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What is known about the quality of out-of-hospital emergency medical services in the Arabian Gulf States? A systematic review


Authors: H. N. Moafa aff001;  S. M. J. van Kuijk aff003;  G. H. L. M. Franssen aff004;  M. E. Moukhyer aff005;  H. R. Haak aff002
Authors place of work: Faculty of Public Health and Tropical Medicine, Jazan University, Jazan, Saudi Arabia aff001;  CAPHRI Care and Public Health Research Institute, Maastricht University, Maastricht, The Netherlands aff002;  Department of Clinical Epidemiology and Medical Technology Assessment, Maastricht University Medical Centre+, Maastricht, The Netherlands aff003;  Maastricht University Library, Maastricht, The Netherlands aff004;  Faculty of Applied Medical Sciences, Jazan University, Jazan, Saudi Arabia aff005;  Department of Internal Medicine, Maxima Medisch Centre, Eindhoven, The Netherlands aff006;  Division of General Internal Medicine, Department of Internal Medicine, Maastricht University Medical Centre+, Maastricht, The Netherlands aff007
Published in the journal: PLoS ONE 14(12)
Category: Research Article
doi: https://doi.org/10.1371/journal.pone.0226230

Summary

Background

The Emergency Medical Services (EMS) have been developed in the Arabian Gulf States (AGS) in the last three decades. The EMS needs continuous quality assessment of their performance to improve and provide the best out-of-hospital care. This study aims to assess the quality of EMS in the AGS according to the six quality domains of the Institute of Medicine.

Methods

We searched four databases (i.e., PubMed, EMBASE, Web of Science, and CINAHL) for studies that reported on the quality of EMS in any of the AGS using clinical or non-clinical performance indicators. To quantify study quality and risk of bias, the adapted Newcastle Ottawa Scale was used. We focused on structural and functional indicators, clinical and non-clinical.

Results

Twenty-five studies were eligible for inclusion. One study contained result of safety, fifteen time-centeredness, twenty effectiveness, five patient-centeredness, and thirteen studies reported on equity of EMS. None of the studies reported on efficiency of EMS. A significant proportion of studies showed high scores on the Newcastle-Ottawa scale. Limited studies on EMS quality were available, not covering all relevant quality domains and not covering the whole AGS region. The equity domain showed the best outcome performance finding, whereas finding of the patient-centeredness domain showed room for improvement in the foreseeable future.

Conclusion

This review highlights the need for more and better studies of sufficient quality about all domains of quality in EMS in all the AGS. EMS research in Kuwait and Bahrain is warranted, as currently studies of EMS quality are unavailable for these States. Moreover, efficiency researches exploring this discipline should be conducted specially no studies were found has been searching this domain.

Trial registration

PROSPERO registration number: CRD42019123896.

Keywords:

Death rates – Critical care and emergency medicine – Hospitals – Transportation – Ambulances – Intubation – Kuwait – Medical services

Introduction

The Arabian Gulf States (AGS) are composed of six nations (i.e., Saudi Arabia [SA], Oman, the United Arab Emirates [UAE], Qatar, Kuwait and Bahrain). These countries provide Emergency Medical Services (EMS) for all different levels of emergency in all regions. They have full collaboration with all governmental and non-governmental health sectors e.g. Primary Health Centers and Hospitals, and also with non-health sectors such as Civil Defense, Polices, and Municipalities. In Addition, they have many types of ambulance vehicles equipped with prescribed standards such as defibrillators, ventilators, and cardiac resuscitation medications. They triage cases based on a specific triaging system guideline to identify the emergency severity and urgency level. They then dispatch the appropriate vehicle(s), through utilizing a Computer Aided Dispatch System (CAD), to the scene from one of many scattered ambulance stations. All EMS providers in AGS can treat patients on the scene without transporting them once their clinical condition does not urge the necessary transportation. Additional characteristics of EMS stratified by country are shown in S1 Table. The EMS in SA is provided at no direct cost to the general public by the Saudi Red Crescent Authority (SRCA), and has played a critical role in assuring the local public that medical aid is readily available and just a phone call away regardless of the distance.[1]

The EMS in the AGS, like that of any nation, needs continuous quality assessment of their performance indicators, so that they can provide the best possible out-of-hospital care. In 2001, the National Academy of Medicine (NAM) formerly known as Institute of Medicine (IOM), identified 6 quality domains for improving health care systems: safety, time-centeredness, effectiveness, patient-centeredness, efficiency, and equity.[2, 3] The World Health Organization (WHO) highly recommends these domains for national health systems and policy makers to reform and optimize outcomes.[4]

In some other parts of the world, institutions provide guidelines and recommendations to aid in obtaining the highest quality of EMS. For example, the Joint Royal College Ambulance Liaison Committee (JRCALC) in the United Kingdom provides guidance to general practitioners, Out-of-Hospital care providers, ambulance technicians, and paramedics. Its guidelines provide valuable information and treatment algorithms to follow in case of emergency events, such as acute coronary syndromes (ACS), asthma, abdominal pain, trauma and many others.[5] The US has The American Ambulance Association (AAA),[6] and the National Association of State EMS Officials (NASEMSO),[7] both of which play a pivotal role in promoting high-quality care for acutely ill and injured clients, improving the quality and efficiency of state EMS program administration. No such organizations are available for the AGS, nor has much research been performed to quantify and compare performance indicators for the current state of the EMS in the AGS on the whole.

The aim of this study is to assess the quality of EMS systems in the AGS according to the six quality domains of the IOM. To do so, we performed a systematic literature review and identified quality indicators of the six predefined quality domains.

Materials and methods

This review was reported in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement, see S2 Table, PRISMA 2009 checklist.[8] A protocol for this review was registered with PROSPERO, an international database of prospectively registered systematic reviews. (record CRD42019123896; CRD = Centre for reviews and Dissemination).

Search strategy

We considered studies eligible for inclusion if they reported on the quality of EMS in any of the AGS using performance indicators. Studies were excluded if they were not written in English or Arabic, they solely investigated the quality of intra-hospital emergency healthcare, or if they focused on intra-hospital patient’s transportation. The search was carried out in four databases (i.e., PubMed, EMBASE, Web of Science, and CINAHL) from inception up to June 1st, 2019. In each database, a sensitive search was performed using the following search term domains: emergency medical services, quality, and region. A fully reproducible search can be found in S3 Table.

Study selection

Two authors (HM and SvK) independently screened for potentially eligible articles based on titles, abstracts and, if necessary, full text. Additionally, the reference sections of all selected manuscripts were screened for studies that might have been missed with the search strategy. In case of disagreement, consensus was reached by discussing the study in the study group during a face to face meeting. Fig 1 shows the search results per search engine and the process of exclusion of irrelevant articles.

Fig. 1. Flow chart of study selection process.
Flow chart of study selection process.

Data extraction

All relevant data of the studies eligible for inclusion were extracted, i.e.: authors, date of publication, country or countries in which the study was performed, study design, particulars of the EMS, process and outcome measures that were relevant for any of the following domains of quality of care: safety, time-centeredness, effectiveness, patient-centeredness, efficiency and equity. To quantify study quality and risk of bias for all of the evaluated studies, the Newcastle Ottawa scale was used after it was adapted by Herzog et al.[9] The adapted Newcastle Ottawa scale consists of items to measure the quality of cross-sectional and cohort studies.

Data synthesis

Meta-analysis has not been considered due to the heterogeneity of study objectives, and design.

Results

The initial search identified 5226 references. In total, 554 duplicated records were removed. After applying the exclusion criteria in the primary screening by title and abstract, we removed another 4,615 records. Next, we read the remaining fifty-seven articles. As a result of the secondary screening, we excluded thirty-two studies because they were not related to the quality of out-of-hospital emergency medical services in the AGS. Finally, twenty-five studies were included for this systematic review. Nineteen out of these twenty-five studies were conducted in one of four different States: eight in SA, four in UAE, five in Qatar, and two in Oman. In addition, two studies were conducted in multiple Asian countries, and included data from the UAE-Dubai ambulance system. The other studies provided data of multiple Gulf States together. Studies from Kuwait and Bahrein were not available. The included studies are summarized in Table 1.

Tab. 1. Characteristics and data extraction of the included studies.
Characteristics and data extraction of the included studies.

Table 2 shows the results of applying the Newcastle-Ottawa scale to the included studies. Ten studies were scored on a six-point scale because multiple items were not relevant for those specific studies. The remaining fifteen studies were scored on an eight-point scale. The item pertaining to the Ascertainment of Exposure was not applicable to any of the included studies, so it was omitted from the scale entirely. The item on comparability between the respondents and non-respondents was applicable to only fourteen studies of which eleven failed to report anything concerning that item. Most studies scored well on the following items of the Newcastle-Ottawa scale: representatives of the sample, sample size, and the use of a validated measurement tool. Moreover, the reliance of many studies on data registries is associated with a low probability of bias while the reliance of few studies on self-reporting might introduce self-selection bias.

Tab. 2. The result of the critical appraisal for the included studies based on the adapted Newcastle-Ottawa scale.
The result of the critical appraisal for the included studies based on the adapted Newcastle-Ottawa scale.

All the included studies were evaluated according to the six quality domains defined by the NAM (safety, time-centeredness, effectiveness, patient-centeredness, efficiency, and equity). A brief summary of the most relevant results stratified by these quality domains is shown in Table 3.

Tab. 3. Summary of findings related to the six different quality domains.
Summary of findings related to the six different quality domains.

Safety

Only one study reported results that were relevant for the Safety domain.[19] This study from SA showed that 98% of EMS providers who participated dispatched clients who were having a stroke to the nearest hospital without considering the availability of stoke treatment facilities (i.e. that have radiological and therapeutic interventional ability).

Time-centeredness

Seven studies reported response times specifically for life-threating cases with emergency level one such as Out-of-Hospital Cardiac Arrest (OHCA), ACS, and stroke, and two measured all emergency cases’ response times. [1829,12,24,32,34] In addition, three studies measured the total EMS time. Response time is defined as the period of time that begins with EMS activation (i.e., a phone call to the dispatcher) and ends with the arrival at the location of the patient. Total EMS time is the response time plus the time to deliver the patient to the hospital. The median response time for OHCA varied between 8.7 min in Qatar and 9 min in the UAE.[20,29] In Qatar, the median total EMS time was 60.5 min (range: 3 to 160) for trauma clients who died on the scene or during transportation to the ER.[10] One study found the response time in Riyadh, SA to be 10.23 min on average.[11] Another SA study reported that 81% of calls were responded to within twenty-five minutes or less and 65% were responded to in fifteen minutes or less.[18] A Saudi study conducted in Jeddah, found the majority of civilians estimated that the response time of an ambulance to their home would be about thirty minutes or more in SA.[28]

The time to get access to hospital facilities was evaluated after clients had been delivered to the ER by EMS. One study conducted in the UAE found EMS transportation was associated with a shorter time to treatment in the hospitals when compared with other modes of transportation.[24] A study conducted in multiple countries of AGS to compare the usage of private transportation Vs EMS for clients with ACS found that among EMS transported clients, reperfusion therapy was significantly less likely for ST-elevated myocardial infarctions (STEMI) and for left bundle branch block (LBBB) clients compared to other modes of transport due to the major delay from the onset of clients’ symptoms to ER arrival (20% vs. 31%: P<0.001).[27] A study in multiple Gulf States (excluding SA, but including Yemen, which is not a gulf state member) compared the demographic and clinical characteristics of STEMI clients who received timely primary percutaneous intervention (pPCI). They reported door to balloon time (D2B) ≤ 90 minutes versus delayed pPCI (D2B > 90 minutes). Compared to being transported by private means, an ambulance ride was associated with shorter D2B, but this was not statistically significant (30 of 45 [66.7%] patients transported by ambulance had a D2B ≤ 90 minutes, 78 of 153 [51.0%] transported privately, P = .063). [33] Another study conducted in multiple AGS found that clients with STEMI, who arrived by EMS, had a significantly longer median interval from symptom onset to hospital arrival compared to clients transported by private means (184 vs 173 minutes; P = 0.018). However, a similar percentage of transported clients arrived at the ER within 12 hours of symptom onset in both groups. They also showed similar rates of receiving thrombolytic therapy but the median door-to-needle time was shorter for EMS-transported clients (35 vs 40 minutes, P = 0.01) However, they were less likely to receive primary percutaneous intervention (PCI) (26.7 vs 35.5%, P = 0.04). Furthermore, the authors found no significant difference in median length of stay for those who transport by EMS compared with private transport.[15] The last study found that the median time from symptom to ER was significantly shorter (144 minutes) for Out-of-Hospital EMS time when compared to private transportation (185 minutes), (P<0.001).[16]

Information about time management indicators stratified by urgency classification and triage was lacking in all of the included studies for this review.

Effectiveness

Twenty studies considered effectiveness of EMS.[1029,18,2432] The studies concentrated on topics such as the percentage of clients in life-threating situations that are taken to the hospital via EMS, interventional therapy provided by EMS providers during transportation, mortality and morbidity for EMS clients during transportation or after delivery to ER staff, and the outcomes of EMS clients such as resuming of spontaneous circulation (ROSC). In addition, results were presented on emergency medical technician (EMT) qualifications.

Regarding transportation rates, 17 to 25% of all ACS clients were transported by EMS in the AGS.[15,27] The overall transportation rate irrespective of the nature of the emergency was only 3.7% by Out-of-Hospital EMS, 22% inter-hospital EMS transportation, and 75% by private transport.[16] A study in multiple Gulf States compared two groups of clients. The first group of clients received timely pPCI (D2B ≤ 90 minutes) and were compared to delayed pPCI (D2B > 90 minutes). The study showed that the use of ambulance services was substantially low (<30%) in both groups.[33] Dhaffar et al. found that 2.5% of emergency room ER clients were transported by EMS to ER, while 97.5% came to ER by other means.[25] A study in Oman found that 33% of trauma clients were transported by EMS.[12] The percentage of clients with OHCA of cardiac origin that were transported by EMS was about 1.4% in Muscat, Oman, 33% in Riyadh, SA, 99.5% in UAE, and 100% in Qatar. For ACS clients it was 12% in the UAE, and 15% specifically in Abu Dhabi, UAE whereas 5.2% in SA.[1721,20,24,29] In the UAE, all pediatrics OHCA clients were transported by EMS.[34] The percentage of transported cases of OHCA after trauma was 66% in Riyadh, SA and 98% in Qatar.[21],[30] Furthermore, in Qatar, 91.3% of deceased clients had been transported by EMS.[10]

With regard to interventional procedures during transportation, one study found that not in all participating AGS Electro-Cardio-Grams (ECGs) were performed during EMS transportation.[16] In the UAE, no ECGs were performed for any patient during transportation.[24] In the SA, 94% of all EMS providers were unaware of the value of tissue plasminogen activator (t-PA) for stroke cases.[19] In Qatar, a study showed that 55% of clients in urgent need of endotracheal intubation were not intubated during transport.[13] Four studies conducted in Qatar and UAE showed partial protocol adherence; exemplified by the fact that not all of OHCA clients in these two countries received advanced cardiac life support (ACLS).[20,29,30,34]

Concerning the morbidity and mortality of clients who utilized the EMS, two studies used data of the Gulf State Registry, and three studies were conducted in UAE, Oman and in Qatar. They found that the mortality and morbidity are higher for the clients who were transported by EMS compared to private transport, but were unable to sufficiently control for confounding variables.[12,15,24,27]

Finally, five studies measured the ROSC rate of EMS clients before ER arrival. The result varied considerable from 0 to 13% (SA [adult] (0%), UAE [adults] (3.1%), UAE [pediatrics] (6%), Qatar [adult] (13%), and UAE-Dubai [adult] (13%).[20,21,29,32,34]

Patient-centeredness

Five studies discussed the patient-centeredness of EMS in AGS.[14,18,22,23,28] Two studies found that 33% and 55% of people did not know the emergency telephone number in SA and the UAE respectively.[23],[28] Regarding the client impression and satisfaction, Alrazeeni et al. showed that 54% of clients refused transportation of themselves or their relatives in SA.[18] Another study in SA showed that 70% of clients were satisfied about the services that had been given to them.[28] Furthermore, about 60% of paramedics from three major cities in SA reported that they felt that unfavorable impressions that people have of EMS affects their performance. A small percentage of the respondents (17.7%) reported the need for female paramedics to respond to female clients whereas 94% stated that ambulance by air was urgently needed.[14] While the other study related to the impression that civilians have of EMS in the UAE found that around half of clients did not prefer EMS transportation due to its slowness; others preferred private transportation because of easy accesses (13.4%).[23] In addition, a study in the UAE found that less than half of doctors working in a hospitals rated their satisfaction for EMS provider as ‘Somewhat satisfied’ (35%), or ‘very satisfied’ (7%). However, most participants were ‘very likely’ (67%) to advise a patient with a cardiac emergency to use EMS, but only (39%) felt the same for themselves or their family in case of ACS.[22]

Equity

Thirteen studies reported on equity.[1029,15,18,2125,27,3032,34] Males were far more prominent in demanding EMS services.[1029,15,18,2125,27,30,34] Socioeconomic status and its relation to citizenship also had a significant role in requesting EMS services. One study conducted in multiple AGS States found that only 17.5% of Gulf citizens used EMS during STEMI attacks, compared to 82.5% of non-citizens staying in the same States.

Furthermore, clients earning up to $5000 per month were more likely to take the EMS in case of STEMI compared to clients earning over $5000 per month (odds ratio [OR]: 1.6).[16] Two studies conducted in Qatar and one in the UAE showed that most non-Qatari (80%) and non-Emirati (83.3%) ethnicities utilized EMS transportation more than the Qatari and Emirati citizens.[20,29,30]

Efficiency

None of the included studies reported on characteristics of EMS relevant for this domain.

Discussion

In this systematic literature review we described the current status of the quality of EMS in the AGS. To the best of our knowledge, we are the first to do so. However, no studies included in this review described EMS quality for Kuwait or Bahrain. This could be due to their small geographical size and demographics. Even though one study from Kuwait was recently published that described the hospital’s response toward victims who had been exposed to a mosque bombing and showed that 67% of clients had been transported into emergency department of Kuwait hospital in less than 22 minutes, but this study did not provide information about the mode of transportation (EMS versus private vehicle). Therefore the study was excluded from analysis. [35]

Our review identified one study that looked at EMS safety.[19] This study shows inappropriate hospital transportation for stroke clients in SA. The Saudi Arabian Health System classifies hospitals into primary (public), secondary, and tertiary hospital according to the available capacity in terms of equipment, specific specialty, and availability of trained staff. For example, public hospitals in SA do not have technical equipment for the procedures of cardiac catheterization. Hence, clients who have ischemic heart attack would not benefit from the transportation to primary hospitals. Only secondary and tertiary hospitals have the capability of treating stroke clients because of availability of advanced radiology and fibrinolytic medication such as t-PA. Therefore, the different categories of hospitals require the SA EMS policy makers to educate their providers about different emergency cases continuously. They also need to help them to illustrate which hospitals are capable of treating so that the clients are not transferred to inappropriate facilities.

Other important safety findings, such as adverse event rate, wrong medication rate, patient fall rate, and incident report rate, were not available for any of the AGS. A scoping review of Fisher et al. illustrated that the cornerstone of safety assessment is the culture of reporting.[36] Hence, culture of reporting should be established in the AGS EMS systems, making it easier to assess safety in the future. Research should be developed with consideration to adverse event reporting, and should introduce clinical audits.

The total EMS time is a highly important factor for life-threatening diseases. We did not find any study in the AGS that measured any performance indicators of on-phone triaging time. In addition, no studies were found pertaining to search the urgency type that consider measuring the response time based on emergency cases level; starting from life threating up to non-emergency cases. We found the researchers in AGS did not consider the “golden hour” to be a benchmark during their measurement of EMS time. They measured different EMS time intervals and the total EMS time. The median response time in UAE and Qatar was comparable to the response times observed in the US. In the US, for example, a multicenter study found that the median response time for clients calling from either urban or suburban areas was about six minutes. For rural areas, the response time was almost double with a median of thirteen minutes.[37] However, the studies included in this review did not describe the EMS time in rural regions. It is worth mentioning that we did not find any studies measuring EMS intervals in SA focusing only on life-threating cases. We argue that response time should be documented by objective quantitative tools through reviewing information report or using information system technology.

Variation of time spent on the scene is subject to many different confounding factors such as severity of the case, geography, and type of EMS system protocol. Therefore, prolonged scene time cannot be considered as a negative indicator per se, unless the client’s outcome such as his medical condition and satisfaction were measured and show a negative outcome due to waste of effective time in non-indicated procedures. Irfan et al. found that in Qatar the median scene time for highly critical cases was more than half an hour.[29] This finding could be due to the fact that in Qatar ACLS has only recently been introduced and might be still under further strategic development.[38,39] Another study in Qatar showed that case severity and scene time affect total EMS time.[10] Demography and cultural factors may also affect the scene time in AGS. For example, female clients often need their own relative to be beside them during paramedic examinations. Another example is mass gathering of people at the scene during road traffic accidents.[40] Hence, sometimes the increased scene time is a result of community culture rather than of slowness of the system. Therefore, in order to identify the effectiveness of prolonged scene time, further research is still needed in the AGS.

None of the included studies considered the time of delivery of clients to ER staff. Undoubtedly, Hospitals resource levels and type (private or governmental), and ER bed consumption have a major role in this specific time. We found only one study that showed the time of delivery of clients but did not point to the type of emergency cases being delivered nor to the category of hospital [11].

Future research for EMS time domain could identify obstacles related to time management and it could provide solutions that improve outcomes. In general, the times to delivery to ER staff are important, irrespective of the possible underlying disease. The researchers in AGS should avoid benchmarking the EMS total time with the “golden hour” when they are planning to measure the time without stratifying on severity of cases or urgency type. In addition, high-quality studies are still needed, particularly, studies that focus on time attributes, such as call activation to first defibrillation time, crews’ scene arrival to first defibrillation time, time from collapse to first ROSC, and from arrival to initial CPR performed.

Studies that reported on the effectiveness domain showed the impact of process attributes on outcome finding. For example, the conveyance rates of OHCA or non-life-threating cases and compliance and adherence to EMS protocol or guidelines were often accompanied by outcome finding such as ROSC, survival rate to ER, or mortality rate. We found that all but one study showed a high conveyance rate of OHCA.[10,20,21,30,34] Bin Salleeh et al. found an alarmingly low conveyance rate of OHCA clients to hospital.[21] Moreover, they found ROSC and survival rates of zero percent, likely a consequence of the low transportation rate. In contrast, the reasons given for low ROSC rate in Qatar and UAE were partial adherence and compliance to protocol. The ROSC rate in Qatar and UAE were high in comparison to SA, but lower when compared to the US.[41]

The study by Bin Salleeh et al was not the only study showing low EMS utilization.[21] Dhaffar et al. reported very low conveyance rate of EC to Hospital in Makkah, and the partial adherence to protocols as well.[25] The low OHCA conveyance rate particularly in SA, the partial adherence to protocols in many AGS, and the low ROSC rate should be considered major challenges. A recent SA review concluded that socioeconomic status could be an important factor for the willingness of people to use private cars of transportation instead of EMS to reach the ER.[40] A US study showed that despite that 85% had insurance coverage that included eligibility to be transported by ambulance, 78.4% of them showed willingness to seek ER treatment by any alternative means, while 61.6% of the total were willing to come by private car.[42] Another study in the US showed that 88.7% of participants would first call EMS call number, if one of them or their relative will have recognized multiple symptoms of stroke.[43] Those studies showed that further research on those who choose EMS and those who choose using private transportation in AGS to identify this performance procedure are necessary.

A study conducted in Qatar identified the success rate of interventional endotracheal intubation. It showed that endotracheal intubation by the EMS crew was performed on only half of clients.[13] This could be lack of competency of EMS providers or could be due to large number of clients that were difficult to intubate. The incompetency of adherence to protocols is not only a challenge for AGS. Ebben et al. found many different internal and external factors affecting the EMS providers adherence to protocol.[44] Consequently, the AGS stakeholder should overcome those obstacles affecting their EMS providers of completely adhere to the national protocols.

The non-conveyance rate in an urban area of SA was shown to be low, mainly because of refusal of transportation.[18] Unfortunately, the study did not provide reasons for refusal. Reasons could be related to clients’ satisfaction, but further research is needed to explore non-conveyance reasons. A recent Dutch study showed very similar non-conveyance rates in the Netherlands, and explored numerous reasons for non-conveyance.[45]

Accessing EMS by phone is free of charge in AGS. Two studies identified moderate rates of unawareness of EMS phone numbers in UAE and SA.[23,28] The finding of unawareness of EMS number intersect with other SA studies in this review conclude the low EMS utilization.[1525,21,40] Moreover, the two states have a massive influx of foreigners because of trading and holy mosque visiting.[46] Perhaps expats involved in the study could explain the unawareness in part, but this has not been explored by the researchers.

Most EMS systems in the AGS are operated in the field by male staff with some minor exceptions such as the regional federal Dubai Ambulance Authority, which recently started with all-female first responder teams. Despite the female role in Dubai EMS, the rate of female to male is still low. In addition, most of the female providers are not citizens. A recent study in Dubai revealed that only one quarter of the participants are female and all of them were not Emirates. [47] Naturally, even when there are no female paramedics, women have full rights to use EMS. One included study showed that few participants still refuse all-male crews responding to female clients in the absence of her relatives.[28] This may be in part the cause that, on average, female clients with STEMI are late in attendance to emergency department compared to males in SA.[48] Therefore, women-centered research might give further insight into factors that prevent these women from accessing EMS. Furthermore, we found that male clients are the most prevalent consumers of EMS [12,15,16,18,20,29,30,32,34] To illustrate that, 48% of the AGS population are expats, and the majority of the expats are male.[46] As a consequence, the gender ratio in the AGS is considered to be 1 female to 2 males. Hence, the results related to the equity in this review are close to ratio of the real population in AGS.

Regarding ethnicity, the EMS in AGS provides services to all people with no discrimination. The studies included in this review showed that both citizens and non-citizens used EMS, but did not show sufficient data to explore differences in willingness to use EMS. Hence, further research is still needed to affirm the equity and accessibility to EMS.

Interestingly, one study indicated that low to moderate socio-economic status was a predictor of high EMS consumption.[16] It might be important for the high classes to be surveyed in future researches to identify factors affecting their willingness to use EMS in AGS.

Limitations

The average quality of the included studies was only moderate. The apparent lack of good quality EMS research may be explained by the many difficulties faced worldwide.[49] For example, Delbridge, et al. demonstrated in their study the challenges and reasons for poor performance in conducting a high quality research in EMS in the US.[50] The last chapter of the IOM report described the challenges of optimizing the research that would help the American EMS. This chapter proposed an agenda to improve research, particularly interventional methods to improve the effectiveness.[51] Furthermore, none of the studies included in this review tested any predefined model to detect system improvement. An example of such a model is the one used in Singapore. They assessed their EMS system after they had applied a Discrete Event Simulation Model to detect the reduction of response time without any passive impact on the EMS utilization rate.[52]

Conclusion

This review highlights the need for more and better studies of sufficient quality about all domains of quality in EMS in all the AGS. Future studies in urban and in rural areas should prioritize which cases are more crucial and therefore need to be handled more efficiently. EMS research in Kuwait and Bahrain is warranted as currently studies of EMS quality are unavailable for these States. Oman need further research to identify the possible causes for the low utilization rate for ambulance services for highly critical cases. Moreover, research into EMS efficiency should be conducted as not a single study was found on this domain.

Supporting information

S1 Table [docx]
Structure characteristic of EMS in the Arabian Gulf States.

S2 Table [doc]
PRISMA 2009 checklist.

S3 Table [docx]
Search strategy for PubMed, web of science, CINAHL, and EMBASE up to June 1, 2019.


Zdroje

1. Saudi Red Crescent Authority. About the Authority. 2018 [Available from: https://www.srca.org.sa/en/About/About.

2. Baker R. Crossing the quality chasm: A new health system for the 21st century. The Journal of Clinical Governance. 2002;10(1):43–4.

3. The Institute of Medicine. Crossing the Quality Chasm: A New Health System for the 21st Century: National Academies Press; 2001.

4. World Health Organization. Quality of care: a process for making strategic choices in health systems. 2006:Page 3.

5. Jrcalc A. UK Ambulance Services Clinical Practice Guidelines 2016. illustrated ed: Class Publishing; 2016. 546 p.

6. American Ambulance Association. Mission of the American Ambulance Association 2018 [Available from: https://ambulance.org/our-mission/.

7. The National Association of State EMS Officials. Mission and Goals of The National Association of State EMS Officials 2019 [Vision, Mission, Strategy,and Goals. Available from: https://nasemso.org/about/overview/.

8. Liberati A, Altman DG, Tetzlaff J, Mulrow C, Gøtzsche PC, Ioannidis JP, et al. The PRISMA statement for reporting systematic reviews and meta-analyses of studies that evaluate health care interventions: explanation and elaboration. PLoS medicine. 2009;6(7):e1000100. doi: 10.1371/journal.pmed.1000100 19621070

9. Herzog R, Álvarez-Pasquin MJ, Díaz C, Del Barrio JL, Estrada JM, Gil Á. Are healthcare workers’ intentions to vaccinate related to their knowledge, beliefs and attitudes? A systematic review. BMC public health. 2013;13(1):154.

10. Abdelrahman H, El-Menyar A, Al-Thani H, Consunji R, Zarour A, Peralta R, et al. Time-based trauma-related mortality patterns in a newly created trauma system. World journal of surgery. 2014;38(11):2804–12. doi: 10.1007/s00268-014-2705-x 25099683

11. Al-Ghamdi AS. Emergency medical service rescue times in Riyadh. Accident; analysis and prevention. 2002;34(4):499–505. doi: 10.1016/s0001-4575(01)00047-1 12067112

12. Al-Shaqsi S, Al-Kashmiri A, Al-Hajri H, Al-Harthy A. Emergency medical services versus private transport of trauma patients in the Sultanate of Oman: A retrospective audit at the Sultan Qaboos University Hospital. Emergency Medicine Journal. 2014;31(9):754–7. doi: 10.1136/emermed-2013-202779 23825061

13. Al-Thani H, El-Menyar A, Latifi R. Prehospital versus emergency room intubation of trauma patients in Qatar: A-2-year observational study. North American Journal of Medical Sciences. 2014;6(1):12–8. doi: 10.4103/1947-2714.125855 24678471

14. Alanazi AF. Emergency medical services in Saudi Arabia: A study on the significance of paramedics and their experiences on barriers as inhibitors of their efficiency. International journal of applied & basic medical research. 2012;2(1):34–7.

15. AlHabib KF, Alfaleh H, Hersi A, Kashour T, Alsheikh-Ali AA, Al Suwaidi J, et al. Use of Emergency Medical Services in the Second Gulf Registry of Acute Coronary Events. Angiology. 2014;65(8):703–9. doi: 10.1177/0003319713502846 24019088

16. AlHabib KF, Sulaiman K, Al Suwaidi J, Almahmeed W, Alsheikh-Ali AA, Amin H, et al. Patient and System-Related Delays of Emergency Medical Services Use in Acute ST-Elevation Myocardial Infarction: Results from the Third Gulf Registry of Acute Coronary Events (Gulf RACE-3Ps). PloS one. 2016;11(1):e0147385. doi: 10.1371/journal.pone.0147385 26807577

17. Alhabib KF, Kinsara AJ, Alghamdi S, Al-Murayeh M, Hussein GA, AlSaif S, et al. The first survey of the Saudi Acute Myocardial Infarction Registry Program: Main results and long-term outcomes (STARS-1 Program). Plos One. 2019;14(5).

18. Alrazeeni DM, Sheikh SA, Mobrad A, Al Ghamdi M, Abdulqader N, Al Gadgab M, et al. Epidemiology of non-transported emergency medical services calls in Saudi Arabia. Saudi medical journal. 2016;37(5):575–8. doi: 10.15537/smj.2016.5.13872 27146623

19. Althubaity E, Yunus F, Al Khathaami AM. Assessment of the experience of Saudi emergency medical services personnel with acute stroke: On-scene stroke identification, triaging, and dispatch of acute stroke patients. Neurosciences. 2013;18(1):40–5. 23291796

20. Batt AM, Al-Hajeri AS, Cummins FH. A profile of out-of-hospital cardiac arrests in Northern Emirates, United Arab Emirates. Saudi medical journal. 2016;37(11):1206–13. doi: 10.15537/smj.2016.11.16126 27761558

21. Bin Salleeh HM, Gabralla KA, Leggio WJ, Al Aseri ZA. Out-of-hospital adult cardiac arrests in a university hospital in central Saudi Arabia. Saudi medical journal. 2015;36(9):1071–5. doi: 10.15537/smj.2015.9.12081 26318464

22. Callachan EL, Alsheikh-Ali AA, Bruijns S, Wallis LA. Physician perceptions and recommendations about pre-hospital emergency medical services for patients with ST-elevation acute myocardial infarction in Abu Dhabi. Journal of the Saudi Heart Association. 2016;28(1):7–14. doi: 10.1016/j.jsha.2015.05.005 26778900

23. Callachan EL, Alsheikh-Ali AA, Nair SC, Bruijns S, Wallis LA. Utilizations and Perceptions of Emergency Medical Services by Patients with ST-Segments Elevation Acute Myocardial Infarction in Abu Dhabi: A Multicenter Study. Heart views: the official journal of the Gulf Heart Association. 2016;17(2):49–54.

24. Callachan EL, Alsheikh-Ali AA, Nair SC, Bruijns S, Wallis LA. Outcomes by mode of transport of st elevation mi patients in the United Arab Emirates. Western Journal of Emergency Medicine. 2017;18(3):349–55. doi: 10.5811/westjem.2017.1.32593 28435484

25. Dhaffar KO, Sindy AF, Gazzaz ZJ, Shabaz J. Evaluation of an emergency service attempted by the Saudi Red Crescent Society. Saudi Medical Journal. 2005;26(2):357–9. 15770333

26. El-Menyar A, Consunji R, Abdelrahman H, Latifi R, Wahlen BM, Al-Thani H. Predictors and Time-Based Hospital Mortality in Patients with Isolated and Polytrauma Brain Injuries. World journal of surgery. 2018;42(5):1346–57. doi: 10.1007/s00268-017-4310-2 29063224

27. Fares S, Zubaid M, Al-Mahmeed W, Ciottone G, Sayah A, Al Suwaidi J, et al. Utilization of emergency medical services by patients with acute coronary syndromes in the Arab Gulf States. Journal of Emergency Medicine. 2011;41(3):310–6. doi: 10.1016/j.jemermed.2010.05.002 20580517

28. Hamam AF, Bagis MH, AlJohani K, Tashkandi AH. Public awareness of the EMS system in Western Saudi Arabia: identifying the weakest link. International Journal of Emergency Medicine. 2015;8 (1) (no pagination)(35).

29. Irfan FB, Bhutta ZA, Castren M, Straney L, Djarv T, Tariq T, et al. Epidemiology and outcomes of out-of-hospital cardiac arrest in Qatar: A nationwide observational study. International Journal of Cardiology. 2016;223:1007–13. doi: 10.1016/j.ijcard.2016.08.299 27611569

30. Irfan FB, Consunji R, El-Menyar A, George P, Peralta R, Al-Thani H, et al. Cardiopulmonary resuscitation of out-of-hospital traumatic cardiac arrest in Qatar: A nationwide population-based study. International Journal of Cardiology. 2017;240:438–43. doi: 10.1016/j.ijcard.2017.03.134 28395982

31. Nadar SK, Mujtaba M, Al-Hadi H, Sadiq M, Al-Riyami A, Ali M, et al. Epidemiology, Outcomes and Coronary Angiography Findings of Patients Following Out-of-Hospital Cardiac Arrest: A single-centre experience from Oman. Sultan Qaboos University medical journal. 2018;18(2):e155–e60. doi: 10.18295/squmj.2018.18.02.006 30210844

32. Ong MEH, Shin SD, De Souza NNA, Tanaka H, Nishiuchi T, Song KJ, et al. Outcomes for out-of-hospital cardiac arrests across 7 countries in Asia: The Pan Asian Resuscitation Outcomes Study (PAROS). Resuscitation. 2015;96:100–8. doi: 10.1016/j.resuscitation.2015.07.026 26234891

33. Shehab A, Al-Habib K, Hersi A, Al-Faleh H, Alsheikh-Ali A, Almahmeed W, et al. Quality of care in primary percutaneous coronary intervention for acute ST-segment—elevation myocardial infarction: Gulf RACE 2 experience. Annals of Saudi Medicine. 2014;34(6):482–7. doi: 10.5144/0256-4947.2014.482 25971820

34. Tham LP, Wah W, Phillips R, Shahidah N, Ng YY, Shin SD, et al. Epidemiology and outcome of paediatric out-of-hospital cardiac arrests: A paediatric sub-study of the Pan-Asian resuscitation outcomes study (PAROS). Resuscitation. 2018;125:111–7. doi: 10.1016/j.resuscitation.2018.01.040 29421664

35. Al Sabah S, Alsharqawi N, Al Haddad EJIJoS. The aftermath of the Kuwait mosque bombing: A retrospective cohort analysis and lessons learned. 2018;56:15–20. doi: 10.1016/j.ijsu.2018.06.003 29886282

36. Fisher JD, Freeman K, Clarke A, Spurgeon P, Smyth M, Perkins GD, et al. Patient safety in ambulance services: a scoping review. Health Serv Deliv Res. 2015;3(21).

37. Mell HK, Mumma SN, Hiestand B, Carr BG, Holland T, Stopyra J. Emergency medical services response times in rural, suburban, and urban areas. JAMA surgery. 2017;152(10):983–4. doi: 10.1001/jamasurg.2017.2230 28724118

38. Hamad Medical Corporation. Qatar Ambulance Service Qatar: Hamad Medical Corporation; 2018 [Available from: https://www.hamad.qa/EN/Hospitals-and-services/Ambulance-Service/Pages/default.aspx.

39. Munk M-D, White SD, Perry ML, Platt TE, Hardan MS, Stoy WAJPEC. Physician Medical Direction andClinical Performance at an Established Emergency Medical Services System. 2009;13(2):185–92. doi: 10.1080/10903120802706120 19291555

40. AlShammari T, Jennings P, Williams B. Evolution of emergency medical services in Saudi Arabia. Journal of Emergency Medicine, Trauma and Acute Care. 2017;2017(1):4.

41. Eisenberg MS. Resuscitate!: How Your Community Can Improve Survival from Sudden Cardiac Arrest: University of Washington Press; 2013.

42. Yarris LM, Moreno R, Schmidt TA, Adams AL, Brooks HS. Reasons why patients choose an ambulance and willingness to consider alternatives. Academic emergency medicine. 2006;13(4):401–5. doi: 10.1197/j.aem.2005.11.079 16531606

43. Seo M, Begley C, Langabeer JR, DelliFraine JL. Barriers and disparities in emergency medical services 911 calls for stroke symptoms in the United States adult population: 2009 BRFSS Survey. Western Journal of Emergency Medicine. 2014;15(2):251. doi: 10.5811/westjem.2013.9.18584 24926394

44. Ebben RH, Vloet LC, Verhofstad MH, Meijer S, Mintjes-de Groot JA, van Achterberg T. Adherence to guidelines and protocols in the prehospital and emergency care setting: a systematic review. Scandinavian journal of trauma, resuscitation and emergency medicine. 2013;21(1):9.

45. Vloet LC, de Kreek A, van der Linden EM, van Spijk JJ, Theunissen VA, van Wanrooij M, et al. A retrospective comparison between non-conveyed and conveyed patients in ambulance care. Scandinavian journal of trauma, resuscitation and emergency medicine. 2018;26(1):91. doi: 10.1186/s13049-018-0557-3 30373652

46. National Institutes of Statistics. Total population and percentage of nationals and non-nationals in GCC countries (latest national statistics, (2010–2015). Gulf Research Center; 2015 31 March 2015.

47. Shire F, Kasim Z, Alrukn S, Khan M. Stroke awareness among Dubai emergency medical service staff and impact of an educational intervention. BMC research notes. 2017;10(1):255. doi: 10.1186/s13104-017-2585-x 28683821

48. Alshahrani H, McConkey R, Wilson J, Youssef M, Fitzsimons D. Female gender doubles pre-hospital delay times for patients experiencing ST segment elevation myocardial infarction in Saudi Arabia. European Journal of Cardiovascular Nursing. 2014;13(5):399–407. doi: 10.1177/1474515113507159 24104612

49. Howard I, Cameron P, Wallis L, Castren M, Lindstrom V. Quality indicators for evaluating prehospital emergency care: a scoping review. Prehospital and disaster medicine. 2018;33(1):43–52. doi: 10.1017/S1049023X17007014 29223193

50. Delbridge TR, Bailey B, Chew JL, Conn AK, Krakeel JJ, Manz D, et al. EMS agenda for the future: where we are… where we want to be. Prehospital Emergency Care. 1998;2(1):1–12. doi: 10.1080/10903129808958832 9737400

51. Alam N, Oskam E, Stassen PM, van Exter P, van de Ven PM, Haak HR, et al. Prehospital antibiotics in the ambulance for sepsis: a multicentre, open label, randomised trial. The Lancet Respiratory Medicine. 2018;6(1):40–50. doi: 10.1016/S2213-2600(17)30469-1 29196046

52. Wei Lam SS, Zhang ZC, Oh HC, Ng YY, Wah W, Hock Ong ME, et al. Reducing ambulance response times using discrete event simulation. Prehospital Emergency Care. 2014;18(2):207–16. doi: 10.3109/10903127.2013.836266 24134647


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