Outcomes of Physician‐Staffed Versus Non‐Physician‐Staffed Helicopter Transport for ST‐Elevation Myocardial Infarction


Outcomes of Physician-Staffed Versus Non-Physician-Staffed
Helicopter Transport for ST-Elevation Myocardial Infarction
Sverrir I. Gunnarsson, MD; Joseph Mitchell, MD; Mary S. Busch, RN; Brenda Larson, RN; S. Michael Gharacholou, MD; Zhanhai Li, PhD;
Amish N. Raval, MD

Background-—The effect of physician-staffed helicopter emergency medical service (HEMS) on ST-elevation myocardial infarction
(STEMI) patient transfer is unknown. The purpose of this study was to evaluate the characteristics and outcomes of physician-
staffed HEMS (Physician-HEMS) versus non-physician-staffed (Standard-HEMS) in patients with STEMI.

Methods and Results-—We studied 398 STEMI patients transferred by either Physician-HEMS (n=327) or Standard-HEMS (n=71)
for primary or rescue percutaneous coronary intervention at 2 hospitals between 2006 and 2014. Data were collected from
electronic medical records and each institution’s contribution to the National Cardiovascular Data Registry. Baseline
characteristics were similar between groups. Median electrocardiogram-to-balloon time was longer for the Standard-HEMS group
than for the Physician-HEMS group (118 vs 107 minutes; P=0.002). The Standard-HEMS group was more likely than the Physician-
HEMS group to receive nitroglycerin (37% vs 15%; P<0.001) and opioid analgesics (42.3% vs 21.7%; P<0.001) during transport.
In-hospital adverse outcomes, including cardiac arrest, cardiogenic shock, and serious arrhythmias, were more common in the
Standard-HEMS group (25.4% vs 11.3%; P=0.002). After adjusting for age, sex, Killip class, and transport time, patients transferred
by Standard-HEMS had increased risk of any serious in-hospital adverse event (odds ratio=2.91; 95% CI=1.39–6.06; P=0.004).
In-hospital mortality was not statistically different between the 2 groups (9.9% in the Standard-HEMS group vs 4.9% in the
Physician-HEMS group; P=0.104).

Conclusions-—Patients with STEMI transported by Standard-HEMS had longer transport times, higher rates of nitroglycerin and
opioid administration, and higher rates of adjusted in-hospital events. Efforts to better understand optimal transport strategies in
STEMI patients are needed. (J Am Heart Assoc. 2017;6:e004936. DOI: 10.1161/JAHA.116.004936.)

Key Words: acute myocardial infarction • outcome • percutaneous coronary intervention • ST-segment elevation myocardial
infarction • treatment

P rimary percutaneous coronary intervention (PCI)improves survival in patients with ST-elevation myocar-
dial infarction (STEMI) and is the optimal treatment when
performed expeditiously.1 Over 70% of patients experiencing

STEMI in the United States initially present to hospitals
without PCI capability and thus are at risk for delayed
reperfusion.2 To ensure rapid interfacility transport for PCI,
regional systems of care are recommended.3–5

Helicopter Emergency Medical Services (HEMS) are com-
monly used to transport patients from non-PCI centers (ie,
STEMI referral hospitals) to PCI centers (ie, STEMI receiving
hospitals). HEMS have been shown to be feasible, safe, and
reduce transport time to the receiving facility.6–8 Thus, HEMS
are important in rural or urban areas where ground transport
times are predicted to be too long. The HEMS flight crew
typically consists of paramedics and flight nurses who are
skilled at performing a variety of advanced cardiac life support
procedures. However, only �5% of HEMS in the United States
will also include an emergency-medicine–trained physician as
part of the flight crew.9 Local resources, cost, and hospital
affiliations are factors that currently influence HEMS avail-
ability and crew composition.

There are limited data evaluating the composition and
outcome of HEMS and no data comparing different HEMS

From the Division of Cardiovascular Medicine, Departments of Medicine (S.I.G.,
J.M., B.L., A.N.R.) and Biostatistics and Medical Informatics (Z.L.), University of
Wisconsin, Madison, WI; Mayo Clinic Health System-Franciscan Healthcare, La
Crosse, WI (M.S.B., S.M.G.); Division of Cardiology, Mayo Clinic, Rochester, MN
(S.M.G.).

Correspondence to: Amish N. Raval, MD, FACC, FSCAI, FAHA, Division of
Cardiovascular Medicine, Department of Medicine, University of Wisconsin
School of Medicine and Public Health, University of Wisconsin Hospital and
Clinics (site of research), CSC H4/568, 600 Highland Ave, Madison, WI
53792. E-mail: anr@medicine.wisc.edu

Received October 31, 2016; accepted December 15, 2016.

ª 2017 The Authors. Published on behalf of the American Heart Association,
Inc., by Wiley Blackwell. This is an open access article under the terms of the
Creative Commons Attribution-NonCommercial-NoDerivs License, which
permits use and distribution in any medium, provided the original work is
properly cited, the use is non-commercial and no modifications or adaptations
are made.

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systems on transport times, treatments administered during
patient transport, and in-hospital events in patients with STEMI.
As such, practice guidelines do not address the issue of crew
composition during interfacility transfer. The primary objective of
this study was to evaluate the characteristics, treatment
patterns, in-transport, and in-hospital outcomes of STEMI
patients transferred byphysician-staffed HEMS (Physician-HEMS
group) versus nonphysician (Standard-HEMS group) flight crews.

Methods
The institutional review boards of both the University of
Wisconsin Hospital and Clinics (UWHC) and Mayo Clinic
approved this study. Patient demographic information,
in-transport treatments and events, and in-hospital outcomes
were abstracted from institutional contributions to the National
Cardiovascular Data Registry (NCDR), electronic medical
records, and the HEMS flight records. STEMI was defined
based on 3 criteria: (1) electrocardiogram (ECG) evidence of
ST-elevation based on the 2013 American Heart Association/
American College of cardiology (AHA/ACC) STEMI Guidelines5;
(2) a culprit artery identified by emergency invasive coronary
angiography; and (3) performance of either primary PCI or PCI
following fibrinolytic administration (ie, rescue PCI).

In-transport adverse events were defined as death, cardiac
arrest, serious arrhythmia (ie, rapid supraventricular arrhyth-
mias requiring direct current cardioversion, sustained ventric-
ular tachycardia or ventricular fibrillation, or brady-arrhythmias
requiring external pacing), or endotracheal intubation. Data
pertaining to the use of adjunctive medications, additional
procedures, and vital signs were also recorded. In-hospital
outcomes were reviewed by trained abstractors using standard
definitions established by the NCDR ACTION Registry and
included death, stroke, cardiac arrest, bleeding, cardiogenic
shock, new requirement for dialysis, recurrent myocardial
infarction (MI), and vascular complications.10

Helicopter Emergency Medical Services
Within both institutions’ STEMI systems of care, HEMS are
requested directly by the STEMI referral hospital. The choice
of commercial HEMS is dependent upon availability, local
contractual affiliation, and regional emergency department
staff preference. The majority of STEMI transfers destined for
the UWHC are managed by UW Med Flight, a physician-staffed
service. The physician-staffed HEMS crew is comprised of an
emergency-medicine–trained flight physician, a flight nurse,
and a pilot. This service utilizes EC-135 model helicopters
(American Eurocopter, Grand Prairie, TX), which have a
maximum speed of 140 knots (kts).

Non-physician-staffed HEMS that transport to UWHC
(REACT of Rockford, IL; Flight for Life, Milwaukee and Fond

du Lac, WI; and MedLink Air of La Crosse, WI) consist of a pilot
and either 2 flight paramedics or a flight paramedic and a
flight nurse. These HEMS utilize either EC-145 model or
BK-117 helicopters (American Eurocopter). The EC-145 and
BK-117 models have maximum speeds of 145 and 150 kts,
respectively.

All HEMS and STEMI referring and receiving hospitals
follow a standardized antithrombotic protocol, which includes
aspirin 325 mg, clopidogrel 600 mg loading dose, and weight-
adjusted heparin; however, deviation from the protocol can
occur when clinically appropriate.11 The STEMI protocol
suggests that nitroglycerin and opioids (morphine or fentanyl)
may be administered as clinically indicated.

Statistical Analysis
Continuous variables were analyzed using the Wilcoxon rank-
sum test. Categorical variables were tested using the chi-
square test. Fischer’s exact was applied in those instances
where the counts of observed outcomes were numerically
small or the expected cell counts <5. Logistic regression
models were constructed to evaluate independent predictors
of outcomes. All tests were considered statistically significant
if P<0.05. All analyses were performed using Statistical
Package for the Social Sciences (SPSS) software (version
23.0; IBM Inc., Chicago, IL).

Results
From August 2006 through December 2014, a total of 398
STEMI patients were transferred for primary or rescue PCI. Of
those, 327 patients were transported by Physician-HEMS and
71 patients by Standard-HEMS.

Patient Characteristics
There was no significant difference in baseline age or
frequency of cardiovascular disease risk factor between the
Physician-HEMS and Standard-HEMS groups (Table 1). There
was no significant difference in the baseline Killip class
between the 2 groups (P=0.790). The right coronary artery
(RCA) was the most common culprit artery in both groups.
However, the Physician-HEMS group was more likely to have
the left anterior descending (LAD) coronary artery as the
culprit for STEMI (P=0.017; Table 1).

In-Transport Events
In transport mortality was 0% in both groups. There was no
significant difference in the frequency of serious adverse
events, such as cardiac arrest, arrhythmia, intubation or need
for transcutaneous pacing, direct current cardioversion, or

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cardiopulmonary resuscitation (Table 2). The Standard-HEMS
group was more likely than the Physician-HEMS group to
receive intravenous analgesics, such as fentanyl or morphine
and nitroglycerin, during transport (42.3% vs 21.7% and 36.6%
vs 15.3%; P<0.001 for both; Table 2). Of the 76 patients who
received nitroglycerin during transport, 30 (39.5%) had RCA as
culprit vessel. In the Standard-HEMS group, 12 of 32 (37.5%)
of the patients who had occluded RCA received nitroglycerin
compared to 18 of 155 (11.6%) patients in the Physician-
HEMS group (P<0.001). The Standard-HEMS group was more
likely to receive fluid bolus and anti-thrombotic medication
in-flight. The median first electrocardiogram-to-balloon
(ECG2B) time was longer for the Standard-HEMS group

compared to the Physician-HEMS group (118 vs 107 minutes;
P=0.002; Table 3). There was no statistical difference in flight
distance, ground time, and flight time between the 2 groups.

Table 1. Patient Characteristics*

Physician-
HEMS (n=327)

Standard-
HEMS (n=71) P Value

Age, y 60.4�13.0 61.3�12.3 0.187
Male, n (%) 248 (75.8) 50 (70.4) 0.340

Diabetes mellitus, n (%) 88 (26.9) 14 (19.7) 0.208

Active smoker, n (%) 164 (50.2) 36 (50.7) 0.952

Hypertension, n (%) 209 (63.9) 41 (57.7) 0.330

Dyslipidemia, n (%) 227 (69.4) 48 (67.6) 0.764

Previous MI, n (%) 57 (17.4) 9 (12.7) 0.329

Initial vital signs

Median SBP,
mm Hg (IQR)

128 (116–145) 137 (116–162) 0.148

Median DBP,
mm Hg (IQR)

78 (68–90) 82 (72–98) 0.117

Median HR, rate
per minute (IQR)

71 (62–86) 77 (63–89) 0.616

Killip class 0.790

I, n (%) 253 (77.4) 56 (78.9)

II, n (%) 3 (0.9) 2 (2.8)

III, n (%) 14 (4.3) 2 (2.8)

IV, n (%) 57 (17.4) 11 (15.5)

Culprit coronary artery 0.017

LAD, n (%) 135 (41.3) 19 (26.8)

RCA, n (%) 155 (47.4) 35 (49.3)

Left circumflex, n (%) 33 (10.1) 14 (19.7)

Other, n (%) 4 (1.2) 3 (4.2)

Rescue PCI, n (%) 26 (8.0) 4 (5.6) 0.626

DBP indicates diastolic blood pressure; HR, heart rate; IQR, interquartile range; LAD, left
anterior descending; MI, myocardial infarction; PCI, percutaneous coronary intervention;
Physician-HEMS, physician-staffed helicopter emergency medical service; RCA, right
coronary artery; SBP, systolic blood pressure; Standard-HEMS, non-physician-staffed
helicopter emergency medical service.
*Continuous variables are expressed as means�SD (standard deviation) or
median�IQR.

Table 2. In-Transport Events, Procedures and Medications

Physician-
HEMS (n=327)

Standard-
HEMS (n=71) P Value

Events

Death, n (%) 0 0 NA

Cardiac arrest, n (%) 8 (2.4) 1 (1.4) 1.00

Serious arrythmia, n (%) 11 (3.4) 3 (4.2) 0.715

Procedures

Intubation, n (%) 18 (5.5) 5 (7.0) 0.051

DCCV, n (%) 7 (2.1) 2 (2.8) 0.651

Transcutaneous pacing,
n (%)

3 (0.9) 1 (1.4) 0.522

CPR, n (%) 3 (0.9) 5 (7.0) 1.00

Medications

Analgesics, n (%) 71 (21.7) 30 (42.3) <0.001

Paralytics, n (%) 7 (2.1) 0 0.608

Fluid bolus, n (%) 18 (5.5) 9 (12.7) 0.019

Intravenous metoprolol,
n (%)

43 (13.1) 3 (4.2) 0.057

Vasopressors, n (%) 2 (0.6) 3 (4.2) 0.036

Anti-arrhythmics, n (%) 8 (2.4) 3 (4.2) 0.408

Anti-thrombotics, n (%) 14 (4.3) 22 (31) <0.001

Nitroglycerin, n (%) 50 (15.3) 36 (36.6) <0.001

CPR indicates cardiopulmonary resuscitation; DCCV, direct current cardioversion;
Physician-HEMS, physician-staffed helicopter emergency medical service; Standard-
HEMS, non-physician-staffed helicopter emergency medical service.

Table 3. Transportation Metrics*

Physician-
HEMS (n=327)

Standard-
HEMS (n=71) P Value

Flight distance,
nautical miles (IQR)

33 (30–37) 33 (29–37) 0.980

Ground time,
minute (IQR)

18 (15–21) 17 (13–21) 0.057

Flight time, minute (IQR) 18 (15–20) 19 (16–22) 0.619

ECG2B, minute (IQR) 107 (94–121) 118 (98–138) 0.002

D2B, minute (IQR) 113 (99–134) 124 (102–148) 0.014

D2B indicates time from arrival at percutaneous coronary intervention (PCI) referring
hospital to balloon inflation; ECG2B, time from first electrocardiogram acquisition to
balloon inflation; Flight time, time from helicopter takeoff to landing; Ground time, time
from helicopter landing at PCI referring hospital to take-off; IQR, interquartile range;
PS-HEMS, physician-staffed helicopter emergency medical service; Standard-HEMS,
non-physician-staffed helicopter emergency medical service.
*Continuous variables are expressed as median�IQR.

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In-Hospital Outcomes
There was no statistical difference in the rate of in-hospital
death between the Standard-HEMS and Physician-HEMS
groups (9.9% vs 4.9%; P=0.104; Table 4). The rate of any
serious in-hospital adverse event was higher in the Standard-
HEMS group compared to the Physician-HEMS group (25.4%
vs 11.3%; P=0.002), including cardiac arrest (8.5% vs 1.2%;
P=0.003), cardiogenic shock (14.1% vs 5.5%; P=0.01), and
need for intra-aortic balloon counter-pulsation (21.1% vs
11.9%; P=0.04). Of the patients who sustained any in-hospital
adverse outcome (n=52), 3 of 15 (20%) in the Standard-HEMS
group were given nitroglycerin versus 6 of 37 (16.2%) of those
in the Physician-HEMS group (P=0.044). Similarly, 6 of 15
(40%) of the patients who were given analgesics in the
Standard-HEMS group sustained an in-hospital adverse event
compared to 10 of 37 (27%) of those in the Physician-HEMS
group (P=0.025).

Median length of hospital stay was not statistically
different between the 2 groups (3 days for both groups;
P=0.234). After adjusting for age, sex, Killip class, and
transport time, patients transferred by Standard-HEMS had an
increased risk of any serious in-hospital adverse event (odds
ratio [OR]=2.91; 95% CI=1.39–6.06; P=0.004; Table 5).

Discussion
To our knowledge, this is the first study to compare physician-
staffed to non-physician-staffed HEMS for patients with
STEMI. The main findings from our study are that patients
transferred by Standard-HEMS: (1) were more likely to receive
opioid analgesics during transport; (2) were more likely to
receive nitroglycerin and intravenous fluids; and (3) had a
nearly 3-fold higher adjusted risk of in-hospital adverse
outcomes. These differences were not associated with a
statistically significant difference in mortality between the
groups.

A previous study showed that nonphysician HEMS trans-
port of patients with acute coronary syndrome was safe.12

However, that study was not designed to compare different
methods of transportation. A survey of flight nurses showed
that physicians made unique and important contributions to
the care of 18% of patients with MI.13

Outcomes comparison before and after implementation of
physician-staffed HEMS has been done for trauma transport.
One study found that physician-staffed HEMS was associated
with lower mortality of >250 blunt trauma patients.14

Contemporary series have shown several benefits of having
physician-staffed crews for regional trauma systems, includ-
ing faster transport time.15,16

We think that the observed association between Standard-
HEMS and higher rates of adverse in-hospital outcomes, such
as cardiac arrest and cardiogenic shock, might be explained
by several factors. First, the Standard-HEMS group had
slightly longer ECG2B time, but the effects of early revascu-
larization on survival are well known.17 Given that the ground
time and flight time were not significantly different between
the 2 groups, this could be because of shorter transfer time
after landing at the receiving PCI hospital. Or, this could be

Table 4. In-Hospital Outcomes*

Physician-
HEMS (n=327)

Standard-
HEMS (n=71) P Value

Death, n (%) 16 (4.9) 7 (9.9) 0.104

IABP, n (%) 39 (11.9) 15 (21.1) 0.04

Cardiogenic shock, n (%) 18 (5.5) 10 (14.1) 0.01

Bleeding, n (%) 4 (1.2) 2 (2.8) 0.291

Tamponade, n (%) 2 (0.6) 0 1.00

Ventricular free wall
rupture, n (%)

1 (0.3) 0 1.00

Need for dialysis, n (%) 1 (0.3) 0 1.00

Ventilator-associated
pneumonia, n (%)

1 (0.3) 2 (2.8) 0.083

Cardiac arrest, n (%) 4 (1.2) 6 (8.5) 0.003

Serious arrhythmia, n (%) 8 (2.4) 12 (16.9) <0.001

Recurrent MI, n (%) 3 (0.9) 1 (1.4) 0.546

Stroke, n (%) 2 (0.6) 0 1.00

Any adverse event, n (%) 37 (11.3) 18 (25.4) 0.002

Median LOS, days (IQR) 3 (2–3) 3 (2–4) 0.234

Median LVEF, % (IQR) 50 (40–55) 50 (41–56) 0.514

IABP indicates intra-aortic balloon counterpulsation; IQR, interquartile range; LOS, length
of stay; LVEF, left ventricular ejection fraction; MI, myocardial infarction; Physician-
HEMS, physician-staffed helicopter emergency medical service; Standard-HEMS, non-
physician-staffed helicopter emergency medical service.
*Continuous variables are expressed as median�IQR.

Table 5. Predictors of Any Adverse In-Hospital Outcomes of
ST-Elevation Patients Transferred by Helicopter Emergency
Medicine Services*

OR 95% CI P Value

Age 1.01 0.99 to 1.04 0.417

Sex 0.77 0.37 to 1.56 0.462

Killip class 2.17 1.71 to 2.75 <0.001

Ground time 0.94 0.89 to 0.99 0.025

Flight time 1.03 0.96 to 1.10 0.479

Non-physician-staffed HEMS 2.91 1.39 to 6.06 0.004

HEMS indicates non-physician-comprised helicopter emergency medicine flight crews;
OR, odds ratio.
*Any adverse in-hospital outcome was defined as having any of the following: death,
stroke, cardiac arrest, need for intra-aortic balloon pump, bleeding, cardiogenic shock,
new requirement for dialysis, recurrent myocardial infarction, serious arrhythmia, or
vascular complication.

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explained by a delay from first ECG to HEMS arrival. Second,
the Standard-HEMS group was more likely to receive intra-
venous nitroglycerin and opioid analgesics, such as morphine
and fentanyl. This finding could suggest that flight paramedics
and nurses are more likely to give these medications routinely
compared with flight physicians. Interestingly, in this study,
almost 40% of the patients who received nitroglycerin had
RCA as the culprit vessel. Previous studies have shown that
nitroglycerin can cause hypotension and worse outcomes,
particularly in the setting of right ventricular infarction.18,19 In
a recent study, STEMI patients who were given morphine
demonstrated decreased response to antiplatelet agents,
possibly attributed to delayed gastric transit and impaired
absorption. This effect could increase risk of thrombosis and
recurrent MI.20 The 2013 AHA/ACC STEMI guidelines
recommend morphine for chest pain and pulmonary edema,
but this medication has been linked to increased mortality.21

Third, the Standard-HEMS group was more likely receive
intravenous fluid bolus, which could lead to pulmonary edema
in patients who already have a propensity for high left
ventricular filling pressure.

Baseline demographics and cardiovascular disease risk
factors were similar in the 2 groups and thus are unlikely to
explain the difference in outcomes. Also, baseline Killip class—
a strong predictor of adverse outcomes22—was not signifi-
cantly different between the 2 groups. The same was also true
when we compared the demographics and patient manage-
ment transferred to University of Wisconsin without a physician
(n=23) and the Mayo La Crosse group (n=48). The Physician-
HEMS group had a higher rate of LAD occlusion than the
Standard-HEMS group. We think that this difference is also
unlikely to have affected our results because LAD occlusion has
been shown to be associated with worse prognosis,23 which is
contrary to our findings given that the Physician-HEMS group
had lower rates of in-hospital adverse outcomes.

Our study has several limitations that are worth mention-
ing. First, this is a retrospective analysis and is potentially
subject to documentation and recall bias. Second, the
Physician-HEMS group was larger than the Standard-HEMS
group. This is because the majority (>90%) of STEMI patients
transferred by helicopter to the University of Wisconsin is by
physician-staffed HEMS. Third, the overall number of patients
in our study is modest, but still larger than similar studies on
helicopter transport of STEMI patients.6 However, we had
enough clinical events to construct robust models for
multivariable adjustment. The patient cohorts received treat-
ment by 2 different care teams at two hospitals, which is a
potential confounder despite similar baseline characteristics.
Also, the indications for medications (such as nitroglycerin
and analgesics) given during transfer were unavailable, and
thus we could not assess appropriateness of medication
administration.

Furthermore, we were unable to compare troponin con-
centrations (to estimate infarct size) in the 2 groups because
University of Wisconsin uses Troponin-T, but Mayo Clinic uses
Troponin-I. However, we had information on postprocedure
left ventricular ejection fraction (LVEF), and this was not
different between the 2 groups. Because of study design, we
could not report compliance with medications such as anti-
thrombotics or beta-blockers before transfer. However, the
vast majority of the patients received recommended medical
therapy during their acute hospitalization for STEMI. Last, a
more-detailed analysis of the HEMS crews (eg, physician/
registered nurse [RN] vs RN/paramedic or paramedic/
paramedic) may have given additional insight into crew
composition and its association with outcomes.

In conclusion, our findings suggest a higher rate of
in-hospital adverse outcomes in STEMI patients transferred
by non-physician-staffed HEMS. However, there was no
difference in the rate of adverse events during transport.
The higher risk of in-hospital adverse outcomes could be
related to medications such as nitroglycerin or intravenous
analgesics in-flight or because of other patient- or transport-
related unmeasured confounders. The data are retrospective
and thus only hypothesis generating. However, the results
could have important clinical implications if confirmed in
prospective or randomized trials. One potential implication is
a novel recommendation for physician-staffed HEMS in STEMI
transfer systems. A cost-benefit analysis would be helpful
before such implementation because of increased cost
related to the addition of a physician to the flight crew.12

Finally, our results underscore the importance of judicious use
of nitroglycerin and intravenous analgesics for STEMI
patients. Further investigation of administration of these
medications during transport is needed.

Sources of Funding
This project was supported, in part, by the University of
Wisconsin Institute for Clinical and Translational Research
(UW ICTR), funded through an NIH Clinical and Translational
Science Award (CTSA), grant number 1 UL1 TR000427,
NCATS, and the Herman and Gwendolyn Shapiro Summer
Research Program, and the University of Wisconsin School of
Medicine and Public Health Department of Medicine.

Disclosures
None.

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DOI: 10.1161/JAHA.116.004936 Journal of the American Heart Association 6

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