Keywords
clinical decision support systems - colorectal surgery - electronic health records
- patient safety
Objectives: On completion of this article, the reader should be able to define and provide examples
of clinical decision support for colon and rectal surgery.
Following the two seminal and influential Institute of Medicine reports, “To Err Is
Human”[1] and “Crossing the Quality Chasm,”[2] clinicians and healthcare organizations have been implementing electronic health
records (EHRs) in an attempt to achieve the sought-after transformational breakthroughs
to improve quality and service while simultaneously reducing costs. Further, early
studies of computerized provider order entry (CPOE) with embedded clinical decision
support (CDS) suggest that such systems could significantly reduce the rate of medication
errors by as much as 81%.[3]
[4]
[5]
[6]
[7]
[8]
[9] However, these transformations have been much harder to achieve than anyone expected.[10]
[11] More recently the American Recovery and Reinvestment Act (ARRA) stimulus with its
Health Information Technology for Economic and Clinical Health (HITECH) Act has significantly
increased the pressure on healthcare providers to implement state of the art EHRs
with at least a minimal amount of CDS with the Meaningful Use Regulation, led by the
Centers for Medicare and Medicaid Services and the Department of Health and Human
Services.[12]
[13]
Historically, the majority of CDS for patient care has been developed for internal
medicine. The literature on CDS therefore is primarily focused on applications, interventions,
and outcomes outside of the surgical subspecialty domain. Colon and rectal surgery
(CRS) practice, however, has unique needs for health information technology (HIT)
and CDS that may differ from what is traditionally described.[14] Although many of the clinical examples described in the literature are not directly
applicable to CRS, we nevertheless believe that CDS can be beneficial in CRS settings.
In this article, we define CDS, describe the evidence for CDS, outline the implementation
process for CDS, and present some potential applications of CDS in CRS.
Definition of Clinical Decision Support
Definition of Clinical Decision Support
Several definitions of CDS have been described in various manuscripts, textbooks,
and regulations.[15] One broad definition for CDS is “a process for enhancing health-related decisions
and actions with pertinent, organized clinical knowledge and patient information to
improve health and healthcare delivery.”[16] That said, CDS is often best defined by examples. Some of the most familiar examples
of CDS are drug-drug interaction alerts, computerized dosing reminders, and guideline-based
order sets. These are tools, generally embedded in an EHR, to help clinicians make
decisions or remind them of data or facts they may have forgotten or overlooked.
Several approaches for providing and classifying CDS exist. In particular, one recent
report describes a taxonomy for CDS, providing definitions and examples of each CDS
type.[17] The major categories within the taxonomy include medication dosing support, order
facilitators, point of care alerts or reminders, relevant information display, expert
systems, and workflow support. We describe these categories in detail with several
examples relevant to CRS below.
Evidence for Clinical Decision Support
Evidence for Clinical Decision Support
Extensive literature has described the effect of several different types of CDS on
patient, process, and cost outcomes.[18]
[19]
[20]
[21]
[22] Most studies report benefits of CDS implementations on process outcomes; examples
of these include appropriate ordering of medications, preventive therapies, and laboratory
test result monitoring.[20]
[23] A recent systematic review determined that the random-effects combined odds ratios
for studies reporting adherence to recommendations for preventive services, ordering
clinical studies, and prescribing appropriate treatments was 1.42, 1.72, and 1.575,
respectively, confirming a positive effect of CDS on process outcomes.[23]
In addition to improved process outcomes, CDS has also resulted in significant cost
savings.[23] One study reported a net savings of $16.7 million and net operating budget savings
of $9.5 million over 10 years, citing renal dosing guidance, nursing time utilization,
specific drug guidance, and adverse drug event prevention as items resulting in the
greatest cumulative savings.[22] However, initial costs of implementing HIT to deliver CDS are extremely high, often
limiting implementations in smaller or less well-funded organizations from realizing
these savings.[24] With the release of the Meaningful Use Regulation, which includes incentive payments
for those attesting prior to 2015,and penalties beginning afterward for those who
have not attested, in the coming several years, implementation of CDS will continue
to increase.[12]
Despite these findings and the initial promise of CDS success at improving patient
outcomes, only a few centers have rigorously demonstrated significant, positive findings
with CDS.[18]
[23] Further, many of these studies focused on custom-built CDS implemented within locally
developed health information technology systems in large, academic medical centers,
and further research is necessary to better quantify the benefits of CDS across all
healthcare settings and to demonstrate the scalability of CDS for subspecialty settings.[25]
The Clinical Decision Support Implementation Process
The Clinical Decision Support Implementation Process
Creating a CDS program for any organization or practice is a difficult undertaking.
It is important to build a shared vision among all stakeholders within the organization
or practice, including how the CDS interventions will enhance clinical, operational,
and financial performance.[26] The vision should be informed by both internal and external factors. Currently,
external regulatory pressures such as Meaningful Use, combined with internal pressures
to develop and/or participate in an Accountable Care Organization (ACO),[27] are driving these decisions in many healthcare organizations. Once the goals of
a particular CDS program have been identified, the organization can begin to identify
specific clinical objectives to address.The organization should attempt to broadly
integrate these new CDS-focused objectives into existing clinical governance, planning,
and operational committees.[28]
The next major hurdle is identifying the key personnel who will be responsible for
the actual development and implementation of the CDS interventions. Key roles to be
filled include clinical champions responsible for encouraging and teaching other clinicians
regarding reasons for and use of the CDS interventions; technical resources responsible
for implementing the CDS logic within the EHR; and administrative supporters who must
ensure that there will be adequate funding for new parts of the technical architecture,
have access to external consultants and vendor personnel that may be required to help
implement the CDS, and test the new interventions.[29] The organization must also investigate what is feasible, given the technical limitations
of their particular EHR and other HIT systems coupled with the availability, accuracy,
and timeliness of the data required to drive the CDS.[30]
The organization should also consider how they will measure and monitor the effect
of each CDS intervention because a critical component of any CDS intervention implementation
is proper testing.[31] These tests must be done at many different levels. For example, a technical person
needs to ensure that the intervention performs as expected (e.g., storage of specific
data values leads to the appropriate alert appearing in a pop-up window, or entry
of a specific problem onto the patient's problem list creates a link to an appropriate
order set). Similarly, each intervention must be tested by clinicians to ensure that
it makes sense within their normal clinical workflow. Finally, following go-live,
the intervention needs to be monitored closely to ensure that it is working as expected
(e.g., the alert is firing when expected, but not more often than necessary, or the
order set is appearing for patients with the appropriate conditions and the correct
default items within the order set are selected).The organization should make sure
that there is a mechanism to allow clinicians to provide feedback to the HIT staff
regarding any potential issues with the CDS.[32] These complaints should be quickly investigated and fixed if necessary. Finally,
the organization should carefully monitor the intervention to ascertain whether it
has positively affected the originally defined clinical objective.[33] Often, the intervention will need to be optimized in some manner to get the desired
outcome.[34]
[35] [Fig. 1] provides a diagram that illustrates the iterative nature of the CDS implementation
process. It is important to note that it is not uncommon for CDS interventions to
have to be modified in some way following implementation to get the desired effect.
Fig. 1 An overview of the clinical decision support design, development, implementation,
and evaluation lifecycle. Adapted from Osheroff et al.
[16]
Applications of Clinical Decision Support for Colon and Rectal Surgery
Applications of Clinical Decision Support for Colon and Rectal Surgery
[Table 1]
[36]
[37]
[38]
[39]
[40]
[41]
[42]
[43]
[44]
[45]
[46] depicts the previously described CDS taxonomy[17] and provides several examples of CDS relevant to CRS, with references when applicable.
Medication dosing support is the first category of CDS and includes medication dose
adjustment, formulary checking, dose checking, default doses, and indication-based
ordering. This category of CDS has been demonstrated to be highly effective in both
improving patient safety and reducing associated costs.[22]
[47] Although few examples specific to CRS have been described in the literature, several
examples exist that may be relevant, including dosing advisors for antibiotics based
on renal function.[47]
Table 1
Types of clinical decision support and examples relevant to colon and rectal surgery
|
Type
|
Example
|
|
Medication dosing support
|
|
Medication dose adjustment
|
Dosing advisor for antibiotics based on renal function.[47]
|
|
Formulary checking
|
Suggest nifedipine ointment as a more cost-effective alternative to diltiazem ointment
in the treatment of anal fissure.[36]
|
|
Single-dose range checking
|
Alert on a single dose of acetaminophen 2 g for postoperative analgesia.
|
|
Maximum daily dose checking
|
Alert on a total daily dose of acetaminophen 7 g for postoperative analgesia.
|
|
Maximum lifetime dose checking
|
Alert if the total cumulative amount of radiation therapy exceeds the recommended
maximum amount in the setting of neoadjuvant chemoradiotherapy for rectal cancer.[37]
|
|
Default doses/pick lists
|
Provide a list of 100 mg, 200 mg, 300 mg, 400 mg, 600 mg, and 800 mg doses for ibuprofen
with a default of 400 mg for postoperative analgesia in adults following an anorectal
procedure.
|
|
Indication-based dosing
|
Order 2% diltiazem ointment topically for anal fissure, but 60 mg three times daily
by mouth for hypertension.
|
|
Order facilitators
|
|
Medication order sentences
|
Allow the provider to order “Heparin 5000 Units Subcutaneously t.i.d.” as a single
unit for perioperative thromboembolic disease prophylactic prevention.
|
|
Subsequent or corollary orders
|
Order hemoglobin test when mesalamine is ordered.
|
|
Indication-based ordering
|
Suggest perioperative intravenous antibiotics at the time of starting an abdominal
surgery.[38]
[39]
|
|
Service-specific order sets
|
Colorectal surgery inpatient admission order set[49]
|
|
Condition-specific order sets
|
Abdominal pain order set
|
|
Procedure-specific order sets
|
Postoperative colectomy order set[48]
|
|
Condition-specific treatment protocol
|
Inflammatory bowel disease treatment protocol
|
|
Transfer order set
|
Transfer to surgery step-down unit order set
|
|
Nonmedication order sentences
|
Allow the provider to order “Call HO for temperature > 101, SBP > 180, DBP < 90, HR > 120,
HR < 50, RR > 30, RR < 10, O2 saturation < 92%” as a single unit.
|
|
Point of care alerts/reminders
|
|
Drug/condition interaction checking
|
Alert when a provider orders metronidazole in the setting of Clostridium difficile colitis for a female patient of childbearing age.
|
|
Drug/drug interaction checking
|
Alert about the possibility of thrombosis when a provider orders omeprazole in a patient
receiving clopidogrel.[40]
|
|
Drug/allergy interaction checking
|
Alert when a provider orders cefotetan for perioperative antibiotics in a patient
with a documented penicillin allergy.
|
|
Plan of care alerts
|
Reminders to reassess the need for restraints and reorder if necessary at least every
24 h.
|
|
Critical laboratory value checking
|
Notify providers about positive FOBT results.[54]
|
|
Duplicate order checking
|
Alert when a provider orders metoprolol in a surgical patient with active order for
atenolol or when it is already on the medication list.
|
|
Care reminders
|
Remind providers to order a yearly FOBT for patients between 45 and 85.[52]
[53]
|
|
Look-alike/sound-alike medication warnings
|
Warn providers ordering prednisone or prednisolone to ensure that they have chosen
the drug they intended.
|
|
Ticklers
|
Alert a provider when colonoscopy has been ordered but not scheduled or performed
within three months.
|
|
Problem list management
|
When ordering mesalamine, ask the provider if he/she would like to add inflammatory
bowel disease to the problem list if not already documented.[41]
|
|
Radiology ordering support
|
Order a CT scan of the abdomen and pelvis (rather than only the abdomen) in a patient
with abdominal pain to ensure full visualization of the peritoneal cavity.
|
|
IV/PO conversion
|
Convert patient from IV metronidazole to PO metronidazole when patient is no longer
NPO.
|
|
High-risk state monitoring
|
Alert the provider to order contact precautions for patients with known methicillin-resistant
Staphylococcus aureus colonization.
|
|
Polypharmacy alerts
|
Alert the provider that a patient is on >8 medications and suggest pharmacy consult.[42]
|
|
Relevant information display
|
|
Context-sensitive information retrieval
|
Allow the provider to link directly to prescribing information for a medication at
the time of ordering.[19]
|
|
Patient-specific relevant data displays
|
Display recent creatinine levels when ordering Fleets Phospho-Soda with a bowel preparation.
|
|
Medication/test cost display
|
Indicate that a CBC costs $66 at the time of ordering.
|
|
Tallman lettering
|
Show prednisone and prednisolone as predniSONE and prednisoLONE in a pick list.[43]
|
|
Context-sensitive user interface
|
Provide a special interface for chemotherapy order entry, which might include relevant
data display, special facilities for ordering complex or time-based protocols and
reference information.
|
|
Expert systems
|
|
Antibiotic ordering support
|
Suggest metronidazole for empiric antibiotic therapy for patients with suspected Clostridium difficile.
|
|
Ventilator support
|
Unless the FiO2 is already at 1.0, suggest increasing the FiO2 by 0.1 if the PaO2 is > 50 but < 60 mmHg in patients with acute respiratory distress syndrome.[44]
|
|
Diagnostic support
|
Provide a tool to help providers distinguish between types of inflammatory bowel disease
and related conditions.
|
|
Risk assessment tools
|
Estimate 10-year diverticulitis recurrence risk for a patient with complicated diverticulitis.[55]
|
|
Prognostic tools
|
Estimate survival for colorectal cancer patients based on pathologic tumor grade and
stage.[45]
|
|
Transfusion support
|
Suggest fresh frozen plasma for patients with a high INR and taking warfarin.
|
|
Nutrition ordering tools
|
Suggest increased protein in TPN for patients with active infection.
|
|
Laboratory test interpretation
|
Based on microbiology sensitivity testing, report that a patient with an intraabdominal
abscess has vancomycin-resistant enterococcus and needs to be placed on contact precautions.
|
|
Treatment planning
|
A computerized system to facilitate management of surgical sepsis.[56]
|
|
Triage tools
|
Computer-based recommendations for patients with acute abdominal pain.[46]
|
|
Syndromic surveillance
|
City-wide reporting and monitoring of emergency department chief complaints to detect
E. coli O157:H7 outbreaks.
|
|
Workflow support
|
|
Order routing
|
Route order for stoma marking to wound ostomy continence nursing.
|
|
Registry functions
|
Send a letter to eligible patients to recommend FOBT.[57]
[58]
[59]
|
|
Medication reconciliation
|
Upon postprocedure admission, automatically generate a preadmission medication list
based on outpatient medication orders and pharmacy dispensing data.
|
|
Automatic order termination
|
Automatically terminate antibiotic orders after the conclusion of the order duration.
|
|
Order approvals
|
Send all colonoscopy orders to CRS for approval.
|
|
Free-text order parsing
|
Allow the user to enter the text “amox 500 mg QID 10d” and translate that to a complete,
structured amoxicillin order that can be automatically processed by the pharmacy system.
|
|
Documentation aids
|
Structured documentation template for a CRS visit that has common findings.
|
Abbreviations: t.i.d., three times daily; HO, house officer; SBP, systolic blood pressure;
DBP, diastolic blood pressure; HR, heart rate; RR, respiratory rate; FOBT, fecal occult
blood test; CT, computed tomography; IV, intravenous; PO, by mouth; NPO, nothing by
mouth; CBC, complete blood count; INR, international normalized ratio; TPN, total
parenteral nutrition; CRS, colon and rectal surgery; QID, four times daily.
Order facilitators are the next category of CDS, including order sentences, subsequent
or corollary orders, indication-based ordering, and order sets. For busy surgeons,
order facilitators can reduce the amount of time spent entering orders and leave more
time for providing patient care. Order sets, collections of orders that are grouped
by a specific clinical purpose, are frequently used by hospitals to ensure adherence
to guidelines or protocols.[48] In surgical settings, order set examples include those for admission to the CRS
service or for postoperative care of patients.[48]
[49]
Point-of-care alerts and reminders comprise the third category of CDS, representing
one of the CDS types most frequently evaluated in the literature. This type of CDS
prompts clinicians about drug-condition, drug-drug, and drug-allergy interactions;
reminds clinicians to assess specific care items; and notifies clinicians about critical
laboratory values or high-risk states. These reminders can be passive alerts that
display additional text, change existing text colors, or show images, without interrupting
the workflow, and can also be interruptive alerts, which require that providers acknowledge
or respond to the alert before resuming order entry.[50]
[51] For colon and rectal diseases, alerts often prompt primary care providers to order
or remind patients about cancer-screening tests or to follow up with patients after
abnormal screening test results.[52]
[53]
[54] Alerts can also be beneficial directly to CRS practice, given the protocoled nature
of many CRS conditions and the high number of potential interactions with antibiotics
and other medications frequently ordered.
The fourth type of CDS is relevant information display. This type ensures that clinicians
have up-to-date and necessary patient data to make decisions in providing care to
the patients, such as showing recent laboratory test values during medication ordering.
Specific examples for CRS have not been extensively described in the literature, although
knowledge about laboratory trends or cost of care is an important consideration for
clinicians across all care settings.
Expert systems are the fifth type of CDS, and these apply advanced logic or computational
methods to assist clinicians in ordering, diagnosing, treating, and interpreting elements
within the EHR. One example specific to CRS includes a study that applied statistical
methods to predict outcomes for patients with diverticulitis.[55] Another study evaluated a treatment planning system that suggests volume resuscitation
and medication therapy, such as use of antibiotics and vasopressors, for surgical
patients identified as having sepsis, and found that use of the CDS improved mortality
in the observed patients.[56]
The final type of CDS is workflow support, including order routing, registry functions,
medication reconciliation, automatic order termination, order approvals, free-text
order parsing, and documentation aids. Registry functions are especially important
for CRS, where appropriate patient follow-up is imperative for providing optimal care.
For example, several studies have described reminders sent to patients, through mailed
letters or telephone calls, to remind patients about completion of fecal occult blood
tests.[57]
[58]
[59]
Challenges for Clinical Decision Support
Challenges for Clinical Decision Support
Despite the reported benefits CDS can provide, several barriers and challenges exist
that frequently prevent patient safety and other healthcare improvements. One challenge
is that CDS is often not implemented in a manner that allows it to be as effective
as possible in practice. First, CDS must be presented in a manner that fits into the
optimal workflow for clinicians and is intuitive for clinicians to view and respond.[60]
[61] [Fig. 2] depicts the basic workflow for clinical encounters, indicating core actions that
are associated with each step in the workflow and CDS interventions that are appropriate
for each core action.[16]
Fig. 2 Flowchart of clinical workflow with core actions and typical clinical decision support
opportunities. Adapted from Osheroff et al.
[16]
CDS must also be specific and relevant to both the clinician and patient receiving
the CDS. For example, an alert about a medication contraindicated in pregnancy should
be suppressed for a patient who is postmenopausal or has had a hysterectomy. However,
it can be difficult to implement highly specific CDS systems, as these require that
relevant patient information be computable in acoded instead of free-text format.
When coded or structured data are not available, some computation methods may be applied
to transform the free-text information into coded data, using techniques such as natural
language processing.[62] These methods have been applied to process surgical and pathology reports, which
could improve CDS delivered to CRS clinicians.[63]
[64]
[65]
Further problems arise with ineffective CDS solutions, such as alert fatigue, which
occurs when clinicians receive too many CDS alerts and subsequently ignore many alerts
that are displayed by the system.[66] Studies have found that 49–96% of alerts displayed to clinicians are overridden,
most often due to frequent alerts that are irrelevant or not serious.[67] To prevent alert fatigue, it is necessary that institutions effectively evaluate
and refine the implementation of any CDS tool both prior to and following implementation.[68] Computer-based pharmacy surveillance of patients with high-risk conditions or of
alerts with high rates of overrides may also prevent errors when the CDS is insufficient.[69]
[70]
Another challenge to implementing effective CDS is the difficulty in managing and
sharing CDS knowledge.[71]
[72] Currently, most CDS systems are implemented locally, and replicating these systems
at other institutions requires considerable effort by HIT staff and may be prone to
errors. The development of methods for sharing CDS across institutions and EHRs could
increase CDS adoption. One approach to sharing CDS utilizes a service-oriented architecture,
where CDS interventions are hosted remotely and institutions can subscribe to receive
CDS without having to develop and maintain the services locally.[73] Another approach might involve CDS repositories, where an organization makes rules
available, and the rules are downloaded locally, where they can be maintained, modified,
and integrated into existing EHRs.[71]
Conclusion
CDS can be an effective method to improve clinical processes and patient safety. Given
the episodic nature of CRS care, CDS such as order sets, documentation templates,
and any variety of order facilitation aids is most likely to be beneficial in CRS,
whereas other types of CDS (such as registry management tools) or reminders may be
more useful for primary care providers. However, colon and rectal surgeons can still
play an important role in developing CRS-related CDS for other providers by, for example,
participating in the development of screening reminder systems that help primary care
providers select appropriate screening tests and intervals. Even though the tools
would primarily be used by primary care providers, colon and rectal surgeons have
special expertise that could contribute to the process of development. Further research
is necessary to identify and better evaluate additional CDS systems in the setting
of CRS.
