Laboratory informatics

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A Bio-Rad thermal cycler as an example of a laboratory device that measures, processes, and sends information. Such a device can be interfaced with laboratory informatics solutions like a laboratory information system (LIS), sometimes with the help of middleware.

Laboratory informatics is the specialized application of information through a platform of instruments, software, and data management tools that allow scientific data to be captured, migrated, processed, and interpreted for immediate use, as well as stored, managed, and shared to support future research, development, and lab testing efforts while maximizing the efficiency of laboratory operations.[1][2]

History

The term "laboratory informatics" has been in use at least since the early 1980s[3][4][5] and has expanded in meaning since then. Before the advent of computer technology, information management played an important role in laboratories and research efforts of all sorts. And while today the process of information management continues to be important, laboratory informatics tends to focus more on the technology and workflows associated with that information management process.[6]

The field itself is one which has seen significant growth as demand for fast and efficient electronic data exchange has boomed. A rapid series of technological developments have made laboratory equipment less static and more interactive, allowing large networks of integrated lab devices, computers, and telecommunications equipment to log, analyze, and distribute data. This has progressively enabled scientific research projects to move from a localized model to a more global model, one that allows "involved researchers to spend less time collecting data or waiting for information to arrive from another location, which in turn allows them to focus more on the work at hand and makes their research both faster and more efficient."[7] Tangentially, more robust and scalable data management systems have been developed to help laboratories stay competitive. Today, this often means adopting laboratory automation solutions that are capable of being developed and deployed in an agile fashion.[8][9] Additionally, the rapid rate of change in the technological (e.g., cloud computing, big data) and operational needs (e.g., more automated workflows) of researchers—coupled with growing competition—has led to a variety of related efforts, such as conferences and trade shows, to assist directors, managers, and researchers in better keeping up with the industry.[10]

Today, the concept of laboratory informatics continues to evolve, with market research groups like Gartner identifying need-based shifts towards multi-purpose solutions that address end-to-end management of laboratory data and operations.[11][12][13][14] This can be seen in developing concepts such as "enterprise laboratory informatics," which attempts to integrate laboratory informatics systems and functionality across an entire laboratory-supported enterprise, often through the use of a more unified, platform-based approach that uses future-focused software architectures to help reduce complexity, cost of ownership, and time to market while also improving efficiency and quality.[13] This concept of unifying laboratory informatics systems and functionality into a more streamlined approach across an entire enterprise is most readily seen in laboratory-supported organizations that not only conduct research and development (R&D) activities but also manufacture their researched products.[11][12][13]

Sub-elements in laboratory informatics

Laboratory informatics is often modeled as a central component or hub for other branching elements of the field. However, looking at the architecture in this fashion oversimplifies the field of laboratory informatics and risks giving the false appearance that branched elements of the field have greater importance than others. Instead, a multi-layered, non-hierarchical model of these elements that places an emphasis on an individual laboratory's identified business needs may be more appropriate.[2] A cottage industry of businesses and consultants has developed from this philosophy, helping laboratories map their informatics needs to their corporate strategy.[15]

Yet it's difficult to deny the existence of branching elements of laboratory informatics. Many scientific pursuits require a laboratory, from medicine to astrophysics. This has led to special "sub-applications" of informatics to more specialized laboratories. Genome informatics developed as genetics laboratories sought more efficient ways to manage the large amounts of data being acquired from experiments and research. As scientists continue their pursuit of unlocking the secrets of the brain, neuroinformatics and its associated technology has developed to aid those researchers in their endeavors. And as hydrologists tackle the issues of equitable and efficient use of water for many different purposes, hydroinformatics and computational hydraulics have emerged.

These sub-applications of laboratory informatics are also discussed in ASTM International's ASTM E1578-18 Standard Guide for Laboratory Informatics. Updated in mid-2019, the standard not only covers applications of informatics to general analytical laboratories but also to environmental, life science, medical, industrial, and public sector labs. The update brought with it new insights into laboratory informatics tools and how to integrate them into laboratory workflow, and with other hardware and software. And though relatively in their infancy in laboratory application, the revision added content about the application of the internet of things (IoT), artificial intelligence (AI), and smart objects to the laboratory.[16]

Additional considerations in laboratory informatics

The actual processes (i.e., workflows) that involve information management in the laboratory should not be overlooked. Laboratories are usually required to meet regulatory requirements that dictate what data should be managed; when it should be collected and stored; how it should be collected, used, and stored; where it should be housed; and who has access to it.[17][18] This type of regulation has, of course, had an impact on the development of software in general[19][20], including laboratory informatics applications. Developers of these applications, including enterprise laboratory informatics applications, must take into account[13][16]:

These and other considerations are discussed in standards such as ASTM E1578-18[16] and ISO/IEC 17025.[21]

Technology of laboratory informatics

Important hardware and software systems that play a role in laboratory informatics include but are not limited to:

See also

For specialized applications of informatics to scientific disciplines, many of them involving laboratory work, see the informatics page.

References

  1. Metrick, G. (20 July 2008). "Informatics Are Really, Really, Really Important". Lab Manager Magazine. https://www.labmanager.com/laboratory-informatics-20964. Retrieved 27 March 2024. 
  2. 2.0 2.1 Wood, S. (September 2007). "Comprehensive Laboratory Informatics: A Multilayer Approach" (PDF). American Laboratory. pp. 3. Archived from the original on 25 August 2017. https://web.archive.org/web/20170825181932/https://www.it.uu.se/edu/course/homepage/lims/vt12/ComprehensiveLaboratoryInformatics.pdf. Retrieved 27 March 2024. 
  3. "Section 36: Health Economics and Hospital Management". Excerpta Medica 19 (1): 72, 534. 1983. https://books.google.com/books?id=z4GaAAAAIAAJ&q=%22laboratory+informatics%22&dq=%22laboratory+informatics%22&hl=en. 
  4. "Research". New Scientist (New Science Publications) 109: 66. 1986. https://books.google.com/books?id=uyceAQAAMAAJ&q=%22laboratory+informatics%22&dq=%22laboratory+informatics%22&hl=en. 
  5. "Introduction". Informatics in Pathology (Grune & Stratton) 1 (1): 1. 1986. https://books.google.com/books?id=PbNYAAAAYAAJ&q=%22laboratory+informatics%22&dq=%22laboratory+informatics%22&hl=en. 
  6. Cowan, D., ed. (2002). Informatics for the Clinical Laboratory: A Practical Guide (1st ed.). Springer. pp. 9. ISBN 9780387244495. https://books.google.com/books?id=OKqGfr6xgFkC&pg=PA9. 
  7. "Laboratory Informatics". virtualinformatics.com. 9 April 2011. Archived from the original on 25 April 2015. http://web.archive.org/web/20150425070143/http://virtualinformatics.com/content/Laboratory_informatics.htm. Retrieved 27 March 2024. 
  8. Krasovec, E. (2009). "LIMS Get Agile" (PDF). International Clinical Trials Spring 2009: 32, 34. Archived from the original on 26 January 2021. https://web.archive.org/web/20210126145540/https://www.informatics.abbott/shared/lims-get-agile.pdf. Retrieved 27 March 2024. 
  9. "Agile Development in Laboratory Informatics". CSols, Inc.. 5 December 2019. https://www.csolsinc.com/blog/agile-development-in-laboratory-informatics/. Retrieved 27 March 2024. 
  10. Metrick, G. (8 December 2010). "Trends in Laboratory Informatics". Lab Manager Magazine. https://www.labmanager.com/trends-in-laboratory-informatics-19119. Retrieved 27 March 2024. 
  11. 11.0 11.1 Shanler, M.; Sinha, R. (4 August 2021). "Market Guide for Laboratory Informatics". Gartner, Inc. https://www.gartner.com/en/documents/4004372. Retrieved 27 March 2024. 
  12. 12.0 12.1 "Gartner Market Guide for Laboratory Informatics". AgiLab SAS. 29 October 2021. https://www.agilab.com/gartner-market-guide-laboratory-informatics-2/. Retrieved 27 March 2024. 
  13. 13.0 13.1 13.2 13.3 Shanler, M.; Franzosa, R.; Nieradka, M. (27 July 2023). "Hype Cycle for Life Science Manufacturing, Quality and Supply Chain, 2023" (PDF). Gartner, Inc. https://www.antaresvisiongroup.com/lifescience/wp-content/uploads/sites/3/2023/08/Hype_Cycle_for_Life__788244_ndx.pdf. Retrieved 27 March 2024. 
  14. "Accelerating science with a well-architected digital experience" (PDF). Thermo Fisher Scientific, Inc. June 2023. https://assets.thermofisher.com/TFS-Assets/DSD/brochures/Thermo_RoleOfLIMSPlatform_EN.pdf. Retrieved 27 March 2024. 
  15. "Laboratory Informatics Strategy". Labvantage Solutions, Inc. Archived from the original on 13 February 2013. https://web.archive.org/web/20130213132659/http://www.labvantage.com/services/laboratory-strategy.aspx. Retrieved 27 March 2024. 
  16. 16.0 16.1 16.2 "ASTM E1578-18 Standard Guide for Laboratory Informatics". ASTM International. 23 August 2019. https://www.astm.org/e1578-18.html. Retrieved 27 March 2024. 
  17. Matsushita, H.; Miyachi, H. (2009). "Compliance with laboratory requirements regarding the secondary use of clinical specimens and laboratory data". Rinsho Byori 57 (7): 678–82. PMID 19708538. 
  18. Poosa, S. (November 2015). "An Explanation of Laboratory Governing Bodies, Regulations, and Applicable Laws" (PDF). BC Solutions, LLC. Archived from the original on 19 March 2020. https://web.archive.org/web/20200319213139/http://www.bcsolutionsrfn.com/wp-content/uploads/2015/11/explanation-of-laboratory-governing-bodies-regulations-and-applicable-laws.pdf. Retrieved 27 March 2024. 
  19. Hamou-Lhadj, A. (2010). "Regulatory Compliance and its Impact on Software Development" (PDF). Proceedings from the First Workshop on Law Compliancy Issues in Organisational Systems and Strategies (iComply10): 1–5. https://www.semanticscholar.org/paper/Regulatory-Compliance-and-its-Impact-on-Software-Hamou-Lhadj/033e3f4cb88026804d1de861b6e1944d652cbd74?p2df. 
  20. Miri, M.; Foomany, F.H.; Mohammed, N. (2018). "Complying With GDPR: An Agile Case Study". ISACA Journal 2: 1–7. https://www.isaca.org/resources/isaca-journal/issues/2018/volume-2/complying-with-gdpr-an-agile-case-study. 
  21. "ISO/IEC 17025:2017(en) - General requirements for the competence of testing and calibration laboratories". ISO Online Browsing Platform (OBP). International Organization for Standardization. 2017. https://www.iso.org/obp/ui/#iso:std:iso-iec:17025:ed-3:v1:en. Retrieved 27 March 2024.