Clinical decision support system

A clinical decision support system (CDSS) is a health information technology system that is designed to provide physicians and other health professionals with clinical decision support (CDS), that is, assistance with clinical decision-making tasks. A working definition has been proposed by Robert Hayward of the Centre for Health Evidence: "Clinical Decision Support systems link health observations with health knowledge to influence health choices by clinicians for improved health care". CDSSs constitute a major topic in artificial intelligence in medicine.

Effectiveness

The evidence of the effectiveness of CDSS is mixed. A 2014 systematic review did not find a benefit in terms of risk of death when the CDSS was combined with the electronic health record.[1] There may be some benefits, however, in terms of other outcomes.[1]

A 2005 systematic review concluded that CDSSs improved practitioner performance in 64% of the studies. The CDSSs improved patient outcomes in 13% of the studies. Sustainable CDSSs features associated with improved practitioner performance include the following:

Both the number and the methodological quality of studies of CDSSs increased from 1973 through 2004.[2]

Another 2005 systematic review found... "Decision support systems significantly improved clinical practice in 68% of trials." The CDSS features associated with success include the following:[3]

However, other systematic reviews are less optimistic about the effects of CDS, with one from 2011 stating "There is a large gap between the postulated and empirically demonstrated benefits of [CDSS and other] eHealth technologies ... their cost-effectiveness has yet to be demonstrated".[4]

A 5-year evaluation of the effectiveness of a CDSS in implementing rational treatment of bacterial infections was published in 2014; according to the authors, it was the first long term study of a CDSS.[5]

Characteristics

A clinical decision support system has been defined as an "active knowledge systems, which use two or more items of patient data to generate case-specific advice."[6] This implies that a CDSS is simply a decision support system that is focused on using knowledge management in such a way so as to achieve clinical advice for patient care based on multiple items of patient data.

Purpose

The main purpose of modern CDSS is to assist clinicians at the point of care.[7] This means that clinicians interact with a CDSS to help to analyse, and reach a diagnosis based on, patient data.

In the early days, CDSSs were conceived of as being used to literally make decisions for the clinician. The clinician would input the information and wait for the CDSS to output the "right" choice and the clinician would simply act on that output. However, the modern methodology of using CDSSs to assist means that the clinician interacts with the CDSS, utilizing both their own knowledge and the CDSS, to make a better analysis of the patient's data than either human or CDSS could make on their own. Typically, a CDSS makes suggestions for the clinician to look through, and the clinician is expected to pick out useful information from the presented results and discount erroneous CDSS suggestions.[6]

There are two main types of CDSS:[7]

as detailed below.

An example of how a CDSS might be used by a clinician is a specific type of Clinical Decision Support System, a DDSS (Diagnosis Decision Support Systems). A DDSS requests some of the patients data and in response, proposes a set of appropriate diagnoses. The doctor then takes the output of the DDSS and determines which diagnoses might be relevant and which are not,[7] and if necessary orders further tests to narrow down the diagnosis.

Another important classification of a CDSS is based on the timing of its use. Doctors use these systems at point of care to help them as they are dealing with a patient, with the timing of use being either pre-diagnosis, during diagnosis, or post diagnosis. Pre-diagnosis CDSS systems are used to help the physician prepare the diagnoses. CDSS used during diagnosis help review and filter the physician's preliminary diagnostic choices to improve their final results. Post-diagnosis CDSS systems are used to mine data to derive connections between patients and their past medical history and clinical research to predict future events.[7] It has been claimed that decision support will begin to replace clinicians in common tasks in the future.[8]

Another approach, used by the National Health Service in England, is to use a DDSS (either, in the past, operated by the patient, or, today, by a phone operative who is not medically-trained) to triage medical conditions out of hours by suggesting a suitable next step to the patient (e.g. call an ambulance, or see a general practitioner on the next working day). The suggestion, which may be disregarded by either the patient or the phone operative if common sense or caution suggests otherwise, is based on the known information and an implicit conclusion about what the worst-case diagnosis is likely to be (which is not always revealed to the patient, because it might well be incorrect and is not based on a medically-trained person's opinion - it is only used for initial triage purposes).

Knowledge-based CDSS

Most CDSSs consist of three parts: the knowledge base, an inference engine, and a mechanism to communicate. The knowledge base contains the rules and associations of compiled data which most often take the form of IF-THEN rules. If this was a system for determining drug interactions, then a rule might be that IF drug X is taken AND drug Y is taken THEN alert user. Using another interface, an advanced user could edit the knowledge base to keep it up to date with new drugs. The inference engine combines the rules from the knowledge base with the patient's data. The communication mechanism allows the system to show the results to the user as well as have input into the system.[6][7]

Non-knowledge-based CDSS

CDSSs that do not use a knowledge base use a form of artificial intelligence called machine learning,[9] which allow computers to learn from past experiences and/or find patterns in clinical data. This eliminates the need for writing rules and for expert input. However, since systems based on machine learning cannot explain the reasons for their conclusions (they are so-called "black boxes", because no meaningful information about how they work can be discerned by human inspection), most clinicians do not use them directly for diagnoses, for reliability and accountability reasons.[6][7] Nevertheless, they can be useful as post-diagnostic systems, for suggesting patterns for clinicians to look into in more depth.

Three types of non-knowledge-based systems are support vector machines, artificial neural networks and genetic algorithms.[10]

  1. Artificial neural networks use nodes and weighted connections between them to analyse the patterns found in patient data to derive associations between symptoms and a diagnosis.
  2. Genetic algorithms are based on simplified evolutionary processes using directed selection to achieve optimal CDSS results. The selection algorithms evaluate components of random sets of solutions to a problem. The solutions that come out on top are then recombined and mutated and run through the process again. This happens over and over until the proper solution is discovered. They are functionally similar to neural networks in that they are also "black boxes" that attempt to derive knowledge from patient data.
  3. Non-knowledge-based networks often focus on a narrow list of symptoms, such as symptoms for a single disease, as opposed to the knowledge based approach which cover the diagnosis of many different diseases.[6][7]

Regulations

United States

With the enactment of the American Recovery and Reinvestment Act of 2009 (ARRA), there is a push for widespread adoption of health information technology through the Health Information Technology for Economic and Clinical Health Act (HITECH). Through these initiatives, more hospitals and clinics are integrating Electronic Medical Records (EMRs) and Computerized physician order entry (CPOE) within their health information processing and storage. Consequently, the Institute of Medicine (IOM) promoted usage of health information technology including Clinical Decision Support Systems to advance quality of patient care. The IOM had published a report in 1999, To Err Is Human, which focused on the patient safety crisis in the United States, pointing to the incredibly high number of deaths. This statistic attracted great attention to the quality of patient care.

With the enactment of the HITECH Act included in the ARRA, encouraging the adoption of health IT, more detailed case laws for CDSS and EMRs are still being defined by the Office of National Coordinator for Health Information Technology (ONC) and approved by Department of Health and Human Services (HHS). A definition of "Meaningful use" is yet to be polished.

Despite the absence of laws, the CDSS vendors would almost certainly be viewed as having a legal duty of care to both the patients who may adversely be affected due to CDSS usage and the clinicians who may use the technology for patient care. However, duties of care legal regulations are not explicitly defined yet.

With recent effective legislations related to performance shift payment incentives, CDSS are becoming more attractive.

Challenges to adoption

Clinical challenges

Much effort has been put forth by many medical institutions and software companies to produce viable CDSSs to support all aspects of clinical tasks. However, with the complexity of clinical workflows and the demands on staff time high, care must be taken by the institution deploying the support system to ensure that the system becomes a fluid and integral part of the clinical workflow. Some CDSSs have met with varying amounts of success, while others have suffered from common problems preventing or reducing successful adoption and acceptance.

Two sectors of the healthcare domain in which CDSSs have had a large impact are the pharmacy and billing sectors. There are commonly used pharmacy and prescription ordering systems that now perform batch-based checking of orders for negative drug interactions and report warnings to the ordering professional. Another sector of success for CDSS is in billing and claims filing. Since many hospitals rely on Medicare reimbursements to stay in operation, systems have been created to help examine both a proposed treatment plan and the current rules of Medicare in order to suggest a plan that attempts to address both the care of the patient and the financial needs of the institution.

Other CDSSs that are aimed at diagnostic tasks have found success, but are often very limited in deployment and scope. The Leeds Abdominal Pain System went operational in 1971 for the University of Leeds hospital, and was reported to have produced a correct diagnosis in 91.8% of cases, compared to the clinicians' success rate of 79.6%.

Despite the wide range of efforts by institutions to produce and use these systems, widespread adoption and acceptance has still not yet been achieved for most offerings. One large roadblock to acceptance has historically been workflow integration. A tendency to focus only on the functional decision making core of the CDSS existed, causing a deficiency in planning for how the clinician will actually use the product in situ. Often CDSSs were stand-alone applications, requiring the clinician to cease working on their current system, switch to the CDSS, input the necessary data (even if it had already been inputted into another system), and examine the results produced. The additional steps break the flow from the clinician's perspective and cost precious time.

Technical challenges and barriers to implementation

Clinical decision support systems face steep technical challenges in a number of areas. Biological systems are profoundly complicated, and a clinical decision may utilize an enormous range of potentially relevant data. For example, an electronic evidence-based medicine system may potentially consider a patient's symptoms, medical history, family history and genetics, as well as historical and geographical trends of disease occurrence, and published clinical data on medicinal effectiveness when recommending a patient's course of treatment.

Clinically, a large deterrent to CDSS acceptance is workflow integration, as mentioned above.

Another source of contention with many medical support systems is that they produce a massive number of alerts. When systems produce high volume of warnings (especially those that do not require escalation), aside from the annoyance, clinicians may pay less attention to warnings, causing potentially critical alerts to be missed.

Maintenance

One of the core challenges facing CDSS is difficulty in incorporating the extensive quantity of clinical research being published on an ongoing basis. In a given year, tens of thousands of clinical trials are published.[11] Currently, each one of these studies must be manually read, evaluated for scientific legitimacy, and incorporated into the CDSS in an accurate way. In 2004, it was stated that the process of gathering clinical data and medical knowledge and putting them into a form that computers can manipulate to assist in clinical decision-support is "still in its infancy".[12]

Nevertheless, it is more feasible for a business to do this centrally, even if incompletely, than for each individual doctor to try to keep up with all the research being published.

In addition to being laborious, integration of new data can sometimes be difficult to quantify or incorporate into the existing decision support schema, particularly in instances where different clinical papers may appear conflicting. Properly resolving these sorts of discrepancies is often the subject of clinical papers itself (see meta-analysis), which often take months to complete.

Evaluation

In order for a CDSS to offer value, it must demonstrably improve clinical workflow or outcome. Evaluation of CDSS is the process of quantifying its value to improve a system's quality and measure its effectiveness. Because different CDSSs serve different purposes, there is no generic metric which applies to all such systems; however, attributes such as consistency (with itself, and with experts) often apply across a wide spectrum of systems.[13]

The evaluation benchmark for a CDSS depends on the system's goal: for example, a diagnostic decision support system may be rated based upon the consistency and accuracy of its classification of disease (as compared to physicians or other decision support systems). An evidence-based medicine system might be rated based upon a high incidence of patient improvement, or higher financial reimbursement for care providers.

Combining with electronic health records

Implementing electronic health records (EHR) was an inevitable challenge. The reasons behind this challenge are that it is a relatively uncharted area, and there are many issues and complications during the implementation phase of an EHR. This can be seen in the numerous studies that have been undertaken. However, challenges in implementing electronic health records (EHRs) have received some attention, but less is known about the process of transitioning from legacy EHRs to newer systems.[14]

With all of that said, electronic health records are the way of the future for healthcare industry. They are a way to capture and utilise real-time data to provide high-quality patient care, ensuring efficiency and effective use of time and resources. Incorporating EHR and CDSS together into the process of medicine has the potential to change the way medicine has been taught and practiced.[15] It has been said that "the highest level of EHR is a CDSS".[16]

Since "clinical decision support systems (CDSS) are computer systems designed to impact clinician decision making about individual patients at the point in time that these decisions are made",[15] it is clear that it would be beneficial to have a fully integrated CDSS and EHR.

Even though the benefits can be seen, to fully implement a CDSS that is integrated with an EHR has historically required significant planning by the healthcare facility/organisation, in order for the purpose of the CDSS to be successful and effective. The success and effectiveness can be measured by the increase in patient care being delivered and reduced adverse events occurring. In addition to this, there would be a saving of time and resources, and benefits in terms of autonomy and financial benefits to the healthcare facility/organisation.[17]

Benefits of CDSS combined with EHR

A successful CDSS/EHR integration will allow the provision of best practice, high quality care to the patient, which is the ultimate goal of healthcare.

Errors have always occurred in healthcare, so trying to minimise them as much as possible is important in order to provide quality patient care. Three areas that can be addressed with the implementation of CDSS and Electronic Health Records (EHRs), are:

  1. Medication prescription errors
  2. Adverse drug events
  3. Other medical errors

CDSSs will be most beneficial in the future when healthcare facilities are "100% electronic" in terms of real-time patient information, thus simplifying the number of modifications that have to occur to ensure that all the systems are up to date with each other.

The measurable benefits of clinical decision support systems on physician performance and patient outcomes remain the subject of ongoing research, as noted in the § Effectiveness section above.

Barriers

Implementing electronic health records (EHR) in healthcare settings incurs challenges; none more important than maintaining efficiency and safety during rollout,[18] but in order for the implementation process to be effective, an understanding of the EHR users' perspectives is key to the success of EHR implementation projects.[19] In addition to this, adoption needs to be actively fostered through a bottom-up, clinical-needs-first approach.[20] The same can be said for CDSS.

The main areas of concern with moving into a fully integrated EHR/CDSS system are:

  1. Privacy
  2. Confidentiality
  3. User-friendliness
  4. Document accuracy and completeness
  5. Integration
  6. Uniformity
  7. Acceptance
  8. Alert desensitisation

[21] as well as the key aspects of data entry that need to be addressed when implementing a CDSS to avoid potential adverse events from occurring. These aspects include whether:

A service oriented architecture has been proposed as a technical means to address some of these barriers.[22]

Status in Australia

As of July 2015, the planned transition to EHRs in Australia is facing difficulties. The majority of healthcare facilities are still running completely paper-based systems, and some are in a transition phase of scanned EHRs, or are moving towards such a transition phase.

Victoria has attempted to implement EHR across the state with its HealthSMART program, but due to unexpectedly high costs it has cancelled the project.[23]

South Australia (SA) however is slightly more successful than Victoria in the implementation of an EHR. This may be due to all public healthcare organisations in SA being centrally run. (However, on the other hand, the UK's National Health Service is also centrally administered, and its National Programme for IT in the 2000s, which included EHRs in its remit, was an expensive disaster.)

SA is in the process of implementing "Enterprise patient administration system (EPAS)". This system is the foundation for all public hospitals and health care sites for an EHR within SA and it was expected that by the end of 2014 all facilities in SA will be connected to it. This would allow for successful integration of CDSS into SA and increase the benefits of the EHR.[24] By July 2015 it was reported that only 3 out of 75 health care facilities implemented EPAS.[25]

With the largest health system in the country and a federated rather than centrally administered model, New South Wales is making consistent progress towards statewide implementation of EHRs. The current iteration of the state's technology, eMR2, includes CDSS features such as a sepsis pathway for identifying at-risk patients based upon data input to the electronic record. As of June 2016, 93 of 194 sites in-scope for the initial roll-out had implemented eMR2[26]

See also

References

  1. 1 2 Moja, L; Kwag, KH; Lytras, T; Bertizzolo, L; Brandt, L; Pecoraro, V; Rigon, G; Vaona, A; Ruggiero, F; Mangia, M; Iorio, A; Kunnamo, I; Bonovas, S (December 2014). "Effectiveness of computerized decision support systems linked to electronic health records: a systematic review and meta-analysis.". American Journal of Public Health. 104 (12): e12–22. doi:10.2105/ajph.2014.302164. PMID 25322302.
  2. Garg AX, Adhikari NK, McDonald H, Rosas-Arellano MP, Devereaux PJ, Beyene J, et al. (2005). "Effects of computerized clinical decision support systems on practitioner performance and patient outcomes: a systematic review.". JAMA. 293 (10): 1223–38. doi:10.1001/jama.293.10.1223. PMID 15755945.
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  5. Nachtigall, I; Tafelski, S; Deja, M; Halle, E; Grebe, M C; Tamarkin, A; Rothbart, A; Unrig, A; Meyer, E; Musial-Bright, L; Wernecke, K D; Spies, C (22 December 2014). "Long-term effect of computer-assisted decision support for antibiotic treatment in critically ill patients: a prospective 'before/after' cohort study". BMJ Open. 4 (12): e005370. doi:10.1136/bmjopen-2014-005370.
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  14. Zandieh, Stephanie O.; Kahyun Yoon-Flannery; Gilad J. Kuperman; Daniel J. Langsam; Daniel Hyman; Rainu Kaushal (2008). "Challenges to EHR Implementation in Electronic- Versus Paper-based Office Practices". Journal of Global Information Management: 755–761.
  15. 1 2 Berner, Eta S.; Tonya J.La Lande (2007). "1". Clinical Decision Support Systems: Theory and Practice (2 ed.). New York: Springer Science and Business Media. pp. 3–22.
  16. Rothman, Brian; Joan. C. Leonard; Michael. M. Vigoda (2012). "Future of electronic health records: implications for decision support". Mount Sinai Journal of Medicine. 79 (6): 757–768. doi:10.1002/msj.21351.
  17. Sambasivan, Murali; Pouyan Esmaeilzadeh; Naresh Kumar; Hossein Nezakati (2012). "Intention to adopt clinical decision support systems in a developing country: effect of Physician's perceived professional autonomy, involvement and belief: a cross-sectional study". BMC Medical Informatics and Decision Making. 12: 142–150. doi:10.1186/1472-6947-12-142.
  18. Spellman Kennebeck, Stephanie; Nathan Timm; Michael K Farrell; S Andrew Spooner (2012). "Impact of electronic health record implementation on patient flow metrics in a pediatric emergency department". Journal of the American Medical Informatics Association. 19: 443–447. doi:10.1136/amiajnl-2011-000462.
  19. McGinn, Carrie A; Marie-Pierre Gagnon; Nicola Shaw; Claude Sicotte; Luc Mathieu; Yvan Leduc; Sonya Grenier; Julie Duplantie; Anis B Abdeljelil; France Légaré (2012). "Users' perspectives of key factors to implementing electronic health records in Canada: a Delphi study". BMC Medical Informatics & Decision Making. 12: 105–118. doi:10.1186/1472-6947-12-105.
  20. Rozenblum, Ronen; Yeona Jang; Eyal Zimlichman; Claudia Salzberg; Melissa Tamblyn; David Buckeridge; Alan Forster; David W. Bates and Robyn Tamblyn (2011). "A qualitative study of Canada's experience with the implementation of electronic health information technology". Canadian Medical Association Journal: 281–288.
  21. Berner, Eta S.; Tonya J.La Lande (2007). "4". Clinical Decision Support Systems: Theory and Practice (2 ed.). New York: Springer Science and Business Media. pp. 64–98.
  22. Loya, S. R.; Kawamoto, K; Chatwin, C; Huser, V (2014). "Service oriented architecture for clinical decision support: A systematic review and future directions". Journal of Medical Systems. 38 (12): 140. doi:10.1007/s10916-014-0140-z. PMID 25325996.
  23. Charette, Robert N. "Troubled HealthSMART System Finally Cancelled in Victoria Australia". Retrieved 18 May 2013.
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External links

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