Difference between revisions of "User:Shawndouglas/sandbox/sublevel1"

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From law firms<ref name="SobowaleLaw17">{{cite web |url=http://www.abajournal.com/magazine/article/managing_cybersecurity_risk/ |title=Law firms must manage cybersecurity risks |author=Sobowale, J. |work=ABA Journal |publisher=American Bar Association |date=01 March 2017 |accessdate=18 November 2021}}</ref> to automotive manufacturers<ref name="WatneyAddress17">{{cite web |url=https://www.rstreet.org/wp-content/uploads/2018/04/118-1.pdf |format=PDF |title=Addressing new challenges in automotive cybersecurity |author=Watney, C.; Draffin, C. |work=R Street Policy Study No. 118 |publisher=R Street Institute |date=November 2017 |accessdate=18 November 2021}}</ref>, the need to address cybersecurity is increasingly apparent. In 2018, the Center for Strategic & International Studies estimated that cybercrime causes close to $600 billion in damages to the global economy every year<ref name="LewisEcon18">{{cite web |url=https://www.csis.org/analysis/economic-impact-cybercrime |title=Economic Impact of Cybercrime |author=Lewis, J.A. |publisher=Center for Strategic & International Studies |date=21 February 2018 |accessdate=18 November 2021}}</ref>, though due to underreporting of crimes, that number may be much higher. That number also likely doesn't take into account lost business, fines, litigation, and intangible losses<ref name="SBDCC_BlogCost17">{{cite web |url=https://www.virginiasbdc.org/blog-cost-of-cyber-crime-to-small-businesses/ |archiveurl=https://web.archive.org/web/20200705061737/https://www.virginiasbdc.org/blog-cost-of-cyber-crime-to-small-businesses/ |title=BLOG: Cost of Cyber Crime to Small Businesses |work=Virginia SBDC Blog |publisher=Virginia SBDC |date=30 May 2017 |archivedate=05 July 2020 |accessdate=18 November 2021}}</ref> In the end, businesses of all sizes average about $200,000 in losses due to a cybersecurity incident<ref name="HiscoxHiscox19&quot;">{{cite web |url=https://www.hiscox.com/documents/2019-Hiscox-Cyber-Readiness-Report.pdf |format=PDF |title=Hiscox Cyber Readiness Report 2019 |publisher=Hiscox Ltd |date=April 2019 |accessdate=18 November 2021}}</ref>, and nearly 60 percent of small and midsize businesses go bankrupt within six months because of it.<ref name="Galvin60_18">{{cite web |url=https://www.inc.com/joe-galvin/60-percent-of-small-businesses-fold-within-6-months-of-a-cyber-attack-heres-how-to-protect-yourself.html |title=60 Percent of Small Businesses Fold Within 6 Months of a Cyber Attack. Here's How to Protect Yourself |author=Galvin, J. |work=Inc.com |date=07 May 2018 |accessdate=18 November 2021}}</ref>
Without a doubt, it's vital that medical diagnostic and research laboratories operate within the bounds of a regulatory atmosphere, not only to better ensure the best patient outcomes but also to ensure the quality of test results, the privacy of patient information, and the safety of personnel. Maintaining regulatory compliance requires deliberate approaches to developing and enforcing processes and procedures, quality training, consistent communication, and knowledgeable personnel. It also requires a top-down appreciation and commitment to a culture of quality. From the [[Clinical Laboratory Improvement Amendments]] (CLIA) and [[Health Insurance Portability and Accountability Act]] (HIPAA) to [[21 CFR Part 11]] and the [[General Data Protection Regulation]], laboratories have much to consider in regards to what regulations impact them.


Medical diagnostic and research laboratories are no exception, regardless of business size. Even tiny labs whose primary digital footprint is a WordPress website advertising their lab are at risk, as hackers could still spread malware, steal user data, add the website to a bot network, hack the site for the learning experience, or even hack it just for fun.<ref name="GrimaTop19">{{cite web |url=https://www.wpwhitesecurity.com/why-malicious-hacker-target-wordpress/ |title=Top reasons why WordPress websites get hacked (and how you can stop it) |author=Grima, M. |publisher=WP White Security |date=14 November 2019 |accessdate=18 November 2021}}</ref><ref name="MoenWhatHack16">{{cite web |url=https://www.wordfence.com/blog/2016/04/hackers-compromised-wordpress-sites/ |title=What Hackers Do With Compromised WordPress Sites |author=Moen, D. |work=Wordfence Blog |publisher=Defiant, Inc |date=19 April 2016 |accessdate=18 November 2021}}</ref><ref name="TalalevWebsite19">{{cite web |url=https://patchstack.com/website-hacking-statistics/ |title=Website Hacking Statistics You Should Know in 2021 |author=Talaleve, A. |publisher=Patchstack |date=22 February 2021 |accessdate=18 November 2021}}</ref> Even more importantly are those labs performing digital data management tasks that handle sensitive patient and proprietary data, requiring additional cybersecurity considerations.
That said, consider approaching the question of regulatory compliance from the standpoint of adopting standards. Consider first that the risks and consequences of performing a task poorly drives regulation and, more preferably<ref name="CiocoiuTheRole10">{{cite book |chapter=Chapter 1. The Role of Standardization in Improving the Effectiveness of Integrated Risk Management |title=Advances in Risk Management |author=Ciocoui, C.N.; Dobrea, R.C. |editor=Nota, G. |publisher=IntechOpen |year=2010 |isbn=9789535159469 |doi=10.5772/9893}}</ref><ref name="JPMorganData18">{{cite web |url=https://www.jpmorganchase.com/content/dam/jpmc/jpmorgan-chase-and-co/documents/call-to-action.pdf |format=PDF |title=Data Standardization: A Call to Action |publisher=JPMorgan Chase & Co |date=May 2018 |accessdate=18 November 2021}}</ref>, standardization, which in turn moves the "goalposts" of quality and security among organizations. In the case of regulations, those organization that get caught not conforming to the necessary regulations tend to suffer negative consequences, providing some incentive for them to improve organizational processes and procedures.  


A laboratory can integrate cybersecurity thinking into its laboratory informatics product selection in several ways. First, the lab should have a cybersecurity plan in place, or if not, it should be on the radar. This is a good resource to tap into in regards to deciding what cybersecurity considerations should be made for the software. Can the software help your lab meet your cybersecurity goals? What regulatory requirements for your lab are or are not covered by the software?<ref name="DouglasComp20">{{cite web |title=[[LII:Comprehensive Guide to Developing and Implementing a Cybersecurity Plan|''Comprehensive Guide to Developing and Implementing a Cybersecurity Plan'']] |author=Douglas, S.E. |work=LIMSwiki |date=July 2020 |accessdate=18 November 2021}}</ref> Another tool to consider—which may have been used in any prior cybersecurity planning efforts—is a cybersecurity framework. Many, but not all, cybersecurity frameworks include a catalog of security controls. Each control is "a safeguard or countermeasure prescribed for an information system or an organization designed to protect the confidentiality, integrity, and availability of its information and to meet a set of defined security requirements."<ref name="NISTSecurity19">{{cite web |url=https://csrc.nist.gov/glossary/term/security_control |title=security control |work=Computer Security Resource Center |publisher=National Institute of Standards and Technology |date=2019 |accessdate=18 November 2021}}</ref> These controls give the implementing organization a concrete set of configurable goals to apply to their overall cybersecurity strategy. Other frameworks may be less oriented to security controls and more program-based or risk-based. Choosing the best frameworks will likely depend on multiple factors, including the organization's industry type, the amount of technical expertise within the organization, the budget, the organizational goals, the amount of buy-in from key organizational stakeholders, and those stakeholders' preferred approach.<ref name="DouglasComp20" />
One of the downsides of regulations is that they can at times be "imprecise" or "disconnected"<ref name="JPMorganData18" /> from what actually occurs within the organization and its information systems. Rather than focusing heavily on regulatory conformance, well-designed standards may, when adopted, provide a clearer path of opportunity for organizations to improve their operational culture and outcomes, particularly since standards are usually developed with a broader consensus of interested individuals with expertise in a given field.<ref name="CiocoiuTheRole10" /> In turn, the organizations that adopt well-designed standards likely have a better chance of conforming to the regulations they must, and they'll likely have more interest in maintaining and improving the goalposts of quality and security in the lab.


Finally, having a cybersecurity plan that incorporates one or more cybersecurity frameworks gives the laboratory ample opportunity to apply stated goals and chosen security controls to the evaluation and selection process. In particular, a user requirements specification (URS) that incorporates cybersecurity considerations will certainly help a laboratory with meeting regulatory requirements while also protecting its data systems. A USR that is pre-built with cybersecurity controls in mind—such as [[Book:LIMSpec 2019 R1|LIMSpec]], discussed later—makes the evaluation process even easier.
Additionally, reputable software developers of laboratory informatics software will not only adopt their own industry standards for software development but also understand the standards and regulations that affect laboratories and research centers. In turn, the developed software should meet regulations and standards, help the laboratory comply with its regulations and standards, and be of reliably good quality.
 
If you're a potential buyer of a laboratory informatics solution, it may be that you know a bit about your laboratory's workflow and a few of the regulations and standards that influence how that workflow is conducted, but you're not entirely informed about all the regulations and standards that affect your lab. Turning to a URS such as LIMSpec—which was developed around laboratory regulations and standards—and reviewing the various statements contained within may be necessary to help further inform you. Additionally, as you investigate various informatics options, you can then use the requirements in the URS as a base for your laboratory's own requirements list. Using the categories and their subdivisions, you can then add those requirements that are unique to your laboratory and industry that are not sufficiently covered by the base URS. As you review the various options available to you and narrow down your search, your own list of requirements can be used as both as a personal checklist and as a requirements list you hand over to the vendor you query. And since your URS is based off the standards and regulations affecting your lab, you can feel more confident in your acquisition and its integration into your laboratory workflow.


==References==
==References==
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{{Reflist}}

Revision as of 23:48, 21 January 2022

Without a doubt, it's vital that medical diagnostic and research laboratories operate within the bounds of a regulatory atmosphere, not only to better ensure the best patient outcomes but also to ensure the quality of test results, the privacy of patient information, and the safety of personnel. Maintaining regulatory compliance requires deliberate approaches to developing and enforcing processes and procedures, quality training, consistent communication, and knowledgeable personnel. It also requires a top-down appreciation and commitment to a culture of quality. From the Clinical Laboratory Improvement Amendments (CLIA) and Health Insurance Portability and Accountability Act (HIPAA) to 21 CFR Part 11 and the General Data Protection Regulation, laboratories have much to consider in regards to what regulations impact them.

That said, consider approaching the question of regulatory compliance from the standpoint of adopting standards. Consider first that the risks and consequences of performing a task poorly drives regulation and, more preferably[1][2], standardization, which in turn moves the "goalposts" of quality and security among organizations. In the case of regulations, those organization that get caught not conforming to the necessary regulations tend to suffer negative consequences, providing some incentive for them to improve organizational processes and procedures.

One of the downsides of regulations is that they can at times be "imprecise" or "disconnected"[2] from what actually occurs within the organization and its information systems. Rather than focusing heavily on regulatory conformance, well-designed standards may, when adopted, provide a clearer path of opportunity for organizations to improve their operational culture and outcomes, particularly since standards are usually developed with a broader consensus of interested individuals with expertise in a given field.[1] In turn, the organizations that adopt well-designed standards likely have a better chance of conforming to the regulations they must, and they'll likely have more interest in maintaining and improving the goalposts of quality and security in the lab.

Additionally, reputable software developers of laboratory informatics software will not only adopt their own industry standards for software development but also understand the standards and regulations that affect laboratories and research centers. In turn, the developed software should meet regulations and standards, help the laboratory comply with its regulations and standards, and be of reliably good quality.

If you're a potential buyer of a laboratory informatics solution, it may be that you know a bit about your laboratory's workflow and a few of the regulations and standards that influence how that workflow is conducted, but you're not entirely informed about all the regulations and standards that affect your lab. Turning to a URS such as LIMSpec—which was developed around laboratory regulations and standards—and reviewing the various statements contained within may be necessary to help further inform you. Additionally, as you investigate various informatics options, you can then use the requirements in the URS as a base for your laboratory's own requirements list. Using the categories and their subdivisions, you can then add those requirements that are unique to your laboratory and industry that are not sufficiently covered by the base URS. As you review the various options available to you and narrow down your search, your own list of requirements can be used as both as a personal checklist and as a requirements list you hand over to the vendor you query. And since your URS is based off the standards and regulations affecting your lab, you can feel more confident in your acquisition and its integration into your laboratory workflow.

References

  1. 1.0 1.1 Ciocoui, C.N.; Dobrea, R.C. (2010). "Chapter 1. The Role of Standardization in Improving the Effectiveness of Integrated Risk Management". In Nota, G.. Advances in Risk Management. IntechOpen. doi:10.5772/9893. ISBN 9789535159469. 
  2. 2.0 2.1 "Data Standardization: A Call to Action" (PDF). JPMorgan Chase & Co. May 2018. https://www.jpmorganchase.com/content/dam/jpmc/jpmorgan-chase-and-co/documents/call-to-action.pdf. Retrieved 18 November 2021. 
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