A qualitative study to identify barriers to deployment and student training in the use of automated external defibrillators in schools
© The Author(s). 2017
Received: 8 July 2016
Accepted: 3 January 2017
Published: 19 January 2017
Student training in use of automated external defibrillators and deployment of such defibrillators in schools is recommended to increase survival after out-of-hospital cardiac arrest. Low implementation rates have been observed, and even at schools with a defibrillator, challenges such as delayed access have been reported. The purpose of this study was to identify barriers to the implementation of defibrillator training of students and deployment of defibrillators in schools.
A qualitative study based on semi-structured individual interviews and focus groups with a total of 25 participants, nine school leaders, and 16 teachers at eight different secondary schools in Denmark (2012–2013). Thematic analysis was used to identify regular patterns of meaning using the technology acceptance model and focusing on the concepts of perceived usefulness and perceived ease of use.
School leaders and teachers are concerned that automated external defibrillators are potentially dangerous, overly technical, and difficult to use, which was related to their limited familiarity with them. They were ambiguous about whether or not students are the right target group or which grade is suitable for defibrillator training. They were also ambiguous about deployment of defibrillators at schools. Those only accounting for the risk of students, considering their schools to be small, and that time for professional help was limited, found the relevance to be low. Due to safety concerns, some recommended that defibrillators at schools should be inaccessible to students. They lacked knowledge about how they work and are operated, and about the defibrillators already placed at their campuses (e.g., how to access them). Prior training and even a little knowledge about defibrillators were crucial to their perception of student training but not for their considerations on the relevance of their placement at schools.
It is crucial for implementation of automated external defibrillators in schools to inform staff about how they work and are operated and that students are an appropriate target group for defibrillator training. Furthermore, it is important to provide schools with a basis for decision making about when to install defibrillators, and to ensure that school staff and students are informed about their placement.
KeywordsAutomated external defibrillator Defibrillators Cardiopulmonary resuscitation Resuscitation Out-of-hospital cardiac arrest Training Schools Technology acceptance model Implementation
Out-of-hospital cardiac arrest (OHCA) is a major public health problem that can strike seemingly healthy individuals of any age, often without warning . In Europe, the survival rate following OHCA is only ≈ 10% and costs 350,000 lives each year . It has been known for more than two decades that bystander cardiopulmonary resuscitation (CPR) before the arrival of emergency medical services (EMS) increases survival rates 2–4 times [3, 4]. While CPR can extend the window for successful defibrillation, it is only defibrillation that can re-establish a normal, spontaneous heart rhythm , and survival rates >50% have been documented when an automated external defibrillator (AED) is used . However, research suggests that bystanders face barriers in attempting resuscitation, especially concerning the use of AEDs [4, 6].
According to the World Health Organization, the American Heart Association (AHA), and the Institute of Medicine, school-based CPR and AED training are key strategies to increase bystander intervention [1, 2, 7–10]. Training students in CPR and AED use has become mandatory or at least recommended in several countries [2, 7, 10], but even in countries like Denmark that have mandatory resuscitation training in schools, low implementation rates have been observed, particularly for AED training [11, 12]. Previous studies have identified barriers to the implementation of CPR training in school such as perceived need for extensive CPR instruction skills, need for training material, excessive consumption of teaching time, and excessive costs [11–17].
Cardiac arrests in schools are rare events, but the death of a seemingly healthy young person can be especially devastating for the family and local community. Schools with an AED on campus have demonstrated high survival rates for students as well as adults who suffer cardiac arrests [1, 18]. For this reason, there is a growing trend towards placing AEDs in schools [1, 18, 19]. Nevertheless, far from all schools have an AED at campus, and even at campuses with an AED the problems of infrequent application, delayed access to the device, and delayed defibrillation have been observed [1, 20]. Limited funds have been pointed out as the main barrier for widespread implementation [1, 18, 20, 21].
No studies have directed their focus on barriers specifically connected to implementation of AED training of students, and little is known about the barriers to deployment of AEDs at schools. These barriers are likely related to school leaders’ and teachers’ perspectives since they are important actors in the implementation of school changes. Moreover, the national legislation in many countries holds school leaders responsible for ensuring resuscitation training of students and expects teachers to play an important role in the training [11, 15, 22]. Experts do also recommend that teachers conduct the training [7, 23]. The technology acceptance model suggests that the acceptance, adoption, and use of a new technology − in this case the AED − are determined by perceived usefulness and perceived ease of use [24, 25]. By employing the concepts of the technology acceptance model, this study explores school leaders’ and teachers’ perceptions of AEDs to understand more clearly the barriers to implementation of student AED training and AED deployment in schools.
This qualitative study was based on interviews with school leaders and teachers and was carried out during November 2012 to January 2013 at secondary schools in Denmark (6th- to 9th- grade students, age 12 to 16). We used qualitative methods because our aim was to reach an in-depth understanding of the problem and not to measure factors identified in prior research. Qualitative methods are best suited to elicit meaning and experience from the participants’ point of view and when seeking to describe the complexity of a problem and to reveal issues that the researchers may not have anticipated [26–28].
There are approximately 5,6 million people in Denmark and 3500 people are treated annually following OHCA. While the bystander CPR rate has improved significantly from 21% in 2001 to 45% in 2010, the use of defibrillation has remained low at only 2% despite a rapid increase in public access AEDs. In the same period, the 1-year survival increased from 3 to 10% . In 2016, over 14,000 AEDs were registered in the Danish nationwide AED network . There are approximately 2000 secondary schools in Denmark, with around 250,000 students (6th-9th grade) and 22,000 teachers , and in 2013 about half of schools had an AED deployed at campus . There is no systematic CPR/AED training of school leaders and teachers in Denmark. It is not compulsory at the teachers college , and it is up to the individual municipality and school to decide whether to offer such education.
Sampling of participants
Main characteristics of the study participants
School leaders ( n = 9)
Teachers ( n = 16)
Years at the school
Yes, incl. AED use
Yes, excl. AED use
Years as member of the school leadership
Semi-structured interview protocol showing the AED specific questions
1) What comes to your mind, when I say AED?
2) What do you know about AEDs?
3) Do you have an AED at the school?
4) Can you imagine AEDs as part of the CPR training of students?
5) What do you think other teachers, students, parents etc. will think about it?
6) Do you have any experiences with AED training of students?
7) What is your opinion about deployment of AEDs in public places?
Theoretical framework and analysis
Data analysis procedure
The interviews were transcribed (LZ) and read repeatedly by two researchers (LZ and CMH) to gain an overall impression and become familiar with the data’s diversity. The two researchers independently used open coding for each paragraph to discover categories, characteristics, and dimensions of the material  and thereafter met to discuss and refine the categories.
The categories were discussed with the multidisciplinary research team that included professionals from anthropology (TTT and MHR), medicine (CMH, FF and CTP), and public health (LZ). The coding manual was developed by linking categories into major themes with subthemes (LZ, SMR, TTT, and MH). In this process, we applied the technology acceptance model [24, 25] as a framework for the empirical categories.
The data was coded according to the manual (LZ and SMR). As such, the coding was driven by theory as it was organized according to the theoretical categories in the technology acceptance model (e.g., the perceived usefulness of AED training of students and the perceived usefulness of AED deployment at school). But the coding was also data driven as additional themes and subthemes that had emerged from the data were applied (e.g., knowledge and experience with AEDs).
Information for each theme was extracted from all of the interviews, and quotes were selected based on how well they illustrated and elucidated the themes (LZ).
We looked at relations between the themes
The results are presented according to three main themes: AEDs as challenging life savers, AED training at schools, and AED deployment at schools. The concepts of ‘perceived usefulness’ and ‘perceived ease of use’ are employed in each of these themes.
AEDs as challenging life savers
It's insanely important [with AEDs] when you come from here where there isn’t much. If you live in [name of village], it takes several hours before the arrival of an ambulance. (Teacher 3, School 6, Not AED trained)
That is why it’s great with the defibrillator nowadays because it works 10 times better than ventilations and chest compressions, or at least chest compressions, because that is really physically demanding. (Teacher 4, School 8, AED trained)
I have no idea. I should say. The courses I have taken haven’t [included AED training]. I don’t know. I have no idea. I wouldn’t know how to use it. I would hope for a written instruction to be able to do a little. (School Leader, School 7, Not AED trained)
Another contributing factor to this was school leaders’ and teachers’ knowledge about AEDs traditionally being used by health professionals only. Most would feel uncomfortable using an AED without prior instruction, and some even expected training to be necessary for using one.
I think you should be familiar with it [the AED] because if you have to study it on the wall in a panic situation, I think it would not be particularly smart. It wouldn’t be smart for me. I would run around in circles. I wouldn’t even remember one line. (Teacher 2, School 7, Not AED trained)
It [the AED] may not do any good if something has to be done in a special way. Otherwise, you risk causing harm. That was not the intention. It was the opposite you wanted to achieve. […] It is not of any use that you have the best intentions but end up killing the man. (Teacher 2, School 7, Not AED trained)
Before I attended all this [CPR/AED training], I'm not sure I would dare to open it [the AED]. Because will it provide a shock immediately, or what does it do, or should I be careful not to touch it with two hands, or should I sit down, or should I… There are so many things with this device where you would think, Hmmm. (School Leader, School 8, AED trained)
Just that information is enough to … Now you are not nervous of doing anything wrong. But when you don’t know better, then you think, Wow! (Teacher 2, School 7, Not AED trained)
It is limited how much wrong you can do when providing rescue breathings or artificial ventilation and things like that. And it’s probably, or it is the same with the AED. But now you are suddenly applying a device instead of yourself and doing something to another human being. (School Leader, School 5, Not AED trained)
Thus, knowledge and AED training seemed to be crucial for school leaders’ and teachers’ perception of the ease of use of and potential harm by AEDs, yet the insecurity caused by the technical aspect of the AED remained.
AED training at schools
No. of interviewees
CPR training of students
AED training of students
Location of the AED
Number of studentsa
Distance from a hospitalb
Urban or rural
1 school leader
School and sport facility
1 school leader and 1 teacher
1 school leader and 5 teachers
1 school leader
School leader does not know
School leader does not know
1 school leader
2 school leader and 3 teachers
1 school leader and 3 teachers
1 school leader and 4 teachers
It is only natural that it [the AED] is part of the [resuscitation] training. You have to follow the development. And if that’s what it takes to save more lives, then it's just fine. (Teacher 1, School 1 AED trained)
It’s natural, because there are more and more AEDs around. Thus, it would be completely illogical to do without it. (Teacher 3, School 8, AED trained)
It might have been red, the one they [the students] trained with, but this one is green, but they will still remember to open it up and that it says something where others might not dare to open it because, ‘Does it shock me? What happens?’ Just the fact that they have heard about it, have received the training here in school, is enough for them to dare to start up. (School Leader, School 8, AED trained)
Regarding training of the children, I actually do not know. I would say, ‘Let me see how relevant is it for the students and which age group’ … There is no need to train children in kindergarten who don’t understand what this is all about. You know about it. Would 8 th and 9 th grade be appropriate? Would they be able to use it? (School Leader, School 7, Not AED trained)
Hmm … There are a few [students], I would rather not see with an AED in their hands. I don’t think John should try that. No, I cannot imagine that. I think it needs to be in high school. (School Leader, School 5, Not AED trained)
I think it has something to do with… That when it is rescue breathings and chest compressions, it is such a hands-on thing where the AED is a machine, which they [the students] have to pull down from the wall, and then it has such a funny computer voice. I think they will distance themselves more from it because it is a machine. But it’s only a hunch. I don’t know at all. (Teacher 3, School 3, AED trained)
I really believe that the technical use of it [the AED]… I think children would be able to do that and many of them even faster than us. That is what we can see with everything else, they get in their hands. Pacifiers in their mouths and up we go in front of the computer. (Teacher 2, School 7, Not AED trained)
It's not like there is a special reaction [from the students] when it is about AEDs [compared to CPR training]. (Teacher 5, AED trained)
The interviewees (both AED trained and not AED trained) emphasized the need for the AED to be included in CPR-training material in order for it to become a natural part of resuscitation training. Those using such materials also explained how this had facilitated the AED to be included in the training.
AED deployment at schools
I have thought about… I see it [the AED] every morning. I wonder if it is locked. It surely cannot be locked if I suddenly need it immediately. (Teacher 2, Not AED trained)
I just think that there is a long distance to the oldest students. (Teacher 3, Not AED trained)
It’s something like, I start with chest compressions, and then another one has to run to get it. (Teacher 2)
You just have to find someone who has the key if it’s locked. (Teacher 1, Not AED trained)
It better not be. You can see how little we know about it. We know nothing about it. (Teacher 2)
I suppose it’s sealed like our fire equipment. (Teacher 1)
I'm not sure I would dare to have it [the AED] placed so they [the students] could access it. (Teacher 3, School 7, Not AED trained)
If we should have one [an AED], I always think like that in a school such as ours. I don’t know. Someone may be able to say whether that is reasonable. The probability of it being used with 400 children is not very big. However, there are many adults. I would probably be the first. (School Leader, School 2, Not AED trained)
It has also something to do with the size of the school. I cannot understand why there isn’t an AED in a school or at other institutions where there are so many people. (Teacher 2, School 7, Not AED trained)
Perhaps it would be a little bit of overkill [to have an AED]. We have a hospital over there and another hospital is 45 s away if they are fast. That should also be taken into account. (School Leader, School 5, Not AED-trained)
School leaders and teachers found the usefulness of AED deployment at schools to be low if they did not take others’ risk of having a cardiac arrest into account (other than students), considered their school to be relatively small, and perceived time to professional help to be short (based on distance from the nearest hospital). They did not reject the idea but requested expert opinions on whether or not they should have AEDs placed at their school. Their considerations on this matter did not seem to be influenced by prior AED training. Nonetheless, one teacher expressed that it would be useless to have an AED at the school if no one were trained in how to use one. The interviewees only rarely mentioned the cost of AEDs as a barrier for placing them in schools. In one focus group, teachers had not received an AED after requesting their school leader for one, and they believed the costs had been decisive but had not been given an explanation. A school leader at another public school asked the interviewer about the price of an AED, and when the interviewer gave him an approximate price, he stated that this was no obstacle for the school to purchase a couple of AEDs.
School leaders and teachers are concerned with the perceived ease of use of AEDs. They believe that AEDs are potentially dangerous, overly technical, and difficult to use. This was related to their familiarity with AEDs, which was generally low. For instance, few knew how AEDs work and are operated. They were therefore ambiguous about whether or not secondary school students (6th- to 9th-grade students, ages 12 to 16) are the right target group or which grade is suitable for AED training, even though they perceived the training to be useful. School leaders and teachers were also ambiguous about AED deployment at schools, which was rooted in their perceived usefulness of such an initiative. Those only accounting for the risk of cardiac arrest among students, who considered their schools to be small and thought that the time of arrival of professional help was short, found the relevance of AEDs at schools to be low. Furthermore, due to the perception of the AED being potentially dangerous, some recommended that AEDs at schools should be unreachable to students. Interviewees lacked information on the AEDs placed on their campus (e.g., how to access the devices). Prior training and even a little knowledge about AEDs (e.g., that they cannot cause harm) were crucial for school leaders’ and teachers’ perceptions of AED training of students but not for their considerations on the relevance of AED placement at schools.
Discussion of findings
AED training of students
We found that school leaders and teachers are concerned about the ease of use of AEDs including the safety aspect of AEDs and the issue of AEDs being technical and difficult to use. This mindset resulted in uncertainty about what student grades should receive AED training and if secondary school students were too young to be trained in how to use an AED. Several studies have demonstrated that AEDs can be safely and effectively used by people with little or no prior training [34–37] and also by children . In simulation training studies, even children of 6–7 years have been found capable of quickly delivering a shock with minimal training . However, there are no clear recommendations on what grade should undergo AED training in schools, and no studies have extensively discussed at what age children should be encouraged to use AEDs in real-life situations . It is also noteworthy that medical experts have previously had the same concerns towards AEDs and have urged caution against allowing AEDs to be used by the general public . It was not until 2000 that the AHA clearly acknowledged the value of AEDs and their safety for lay rescuers . Thus, it is not surprising that school leaders and teachers have reservations towards AED training of students, especially given their limited knowledge of AEDs and the lack of clear guidelines on an appropriate target group for AED training. According to our study, AED training and information about how AEDs work and are operated is crucial since even minimal knowledge was critical for their perception of AED student training. On the other hand, the technical aspect of AEDs caused insecurity among some school leaders and teachers, and they therefore expected students to be apprehensive towards AED training. This insecurity did not seem to be affected by previous AED training. School leaders and teachers with actual experience with AED training of students had not experienced any special reactions from students regarding the AED.
We found that school leaders and teachers disagreed on the usefulness of AEDs placed at schools. None rejected the idea but requested expert opinions on whether or not it was relevant and questioned if they should have an AED at their school. The AHA recommends the deployment of AEDs in schools with a documented need, that is, schools with at least one of the following criteria: (1) frequency of use is such that there is reasonable probability of use within 5 years, (2) children or adults attend the school who are thought to be at high risk for cardiac arrest, and (3) an EMS call-to-shock interval of <5 min cannot be reliably achieved . The contents of these recommendations resemble school leaders’ and teachers’ considerations about the relevance of AED placement at schools. We found that these were centred on the probability of the AED being used (risk assessment of cardiac arrest, number of people at the school, and evaluation of time to professional help). However, it was unclear as to how interviewees evaluated these factors, for instance, what they based their risk assessment on and when they considered time of arrival of professional help to be too long. Moreover, their estimation of EMS response time was misunderstood, for they based this on distance to the nearest hospital and not to the nearest EMS station. We found that perceived usefulness of the AED in the minds of school leaders and teachers was the main challenge for deployment of AEDs at schools. In the literature, there seems to be consensus regarding lack of funding as the primary obstacle, which was built upon several quantitative studies that cited this issue to be the most frequent barrier [1, 18]. However, our study could not confirm these findings since the cost of AEDs were rarely mentioned as a barrier for placing AEDs at schools. The perceived relevance of AEDs at schools (or lack thereof) may have been an underlying mechanism for claiming lack of funding as a barrier in previous studies. After all, this idea might have influenced interviewees’ thoughts on how to prioritize finances and time to apply for funding. Our study further demonstrates challenges with AEDs already installed at schools since school leaders and teachers lack information about location, accessibility, and proper use of AEDs. Many do not know if they can access AEDs or know how to access them and are uncertain about how to use them. They are also insecure about using them without prior instruction, and some are even unaware of the presence of the AEDs in their schools. In line with this, previous studies among American college and university students have demonstrated that the vast majority lacked knowledge of the location of AEDs within their own campuses [42, 43]. We also found that school leaders and teachers recommended that AEDs at schools be unreachable to students due to safety concerns. This may, to some extent, explain why previous studies have found that even with an AED installed at the school, AED application was infrequent [20, 44].
In order to strengthen implementation of student AED training, it is important to disseminate information on how AEDs work and are operated. In addition, AED training should be incorporated in CPR courses of school staff, and staff members should be informed that school students are appropriate recipients of AED training. Future studies should investigate at what age AED training in schools is most suitable and at what age children should be encouraged to use AEDs in real-life situations. To reach successful implementation of AED deployment in schools, schools should be provided with a basis for decision-making about when to install an AED. Authorities should thus provide clear recommendations such as those by the AHA . It is additionally important to prepare schools for how to assess such criteria (e.g., if there are children or adults at the school who are at high risk of cardiac arrest). Schools should also be informed about the importance of ensuring easy access and information to the entire school staff and students about AEDs already installed at their facilities. Our findings provide a strong basis for future quantitative studies which may investigate the generalizability of this study. Together with this study, it would provide solid knowledge to be disseminated to schools and decision makers and to be used as a basis to develop new interventions and initiatives seeking to improve implementation of student AED training and AED deployment in schools. Importantly, our findings also contribute with insight into more general aspects of AED implementation such as the consistently low use of public access AEDs [4, 6] as many of the barriers identified in our study reach beyond the school setting. We found that it is of utmost importance to familiarize lay persons to AEDs. This is supported by a recent study suggesting that prior knowledge and hands-on AED training promoted confidence and prevented panic among lay bystanders in real cardiac arrest situations . Thus, in addition to ensuring placement, accessibility, and visibility of AEDs, it is important to increase bystander willingness to use them. Successfully implementing student training in AED use will contribute to reaching this goal by ensuring that the general public has been familiarized with AEDs.
Strengths and limitations
By using qualitative methods, we were able to reach an in-depth understanding of why implementation of AED training of students has been unsuccessful in Denmark, and to describe school leaders’ and teachers’ complex and ambiguous relationships towards the deployment of AEDs at schools. The character of qualitative research has also been pointed out to contribute to a broader and improved understanding within medical research, including implementation science [26, 27]. We managed to obtain a broad representation of schools and interviewees, successfully portrayed different positions, and reached data saturation, which is defined as the point at which no new relevant data emerges . Nevertheless, we acknowledge that it can be difficult to determine data saturation, and that it is possible that our understanding could have been expanded if we had conducted more interviews with a wider variety of teachers and shool leaders. Also, the perceptions of AEDs in general could have changed since the interviews were conducted in 2012–2013. Furthermore, context-specific considerations should, as always , be taken into account when applying our findings to other settings. This is because the Danish school system or the public’s knowledge and ideas regarding AEDs cannot be generalized for all communities.
School leaders and teachers are ambiguous about whether or not secondary school students is an appropriate target group and do not know what grade is suitable for AED training. This was connected to their perceived ease of use of AEDs. They were also ambiguous about AED deployment at schools, which was rooted in their perceived usefulness of such an initiative, and some recommended that AEDs at schools should be unreachable to students. Moreover, school leaders and teachers only had limited knowledge about the AEDs installed at their schools. Prior training and even a little knowledge about AEDs (e.g., that they cannot cause harm) were crucial for their perceptions of AED training of students but not for their considerations on the relevance of AED placement at schools. In light of our findings, the successful implementation of AEDs in schools (both student AED training and AED deployment) requires school staff to be informed about how AEDs works and that AEDs cannot cause harm. They also must be trained in AED use. Authorities should systematically inform schools that students make for an appropriate target group for AED training and should also provide schools with a basis for decision-making about when to install AEDs. Finally, school staff and students should be informed of the location and accessibility of AEDs deployed in their schools.
Automated external defibrillator
American Heart Association
Emergency medical services
Out-of-hospital cardiac arrest
The authors are particularly grateful to the school leaders and teachers participating in the study. The authors would also like to thank Simone Mørk Rosenkranz for providing assistance with the development of the coding protocol and coding of the first three interviews.
This work was supported by the Danish Foundation TrygFonden (grant number 103291); and the Health Insurance Foundation, Denmark (grant number 2012B189). They had no influence on the study or in writing the manuscript.
Availability of data and materials
Data is not publicly available due to ethical considerations.
LZ drafted the manuscript and was involved in the study conception and design, data collection, transcription of the interviews, analysis and interpretation of data, and editing of the manuscript. CMH was involved in the study conception and design, data collection, analysis and interpretation of data and critically revised the manuscript. MH was involved in the study analysis and interpretation of data and critically revised the manuscript. FF and CTP were involved in the study conception, design and analysis and critically revised the manuscript. TTT was involved in the study conception and design, analysis, and interpretation of data and critically revised the manuscript. All authors have read and approved the final manuscript.
The authors declare that they have no competing interests. C. Malta Hansen reports receiving research grants from The Laerdal Foundation.
Consent for publication
Ethics approval and consent to participate
The study was approved by the Danish Data Protection Agency J.nr. 2012-54-0217 for safe handling and storing of data. This type of study does not require formal ethical approval in Denmark . All participants were informed about the aim of the study and were assured that participation was voluntary, that results would be anonymous, and that we had no intention of evaluating any specific school, school leader, or teacher. We obtained verbal consent from all participants in the study.
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