Received 01/11/2019 
Review began 01/21/2019 
Review ended 01/31/2019 
Published 02/05/2019

© Copyright 2019
Zhang et al. This is an open access
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Finding the ‘QR’ to Patient Safety: Applying
Gamification to Incorporate Patient Safety
Priorities Through a Simulated ‘Escape
Room’ Experience
Xiao Chi Zhang  , Gretchen Diemer  , Hyunjoo Lee  , Rebecca Jaffe  , Dimitrios Papanagnou 

1. Emergency Medicine, Thomas Jefferson University, Philadelphia, USA 2. Medicine, Sidney Kimmel
Medical College at Thomas Jefferson University, Philadelphia, USA 3. Department of Emergency
Medicine, Stony Brook University Hospital, Stony Brook, USA 4. Hospital Medicine, Thomas Jefferson
University, Philadelphia, USA

 Corresponding author: Xiao Chi Zhang, xzhang09@gmail.com 
Disclosures can be found in Additional Information at the end of the article

Abstract
Medical errors are the eighth leading cause of mortality in the United States and contribute to
over one million preventable injuries. In an effort to prevent medical errors, reporting systems
serve as invaluable tools to detect patient safety events and quality problems longitudinally.
Historically, trainees (i.e., students and residents) rarely submit incident reports for
encountered patient safety threats. The authors propose an immersive learning experience
utilizing gamification theory and leveraging the increasingly popular ‘escape room’ to help
resident trainees identify reportable patient safety priorities.

All 130 incoming intern physicians at the Thomas Jefferson University (Jefferson) were enrolled
in the Patient Safety Escape Room study as part of their residency orientation (June 2018). The
residents were randomly divided into 16 teams. Each team was immersed in a simulated escape
room, tasked with identifying a predetermined set of serious patient safety hazards, and
successfully manually entering them into the Jefferson Event Reporting System within the time
allotted to successfully ‘win the game’ by ‘escaping the room’. Quick response (QR) codes were
planted throughout the activity to provide in-game instructions; clues to solve the puzzle; and
key information about patient safety priorities at Jefferson. All participants underwent a formal
debriefing using the feedback capture grid method and completed a voluntary post-study
survey, adapted from Brookfield’s Critical Incident Questionnaire (CIQ). The study was IRB
exempt.

Thematic analysis of the post-activity CIQ survey ( n = 102) revealed that interns were engaged
during the immersive learning experience (n = 42) and were specifically engaged by having to
independently identify patient safety threats (n = 30). Participants identified team role
assignment (n = 52) and effective communication (n = 26) as the two most helpful actions
needed to successfully complete the activity. Participants were overall surprised by the success
of the education innovation (n = 45) and reported that it changed how they viewed patient
safety threats. Areas for improvement include clearer game instructions and using a more
streamlined event reporting process.

The escape room patient-safety activity allowed interns to actively engage in an innovative
orientation activity that highlighted the importance of patient safety hazards, as well as
providing them with the opportunity to document event reports in real-time. Next steps will
include longitudinally tracking the quantity of error reports entered by this cohort to determine

1 2 3 4 1

 
Open Access Technical
Report  DOI: 10.7759/cureus.4014

How to cite this article
Zhang X, Diemer G, Lee H, et al. (February 05, 2019) Finding the ‘QR’ to Patient Safety: Applying
Gamification to Incorporate Patient Safety Priorities Through a Simulated ‘Escape Room’ Experience.
Cureus 11(2): e4014. DOI 10.7759/cureus.4014

https://www.cureus.com/users/58394-xiao-chi-zhang
https://www.cureus.com/users/56354-gretchen-diemer
https://www.cureus.com/users/56765-hyunjoo-lee
https://www.cureus.com/users/94551-rebecca-jaffe
https://www.cureus.com/users/40273-dimitrios-papanagnou-


the effectiveness of this educational intervention.

Categories: Medical Education, Medical Simulation
Keywords: medication error reporting, medical simulation, graduate medical education, gamification,
escape room, advedrse event reporting, innovation

Introduction
In the United States, medical errors are the eighth leading cause of mortality, with an estimated
44,000 to 98,000 unnecessary deaths occurring each year, and over one million preventable
injuries [1]. Estimated medical errors have resulted in nearly $30 billion of lost income
secondary to disability and additional healthcare costs [2]. Specific medical error risk factors
include inexperienced clinicians (i.e., postgraduate trainees), introduction to new procedures,
prolonged hospital stays, complex patient care, and extremes in age [3]. Despite numerous
national and institutional efforts to prevent medical errors, reporting errors through
mandatory or voluntary means (i.e., patient safety event reporting systems) remain an
invaluable tool in identifying and tracking patient safety events and threats to clinical quality.
In the groundbreaking report released by the Institute of Medicine’s (IOM) report, ‘To Err is
Human: Building a Safer Health System’, the authors found that more than 90% of errors were
preventable, and the successful reporting of these errors could provide critical data that would
inform future efforts to improve patient safety [4-6].

Mandatory error reporting systems for serious patient injuries and/or death aim to 1) ensure
further investigation and follow-up; 2) provide incentives to avoid potential penalties and
public exposure; and 3) ultimately improve patient safety [4]. Voluntary reporting systems, in
contrast, are based on a passive form of surveillance, requiring personnel directly involved in a
near-miss event to provide essential information and details [4]. The latter system has the
benefit of capturing true events or near misses that would assist in investigating and learning
more about the circumstances surrounding the event [4].

Despite the confidentiality that comes with voluntary reporting, there are numerous limitations
and barriers to effective, voluntary event reporting. Common physician barriers for submitting
incident reports include: 1) lack of incident follow-up; 2) long forms; 3) perceived ‘trivial’
nature of the incident; 4) lack of time; and 5) unclear responsibility for making the report [7].
Furthermore, increased public pressure on preventable errors, coupled with the threat of legal
action and additional psychological sequelae (i.e. guilt, anger, inadequacy, and depression)
associated with these errors, can perpetuate a culture of blame and avoidance, and deter
helpful voluntary incidental reporting [8-10]. While both reporting systems are integral for
detection and improvement of existing infrastructure weaknesses, efforts are required to
encourage the use of voluntary reporting system.

Clinician educators are tasked with teaching physicians-in-training medical and patient safety
practices. Teaching patient safety and error reporting to the Graduate Medical Education (GME)
audiences, however, is challenging. Only a minority of event reports are contributed by resident
physicians and fellows at Thomas Jefferson University (Jefferson). In the setting of the
aforementioned barriers to reporting, the authors also recognize that a new, unfamiliar system
would potentially further deter new interns from reporting events. 

In effort to augment active learning and engagement with teaching voluntary event reporting,
the authors developed an interactive, immersive learning experience incorporating
gamification and leveraging the increasingly popular ‘escape room’ design to incoming
Jefferson intern and resident physicians to better identify potential patient safety priorities and

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practice logging these events into the Jefferson Event Reporting System. ‘escape rooms’ have
risen in popularity in creating a high-fidelity, foreign environment that rewards players for
working together, solving clues, and completing successions of mind-bending tasks in order to
‘escape the room’ in a limited amount of time. Notably, the immersive and adaptive nature of
the escape room has enabled this team-building activity to be incorporated as an innovative
educational tool for a multitude of medical specialties [10-15].

We propose that exposing incoming interns and residents to various team-based activities on
critical patient safety priorities, as well as providing them with the opportunity for guided
reflection during a facilitated debriefing, will allow them to 1) identify local patient safety
priorities; 2) physically enter an event report using the Jefferson Event Reporting System; and
3) practice using teamwork skills to address patient safety threats.

Technical Report
Study setting
Four standard simulation rooms at the Rector Clinical Skills and Simulation Center at Thomas
Jefferson University in Philadelphia, Pennsylvania (PA) were secured to create four separate
escape rooms that were operated concurrently: two of these rooms simulated a hospital
inpatient room, and the other two rooms simulated a patient room in the emergency
department (ED). The activity took place in June 2018, during new intern and resident
orientation.

Study participant selection
All participants were interns (i.e., post-graduate year one, PGY-1, residents) beginning their
training at Thomas Jefferson University Hospitals. There were no exclusion criteria. All
participants consented to participate in the activity. All incoming PGY-1 residents were asked
to attend this activity as part of their orientation curriculum prior to starting their respective
residency programs.

Materials required
Participants were not asked to bring any additional tools or materials to the escape room.
Specific equipment required for the escape rooms has been listed in Table 1.

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Patient Safety Escape Room Materials

Hospital bed

Mannequin

Computer (with internet connection to enter error report)

Ventilator

Sequential compression devices

Isolation cart with gowns

Opened lumbar puncture kit (with sharps removed for safety)

Identification bracelet

Falls risk bracelet

Allergy bands

Adult diaper

Yellow falls socks

Urinal

Restraints

Incentive spirometer

Quick response (QR) codes

Door sign

Paper chart

Clipboard with blank list for recording hazards and clues (Appendix: hazard list)

TABLE 1: Equipment and materials required for the patient safety escape room
simulation cases

Personnel requirements
In order to coordinate, facilitate, and set-up the rooms for each session, 12 faculty members
were recruited to supervise the events. There were four simulation facilitators, four simulation
observers, two traffic controllers, and two debriefing facilitators. Simulation facilitators were
present in each of the rooms to provide any necessary hints, suggestions, or technical support
to effectively guide the learners through the cases. Observers were able to remotely view all of
the student activity in a control room via video streaming through an encrypted, institution
wireless network. Traffic controllers helped organize and coordinate learners moving from
room to room. The debriefing facilitators were tasked with debriefing teamwork skills used
during the activity, as well as discussing patient safety hazards noted in the rooms.

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Group structure
All 130 incoming interns were randomly divided into 16 teams, each comprising seven to eight
residents. Teams were tasked to work together to identify a predetermined series of patient
safety threats that were planted in each simulated escape room, and successfully enter these
events into the Jefferson Event Reporting System within the allotted time of 20 minutes in
order to successfully ‘escape the room’ and win the game.

Simulation sessions ran throughout the afternoon. Groups were staggered, and interns were
assigned a specific time to arrive at the simulation center. Prior to arrival, they received a 15-
minute didactic session on the Jefferson Event Reporting System, which was led by the
principal investigators (RJ). Participants received a brief primer on the concept of the escape
room activity. They were then led to their respective escape rooms. The day was broken down
into four 90-minute blocks (Blocks 1-4) and took place from 12 pm to 4 pm (Figure 1).

FIGURE 1: Participant flow for the escape room challenge
ETR: escape the room

Detailed activity description
Four simulation rooms were set up for the escape room activity, allowing four teams (up to 32
players) to be assessed concurrently. Half of the simulation rooms were designated as Case 1
(Internal Medicine case), and the other half were designated as Case 2 (Emergency Medicine
case). Cases 1 and 2 represented two distinct simulated clinical environments with a unique
set of respective challenges and patient safety hazards (Figures 2-3). Each case was developed
and revised by a multi-disciplinary team composed of senior faculty clinicians of different
medical specialties in order to 1) mitigate cognitive load; 2) standardize chart content; and 3)
effectively link case content with the medical record, room setup, and patient safety
hazards/learning goals. Each case contained a ‘patient chart’ that included: 1) an objective
structured clinical encounter (OSCE) style ‘door note’ that consisted of a one-sentence
introduction to frame the activity; 2) a physician note; 3) a nursing note; 4) a procedure
section; 5) a clinical data section (i.e., imaging, laboratory results, electrocardiogram); and 6)
an orders section. All props were obtained through the simulation center. There were no sharps
or dangerous objects used. Figures 2 and 3 demonstrate different styles of illustrating the

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https://assets.cureus.com/uploads/figure/file/55644/lightbox_e3eeb00012fc11e99e7bbf6a2f33be13-Figure-1_Participant-Flow.png


overlay of the cases with pertinent relevant patient safety hazards and props.

FIGURE 2: Schematic diagram of the potential clues and
overlay of the simulation for Case #1
Case #1 represented a simulated inpatient hospital room with possible hazards and hidden quick
response (QR) codes

FIGURE 3: Schematic diagram of the potential clues and
overlay of the simulation for case #2

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https://assets.cureus.com/uploads/figure/file/55645/lightbox_ed1a994012fd11e9bfda11f0f57ae2df-Figure-2_Case-1-diagram.png
https://assets.cureus.com/uploads/figure/file/55646/lightbox_435bb4c01c6c11e995c923396a4d6c0f-Case-2.png


Case #2 represented a simulated emergency room with possible hazards and hidden QR codes

QR: quick response

Each team was given 20 minutes to escape the room, followed by a 10-minute team debriefing
facilitated by the simulation observer. A larger 30-minute group debriefing with all of the
participants during each block was also conducted after each group completed both cases.
Quick Response (QR) codes were used to provide teams with instructions, clues, and prompts.
QR codes can be accessed with or without paid ‘apps’ by aiming a smartphone camera directly
onto the picture. Each QR code linked to a web page on a secured network with the associated
information on the safety hazard or clue to be solved (Figure 4). Codes were associated with
some, but not all, hazards (i.e., 3-4 hazards per room). Each code contained key information
about the patient safety priority, as well as the Jefferson Event Reporting Login, password,
and/or patient identifier. There were over 30 patient safety hazards shared between the two
cases, such as lowered bedrails, elevated beds, wrong medication administration, missing
patient-identifying wrist bands, ill-positioned breathing equipment, chart errors, soiled
procedure stations, missing restraints, and ill-placed trash items. These safety hazards were
selected based on a Delphi model with special consideration with implementation feasibility for
this simulated study. All elements were required to be documented in the final event report. In
order to successfully ‘escape the room’, participants were encouraged to practice teamwork
skills (e.g., situation monitoring, closed-loop communication, leadership, and shared mental
models) to solve each unique challenge.

FIGURE 4: Sample QR associated clue and information
Sample QR associated clue and information regarding hand hygiene as a safety hazard

QR: quick response

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https://assets.cureus.com/uploads/figure/file/55647/lightbox_3789f8801c6e11e9971fedb841da0aec-QR-code.png


Debriefing
After each team completed their respective escape rooms, two faculty co-facilitators debriefed
participants using the feedback capture grid method (Figure 5). The feedback capture grid [16]
consisted of four quadrants, each with a guiding question, such as ‘what went well?’ or ‘what
would have you done differently?’ to capture different perspectives. The unique features of the
feedback capture grid allow both learners and facilitators to address the strengths and potential
weaknesses of the teaching activity in an organized manner, as well as provide opportunities
for facilitators to address important patient safety concerns or teamwork dynamics.

FIGURE 5: Feedback capture grid for a large group debriefing
Feedback capture grid for large group debriefing. The 'plus' sign represents things that worked well.
The 'triangle' shape represents what could have been done differently. The 'lightbulb' represents
any new ideas. The 'question mark' represents any new questions that this activity may have
raised.

Activity evaluation
Following the debriefing, participants were asked to complete a voluntary post-study survey,
adapted from Brookfield’s CIQ [17]. The five-item CIQ asked participants to provide anonymous
responses based on different aspects of the teaching session. This allowed investigators to
model critical thinking and reflection; appreciate learning preferences; and identify potential
ideas for improvement during future iterations of the activity. Responses from the
questionnaire were evaluated for thematic codes through open-axial qualitative data analysis
(XCZ, DP).

Results
One-hundred thirty total interns participated in the activity. All 16 teams were able to
successfully escape the room within the 20-minute time limit. Thematic analysis of the post-
activity CIQ survey (n = 102, with a 78.5% survey response rate) revealed that the learners were
highly engaged by the format of the learning experience (n = 42) and the opportunity to identify
safety threats (n = 30). Furthermore, participants found that role assignment (n = 52) and

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https://assets.cureus.com/uploads/figure/file/55648/lightbox_9604f05012fe11e9a062538d645d9b91-Figure-5_Feedback-Capture-Grid.png


communication (n = 26) were the two most helpful actions needed to succeed in the activity.
Participants were surprised by the overall success of the educational innovation (n = 45) and
reported that it changed the way they perceived patient safety threats, especially identifying
easily-missed errors and the large heterogeneity that exists with regards to safety threats (n =
7). Areas for improvement focused primarily on logistical details, where the learners identified
the documentation process (n = 35) and the task completion ( n = 7) of the Jefferson Event
Reporting Interface as the most cumbersome, distancing and confusing elements of the
activity. Table 2 illustrates a detailed thematic analysis of the CIQ questionnaire.

CIQ
Indices

Number of
Themes
Identified

Thematic Codes Generated (with frequencies, n)

Most
engaged
 

7
Immersion in an active learning experience (42); discovering safety threats (30); debriefing
(8); task performance (8); effective communication (7); teaming/team building (5); having a
designated role (4)  

Most
distanced
 

6
Error reporting documentation (35); the escape room experience (16); confusion on the
instructions of the activity (14); debriefing (11); not having a clear role (3); poor group
communication (2) 

Action
most
helpful  

4 Role assignment (52); communication (26); feedback/debriefing (10); time-out (1)  

Action
most
confusing
 

6
Task completion (7); role clarity (5); difficulty in identifying patient safety threats (2);
challenges in communication (2); event reporting (1); team dynamics (1)  

Surprised
you most 

4
Success of the educational innovation (45); paradigm shift in how patient safety threats are
viewed (18); value of teamwork (12); error reporting (3)

TABLE 2: Thematic analysis of the CIQ from the escape room event
Specific CIQ questionnaires can be found in Appendix A.

CIQ: critical incident questionnaire

Discussion
The authors propose that escape rooms can be utilized to teach patient safety hazards and serve
as an effective teambuilding activity. Open-axial qualitative analysis of the participants CIQ
responses revealed that residents recognized the importance of identifying patient safety
hazards and felt fully immersed in this innovative method for teaching patient safety and
team-building. Additional aspects of the program that residents appreciated included the
importance of closed-loop communication, team-work building skills (i.e. taking notes,
assigning a team leader), and formal debriefing. Participants also identified areas of
improvement that distanced themselves from completing the objectives, such as complex event
reporting, confusing instructions (e.g. how to escape the room), and unclear role clarity among
teams, which was limited to the team dynamic of the individual groups, rather than the overall

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escape room activity. Participants, however, were appreciative that efforts were made to
incorporate the institution’s official patient safety reporting system into the simulation
experience, as it allowed them to feel more confident and comfortable with navigating the
software for future use. In order to address these issues, future iteration includes increased
instruction time during the 15-minute didactic session on the goals of the escape room
activities, as well as providing the teams extra preparation time to discuss teamwork tactics or
leadership selection before entering the rooms. 

There are several limitations worth noting. The simulations only included some of the common
patient errors found in the inpatient and ED setting. The inclusion of these patient safety issues
can unintentionally limit learners’ focus on these case-specific details. Furthermore, while we
encouraged event reporting through active practice within the simulations, additional studies
will need to be performed on this cohort to see whether this intervention will lead to an
increased number of reporting rates over time.

Conclusions
The escape room patient-safety activity was well received by incoming resident physicians at
the Thomas Jefferson University. The activity allowed learners to actively engage in a fun, non-
threatening, low-stakes activity that illustrated the expansive world of patient safety hazards,
as well as providing them with the opportunity to document event reports in real time. Next
steps will include tracking the quantity of error reports entered by this cohort longitudinally to
determine the effectiveness of this educational intervention on behavioral change.

Appendices
Appendix A – Critical Incident Questionnaire [16].

1. At what moment during the activity did you feel most engaged with what was happening?

2. At what moment during the activity did you feel most distanced from what was happening?

3. What action did anyone (i.e., faculty member or peer) take during the activity that you found
most affirming and helpful?

4. What action did anyone (i.e., faculty or peer) take during the activity that you found most
puzzling or confusing?

5. What about the activity this week surprised you the most? (This could be something about
your own reactions to what went on, or something that someone did, or anything else that
occurs to you.)

Additional Information
Disclosures
Human subjects: Consent was obtained by all participants in this study. Thomas Jefferson
University issued approval n/a. This study was reviewed and exempted by the Thomas Jefferson
University IRB. Animal subjects: All authors have confirmed that this study did not involve
animal subjects or tissue. Conf licts of interest: In compliance with the ICMJE uniform
disclosure form, all authors declare the following: Payment/services info: All authors have
declared that no financial support was received from any organization for the submitted work.
Financial relationships: All authors have declared that they have no financial relationships at
present or within the previous three years with any organizations that might have an interest in

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the submitted work. Other relationships: All authors have declared that there are no other
relationships or activities that could appear to have influenced the submitted work.

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	Finding the ‘QR’ to Patient Safety: Applying Gamification to Incorporate Patient Safety Priorities Through a Simulated ‘Escape Room’ Experience
	Abstract
	Introduction
	Technical Report
	Study setting
	Study participant selection
	Materials required
	TABLE 1: Equipment and materials required for the patient safety escape room simulation cases

	Personnel requirements
	Group structure
	FIGURE 1: Participant flow for the escape room challenge

	Detailed activity description
	FIGURE 2: Schematic diagram of the potential clues and overlay of the simulation for Case #1
	FIGURE 3: Schematic diagram of the potential clues and overlay of the simulation for case #2
	FIGURE 4: Sample QR associated clue and information

	Debriefing
	FIGURE 5: Feedback capture grid for a large group debriefing

	Activity evaluation
	Results
	TABLE 2: Thematic analysis of the CIQ from the escape room event


	Discussion
	Conclusions
	Appendices
	Additional Information
	Disclosures

	References