INTRODUCTION
The American Heart Association recommendation for care of an ST-segment elevation myocardial infarction (STEMI) is to provide percutaneous coronary intervention (PCI) as the first line of treatment, if it is possible, in a timely manner.Reference O’Connor, Al Ali and Brady
1
This is defined as a reperfusion device within 90 minutes of first medical contact. This has evolved from “door to balloon”; the interval now begins with the first medical contact as the diagnostic (paramedic) electrocardiogram (ECG) and concludes with the device (e.g., wire, balloon) deployed. This recognizes the significant role of paramedics in an integrated STEMI system of care.
An optimized prehospital interval could involve transporting the patient directly to a PCI-capable facility, bypassing the closest emergency department (ED); this process is called STEMI bypass. Guidelines state that the treating paramedics should “be capable of managing complications associated with acute coronary syndrome.” In many systems, primary care paramedics (PCP) are the first on scene because chest pain calls are high priority and the closest unit is dispatched. In some systems, there are no advanced care paramedics (ACP) at all. Can PCP safely care for and transport a STEMI-bypass patient? Dispatching the more distant ACP, for example, would delay the time to aspirin, or first shock in the event that this evolves to a cardiac arrest. Requiring an ACP to transport a STEMI-bypass would also delay reperfusion. A pilot study conducted by Cantor et al. concluded that STEMI patients could be safely transported directly to PCI by paramedics without advanced care training.Reference Cantor, Hoogeveen and Robert
2
The paper published in this volume by Mitchell et al. echoes this recommendation and adds to our understanding of how to best use the skills and resources of paramedic services to safely minimize ischemic time.Reference Mitchell, Dionne and Maloney
3
In the Mitchell paper, a PCP STEMI bypass program in a Canadian urban/suburban paramedic service is described (contact time with paramedics: 29 minutes, 40 seconds).Reference Mitchell, Dionne and Maloney
3
This program began in 2006 and presents safety data for 2011-2016. Although a significant (59%) proportion had clinically important events, complications were transient and often resolved with no therapy. Furthermore, a smaller proportion would be addressed differently by ACP (many were hypotension responding to fluid, which could be addressed by PCP where they can initiate intravenous [IV] and fluid bolus). They conclude that PCP can safely conduct a STEMI bypass.
This adds to the growing body of evidence on the role of paramedics in an integrated STEMI system of care, which includes two other Canadian papers recently published in CJEM. Bussieres et al. present a rural environment with longer transport times (>30 minutes to the PCI centre).Reference Bussières, Bégin and Leblanc
4
Data on 1,114 patients over a period of 8 years reveal 18.5% major events and 12.2% minor for PCP STEMI bypass. Kwong et al. recently presented data from an urban paramedic service.Reference Kwong, Ross and Turner
5
One year of data included 232 PCP-only STEMI bypass, of which 21/232 (9.1%) had indications for an ACP intervention. Eleven patients experienced cardiac arrest; 10 were successfully resuscitated (5 of these by PCPs).
What does this add to our understanding of a STEMI bypass? Evidence-based guidelines recommend direct to PCI, but these same guidelines say the treating paramedics should be capable of managing complications. What are the complications, how often do they happen, and who is capable of managing them? And what are the consequences of the alternative(s)? This series of papers helps us unpack these issues and make evidence-based decisions about system design for STEMI care.
Firstly, these three papers all address the question of what complications arise and how often. All three describe low incidence of events requiring intervention. These three authors also illustrate that few of these events would require an intervention outside of the PCP scope, particularly in a system that endorses PCP IV starts and fluid bolus. They present the option of an ACP intercept, possibly for a selected higher-risk population. Incidence of, and survival from, cardiac arrest was the same in ACP or PCP care. This aligns with prior work by Ryan et al. who studied a system without a PCP STEMI bypass and found that interventions requiring an ACP scope of practice occurred in fewer than 10% of 342 STEMI patients. The most frequent intervention was administration of morphine for chest pain.Reference Ryan, Craig and Turner
6
This provides mounting evidence that complications outside of the scope of a PCP are rather infrequent, and that waiting for an ACP, or transporting first to a non-PCI centre, may have limited added value. If time is muscle, what is the time cost of the alternatives to a PCP STEMI bypass? In a large urban setting, the median additional transport time of a PCP STEMI bypass compared to transport to the closest ED was 5.53 minutes (interquartile [IQR] = 6.71). In the event that it becomes necessary, the median additional time incurred by an ACP-rendezvous was low (7.49 v. 5.53 minutes).Reference Kwong, Ross and Turner
5
Further, transporting STEMI patients to the closest hospital with the need for subsequent interfacility transfer adds significantly more ischemic time.Reference Kwong, Ross and Turner
5
This is borne out in several studies, including Ross et al. who reported that, in 89 PCP STEMI cases transported to the nearest hospital, the ischemic time could have been decreased by an estimated 50 minutes with direct transport to a PCI centre while only incurring a 7-minute increase in the transport interval.Reference Ross, Alsayed and Turner
7
The literature provides evidence on other aspects of optimizing the prehospital interval and the paramedic skill set in an integrated STEMI system of care. In the Kwong paper, paramedics activate the PCI lab based on their own interpretation, guided by the automated computer interpretation.Reference Kwong, Ross and Turner
5
In Mitchell and Bussieres, paramedics transmit and a remote physician is involved in making the decision.Reference Mitchell, Dionne and Maloney
3
,
Reference Bussières, Bégin and Leblanc
4
Multiple studies document feasibility and accuracy of prehospital ECG by appropriately trained paramedics.Reference Ducas, Wassef and Jassal
8
Studies support a time savings from the first diagnostic ECG to device with prehospital acquisition of ECG. Multiple studies have supported the accuracy of paramedic interpretation.Reference Cheskes, Turner and Foggett
9
Removing the step of transmission has been shown to save time from first medical contact to balloon, and avoids the 1 in 5 chance of transmission failure.Reference Le May, Dionne, Maloney and Poirier
10
Transmission to, and direct communication with, interventional cardiology may help further reduce time to device.Reference Sejersten, Sillesen and Hansen
11
The Mitchell paper in this volume, supported by two recent CJEM publications and a growing body of literature, endorses that a STEMI bypass shortens ischemic time; further, it should include regions that have few or no ACP. Treating STEMI with rapid access to PCI decreases ischemic time and improves outcomes. Optimizing paramedic scope of practice and enabling paramedic services to function to their full scope as part of an integrated STEMI system of care, including PCP STEMI bypass, would improve access to this service and improve outcomes from STEMI for more of the population.
INTRODUCTION
The American Heart Association recommendation for care of an ST-segment elevation myocardial infarction (STEMI) is to provide percutaneous coronary intervention (PCI) as the first line of treatment, if it is possible, in a timely manner.Reference O’Connor, Al Ali and Brady 1 This is defined as a reperfusion device within 90 minutes of first medical contact. This has evolved from “door to balloon”; the interval now begins with the first medical contact as the diagnostic (paramedic) electrocardiogram (ECG) and concludes with the device (e.g., wire, balloon) deployed. This recognizes the significant role of paramedics in an integrated STEMI system of care.
An optimized prehospital interval could involve transporting the patient directly to a PCI-capable facility, bypassing the closest emergency department (ED); this process is called STEMI bypass. Guidelines state that the treating paramedics should “be capable of managing complications associated with acute coronary syndrome.” In many systems, primary care paramedics (PCP) are the first on scene because chest pain calls are high priority and the closest unit is dispatched. In some systems, there are no advanced care paramedics (ACP) at all. Can PCP safely care for and transport a STEMI-bypass patient? Dispatching the more distant ACP, for example, would delay the time to aspirin, or first shock in the event that this evolves to a cardiac arrest. Requiring an ACP to transport a STEMI-bypass would also delay reperfusion. A pilot study conducted by Cantor et al. concluded that STEMI patients could be safely transported directly to PCI by paramedics without advanced care training.Reference Cantor, Hoogeveen and Robert 2 The paper published in this volume by Mitchell et al. echoes this recommendation and adds to our understanding of how to best use the skills and resources of paramedic services to safely minimize ischemic time.Reference Mitchell, Dionne and Maloney 3
In the Mitchell paper, a PCP STEMI bypass program in a Canadian urban/suburban paramedic service is described (contact time with paramedics: 29 minutes, 40 seconds).Reference Mitchell, Dionne and Maloney 3 This program began in 2006 and presents safety data for 2011-2016. Although a significant (59%) proportion had clinically important events, complications were transient and often resolved with no therapy. Furthermore, a smaller proportion would be addressed differently by ACP (many were hypotension responding to fluid, which could be addressed by PCP where they can initiate intravenous [IV] and fluid bolus). They conclude that PCP can safely conduct a STEMI bypass.
This adds to the growing body of evidence on the role of paramedics in an integrated STEMI system of care, which includes two other Canadian papers recently published in CJEM. Bussieres et al. present a rural environment with longer transport times (>30 minutes to the PCI centre).Reference Bussières, Bégin and Leblanc 4 Data on 1,114 patients over a period of 8 years reveal 18.5% major events and 12.2% minor for PCP STEMI bypass. Kwong et al. recently presented data from an urban paramedic service.Reference Kwong, Ross and Turner 5 One year of data included 232 PCP-only STEMI bypass, of which 21/232 (9.1%) had indications for an ACP intervention. Eleven patients experienced cardiac arrest; 10 were successfully resuscitated (5 of these by PCPs).
What does this add to our understanding of a STEMI bypass? Evidence-based guidelines recommend direct to PCI, but these same guidelines say the treating paramedics should be capable of managing complications. What are the complications, how often do they happen, and who is capable of managing them? And what are the consequences of the alternative(s)? This series of papers helps us unpack these issues and make evidence-based decisions about system design for STEMI care.
Firstly, these three papers all address the question of what complications arise and how often. All three describe low incidence of events requiring intervention. These three authors also illustrate that few of these events would require an intervention outside of the PCP scope, particularly in a system that endorses PCP IV starts and fluid bolus. They present the option of an ACP intercept, possibly for a selected higher-risk population. Incidence of, and survival from, cardiac arrest was the same in ACP or PCP care. This aligns with prior work by Ryan et al. who studied a system without a PCP STEMI bypass and found that interventions requiring an ACP scope of practice occurred in fewer than 10% of 342 STEMI patients. The most frequent intervention was administration of morphine for chest pain.Reference Ryan, Craig and Turner 6
This provides mounting evidence that complications outside of the scope of a PCP are rather infrequent, and that waiting for an ACP, or transporting first to a non-PCI centre, may have limited added value. If time is muscle, what is the time cost of the alternatives to a PCP STEMI bypass? In a large urban setting, the median additional transport time of a PCP STEMI bypass compared to transport to the closest ED was 5.53 minutes (interquartile [IQR] = 6.71). In the event that it becomes necessary, the median additional time incurred by an ACP-rendezvous was low (7.49 v. 5.53 minutes).Reference Kwong, Ross and Turner 5 Further, transporting STEMI patients to the closest hospital with the need for subsequent interfacility transfer adds significantly more ischemic time.Reference Kwong, Ross and Turner 5 This is borne out in several studies, including Ross et al. who reported that, in 89 PCP STEMI cases transported to the nearest hospital, the ischemic time could have been decreased by an estimated 50 minutes with direct transport to a PCI centre while only incurring a 7-minute increase in the transport interval.Reference Ross, Alsayed and Turner 7
The literature provides evidence on other aspects of optimizing the prehospital interval and the paramedic skill set in an integrated STEMI system of care. In the Kwong paper, paramedics activate the PCI lab based on their own interpretation, guided by the automated computer interpretation.Reference Kwong, Ross and Turner 5 In Mitchell and Bussieres, paramedics transmit and a remote physician is involved in making the decision.Reference Mitchell, Dionne and Maloney 3 , Reference Bussières, Bégin and Leblanc 4 Multiple studies document feasibility and accuracy of prehospital ECG by appropriately trained paramedics.Reference Ducas, Wassef and Jassal 8 Studies support a time savings from the first diagnostic ECG to device with prehospital acquisition of ECG. Multiple studies have supported the accuracy of paramedic interpretation.Reference Cheskes, Turner and Foggett 9 Removing the step of transmission has been shown to save time from first medical contact to balloon, and avoids the 1 in 5 chance of transmission failure.Reference Le May, Dionne, Maloney and Poirier 10 Transmission to, and direct communication with, interventional cardiology may help further reduce time to device.Reference Sejersten, Sillesen and Hansen 11
The Mitchell paper in this volume, supported by two recent CJEM publications and a growing body of literature, endorses that a STEMI bypass shortens ischemic time; further, it should include regions that have few or no ACP. Treating STEMI with rapid access to PCI decreases ischemic time and improves outcomes. Optimizing paramedic scope of practice and enabling paramedic services to function to their full scope as part of an integrated STEMI system of care, including PCP STEMI bypass, would improve access to this service and improve outcomes from STEMI for more of the population.
Competing interests: None declared.