Effective Design, Development, and Evaluation of Video Tutorials for Electronic Medical Record Training

• Abstract
• Background and Significance
• Introduction
• Research Questions
• Methods
• Setting and Sample
• Intervention
• Data Collection
• Data Analysis
• Results
• PCPs View of the Video Tutorials
• Barriers and Facilitators
• Barriers to Applying the EMR Video Tutorial Training to Practice
• Facilitators to Applying the EMR Video Tutorial Training to Practice
• Multifaceted Approach to Promote the Adoption of EMR Video Tutorials
• Suggestions for Design and Development
• PCPs Would Like More EMR Video Tutorials
• PCP Involvement in the Design and Development of EMR Video Tutorials
• Supplementary Written Instructions
• Discussion
• Study Limitations
• Conclusion
• Clinical Relevance Statement
• References

Abstract

Background Electronic medical record (EMR) use by primary care physicians (PCP) in the United States and Canada is suboptimal, especially for supporting chronic diseases like diabetes. PCPs need postimplementation training to achieve value-adding EMR use. Video tutorials demonstrate how to accomplish tasks using software. However, there is a dearth of research on the use of video tutorials for EMR training.

Objective The purpose of the study was to design, develop, and evaluate video tutorials for training PCPs in using EMR advanced features for diabetes care. This study addressed three research questions related to PCP's views of video tutorials as an EMR training method/approach, barriers, and facilitators to applying the EMR video tutorials to PCPs' practice, and how the design of EMR video tutorials can be improved.

Methods The overall research study employed a QUAN (qual) mixed methods approach with an embedded design. This article focuses on the qualitative phase of the mixed methods study. A series of four theory-informed and evidence-based video tutorials for diabetes care was developed with a physician champion. Qualitative data were collected at four time points: 1 month before (O1), immediately before (O2), 3 months after (O3), and 6 months (O4) after the intervention. Semistructured interviews with participants were held at O3 and O4. Qualitative data were analyzed using thematic analysis.

Results In total, 14 PCPs from the overall study participated in interviews (78%). The thematic analysis of the qualitative data revealed seven themes, which fall into two main categories: (1) design and development of EMR video tutorials, and (2) adoption and use of EMR video tutorials.

Conclusion PCPs liked the EMR video tutorials for diabetes care, and would like more EMR video tutorials on various topics and EMR use levels. The study offers a roadmap for health informatics professionals everywhere to develop EMR training videos that meet evidence-based design criteria. It also help to identify opportunities to improve the design, delivery, and adoption of EMR video tutorials for future training interventions.

Background and Significance

An electronic medical record (EMR)[1] can facilitate improved capture, organization, and presentation of patient information. One of the main documented benefits of EMRs is preventive care and chronic disease management (CDM). These benefits are only realized if EMRs are used effectively, which includes complete, accurate, and consistent documentation, and use of advanced features such as recalls/reminders. However, current EMR use by primary care physicians (PCP) in the United States and Canada is suboptimal, especially for supporting chronic diseases[1] [2] [3] [4] [5] [6] [7] like diabetes. PCPs need support and training to achieve this kind of value-adding use[1] [8] [9] [10] [11] [12]. In particular, most PCPs require postimplementation training, as this is an often neglected area of training and probably the most needed by practicing clinicians.

Training provides “the conceptual and procedural knowledge necessary to put the technology to effective use”[13]. Common methods of software training include: (1) course/lecture/seminar; external training, computer-aided instruction, resident expert, and tutorials.[14] In the past two decades, video tutorials have become increasingly popular method for providing software training.

A video tutorial demonstrates how to accomplish tasks using software,[15] and it is a simple, affordable tool to produce authentic, situated, and motivational instructional material.[16] The benefits of video tutorials include: (1) support for users' development of a mental model of the software[16], (2) faster initial learning and better comfort compared with static versions of instructions[16], and (3) increased user control and autonomy.[16] However, a limitation of video tutorials is the “mimicry model” (i.e., memorizing and copying steps without internalizing the task).[17] [18] [19] Another disadvantage is the lack of an inferential step, potentially leading to lower retention of information compared with written instruction. Regardless, video tutorials can reduce cognitive processing for end-users, allowing them to immediately practice the demonstrated skills.[16] Video tutorials may also be considered a cost-effective and scalable tool for vendors to provide software training.

To support electronic health record (EHR) training for nursing students, He et al (2016) had designed and used two EHR video tutorials.[20] The authors identified that video tutorial-based training programs can be improved through hands-on practice and review questions with answers.[20] In another study, Thiyagarajan et al used EHR video tutorials to provide EHR training to medical students.[21] The medical students provided informal positive feedback about the video tutorials. The authors also reported that the video tutorials helped decrease the amount of time needed for EHR staff to orient student clinicians to the EHR.[21] Similarly, Zoghbi et al[22] provided EHR video tutorials to a group of general surgery residents. The study reported statistically significant positive effects of the video tutorials on residents' confidence in carrying out EMR tasks and clinical scores on emergency simulations. The video tutorials also helped to decrease the residents' time required to perform essential EMR tasks.[22] Recently, Randhawa et al (the authors) published a small-scale efficacy study that demonstrated the potential of video tutorials to improve EMR use for chronic diseases, such as diabetes.[23] However, primary research studies on the design of video tutorials for EMR training of PCPs or other practicing physicians have not been published to date.

Currently, there is a considerable need to design EMR theory-informed and evidence-based video tutorials for PCPs. Further, the EMR video tutorials should be designed to support learning for value-adding EMR use. The purpose of the study was to address this gap through the design, development, and evaluation of video tutorials for training PCPs in using EMR advanced features for diabetes care.

Introduction

The effective design of video tutorials should draw from multiple learning and instructional design theories and principles including usability,[24] minimalism,[25] structured writing (information mapping),[26] multimedia learning and multimedia principles,[27] animation,[28] attention,[29] dual coding theory,[30] social learning theory,[31] [32] the four components model,[33] guidelines for recorded demonstrations,[34] and demonstration-based training model[35] (which is based on social learning theory). Key principles from this body of literature are outlined in [Table 1]. In this paper, we focus on social learning theory and dual coding theory.

Based on the theories in [Table 1] and empirical studies of video tutorials, several best practice guidelines have been proposed over the years[34] [36] [37] for designing software video tutorials. However, the eight recommendations developed by van der Meij and van der Meij[36] in 2013 are the most comprehensive set, and “summarize key notions of accepted thinking” for designing instructional videos.[36] These guidelines are[37]:

1. Guideline 1: provide easy access

   • A. Guideline 1.1: craft the title carefully

2. Guideline 2: use animation with narration

   • A. Guideline 2.1: be faithful to the actual interface in the animation

   • B. Guideline 2.2: use a spoken human voice for the narration

   • C. Guideline 2.3: action and voice must be in synch

3. Guideline 3: enable function interactivity

   • A. Guideline 3.1: pace the video carefully

   • B. Guideline 3.2: enable user control

4. Guideline 4: preview the task

   • A. Guideline 4.1: promote the goal

   • B. Guideline 4.2: use a conversational style to enhance perceptions of task relevance

   • C. Guideline 4.3: introduce new concepts by showing their use in context

5. Guideline 5: provide procedural rather than conceptual information

6. Guideline 6: make tasks clear and simple

   • A. Guideline 6.1: follow the user's mental plan in describing an action sequence

   • B. Guideline 6.2: draw attention to the interconnection of user actions and system reactions

   • C. Guideline 6.3: use highlighting to signal screen objects or locations

7. Guideline 7: keep videos short

8. Guideline 8: strengthen demonstration with practice.

Another principle that informed our video tutorials design was homophily. In the end-user support literature for health information systems, homophily is “the degree of similarity between the support source and the end-user, and the degree to which the support source demonstrates understanding of the day-to-day work of the user”[38]. Homophily corresponds with modeling in social learning theory, in which learning occurs by observing a modeled behavior (e.g., physician trainer performing a task using EMR in a video tutorial) and then practicing or reproducing that behavior.[31] [32] [39] [40] It has been shown that adoption of the modeled behavior by individuals is higher when the model is similar to the individual(s).[32] Homophily is also one of the three essentials for learning, as suggested by Eyal and Rubin,[41] along with identification (ability of the observer to engage in perspective taking and share in the observee's experience) and parasocial interaction (friendship or bond with the observee).

This paper describes the implementation of the van der Meij and van der Meij[37] guidelines in video tutorials for using EMR advanced features for diabetes care, and the perceptions of PCPs of these videos.

Research Questions

This study addressed the following research questions:

1. What are PCP's views of video tutorials as a training method/approach for learning EMR advanced features?

2. What are the barriers and facilitators to applying the EMR video tutorials-based training to PCPs' practice?

3. How can the design of EMR video tutorials be improved?

Methods

The overall research study employed a QUAN (qual) mixed methods approach with an embedded design. In this paper, we report the findings from the qualitative portion of the study, which focused on the video tutorial design. Ethics approval was obtained from the University of Victoria Human Research Ethics Board (ethics protocol 17–189). The quantitative results of the mixed methods study (i.e., efficacy of the video tutorial intervention) are reported in a companion paper.[23]

Setting and Sample

Sampling was carried out as a part of the mixed methods study. Study participants included PCPs who use OSCAR EMR, which is one of the major EMRs used in British Columbia (BC) Province, Canada. All PCPs who use the OSCAR EMR in BC (n = 984) were invited to participate in the study. The BC Divisions of Family Practice and OSCAR BC Users' Group recruited participants using an invitation letter and a YouTube video[42] that explained the research study. The Divisions of Family Practice advertised the study opportunity to their division members through emails, newsletters, division meetings, and word of mouth. Interested PCPs signed and submitted a consent form to participate in the study, and were included on a “first come, first served” basis.

Intervention

The study intervention, called MD-PET (Management of Diabetes Postimplementation EMR Training), included a series of four short online video tutorials, each targeting one of the following EMR features for diabetes care:

1. Create and maintain a diabetes registry by coding diabetic patients using the “250” International Classification of Diseases, Ninth Revision (ICD-9) code for diabetes mellitus.

2. Create recalls/reminders for diabetes care.

3. Order/view hemoglobin A1C in the EMR.

4. Record blood pressure for diabetes care visits in the EMR.

These EMR features are similar to the EMR use instructions and applications recently published by Singer and Ivers.[43] The Chronic Care Model (CCM) served as the conceptual framework that underpinned the EMR training intervention, as it is “the best known and most influential” organizational model for chronic care”[44]. The CCM aims to develop well-informed, activated patients interacting with a practice team that is proactive and prepared for them; its end-goal is to improve health outcomes. The video tutorial intervention focused on the “clinical information systems” and “delivery systems design” components of the CCM (i.e., developing and maintaining, registries, and reminders/recalls). The content and topic selection for the video tutorials was determined based on the BC Clinical Guidelines for diabetes care. The order of the video tutorials was based on proactively planning a follow-up diabetes care visit in the EMR for a patient, and aligns with the CCM in terms of developing a patient registry, recalling patients, and viewing and recording process measures for diabetes care.

The guidelines from van der Meij and van der Meij were implemented in designing the video tutorials as described in [Table 2]. In total, 12 guidelines and subguidelines were fully applied and three were partially applied (i.e., guidelines 4.1, 7, and 8). Although users were provided the learning goal for every video as per guideline 4.1 (promote the goal), they were not provided a preview of the task. While guideline 7 (keep videos short) recommends that videos on medical consultation for problem-based learning be kept to 3 minutes, the length of the video tutorials in the study intervention ranged from 3 minutes and 48 seconds to 4 minutes and 48 seconds. Additionally, to ensure that users watched all the video tutorials in the study intervention, users were instructed to practice the tasks at the end of the final video tutorial only. Consequently, guideline 8 (strengthen demonstration with practice) was not fully met.

Consistent with the concept of homophily discussed earlier, a physician champion was involved in the design and recording of the video tutorials. The same physician champion recorded all of the video tutorials. In addition to the computer (EMR) screen, the physician champion's face was recorded simultaneously. The video tutorials were recorded, edited, and produced using Camtasia screencasting software, including the addition of animations, mouse highlighting, transitions, music, etc. Access to the finalized video tutorials was made available to study participants via a private YouTube video link[45] to view at their convenience during the intervention period.

Data Collection

Qualitative data were collected at four time points between July 2017 and May 2018: 1 month before (O1), immediately before (O2), 3 months after (O3), and 6 months (O4) after the intervention. This timing coincided with the quantitative data collection time points of the larger mixed methods study.[23] Data were collected using an open-ended question (“please feel free to share any comments regarding your use of the EMR for diabetes care management”) included within a quantitative Diabetes Care Questionnaire (DCQ) at O1–O4. Semistructured interviews with participants were held at O3 and O4 to understand (1) PCPs' views of the video tutorials, (2) barriers and facilitators to applying the video tutorials to PCPs' practice, and (3) opportunities to improve the design of the video tutorials ([Tables 3] and [4]). Interviews were conducted over the phone, audio-recorded, and transcribed verbatim by the first author. The interviews were 15 to 45 minutes in duration.

Data Analysis

Data from free-text comments in the DCQ and follow-up interviews were analyzed using thematic analysis (i.e., familiarization with data, assignment of preliminary codes, searching for patterns/themes, review, and finalization of themes). Data were reviewed and coded in NVivo 10 qualitative data analysis software.[46] To establish trustworthiness and verify the coding, three (14%) of the interviews and two (10%) of the qualitative comments from the DCQ were double coded. To support verification of the codes, the second researcher was provided the study code book and encouraged to add additional codes as needed. The second researcher coded the data at the highest node level, and there was moderately high agreement (77%) between the coders. Disagreements were related to detailed codes that were not used by the second researcher. To resolve discrepancies and reach consensus, the more detailed code was used. The final coding scheme that emerged is available in [Table 5].

Results

In total, 14 PCPs from the overall study participated in interviews (78%), and their participant demographics are outlined in [Table 6] below. Specifically, 12 PCPs participated in interviews at O3, and nine participated in interviews at O4. Of those PCPs who participated at O4, the majority (n = 7, 78%) had participated in the O3 interviews. The thematic analysis of the qualitative data revealed seven themes, which fall into two main categories: (1) design and development of EMR video tutorials, and (2) adoption and use of EMR video tutorials. A summary table of the themes can also be seen in [Table 7].

PCPs View of the Video Tutorials

All participants had a positive reaction to the EMR video tutorials. For example, according to one participant: “so what I watched was very impressive” (participant 9). Specifically, they liked that the EMR video tutorials were “short,” “simple,” and “accessible.” Hosting the EMR video tutorials on YouTube also increased the accessibility of the video tutorials. PCPs found it to be a convenient way to access EMR training according to their schedules, as they “could do (the training) on (their) own time” (participant 6).

Several PCPs also found the video tutorials to be “helpful” and supporting effective visual learning by showing “on-screen” actions “because it is nice to see them go into the EMR and click on what we need to click on” (participant 13). Some PCPs also found the video tutorials to be a good reference or review because of the ability “to go back to (the EMR video tutorials)” (participant 4), especially when “you forget something you do not use very often, if you forget” (participant 4).

Many PCPs liked the EMR trainer. They found him to be a “clear” communicator. According to one PCP, the EMR trainer “was very enthusiastic and very clear and supportive. I thought he was an excellent person. He spoke slowly. He was fantastic. He showed things I thought it was very effective” (participant 3). Participants also considered the EMR video tutorial trainer to be a knowledgeable “expert of experts” who is a “good spokesperson” for PCPs.

In terms of the design of the video tutorials, PCPs liked the use of cuing to help with EMR interface navigation (e.g., highlighting of the chart) and would like to continue seeing it in EMR video tutorials because it is “very useful” (participant 15) and “helps you to focus your eyes where you are going...and circling the things you are supposed to go to” (participant 11).

All participants were pleased with the content of the EMR video tutorials, and did not think anything was missing for diabetes care, as it was “thorough,” “well done,” and “hit on everything (PCPs) would need for diabetes management” (participant 6). Participants universally stated that they would recommend other PCPs who use OSCAR EMR “to watch the (EMR video tutorials)” (participant 3).

Barriers and Facilitators

Barriers to Applying the EMR Video Tutorial Training to Practice

For many participants, lack of time was the biggest barrier to integrating the EMR video training into their practice. According to one participant using the EMR features (e.g., reminders) for diabetes care “takes time” (participant 13). Consequently, PCPs' use of the diabetes care features varied depending on their time and workload. Given the individual needs of diabetic patients, some PCPs did not use the “recalls” or “ordering lab” features for all of their diabetic patients “because each diabetic has something a little bit different that (the PCP wants) to order a little bit different lab work” (participant 2).

Participants have experienced staff-level barriers to applying the EMR video tutorials in practice, such as “computer literacy” and “having everybody in the office trained on the same system” (participant 1). At the patient level, the patient's responsibility in diabetes care was reported as a barrier because “there is a group of people that just are not going to be responsible” (participant 4). PCPs also experienced barriers at the EMR level, such as the EMR reminders being a “pull message” and not a “push message.” PCPs reported general EMR issues beyond training, as well. For example, for one PCP, the EMR was “not being as user-friendly as (the participant) would like” due to there being too many clicks (participant 9). From a policy perspective, there are barriers related to PCP funding (i.e., protected time) for EMR use because “(PCPs) are not remunerated for a whole lot of work (they) do in the job. Paper work, labs, referrals, EMR, on and on…there is not funding for that whatsoever. So it is a big barrier” (participant 9).

Facilitators to Applying the EMR Video Tutorial Training to Practice

For PCPs, the diabetes flow sheet was a key facilitator to integrating the EMR video tutorial training into practice because “it is so much easier than going through (PCPs') reams of paper...it is just right there” (participant 5). CDM incentive fees and a “desire to do good care” were also key facilitators “to adopt the (EMR video tutorials) fairly aggressively” (participant 12). PCPs' staff has supported applying the EMR video tutorial training in multiple ways, such as having “a (medical office assistant [MOA]) that is dedicated to doing the vitals and show people to their rooms” (participant 1). At the patient level, patients play a facilitating role in diabetes recalls by acting as a “safety net” so that between the PCP and the patient, “somehow (diabetes follow-up care) gets done” (participant 1). One participant shared that policy-related initiatives such as physician feedback serve as facilitators as well.

Multifaceted Approach to Promote the Adoption of EMR Video Tutorials

All PCPs suggested that the Divisions of Family Practice and Pathways (i.e., an online, searchable resource for GPs in BC who are members of a Division of Family Practice) would be best suited to (1) host the EMR video tutorials on their websites, and (2) create awareness about the video tutorials. A few participants suggested that financial incentives may facilitate adoption of the EMR video tutorials because “in the absence of (financial incentives), there is very little incentive to go and look at (EMR video tutorials) in people's spare time” (participant 7). Continuing Professional Development (CPD) credits were also suggested as a potential incentive for PCPs to be “more likely to do (the EMR video tutorial training)” (participant 5). One participant suggested that watching the EMR video tutorials should be a prerequisite for PCPs to receive incentive billing (e.g., for CDM).

To supplement the EMR video tutorials, PCPs would like to have access to additional end-user support sources and follow-up. For example, some participants would appreciate receiving follow-up reminders through the EMR or email to say “hey! look at this video hey! remember this training you did, and was there anything you needed to implement that you have not done yet? Do it. Contact us if you need help or something” (participant 6). Other participants would like to have access to in-person training “because (EMR) training always stimulates more questions, which are not automatically answered. So, in-person would be great. For like an hour or something” (participant 9). Individualized coaching was also suggested as form of end-user support; as well as online forums “as a place where you can go... if you do not have a person (to go to for support)” to ask EMR-related questions (participant 11).

Suggestions for Design and Development

PCPs Would Like More EMR Video Tutorials

Participants reported that they would like to receive more EMR video tutorials to support their increased use and optimization of the EMR and they would like these video tutorials to be short and similar to MD-PET: “… 2 to 3 minutes, and even shorter if possible so (PCPs) can figure out how to do something step by step…and have it organized in a way that could be searchable as well” (participant 2). Participants would also like the video tutorials to be publically available online.

Although PCPs appreciated MD-PET, they wanted EMR video tutorials on additional topics, such as “other chronic diseases like COPD” (participant 5), “determining an active medication list” (participant 13), and developing “forms” and “your own smart labs” (participant 2). Several PCPs also emphasized the need for having more video tutorials available for PCPs who are at different EMR use levels:

“No, I think they are good. You just need more. You need a whole batch of them with an index that physicians can go to get what they are missing because all of the physicians are at different levels of their comfort with the EMR.” (participant 2).

To support PCPs in different communities, one participant also recommended that video tutorials be developed for different communities in BC because “each community may have a different way of doing things and makes the (EMR video tutorials) not useful to them.” (participant 11).

Participants preferred the EMR video tutorials to be available as a searchable library that is “organized and...searchable so that somebody can just say “run reports” or “run diabetes report” and it would flick right to there” (participant 2) because “physicians use stuff that saves time but they will not use (the EMR video tutorials) if it is more time consuming” (participant 2). PCPs would also find it “even more helpful” if the library could be embedded within the EMR to increase accessibility at the point of care. For example, PCPs could “go to the help button and it (would have) all the list of the tutorials” (participant 13).

To support their MOA with increasing EMR use, PCPs suggested developing EMR video tutorials for MOAs because they would be “very helpful” and “MOAs would really appreciate it” (participant 3).

PCP Involvement in the Design and Development of EMR Video Tutorials

To ensure credible and trustworthy EMR training, participants highlighted the importance of having a PCP involved in the design and development of EMR video tutorials. They specifically preferred to have a practicing PCP who uses OSCAR EMR, is an “EMR specialist,” and “is aware of what the EMR can and cannot do” (participant 5).

Participants highlighted the importance of having a physician trainer who is well spoken, can “communicate effectively,” uses appropriate humor, is “concise,” and “to the point.” In terms of communicating, the physician trainer should be “speaking softly” and “enunciating their words.” Further, the physician trainer should be engaging, as “it's got to be lively, entertaining, well presented, clear, short” (participant 7). For participants, having a physician trainer “always lends credibility,” increases PCPs' ability to relate to the trainer and trust the EMR training, because “they understand, you know, [PCPs'] time constraints, and sort of the busyness of doing a practice” (participant 5). One participant described in detail this expected homophily with the physician trainer:

“So the more information that I find out that the person has in common with my situation, the more likely I am going to think they have something to offer me. So if I'm a community physician, you tell me this person is a community physician, and then I will probably listen to him more than if you told me somebody was a university lecturer. Because I'm thinking, how often do they use the system? Do they run into the same problems I do? And how much are they speaking to my level of function. So you have to target it to your audience.” (participant 11)

Additionally, to increase their “connection” and ability to relate with the trainer, several PCPs indicated that they would like to see video of the trainer's face and not just their audio (i.e., voice) because “[PCPs] seem to relate better to faces than to words. So it's nice having the person's face in the corner [of the EMR video tutorial screen]” (participant 15).

In addition to having knowledge, homophily, counseling, and communication skills, the PCP trainer should know “how to do things quickly and efficiently or offset the work to [Medical Office Assistant]” (participant 9). The trainer should also be “somebody with a very simple message. Very practical, demonstrating the skills...and not talking too much, just very direct and about the message you want to, the skill you want to get across” (participant 5).

Finally, several participants it would be valuable to know “the background of trainer, which physician in which location” and because it “would probably be interesting for the person learning” (participant 15).

Supplementary Written Instructions

As a learning supplement and reference, two PCPs stated that they may find it helpful to have written instructions (e.g., step-by-step instruction about how to record a blood pressure in the EMR) available below the EMR video tutorials. This would allow PCPs to watch the video tutorial or to read the written instructions “like a recipe” (participant 2). As such, the viewer “can watch the cook make it or [they] can read the instructions below” (participant 2).

Discussion

This study investigated the design and qualitative evaluation of postimplementation EMR video tutorials for diabetes care. Although video tutorials have recently been applied in a few studies to support EHR training for medical students, medical residents, and nursing students,[20] [21] [22] the design and use of video tutorials to support PCPs or physicians in general has not been widely investigated to date. Further, EMR video tutorials that are informed by the CCM, and are based on clinician-led training and best practices of software video tutorials' design have rarely been examined.

The present study revealed PCPs' unanimous liking of the video tutorials and subsequent desire to have access to more EMR video tutorials. Multiple barriers and facilitators to applying the EMR video tutorial training to practice were also found at the physician, staff, patient, EMR, and policy levels. However, none of the identified barriers specifically related to the design of the intervention, although some enhancements were suggested (e.g., use of a handout in conjunction with a video tutorial). Almost all of the identified barriers and facilitators align with the “barriers to and incentives for change at different levels of healthcare” of Grol and Wensing's framework,[47] including the innovation, individual professional, patient, social context, organizational context, and economic and political context. Lack of time was the biggest barrier to applying the EMR video tutorials to practice. This aligns with previous literature indicating that PCPs require more time for recommended CDM than is available for patients overall,[48] as well as time as a barrier to adopting EHRs.[49] [50] The barrier of adapting the practices demonstrated in video tutorials to individual patient needs maps to the “patient” level barrier of Grol and Wensing's framework. It also aligns with research on the need for individualized diabetes management instead of a “one-size-fits-all” approach and consideration for comorbidities (e.g., patients with diabetes and chronic kidney disease).[51] [52]

To support the future design and development of EMR video tutorials, PCPs would like to have a PCP involved in the process. This preference for clinician-led training reinforces the concept of homophily as a characteristic of end-user support,[38] as well as learning through modeling in social learning theory. The study results also align with Eyal and Rubin's[41] three essentials for learning discussed earlier: (1) homophily: PCPs' preference for having a physician trainer, (2) identification: participants' recommendation to provide biography of the physician trainer with the video tutorial, and (3) parasocial interaction: participants liked seeing the face (video footage) of the physician trainer in the EMR video tutorial.

Additionally, PCPs emphasized the continued need to see the EMR on-screen navigation in the EMR video tutorials. This visual preference may correspond with dual coding theory, which suggests that visual images, coupled with verbal information, aids learning.[30]

Study Limitations

The study employed a small sample that may not be generalizable to the whole population. However, the study provides rich insight into the design and evaluation of EMR video tutorials for PCPs. The present study did not examine effectiveness and additional research is needed to ascertain the design and effectiveness of video tutorials for improving EMR use. Additionally, the video tutorial intervention should fully apply all eight best practice guidelines for designing video tutorials.[37]

Conclusion

This study revealed that PCPs liked the EMR video tutorials for diabetes care and many of the design best practices implemented in them, and that they would like more EMR video tutorials on various topics and EMR use levels. This study offers a roadmap for health informatics professionals and instructional designers to develop EMR training videos for physicians and other EMR users with content and theory that meets evidence-based design criteria. The study results also help to identify opportunities to improve the design and delivery of EMR video tutorials for future training interventions including the development of an EMR video tutorial library, continued use of physician trainers in the design and development of EMR video tutorials, use of a multifaceted EMR training strategy, and provision of incentives to support adoption of video tutorials by PCPs. For future development and deployment of video tutorials, PCPs have suggested a multifaceted approach that includes additional end-user support to promote the adoption of EMR video tutorials. Policy makers and EMR vendors should consider investing in the development of EMR video tutorials informed by theory- and evidence-based best practices for designing software video tutorials. EMR users could benefit from developing an EMR video tutorial library as an open educational resource[53] for all EMRs, which can be hosted on an accessible website such as YouTube. Potential funding or CPDaccreditation for PCPs to watch the EMR video tutorials during protected time should be considered as well. Physician quality improvement programs may consider including EMR video tutorials as a supplementary end-user support resource. The development of EMR video tutorials for MOAs, as suggested by study participants, should also be considered.

Clinical Relevance Statement

Postimplementation EMR training for PCPs is generally inadequate and ineffective at present; to improve value-adding EMR use such as advanced features for diabetes care, training methods must be reliable, valid, feasible, educationally effective, and acceptable to users.[54] This study has demonstrated PCPs' endorsement and desire for video tutorials and video tutorial design best practices as a medium for providing advanced EMR training. They may also use the EMR video tutorials to train their office staff, as well as medical residents and locum physicians.

Conflict of interest

None declared.

Acknowledgments

The authors are sincerely thankful to Dr. John Yap for his support in designing and developing the EMR video tutorials.

The terms EMR and EHR (electronic health record) are often used interchangeably diseases[1]. In Canada, where this study has been conducted, an EMR is a health record under the custodianship of primary care physicians, whereas an EHR is used in secondary and tertiary care (hospital) settings.

Authors' Contributions

Each author made the following contributions toward the completion of the manuscript:

1. Substantial contributions to conception and design, acquisition of data, or analysis and interpretation of data.

2. Drafting the article or revising it critically for important intellectual content.

3. Final approval of the version to be published.

Protection of Human and Animal Subjects

The study was performed in compliance with the World Medical Association Declaration of Helsinki on ethical principles for medical research involving human subjects, and was reviewed by the University of Victoria Human Research Ethics Board (HREB).

• References

• 1 Canada Health Infoway. The emerging benefits of electronic medical record use in community-based care; 1–98. Available at: https://www.pwc.com/ca/en/healthcare/publications/pwc-electronic-medical-record-use-community-based-care-report-2013-06-en.pdf . Accessed April 21, 2013
  PubMed
• 2 Survey NP. What electronic functions are you planning to use in the next two years? NR. 2014:2012. Available at: http://nationalphysiciansurvey.ca/wp-content/uploads/2014/09/2014-FPGP-EN-Q7iii.pdf . Accessed May 7, 2020
  PubMed
• 3 Commonwealth Fund. 2015 International Survey of Primary Care Doctors. 2015. Available at: https://international.commonwealthfund.org/data/2015/ . Accessed May 7, 2020
  PubMed
• 4 Denomme LB, Terry AL, Brown JB, Thind A, Stewart M. Primary health care teams’ experience of electronic medical record use after adoption. Fam Med 2011;43(09):638–642
  PubMed
• 5 Loomis GA, Ries JS, Saywell RM Jr, Thakker NR. If electronic medical records are so great, why aren’t family physicians using them? J Fam Pract 2002;51(07):636–641
  PubMed
• 6 Price M, Singer A, Kim J. Adopting electronic medical records: are they just electronic paper records? Can Fam Physician 2013;59(07):e322-e329
  PubMed
• 7 Randhawa GK, Lau F, Price M. Evaluating the adoption of e-prescribing in primary care. Healthc Q 2013;16(04):55–60
  PubMed
• 8 Swerissen H, Duckett S, Wright J. Chronic failure in primary medical care. 2016. Available at: https://grattan.edu.au/wp-content/uploads/2016/03/936-chronic-failure-in-primary-care.pdf . Accessed March 2, 2016
  PubMed
• 9 Canadian Institute for Health Information. Diabetes care gaps and disparities in Canada. Community Health (Bristol) 2009. Available at: http://secure.cihi.ca/cihiweb/products/Diabetes_care_gaps_disparities_aib_e.pdf . Accessed May 7, 2020
  PubMed
• 10 Edwards G, Kitzmiller RR, Breckenridge-Sproat S. Innovative health information technology training. CIN Comput Informatics Nurs 2012;30(02):104–109
  PubMed
• 11 Dastagir MT, Chin HL, McNamara M, Poteraj K, Battaglini S, Alstot L. Advanced proficiency EHR training: effect on physicians’ EHR efficiency, EHR satisfaction and job satisfaction. AMIA Annu Symp Proc 2012;2012:136–143
  PubMed
• 12 Bredfeldt CE, Awad EB, Joseph K, Snyder MH. Training providers: beyond the basics of electronic health records. BMC Health Serv Res 2013;13:503
  PubMed
• 13 Venkatesh V. Creation of favorable user perceptions: exploring the role of intrinsic motivation. Viswanath Venkatesh Source MIS Q. 1999;23(02):239–260
  PubMed
• 14 Nelson RR, Cheney PH. Training end users - an exploratory-study. MISQ Q. 1987;11(04):547–559
  PubMed
• 15 Baecker R. Showing instead of telling. In: ACM SIGDOC 2002. 2002:10-16. Available at: https://www.dgp.toronto.edu/papers/rbaecker_SIGDOC2002.pdf . Accessed May 7, 2020
  PubMed
• 16 Palaigeorgiou G, Despotakis T. Known and unknown weaknesses in software animated demonstrations (screencasts): a study in self-paced learning settings. J Inf Technol Educ 2010;9:1–18
  PubMed
• 17 Harrison S. A comparison of still, animated, or nonillustrated on-line help with written or spoken instructions in a graphical user interface. Proc SIGCHI Conf Hum Factor Comput Syst. Vol Denver, Colorado, USA: ACM Press/Addison-Wesley Publishing Co.; 1995:82-89. Available at: https://dl.acm.org/doi/fullHtml/10.1145/223904.223915 . Accessed May 7, 2020
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• 18 Palmiter S, Elkerton J. An evaluation of animated demonstrations of learning computer-based tasks. Proc SIGCHI Conf Hum Factors Comput Syst. 1991:257-263. 10.1145/108844.108906. Available at: https://dl.acm.org/doi/10.1145/108844.108906 . Accessed May 7, 2020
  PubMed
• 19 Palmiter S, Elkerton J. Animated demonstrations for learning procural computer-based tasks. Hum Comput Interact 1993;8(03):193–216
  PubMed
• 20 He Z, Marquard J, Henneman E. Model guided design and development process for an electronic health record training program. AMIA Annu Symp Proc 2017;2016:1814–1821
  PubMed
• 21 Thiyagarajan A, Allen C, Peacock J, Cousins R. Implementing training videos for student clinicians to improve charting and utilization of EHR capabilities. 2017;3. Available at: http://www.themspress.org/journal/index.php/freeclinic/article/view/237 . Accessed May 7, 2020
  PubMed
• 22 Zoghbi V, Caskey RC, Dumon KR, et al. “How to” videos improve residents performance of essential perioperative electronic medical records and clinical tasks. J Surg Educ 2018;75(02):489–496
  PubMed
• 23 Randhawa GK, Shachak A, Courtney KL, Kushniruk A. Evaluating a post-implementation electronic medical record training intervention for diabetes management in primary care. BMJ Health Care Inform 2019;26(01):e100086
  PubMed
• 24 Bethke FJ, Dean WM, Kaiser PH, Ort E. Improving the usability of programming publications. IBM Syst J 1981;20(03). Doi: 10.1145/965660.965668
  PubMed
• 25 Van der Meij H, Carroll J. Principles and Heuristics for Designing Minimalist Instruction. Cambridge, MA: MIT Press; 1995
  PubMed
• 26 Horn R. Structured writing at twenty-five. Perform Instr 1993;32:11–17
  PubMed
• 27 Mayer R, Mayer RE. The Cambridge Handbook of Multimedia Learning. Cambridge, MA: Cambridge University Press; 2005
  PubMed
• 28 Tversky B, Morrison JB, Betrancourt M. Animation?: can it facilitate? Int J Hum Comput Stud 2002;247–262
  PubMed
• 29 Neumann O. Theories of attention. In: Neumann O, Sanders AF, eds. Handbook of Perception and Action. Vol. 3. Cambridge, MA: Academic Press; 1996:389–446
  PubMed
• 30 Paivio A. Imagery and Verbal Processes. NY: Holt, Rinehart, and Winston; 1971
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• 31 Bandura A. Social Learning Theory. Englewood Cliffs, NJ: Prentice Hall; 1977
  PubMed
• 32 Bandura A. Social Foundations of Thought and Action: A Social Cognitive Theory. Upper Saddle River, NY: Prentice-Hall, Inc; 1986
  PubMed
• 33 van der Meij H, Gellevij M. The four components of a procedure. IEEE Trans Prof Commun 2004;47(01):5–14
  PubMed
• 34 Plaisant C, Shneiderman B. Show me Guidelines for producing recorded demonstrations. 2005. Available at: http://www.cs.umd.edu/hcil/trs/2005-02/2005-02.pdf . Accessed May 7, 2020
  PubMed
• 35 Brar J, Van Der Meij H. Computers in human behavior complex software training: harnessing and optimizing video instruction. Comput Human Behav 2017;70:475–485
  PubMed
• 36 Swarts J. New modes of help: best practices for instructional video. Tech Commun (Washington) 2012;59(03):195–206
  PubMed
• 37 van der Meij H, van der Meij J. Eight Guidelines for the design of instructional videos for software training. Tech Commun (Washington) 2013;60(03):205–228
  PubMed
• 38 Shachak A, Barnsley J, Tu K, Jadad AR, Lemieux-Charles L. Understanding end-user support for health information technology: a theoretical framework. Inform Prim Care 2011;19(03):169–172
  PubMed
• 39 Grol R, Wensing M. Effective implementation of change in healthcare: a systematic approach. 2013:40–59
  PubMed
• 40 Torre DM, Daley BJ, Sebastian JL, Elnicki DM. Overview of current learning theories for medical educators. Am J Med 2006;119(10):903–907
  PubMed
• 41 Eyal K, Rubin AM, Eyal K, Rubin AM. Viewer aggression and homophily, identification, and parasocial relationships with television characters viewer aggression and homophily, with television characters. J Broadcast Electron Media 2010. Doi: 10.1207/s15506878jobem4701
  PubMed
• 42 Randhawa G. OSCAR EMR study recruitment video. 2017. Available at: https://www.youtube.com/watch?v=zNQTWEyNU2c&feature=youtu.be . Accessed August 9, 2019
  PubMed
• 43 Singer A, Ivers NM. Using your electronic medical record to deliver evidence-based diabetes care. Can Fam Physician 2019;65(01):43–44
  PubMed
• 44 PAHO. The chronic care model. 2013. Available at: https://www.paho.org/hq/index.php?option=com_content&view=article&id=8502:2013-the-chronic-care-model&Itemid=1353&lang=en . Accessed April 4, 2016
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• 45 Randhawa G, Yap J. OSCAR EMR video tutorial series. 2017. Available at: https://www.youtube.com/playlist?list=PLqNVRTDyA_99lsQzVXz4K3X8VvZr7oUXZ . Accessed September 27, 2017
  PubMed
• 46 QSR International Pty Ltd. NVivo qualitative data analysis software, version 10. 2012. Available at: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3930250/ . Accessed February 12, 2014
  PubMed
• 47 Grol R, Wensing M. What drives change? Barriers to and incentives for achieving evidence-based practice. Med J Aust 2004;180(S6):S57–S60
  PubMed
• 48 Østbye T, Yarnall KSH, Krause KM, Pollak KI, Gradison M, Michener JL. Is there time for management of patients with chronic diseases in primary care? Ann Fam Med 2005;3(03):209–214
  PubMed
• 49 Ajami S, Bagheri-Tadi T. Barriers for adopting electronic health records (EHRs) by physicians. Acta Inform Med 2013;21(02):129–134
  PubMed
• 50 Shuval K, Berkovits E, Netzer D, et al. Evaluating the impact of an evidence-based medicine educational intervention on primary care doctors' attitudes, knowledge and clinical behaviour: a controlled trial and before and after study. J Eval Clin Pract 2007;13(04):581–598
  PubMed
• 51 Bailey CJ, Aschner P, Del Prato S, LaSalle J, Ji L, Matthaei S; Global Partnership for Effective Diabetes Management. Individualized glycaemic targets and pharmacotherapy in type 2 diabetes. Diab Vasc Dis Res 2013;10(05):397–409
  PubMed
• 52 Levey AS, Coresh J. Chronic kidney disease. Lancet 2012;379(9811):165–180
  PubMed
• 53 United Nations Educational Scientific and Cultural Organization. What are open educational resources? 2017. Available at: https://en.unesco.org/themes/building-knowledge-societies/oer . Accessed May 7, 2020
  PubMed
• 54 Shachak A, Reis S, Gray K, et al. Evaluating educational interventions for health professions in the digital age. In: Shachak A, Borycki EM, Reis SP, eds. Health Professionals’ Education in the Age of Clinical Information Systems, Mobile Computing and Social Networks. Amsterdam, Netherlands: Elsevier Inc.; 2017:471–488
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Address for correspondence

• References

• 1 Canada Health Infoway. The emerging benefits of electronic medical record use in community-based care; 1–98. Available at: https://www.pwc.com/ca/en/healthcare/publications/pwc-electronic-medical-record-use-community-based-care-report-2013-06-en.pdf . Accessed April 21, 2013
  PubMed
• 2 Survey NP. What electronic functions are you planning to use in the next two years? NR. 2014:2012. Available at: http://nationalphysiciansurvey.ca/wp-content/uploads/2014/09/2014-FPGP-EN-Q7iii.pdf . Accessed May 7, 2020
  PubMed
• 3 Commonwealth Fund. 2015 International Survey of Primary Care Doctors. 2015. Available at: https://international.commonwealthfund.org/data/2015/ . Accessed May 7, 2020
  PubMed
• 4 Denomme LB, Terry AL, Brown JB, Thind A, Stewart M. Primary health care teams’ experience of electronic medical record use after adoption. Fam Med 2011;43(09):638–642
  PubMed
• 5 Loomis GA, Ries JS, Saywell RM Jr, Thakker NR. If electronic medical records are so great, why aren’t family physicians using them? J Fam Pract 2002;51(07):636–641
  PubMed
• 6 Price M, Singer A, Kim J. Adopting electronic medical records: are they just electronic paper records? Can Fam Physician 2013;59(07):e322-e329
  PubMed
• 7 Randhawa GK, Lau F, Price M. Evaluating the adoption of e-prescribing in primary care. Healthc Q 2013;16(04):55–60
  PubMed
• 8 Swerissen H, Duckett S, Wright J. Chronic failure in primary medical care. 2016. Available at: https://grattan.edu.au/wp-content/uploads/2016/03/936-chronic-failure-in-primary-care.pdf . Accessed March 2, 2016
  PubMed
• 9 Canadian Institute for Health Information. Diabetes care gaps and disparities in Canada. Community Health (Bristol) 2009. Available at: http://secure.cihi.ca/cihiweb/products/Diabetes_care_gaps_disparities_aib_e.pdf . Accessed May 7, 2020
  PubMed
• 10 Edwards G, Kitzmiller RR, Breckenridge-Sproat S. Innovative health information technology training. CIN Comput Informatics Nurs 2012;30(02):104–109
  PubMed
• 11 Dastagir MT, Chin HL, McNamara M, Poteraj K, Battaglini S, Alstot L. Advanced proficiency EHR training: effect on physicians’ EHR efficiency, EHR satisfaction and job satisfaction. AMIA Annu Symp Proc 2012;2012:136–143
  PubMed
• 12 Bredfeldt CE, Awad EB, Joseph K, Snyder MH. Training providers: beyond the basics of electronic health records. BMC Health Serv Res 2013;13:503
  PubMed
• 13 Venkatesh V. Creation of favorable user perceptions: exploring the role of intrinsic motivation. Viswanath Venkatesh Source MIS Q. 1999;23(02):239–260
  PubMed
• 14 Nelson RR, Cheney PH. Training end users - an exploratory-study. MISQ Q. 1987;11(04):547–559
  PubMed
• 15 Baecker R. Showing instead of telling. In: ACM SIGDOC 2002. 2002:10-16. Available at: https://www.dgp.toronto.edu/papers/rbaecker_SIGDOC2002.pdf . Accessed May 7, 2020
  PubMed
• 16 Palaigeorgiou G, Despotakis T. Known and unknown weaknesses in software animated demonstrations (screencasts): a study in self-paced learning settings. J Inf Technol Educ 2010;9:1–18
  PubMed
• 17 Harrison S. A comparison of still, animated, or nonillustrated on-line help with written or spoken instructions in a graphical user interface. Proc SIGCHI Conf Hum Factor Comput Syst. Vol Denver, Colorado, USA: ACM Press/Addison-Wesley Publishing Co.; 1995:82-89. Available at: https://dl.acm.org/doi/fullHtml/10.1145/223904.223915 . Accessed May 7, 2020
  PubMed
• 18 Palmiter S, Elkerton J. An evaluation of animated demonstrations of learning computer-based tasks. Proc SIGCHI Conf Hum Factors Comput Syst. 1991:257-263. 10.1145/108844.108906. Available at: https://dl.acm.org/doi/10.1145/108844.108906 . Accessed May 7, 2020
  PubMed
• 19 Palmiter S, Elkerton J. Animated demonstrations for learning procural computer-based tasks. Hum Comput Interact 1993;8(03):193–216
  PubMed
• 20 He Z, Marquard J, Henneman E. Model guided design and development process for an electronic health record training program. AMIA Annu Symp Proc 2017;2016:1814–1821
  PubMed
• 21 Thiyagarajan A, Allen C, Peacock J, Cousins R. Implementing training videos for student clinicians to improve charting and utilization of EHR capabilities. 2017;3. Available at: http://www.themspress.org/journal/index.php/freeclinic/article/view/237 . Accessed May 7, 2020
  PubMed
• 22 Zoghbi V, Caskey RC, Dumon KR, et al. “How to” videos improve residents performance of essential perioperative electronic medical records and clinical tasks. J Surg Educ 2018;75(02):489–496
  PubMed
• 23 Randhawa GK, Shachak A, Courtney KL, Kushniruk A. Evaluating a post-implementation electronic medical record training intervention for diabetes management in primary care. BMJ Health Care Inform 2019;26(01):e100086
  PubMed
• 24 Bethke FJ, Dean WM, Kaiser PH, Ort E. Improving the usability of programming publications. IBM Syst J 1981;20(03). Doi: 10.1145/965660.965668
  PubMed
• 25 Van der Meij H, Carroll J. Principles and Heuristics for Designing Minimalist Instruction. Cambridge, MA: MIT Press; 1995
  PubMed
• 26 Horn R. Structured writing at twenty-five. Perform Instr 1993;32:11–17
  PubMed
• 27 Mayer R, Mayer RE. The Cambridge Handbook of Multimedia Learning. Cambridge, MA: Cambridge University Press; 2005
  PubMed
• 28 Tversky B, Morrison JB, Betrancourt M. Animation?: can it facilitate? Int J Hum Comput Stud 2002;247–262
  PubMed
• 29 Neumann O. Theories of attention. In: Neumann O, Sanders AF, eds. Handbook of Perception and Action. Vol. 3. Cambridge, MA: Academic Press; 1996:389–446
  PubMed
• 30 Paivio A. Imagery and Verbal Processes. NY: Holt, Rinehart, and Winston; 1971
  PubMed
• 31 Bandura A. Social Learning Theory. Englewood Cliffs, NJ: Prentice Hall; 1977
  PubMed
• 32 Bandura A. Social Foundations of Thought and Action: A Social Cognitive Theory. Upper Saddle River, NY: Prentice-Hall, Inc; 1986
  PubMed
• 33 van der Meij H, Gellevij M. The four components of a procedure. IEEE Trans Prof Commun 2004;47(01):5–14
  PubMed
• 34 Plaisant C, Shneiderman B. Show me Guidelines for producing recorded demonstrations. 2005. Available at: http://www.cs.umd.edu/hcil/trs/2005-02/2005-02.pdf . Accessed May 7, 2020
  PubMed
• 35 Brar J, Van Der Meij H. Computers in human behavior complex software training: harnessing and optimizing video instruction. Comput Human Behav 2017;70:475–485
  PubMed
• 36 Swarts J. New modes of help: best practices for instructional video. Tech Commun (Washington) 2012;59(03):195–206
  PubMed
• 37 van der Meij H, van der Meij J. Eight Guidelines for the design of instructional videos for software training. Tech Commun (Washington) 2013;60(03):205–228
  PubMed
• 38 Shachak A, Barnsley J, Tu K, Jadad AR, Lemieux-Charles L. Understanding end-user support for health information technology: a theoretical framework. Inform Prim Care 2011;19(03):169–172
  PubMed
• 39 Grol R, Wensing M. Effective implementation of change in healthcare: a systematic approach. 2013:40–59
  PubMed
• 40 Torre DM, Daley BJ, Sebastian JL, Elnicki DM. Overview of current learning theories for medical educators. Am J Med 2006;119(10):903–907
  PubMed
• 41 Eyal K, Rubin AM, Eyal K, Rubin AM. Viewer aggression and homophily, identification, and parasocial relationships with television characters viewer aggression and homophily, with television characters. J Broadcast Electron Media 2010. Doi: 10.1207/s15506878jobem4701
  PubMed
• 42 Randhawa G. OSCAR EMR study recruitment video. 2017. Available at: https://www.youtube.com/watch?v=zNQTWEyNU2c&feature=youtu.be . Accessed August 9, 2019
  PubMed
• 43 Singer A, Ivers NM. Using your electronic medical record to deliver evidence-based diabetes care. Can Fam Physician 2019;65(01):43–44
  PubMed
• 44 PAHO. The chronic care model. 2013. Available at: https://www.paho.org/hq/index.php?option=com_content&view=article&id=8502:2013-the-chronic-care-model&Itemid=1353&lang=en . Accessed April 4, 2016
  PubMed
• 45 Randhawa G, Yap J. OSCAR EMR video tutorial series. 2017. Available at: https://www.youtube.com/playlist?list=PLqNVRTDyA_99lsQzVXz4K3X8VvZr7oUXZ . Accessed September 27, 2017
  PubMed
• 46 QSR International Pty Ltd. NVivo qualitative data analysis software, version 10. 2012. Available at: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3930250/ . Accessed February 12, 2014
  PubMed
• 47 Grol R, Wensing M. What drives change? Barriers to and incentives for achieving evidence-based practice. Med J Aust 2004;180(S6):S57–S60
  PubMed
• 48 Østbye T, Yarnall KSH, Krause KM, Pollak KI, Gradison M, Michener JL. Is there time for management of patients with chronic diseases in primary care? Ann Fam Med 2005;3(03):209–214
  PubMed
• 49 Ajami S, Bagheri-Tadi T. Barriers for adopting electronic health records (EHRs) by physicians. Acta Inform Med 2013;21(02):129–134
  PubMed
• 50 Shuval K, Berkovits E, Netzer D, et al. Evaluating the impact of an evidence-based medicine educational intervention on primary care doctors' attitudes, knowledge and clinical behaviour: a controlled trial and before and after study. J Eval Clin Pract 2007;13(04):581–598
  PubMed
• 51 Bailey CJ, Aschner P, Del Prato S, LaSalle J, Ji L, Matthaei S; Global Partnership for Effective Diabetes Management. Individualized glycaemic targets and pharmacotherapy in type 2 diabetes. Diab Vasc Dis Res 2013;10(05):397–409
  PubMed
• 52 Levey AS, Coresh J. Chronic kidney disease. Lancet 2012;379(9811):165–180
  PubMed
• 53 United Nations Educational Scientific and Cultural Organization. What are open educational resources? 2017. Available at: https://en.unesco.org/themes/building-knowledge-societies/oer . Accessed May 7, 2020
  PubMed
• 54 Shachak A, Reis S, Gray K, et al. Evaluating educational interventions for health professions in the digital age. In: Shachak A, Borycki EM, Reis SP, eds. Health Professionals’ Education in the Age of Clinical Information Systems, Mobile Computing and Social Networks. Amsterdam, Netherlands: Elsevier Inc.; 2017:471–488
  PubMed