fabrics
**Upholstery
**Etc.
*Wood
**Dowel
**Flooring
**Lumber
**Medium-density fibreboard (MDF)
**Etc.


The justification process for LIMS has a long history, and a lot has changed since the 1980s when the technology was first introduced. Therefore, we need to examine what a LIMS is, what alternatives people commonly turn to, how the technology has evolved, what the history of LIMS justification is, what practical and economic considerations surround LIMS adoption, and how to address any concerns management may raise during the justification process. This guide will attempt to address these things and more. First, let's look at what LIMS is, what alternatives exist, and what the acquisition process looks like then and now. We'll also address what a LIMS matters to today's laboratory.
Test method developers:
 
* Aerospace Industries Association (AIA/NAS/NASM)
===1.1 What is a laboratory information management system (LIMS)?===
* American Architectural Manufacturers Association (AAMA)
A LIMS is a specialized, software-based [[information management]] solution that offers a set of key features that support a modern laboratory's operations. Introduced in the late 1970s and early 1980s<ref name="LIMSHistory">{{cite journal |title=A brief history of LIMS |journal=Laboratory Automation and Information Management |author=Gibbon, G.A. |volume=32 |issue=1 |pages=1–5 |year=1996 |doi=10.1016/1381-141X(95)00024-K}}</ref>, the design and functionality of this software has changed significantly over the years, such that today a majority of a laboratory's processes can benefit from the LIMS' implementation and use. A LIMS has functionality that addresses most of the [[workflow]] phases of a laboratory, including<ref name="MT5310">{{cite journal |title=Laboratory information management systems in the work of the analytic laboratory |journal=Measurement Techniques |author=Skobelev, D.O.; Zaytseva, T.M.; Kozlov, A.D. et al. |volume=53 |issue=10 |pages=1182–1189 |year=2011 |doi=10.1007/s11018-011-9638-7}}</ref>:
* American Association of State Highway and Transportation Officials (AASHTO)
 
* American Association of Textile Chemists and Colorists (AATCC)
*the reception and log in of a [[Sample (material)|sample]] and its associated customer data;
* American Institute of Timber Construction (AITC)
*the assignment, scheduling, and tracking of the sample and the associated analytical workload;
* American National Standards Institute (ANSI)
*the processing and [[quality control]] (QC) associated with the sample and the utilized equipment and inventory;
* American Petroleum Institute (API)
*the storage and access management of data associated with the sample analysis; and
* American Society of Mechanical Engineers (ASME)
*the inspection, approval, and compilation of the sample data for reporting and/or further analysis.
* American Welding Society (AWS)
 
* American Wood Protection Association (AWPA)
Related is the [[laboratory information system]] (LIS), which is tailored to the workflow of a [[clinical laboratory]]. That said, the distinction between the LIMS and LIS has blurred over time, with some LIMS having the same clinical information management features of an LIS. In both cases, the software—when developed, implemented, and maintained well—can improve laboratory workflows and workloads while enhancing safety, quality, and compliance. A well-implemented LIMS can reduce the silos of information and data in a laboratory, while at the same time make that information and data more secure, readily accessible, and actionable. Additionally, many modern LIMS are able to be pre-configured out of the box with analytical and quality control workflow support tools that can be further optimized to a lab's unique industry-based workflow. When integrated with instruments and other software systems, fewer transcription errors occur and traceability becomes easier, while monitoring of supply chain issues, quality control data, instrument use, and more is further enabled, particularly when paired with configurable dashboards and alert mechanisms. This also means that the lab can react more rapidly to issues that compromise compliance with certification to the [[ISO/IEC 17025]] standard, as is necessary in, for example, the food and beverage industry.<ref name="SmithInteg19">{{cite web |url=https://foodsafetytech.com/feature_article/integrated-informatics-optimizing-food-quality-and-safety-by-building-regulatory-compliance-into-the-supply-chain/ |title=Integrated Informatics: Optimizing Food Quality and Safety by Building Regulatory Compliance into the Supply Chain |author=Smith, K. |work=Food Safety Tech |date=02 July 2019 |accessdate=04 July 2023}}</ref><ref name="ApteIsYour20">{{cite web |url=https://foodsafetytech.com/column/is-your-food-testing-lab-prepping-for-an-iso-iec-17025-audit/ |title=Is Your Food Testing Lab Prepping for an ISO/IEC 17025 Audit? |author=Apte, A. |work=Food Safety Tech |date=20 October 2020 |accessdate=04 July 2023}}</ref><ref name="McDermottHowDig18">{{cite web |url=https://foodsafetytech.com/column/how-digital-solutions-support-supply-chain-transparency-and-traceability/ |title=How Digital Solutions Support Supply Chain Transparency and Traceability |author=McDermott, P. |work=Food Safety Tech |date=31 July 2018 |accessdate=04 July 2023}}</ref>
* AOAC International (Association of Official Agricultural Chemists; AOAC)
 
* ASTM International (ASTM)
===1.2 What are the alternatives to a LIMS?===
* Automakers (Ford, GM, Honda, PACCAR, Peugeot, Subaru, Tesla, Toyota, Volvo, etc.)
Introducing new technologies and products often causes people to balk because it represents a change to current operations and an expense, even if the change is beneficial. As such, some may view the acquisition, use, and maintenance of a LIMS to be too daunting. The organization may even see the value in a LIMS but finds several questions arise:
* Canadian Standards Association (CSA)
 
* Chemical Fabrics & Film Association (CFFA)
*What happens if we don’t make the change to a LIMS?
* Consumer Product Safety Commission (CPSC)
*Is there an alternative technology that is less costly?
* Deutsches Institut für Normung (DIN)
 
* Electronic Components Industry Association (ECIA/EIA)
The answer to the first question is straightforward: lab costs continue to increase, operations stagnate, sample backlogs increase, and lab personnel—including management—become increasingly frustrated. This in turn means the lab may fail to achieve its goals. That second question is politically charged, however, particularly in medium to larger organizations. There are two frequently encountered answers, both involving internal software development: let's use a spreadsheet, or let's use an [[enterprise resource planning]] (ERP) system as a solution with similar characteristics to a LIMS. The latter often occurs if a company has recently invested in an ERP solution with the idea that it will take care of all of the company’s needs (i.e., they may not have checked with the labs to see if actually will).
* European Telecommunications Standards Institute (ETSI)
 
* Federal Motor Vehicle Safety Standard (FMVSS)
Before we get into a response to that second question, I'd like to ask you one. What business is your company in? Is it a software development organization, or does it want to become one? I ask this because what often happens is someone in the organization proposes custom software development as an alternative. Suppose you are seriously considering developing a LIMS alternative in-house or through a consulting firm. In that case, that is something you have to think through, taking on all the issues that plague large software development projects, including ongoing maintenance and support once the project is completed.
* FM Approvals (FM)
 
* GE Aerospace (GE)
Software development projects are fraught with issues. Reasons for software project failure include<ref name="DACD5Reasons22">{{cite web |url=https://dac.digital/why-software-projects-fail-and-how-to-make-them-succeed/ |title=5 reasons why software projects fail and how to make them succeed |work=DAC.digital Blog |publisher=DAC.digital |date=19 April 2022 |accessdate=30 June 2023}}</ref><ref name="Singh23Reas22">{{cite web |url=https://www.netsolutions.com/insights/23-reasons-why-software-projects-fail-with-solutions/ |title=23 Reasons Why Software Projects Fail (with Solutions) |author=Singh, S. |work=Net Solutions Insights |publisher=Net Solutions |date=15 June 2022 |accessdate=30 June 2023}}</ref><ref name="Forbes14Comm20">{{cite web |url=https://www.forbes.com/sites/forbestechcouncil/2020/03/31/14-common-reasons-software-projects-fail-and-how-to-avoid-them/amp/ |title=14 Common Reasons Software Projects Fail (And How To Avoid Them) |author=Forbes Technology Council |publisher=Forbes |date=31 March 2020 |accessdate=30 June 2023}}</ref>:
* Government and military (MIL, [https://fedspecs.gsa.gov/s/federal-standards Fed], Consumer Product Safety Commission, CSFA, EPA, FDA, MMM, NAVSEA, United Nations Economic Commission for Europe, etc.)
 
* Industrial Fasteners Institute (IFI)
*insufficient organizational leadership
* Institute of Electrical and Electronics Engineers (IEEE)
*insufficient understanding of business and department problems and requirements, even as they evolve during development
* International Atomic Energy Agency (IAEA) ([https://www.iaea.org/topics/material-analysis 1], [https://www.iaea.org/topics/other-non-destructive-testing 2], [https://www.iaea.org/topics/materials 3])
*inadequate planning and project management
* International Code Council (ICC-ES)
*undefined project roles and responsibilities
* International Electrotechnical Commission (IEC)
*inaccurate time and cost projections
* International Maritime Organization (IMO)
*inadequate use of available resources
* International Organization for Standardization (ISO)
*insufficient understanding of changing software development practices
* International Safe Transit Association (ISTA)
*poor or mismanaged communication methods
* IPC International (Institute for Interconnecting and Packaging Electronic Circuits; IPC)
*poor response to project challenges that inevitably arise
* Japanese Standards Association (JAS/JIS)
*lack of focus on project success
* NACE International (National Association of Corrosion Engineers; NACE)
*lack of focus on soft skills such as training and team building
* National Fire Protection Association (NFPA)
*scope creep
* [https://www.dot.ny.gov/divisions/engineering/structures/manuals/scm/repository/SCM_4th_Edition_1-2018.pdf New York State Steel Construction Manual (NNSSCM/SCM)]
 
* NSF International (National Sanitation Foundation; NSF)
The bottom line is this: software projects develop issues, and while they may eventually succeed, they a may take a year or more to work through during development. Meanwhile, your lab is suffering
* Pressure Sensitive Tape Council (PSTC)
under whatever issues caused you to look for a LIMS in the first place. When you're done with developing the solution, will you have something better than commercial products or just the best you can settle for? Commercial products will be continually improved with new features and capabilities added; that's their business. Do you have the resources and commitment to make it yours?
* Radio Technical Commission for Aeronautics (RTCA)
 
* Suppliers of Advanced Composite Materials Association (SACMA)
We find that software development approaches have their own issues to address, but what about spreadsheets and ERP systems? Spreadsheet-based systems, while seemingly inexpensive, are costly in development time and use. Additionally, spreadsheets are single-user-at-a-time systems. Everyone else has to wait their turn if someone is working with the system. They are fraught with errors creeping in, especially through changes that may not be documented. They are also difficult to validate and keep under modification control. Those factors are red flags to regulatory inspectors, particularly regarding development documentation.<ref name="LiscouskiImproving23">{{cite web |url=https://www.lablynx.com/library/articles/improving-lab-systems-from-paper-to-spreadsheets-to-lims/ |title=Improving Lab Systems: From Paper to Spreadsheets to LIMS |publisher=LabLynx, Inc |date=April 2023 |accessdate=05 July 2023}}</ref> As for ERPs, those systems may address some of the requirements of your lab, but they will have significant problems with instrument connections, a significant source of productivity gains in the laboratory. Do these and similar alternatives represent the most cost-effective way to manage risk and utilize your resources towards the goal of improving laboratory productivity and compliance? The purpose-built LIMS may make more sense given the challenges posed by forcibly shoehorning these alternatives into a role they weren't necessarily designed for.
* SAE International (SAE/AMS/AS)
 
* TAPPI (Technical Association of the Pulp and Paper Industry; TAPPI)
===1.3 LIMS acquisition then and now===
* Truss Plate Institute (TPI)
The laboratory environment of the 1980s, viewed from a behavioral standpoint, would be easily recognizable today: growing test workloads, everyone’s sample was a top priority, and everyone was very busy as all work was manually done. From a technology perspective, things were a lot different. For the most part, there were no computers, and instrument data systems (IDSs) were entering the marketplace. Still, IDSs hadn't become the almost automatic combined instrument-computer combination they are today. Networks were in their early stage of development. [[Laboratory automation|Robotics]] was also in an earlier part of its evolution; Zymark Corporation of Hokinton, Massachusetts (which later became Caliper Life Sciences), was an early developer of lab robotics, which was just beginning to impact the laboratory market. There was no severe shortage of educated laboratory personnel to fill open lab positions. However, few were knowledgeable in [[laboratory informatics]].
* UL Standards and Engagement (UL)
 
* United States Pharmacopeia Convention (USP)
The cost of lab operations was becoming a serious concern for lab management. Although people were available, there was a limit to how many you could hire, given the limitations of
laboratory space and equipment utilization. As a result, economics played a significant role in the justification for equipment and instrumentation, in general, and LIMS, a new technology, in particular. One of the significant differences between then and today is that installing a LIMS meant installing a local computer system; [[Cloud computing|cloud-based]] systems didn't exist.
 
As the productivity issue became more acute, the interest in automation and the efficiency of lab operations grew. In clinical chemistry work, the response was particularly strong with the
development of an industry-wide total laboratory automation (TLA) initiative that focused on driving down the cost of laboratory testing through automation and the development of communications standards to make it easier to connect instruments and computers together into fully functioning networks that would relieve much of the manual clerical effort.
 
Much of the [[information]] we have on the effectiveness of laboratory automation and LIMS installations comes from the life science and clinical industries. The results of TLA could be seen in 1992, when Markin and Hald noted<ref>{{Cite journal |last=Markin |first=Rodney S. |last2=Hald |first2=David L. |date=1992-12 |title=Cost justification of a laboratory information system: An analysis of projected tangible and intangible benefits |url=http://link.springer.com/10.1007/BF00996362 |journal=Journal of Medical Systems |language=en |volume=16 |issue=6 |pages=281–295 |doi=10.1007/BF00996362 |issn=0148-5598}}</ref>:
 
<blockquote>The tangible [financial] benefits which were measured prior to LIS 4 justification totaled $153,471.84 per year based upon fiscal year 1985-86 dollars. The objective re-evaluation of these activities four years after implementation and operation resulted in a measured $115,326.93 per year savings ... Implementation of the laboratory information system at our institution resulted in a 75% capture of the estimated/projected cost avoidance or cost savings.</blockquote>
 
In a more modern example from 2018, Yu ''et al.'', who wishing to improve workflow efficiency in their clinical laboratory, implemented TLA "that connected our pre-analytic processing system with various testing (hematology, coagulation, and chemistry)."<ref name=":0">{{Cite journal |last=Yu |first=Hoi-Ying Elsie |last2=Lanzoni |first2=Harold |last3=Steffen |first3=Tracy |last4=Derr |first4=Warren |last5=Cannon |first5=Kim |last6=Contreras |first6=Jeanene |last7=Olson |first7=Jordan Erik |date=2019-01-01 |title=Improving Laboratory Processes with Total Laboratory Automation |url=https://academic.oup.com/labmed/article/50/1/96/5047095 |journal=Laboratory Medicine |language=en |volume=50 |issue=1 |pages=96–102 |doi=10.1093/labmed/lmy031 |issn=0007-5027}}</ref> They reported their results as such<ref name=":0" />:
 
<blockquote>The implementation of our TLA system resulted in 86% fewer discrete processing steps in specimen handling, even when starting from a partially automated laboratory. Instrument consolidation reduced the testing footprint by 45% and reduced the number of testing personnel by 2.5 full-time employees (FTEs). An 82% reduction in hands-on time associated with add-on processes was achieved. Combining STAT and outreach work on the testing system did not impact turnaround time.</blockquote>
 
Outside of TLA, lacking other driving factors, the primary motivation for implementing automation and LIMS or LIS in the lab early on was productivity and, as a result, finances. A 1986 article by Joseph H. Golden (then at Laboratory Management Systems, Inc.), titled “Economic Considerations of Laboratory Information Management Systems,” addressed that point directly. Considerations and concerns he had included (quoting directly)<ref>{{Cite book |last=Golden, J.H. |date= |year=1986 |editor-last=Provder |editor-first=Theodore |title=Computer Applications in the Polymer Laboratory |url=https://pubs.acs.org/doi/book/10.1021/bk-1986-0313 |chapter=Chapter 2: Economic Considerations of Laboratory Information Management Systems |series=ACS Symposium Series |language=en |publisher=American Chemical Society |place=Washington, DC |volume=313 |pages=6–16 |doi=10.1021/bk-1986-0313.ch002 |isbn=978-0-8412-0977-0}}</ref>:
 
*the "impact on lab operations, reducing administrative work [and] speeding up work";
*"how the laboratory contributes to the corporate bottom line";
*the "need to consider not just what LIMS will do but what it’s worth";
*in regards to R&D, that " productivity improvements amount to at least 10% to 20% of the total staff resources of a laboratory complex”;
*in regards to QA/QC, that "time-value of information" and "ability to accept/reject raw material and avoid off-spec products" is considered, "plus 10-20% saving on clerical costs";
*that commercial testing saw "improved profitability";
*the consideration of "common lab management problems," such as "increasing data volume from increased use of smart instruments and from increased testing and record retention requirements imposed by the Environmental Protection Agency (EPA), [[Food and Drug Administration]] (FDA), Occupational Safety and Health Administration (OSHA), and other regulatory agencies; constantly rising operating and material costs; and ever-tightening constraints on staff and material expenditures, which in turn are "manifested by increasingly burdensome paperwork, inefficient utilization of resources, and exasperating searches for misplaced samples and data"; and
*the costs of "equipment, facilities, cost of money, and investment tax credits."
 
The justification for LIMS acquisition in the 1980s was based on comparing two states: the status quo vs. the introduction of laboratory informatics in the form of an on-premises LIMS. Among the more significant management concerns were whether the costs could be contained and the project kept on track. Large software projects were notorious for cost overruns and scheduling delays during that time. However, demands for improved processes in labs was also increasing, particularly in regulated settings like the pharmaceutical industry. Failure to keep accurate records, and be able to find them, could result in plant closures, and that alone could justify the acquisition for a LIMS.
 
Table 1 compares concessions and considerations made in the 1980s of maintaining existing lab operations vs. acquiring and implementing an on-premises LIMS.
 
{|
| style="vertical-align:top;" |
{| class="wikitable" border="1" cellpadding="5" cellspacing="0" width="60%"
|-
  | colspan="2" style="background-color:white; padding-left:10px; padding-right:10px;" |'''Table 1.''' Comparison of maintaining existing lab operations vs. on-premises LIMS acquisition and deployment in the 1980s.
|-
  ! style="background-color:#e2e2e2; padding-left:10px; padding-right:10px;" |Status quo
  ! style="background-color:#e2e2e2; padding-left:10px; padding-right:10px;" |LIMS acquisition
|- 
  | style="background-color:white; padding-left:10px; padding-right:10px;" |• Survive with inefficient operations<br />• Divert resources for conducting the required clerical work<br />• Resign to not gaining maximum value from data because of the prohibitive cost of doing the work<br />• Live with inefficiently organized data and information management due to everything being on paper<br />• Handle the greater difficulties of meeting government and industry records retention requirements<br />• Manage the rising costs of work and diminished lab productivity due to space, equipment, and hiring constraints<br />• Live with the potential for lab management and personnel to be frustrated with existing operations and need for overtime to get work completed
  | style="background-color:white; padding-left:10px; padding-right:10px;" |• Improve efficiency of lab operations with potential 10 to 20% improvement in productivity<br />• Reduce the need to hire more people (in the 1980s, people were readily available)<br />• Absorb the associated costs of LIMS licensing, training, installation, configuration, hardware, and maintenance and support<br />• Off-set the LIMS costs through investment tax credits, accelerated depreciation rate, and deductible interest rate payments
|-
|}
|}
 
Today, laboratories of all kinds face a variety of factors that drive them to become better at managing their operations. The tools for this improvement are available, and regulatory agencies expect labs to use
the best technologies to meet regulatory requirements. Although it has been technically possible to meet regulatory requirements without computing technology—using paper-based systems—electronic systems make the work much easier and less costly, while improving the lab’s ability to meet inspectors' requests promptly, as well as the lab's workflows themselves. In the past, paper-based approaches to conducting lab operations were the only option in the pre-electronic era, and these approached tended to be slow, inefficient, and expensive. This changed in the late 1970s and into the 1980s, as computerized systems held promise in speeding up lab processes and making them more efficient, though they were still expensive to implement. Today, laboratory informatics options are less expensive, while also living up to the promise of improving lab operations. Laboratories provide data and information as their primary product; the ability to put those products to work and gain value from them is paramount. Continuing to use a paper-based system place limitations on that ability while incurring additional hidden and apparent costs to the lab. The LIMS and other informatics solutions make more sense than ever, particularly given stronger economic and competitive pressures.
 
Regulatory pressures have also increased as the regulatory landscape has changed. During the mid-1980s, when Mr. Golden's analysis was presented, regulatory requirements were beginning to gain new ground. The EPA and FDA had records retention requirements, and companies were starting to understand the FDA's guidelines, first published in 1978. There were still a lot of open issues; the words were there, but the intent wasn't clear. What did "validation" mean? What was the "first written record" of a result? The latter point made sense on paper, but what did it mean when applied to computers acquiring data and writing results into memory?
 
In the next few years:
 
*regulatory requirements were produced by OHSA;
*standards like ISO 9000 were developed by the International Organization for Standardization (ISO);
*the EPA’s good laboratory practices (GLP) came into existence; and
*the International Society of Pharmaceutical Engineers (ISPE) released the [[Good Automated Manufacturing Practice]]s (GAMP).
 
Companies and their laboratories increasingly had to organize and document their work according to external standards, guidelines, and regulations instead of relying on internally defined business practices. These covered more than experimental records; they extended to personnel and their qualifications, equipment maintenance and calibrations, reagent maintenance and testing, and test method documentation and validation. It created a large amount of clerical and administrative work. In addition, the results of that work had to be produced on demand.
 
Additionally, the requirements established by regulatory agencies provided the initial thrust for concerns over data governance, including data management, integrity, and utility. When everything was
on paper, it was a matter of keeping paper documents well organized. There wasn't much else you could do. Then things changed, bringing with them new responsibilities and opportunities.
 
Most instruments today either contain computing capabilities or are attached to computer systems with data storage, some temporary (e.g., [[pH meter]]s and scales) and some long-term (e.g., IDSs). The more instruments we have, the more storage devices that hold laboratory results. In some cases, those results only exist on one storage device as long as a power surge doesn’t disrupt that system. Lab personnel probably know where the data they produce is, but that knowledge walks out the door every night. As such, laboratories need a centralized system to track all the data, information, results, calibrations, schedules, documents, etc., that labs produce. A small lab might be able to get by with a paper-based approach until they discover it no longer works, often when data previously believed to be secure becomes lost. Today, that centralized system is a LIMS.
 
Table 2 looks at a variety of these technological, regulatory, data governance, and data security issues, comparing what the state of thought was in the 1980s vs. today.
 
{|
| style="vertical-align:top;" |
{| class="wikitable" border="1" cellpadding="5" cellspacing="0" width="60%"
|-
  | colspan="3" style="background-color:white; padding-left:10px; padding-right:10px;" |'''Table 2.''' Brief comparison of factors affecting laboratory operations in the 1980s vs. today.
|-
  ! style="background-color:#e2e2e2; padding-left:10px; padding-right:10px;" |Factor
  ! style="background-color:#e2e2e2; padding-left:10px; padding-right:10px;" |1980s
  ! style="background-color:#e2e2e2; padding-left:10px; padding-right:10px;" |Today
|- 
  | style="background-color:white; padding-left:10px; padding-right:10px;" |'''Computing model'''
  | style="background-color:white; padding-left:10px; padding-right:10px;" |Computing was still in the early stages of adoption, and IT support was in its infancy, mostly concerned with corporate issues. Laboratory automation was essentially a few "islands of automation, with little interconnection. Personal computing was also in its infancy, and cloud computing didn't exist.
  | style="background-color:white; padding-left:10px; padding-right:10px;" |Computing is widespread, and IT support can be found in many organizations large and small. Interconnected system are just part of the landscape inside and outside the laboratory. Personal computing is ubiquitous at work and home, as is wired and wireless networking. Cloud computing  is available through a variety of technologies for executing applications, primary data storage, data backup, access to advanced technologies, etc.
|- 
  | style="background-color:white; padding-left:10px; padding-right:10px;" |'''Regulatory landscape'''
  | style="background-color:white; padding-left:10px; padding-right:10px;" |Regulations were in the early stages of development, with the EPA and FDA leading with record retention requirements and guidelines. Enforced regulations were just beginning.
  | style="background-color:white; padding-left:10px; padding-right:10px;" |Regulations come from a variety of sources, with organizations finding themselves under one or more sets of standards, guidelines, and regulations, including ISO 9000, GAMP, and Clinical Laboratory Improvement Amendments (CLIA).
|- 
  | style="background-color:white; padding-left:10px; padding-right:10px;" |'''Personnel'''
  | style="background-color:white; padding-left:10px; padding-right:10px;" |Lab personnel were readily available.
  | style="background-color:white; padding-left:10px; padding-right:10px;" |There is a growing shortage of people interested in and available for laboratory work, particularly in the medical realm.<ref>{{Cite journal |last=Halstead |first=Diane C |last2=Sautter |first2=Robert L |date=2023-01-05 |title=A Literature Review on How We Can Address Medical Laboratory Scientist Staffing Shortages |url=https://academic.oup.com/labmed/article/54/1/e31/6712256 |journal=Laboratory Medicine |language=en |volume=54 |issue=1 |pages=e31–e36 |doi=10.1093/labmed/lmac090 |issn=0007-5027}}</ref>
|- 
  | style="background-color:white; padding-left:10px; padding-right:10px;" |'''Data governance'''
  | style="background-color:white; padding-left:10px; padding-right:10px;" |This concept was in its infancy, mostly in the form of records retention requirements.
  | style="background-color:white; padding-left:10px; padding-right:10px;" |Data governance has become a significant factor in lab operations and management.<ref name="McDowallUnderI17">{{cite web |url=https://www.spectroscopyonline.com/view/understanding-data-governance |title=Understanding Data Governance, Part I |author=McDowll, R.D. |journal=Spectroscopy |volume=32 |issue=2 |pages=32–38 |year=2017 |accessdate=05 July 2023}}</ref><ref name="McDowallUnderII17">{{cite web |url=https://www.spectroscopyonline.com/view/impact-data-governance-laboratory |title=Understanding Data Governance, Part II |author=McDowll, R.D. |journal=Spectroscopy |volume=32 |issue=4 |pages=12–18 |year=2017 |accessdate=05 July 2023}}</ref>
|- 
  | style="background-color:white; padding-left:10px; padding-right:10px;" |'''Computer security'''
  | style="background-color:white; padding-left:10px; padding-right:10px;" |This wasn't a serious issue, but evidence of problems was developing.
  | style="background-color:white; padding-left:10px; padding-right:10px;" |Computer security is a major consideration in all forms of computing.
|- 
  | style="background-color:white; padding-left:10px; padding-right:10px;" |'''Computing legal issues'''
  | style="background-color:white; padding-left:10px; padding-right:10px;" |There wasn't much different from paper-based operations. Anything needed from the lab for legal reasons was printed on paper.
  | style="background-color:white; padding-left:10px; padding-right:10px;" |Legal issues have grown as material on computers is needed for business efficiency, patent evidence creation, intellectual property protection, regulatory compliance, knowledge management, data governance, and more.
|-
|}
|}
 
===1.4 Why a LIMS matters===
Though external pressures to improve operations may have increased, the goals of laboratory work today are much the same as they were in the past: produce high-quality results, with the best productivity possible while keeping initial and ongoing costs to a reasonable level. The goals may look slightly different among the different types of labs, however:
 
*'''Testing''': Whether supporting research programs or conducting contract-based analytical testing for clients, work efficiently and effectively to produce high-quality and accurate analytical test results while maintaining profitability.
*'''Research''': Develop new products, solve production problems, and solve real-world problems (e.g., curing disease, developing alternative fuels, improving food production, etc.), while ensuring at the same time that analyses and studies are conducted consistently, accurately, and ethically.
*'''QA/QC''': Support production and manufacturing operations through accurate and timely testing, while promoting higher levels of quality, consumer safety, and consumer satisfaction.
 
The goals are typically driven by management and other key stakeholders within the organization. Those same people hopefully recognize that meeting those goals requires more than simply managing the lab's personnel. The lab's success also hinges upon the management of equipment, infrastructure (including power), data, information, and the systems used to produce and manage the products of the lab work: analytical data and information. The previous section examined the transition from paper-based to electronic lab, and from that examination we begin to see that LIMS and other laboratory informatics solutions are increasingly an important part of the equation for organizational success. This growing informatics architecture is a hierarchical structure with work requests and the needs of regulatory and corporate
compliance flowing into it, and produced worklists being distributed to stations when the analysis is completed. The results then flow back into the LIMS, the central hub for this activity. Lab results can be interrogated, analyzed, and distributed as needed (Figure 1).
 
 
[[File:Fig1 Liscouski JustLIMSAcqui23.png|800px]]
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{| border="0" cellpadding="5" cellspacing="0" width="800px"
|-
  | style="background-color:white; padding-left:10px; padding-right:10px;" |<blockquote>'''Figure 1.''' LIMS as the hub of lab data and operations management. All work requests are managed through the LIMS. Those work requests are the basis for worklists sent to instruments, with the results again collected in the LIMS. The LIMS provides a one-stop source for all lab activities, greatly simplifying and improving lab operations.</blockquote>
|-
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Your organization must be able to support the lab's goals, meet the demands of regulators, and meet your organization's responsibilities for data governance, all while maintaining an economically sound operation. Can that realistically be done without a LIMS supporting your operations? For example, would you run your accounting department without a software system? From that viewpoint, your accounting system's benefits to that department's work are similar in principle to those provided to your lab by a LIMS.
 
This section only touches upon why a LIMS matters to a laboratory and meetings its operational goals. Introducing a LIMS is an opportunity to solve operational management issues, improve productivity, make it easier to meet regulatory requirements and guidelines, turn your lab's data and information into a valuable asset, and meet modern demands for data governance. The next chapter goes into greater detail about the economic and practical justifications behind acquiring and implementing a LIMS in your lab, further clarifying why the LIMS should matter to you and your organization, and why the benefits of LIMS far outweigh the costs.
 
==References==
{{Reflist|colwidth=30em}}
 
==Citation information for this chapter==
'''Chapter''': 1. Introduction to LIMS and LIMS acquisition
 
'''Title''': ''Justifying LIMS Acquisition and Deployment within Your Organization''
 
'''Edition''': First Edition
 
'''Author for citation''': Joe Liscouski, Shawn E. Douglas
 
'''License for content''': [https://creativecommons.org/licenses/by-sa/4.0/ Creative Commons Attribution-ShareAlike 4.0 International]
 
'''Publication date''':
 
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