Myocardial Infarction Clinical Trial
Official title:
A Developmental Clinical Study of Management Guided by Coronary Angiography Combined With Fractional Flow Reserve (FFR) Measurement Versus Management Guided by Coronary Angiography Alone(Standard Care) in Patients With Non-ST Elevation MI.
Background: In patients with acute non-ST elevation myocardial infarction (NSTEMI) coronary
arteriography is usually recommended however visual interpretation of the coronary angiogram
is subjective. A complementary diagnostic approach involves measuring the pressure drop
across a coronary stenosis (fractional flow reserve, FFR) with a pressure-sensitive
guidewire.
Hypothesis: Routine FFR measurement is feasible in NSTEMI patients and has additive
diagnostic, clinical and health economic utility, as compared to angiography-guided standard
care.
Design: A prospective multi-center randomized controlled trial in 350 NSTEMI patients with
≥1 coronary stenosis ≥30% severity (threshold for FFR measurement). Patients will be
randomized immediately after coronary angiography to the FFR-guided group or
angiography-guided group (FFR measured, not disclosed). All patients will then undergo FFR
measurement in all vessels with a coronary stenosis ≥30% severity. FFR will be measured in
culprit and non-culprit lesions in all patients. FFR will be disclosed to guide treatment in
the FFR guided-group but not disclosed in the 'angiography-guided' group. In the FFR-guided
group, an FFR>0.80 will be an indication for medical therapy whereas an FFR≤0.80 will be an
indication for revascularization by percutaneous coronary intervention (PCI) or coronary
artery bypass surgery (CABG), as appropriate. The primary endpoint is the between-group
difference in the proportion of patients allocated to medical management compared to
revascularization. A key secondary composite outcome is the occurrence of cardiac death or
hospitalization for myocardial infarction or heart failure. Other secondary outcomes include
quality of life, hospitalization for unstable angina, coronary revascularization or stroke,
and healthcare costs. Exploratory analyses will also assess the relationships between FFR
and angiographic lesion characteristics (severity, culprit status). The minimum and average
follow-up periods for the primary analysis are 6 and 18 months respectively. A secondary
analysis with longer term follow-up (minimum 3 years) is planned. Screen failures who gave
informed consent will be entered into a registry.
Importance: Our developmental clinical trial will address the feasibility of FFR measurement
in NSTEMI and the influence of FFR disclosure on treatment decisions and health and economic
outcomes.
Background
Acute non-ST elevation myocardial infarction (NSTEMI) is the commonest form of acute
coronary syndrome (ACS) and a leading global cause of premature morbidity and mortality. A
coronary angiogram is recommended in intermediate-high risk NSTEMI patients to detect
obstructive coronary artery disease (CAD) and so identify patients who may benefit from
coronary revascularization. In ACS patients, stress testing before invasive management is
not recommended and so functional information on ischemia is usually not available.
Therefore, usual care is based on visual interpretation of coronary disease severity
revealed by the angiogram and treatment decisions include medical therapy, percutaneous
coronary intervention (PCI) or coronary artery bypass surgery (CABG). Since visual
assessment of the angiogram may be inaccurate, judgements made by cardiologists in every day
practice are subjective, potentially leading to misdiagnosis and incorrect treatment
decisions.
Recent studies (DEFER, FAME, FAME II) in patients with stable coronary artery disease (CAD)
have presented a new approach to the diagnostic management of CAD. Fractional flow reserve
(FFR) is an index of the physiological significance of a coronary stenosis and is defined as
the ratio of maximal blood flow in a stenotic artery to normal maximal flow. An FFR ≤0.80 is
an evidence-based physiological threshold that correlates with the presence of inducible
ischemia on non-invasive testing. Alternatively, an FFR >0.80 indicates that patients can be
managed safely with medical therapy. DEFER and FAME highlighted the benefits of FFR
measurement in stable CAD to more accurately identify flow-limiting stenoses and guide PCI
leading to improved outcomes and reduced costs compared to angiography alone. In FAME 2,
compared to optimal medical therapy alone, PCI combined with optimal medical therapy reduced
the likelihood of urgent revascularization in patients with stable symptoms and functionally
significant coronary disease. Overall, FFR measurement can identify and exclude obstructive
coronary artery disease with high diagnostic accuracy, including in patients with prior MI.
FFR measurement in unstable coronary artery disease
There is some uncertainty over the validity of FFR when measured in patients with recent MI.
FFR measurement requires maximal coronary hyperemia which theoretically may be less readily
achieved in patients with recent MI, potentially, because of microvascular injury.
The results of several recent studies support the notion that FFR measurements are valid in
medically stabilized MI patients. First, Ntalianis et al measured FFR in 112 non-culprit
coronary lesions repeatedly (average interval 35±4 days) in 101 patients with recent MI and
found similar FFR values at each time-point. In one other study, FFR correctly identified
inducible ischemia on SPECT in 57 patients >6 days after MI and in one other study of 124
ACS patients, deferring revascularization in lesions with an FFR ≥ 0.75 was safe during
longer term follow-up. In hospitalized patients with recent MI and angiographic intermediate
coronary lesions, FFR-guided management reduced in-hospital costs compared to deferred
management with revascularization guided by myocardial stress perfusion scintigraphy.
Finally, nearly one third of the patients randomized in FAME had a history of medically
stabilized unstable angina or NSTEMI five or more days from randomization. The FAME
investigators performed a post-hoc analysis of these patients and found a similar risk
reduction for major adverse cardiovascular events in the FFR group compared to the
angiography-guided group leading them to conclude that the benefit of using FFR to guide PCI
in multivessel disease may not differ between patients with unstable vs. stable coronary
disease. The FAME investigators concluded that their post hoc analysis could not prove
equivalence of effects between subgroups since FAME was neither designed nor powered to do
so.
Therefore, the potential diagnostic, prognostic and health economic impact of FFR
measurement to inform the management of unselected patients with recent (i.e. < 5 days)
medically stabilized NSTEMI has not been established.
Specific uncertainties with angiography-guided treatment decisions in NSTEMI.
First, treatment decisions for non-obstructive (FFR>0.80) culprit CAD lack an evidence base
to guide management. On the one hand, a stent which covers a ruptured coronary plaque might
reduce the risks of recurrent thrombosis. On the other hand, optimal medical therapy with
dual anti-platelet drugs and high dose statins might suffice and unnecessary stenting can be
harmful (e.g. stent thrombosis). Second, in NSTEMI patients with multivessel coronary
disease, evidence is lacking as to whether non-culprit obstructive lesions should undergo
revascularization or not. A post-hoc analyses of the contemporary large scale Acute
Catheterization and Urgent Intervention Triage Strategy (ACUITY) trial found that incomplete
coronary revascularization was a multivariable predictor of major adverse cardiac events at
1 year and the risk was related to the number of non-revascularized lesions. A post hoc
analysis of NSTEMI patients treated during usual care has found that FFR disclosure does
influence cardiologists' treatment decisions leading to improved diagnostic efficiency
compared angiography-guided decisions. Third, uncertainties remain about whether maximal
coronary hyperemia can be achieved in patients with recent MI using the standard dose of
adenosine (140 micrograms/kg/min) or whether higher doses of adenosine (170 - 210
micrograms/kg/min) might be needed. This question is relevant since sub-maximal coronary
vasodilatation could be associated with a falsely elevated FFR value which in turn could
result in an inappropriate decision in favor of medical therapy rather than
revascularization.
Rationale for a trial of FFR-guided management vs. angiography alone in NSTEMI.
FFR measurement is not a current standard of care in NSTEMI patients. Therefore, in our
study, FFR will be measured but not disclosed in the angiography-guided control group.
Second, FFR values and their relationships with clinical outcomes may differ in patients
with unstable coronary disease compared to patients with stable coronary disease. In our
trial, FFR will be measured in all patients including in the angiography-guided control
group (175 patients) in whom FFR will be measured but not disclosed to the clinical team
responsible for the patient. Since patients will be followed-up for clinical events, the
relationships (and ROC values) between FFR and health outcomes (composite cardiovascular
events) will be prospectively evaluated.
Third, since stress testing is not appropriate in acute MI patients, FFR-guided management
could obviate the need for 'deferred' management. Fourth, FFR has the potential to guide the
decision for or against revascularization of culprit and non-culprit lesions. Since there
are no data to support stenting in lesions which are not functionally significant, the
investigators propose that the treatment decisions are consistently guided by the FFR values
in both culprit and non-culprit arteries using the established FFR threshold of 0.80 for
revascularization. Non-flow limiting lesions (FFR>0.80) would be treated with optimal
medical therapy and flow-limiting lesions (FFR≤0.80) should revascularized by PCI or CABG.
Fifth, when stenting is performed, the post-stent FFR can be used to ensure that an optimal
stent result is achieved i.e. an FFR >0.9 in both the culprit and non-culprit lesions
treated by PCI.
Study Hypothesis
Routine FFR measurement is feasible in NSTEMI patients and has additive diagnostic, clinical
and health economic utility, as compared to current standards of care based on visual
assessment of the angiogram.
Methodology
Overall aim: To generate evidence that will permit (or not) the development of new
diagnostic and disease management strategies which will accurately and efficiently
distinguish between flow limiting and non-flow limiting coronary stenoses, a major challenge
in current revascularization strategies in patients with recent MI directed by angiography
alone.
Primary Aims:
1) To determine if the treatment and outcomes of NSTEMI patients whose management is guided
by FFR disclosure differ compared to patients whose treatment is guided by visual
interpretation of the angiogram alone (FFR measured, not disclosed).
Secondary Aims:
1. To determine the feasibility and safety of routine coronary guidewire-based FFR
measurement in NSTEMI,
2. To determine the level of agreement between functional (FFR) and visual assessments of
coronary disease severity in NSTEMI patients,
3. To assess the proportion of patients with a clinical response to adenosine (initial
dose of 140 µg/kg/min, maximum dose 210 µg/kg/min), as revealed by typical changes in
heart rate and blood pressure and the occurrence of patient symptoms,
4. To determine the relationships between FFR values during the baseline procedure (and
receiver operating characteristic) and cardiac events during follow-up in all patients,
5. To provide preliminary data on whether FFR-guided management is associated with
improved health outcomes and quality of life in the longer term compared to
angiography-guided treatment decisions,
6. To perform a health-economic analysis.
Standard care of NSTEMI patients in the UK National Health Service
The participating hospitals adhere to current guidelines for optimal medical therapy and
optimal revascularization. A left main stenosis of >50% and an epicardial coronary stenosis
>70% are usually taken to be obstructive lesions for which revascularization should be
considered. In usual care, FFR is normally measured in a minority of patients (<10% of
patients overall) and is not standard care. Patients who may be candidates for CABG will be
discussed at the Multidisciplinary Heart Team meeting in each center. If staged PCI is
clinically indicated then all procedures should take place during the index hospitalization.
Setting and Design
A prospective randomized controlled trial will be conducted in up to 6 UK centers including
3 academic cardiothoracic centers and 3 non-academic regional hospitals.
Study population
The investigators estimate 1400 consecutive NSTEMI patients with known or suspected Type 1
MI will be screened before coronary angiography. The inclusion and exclusion criteria are
listed below. Patients who have given informed consent but were not randomized will be
included in a follow-up registry.
Catheter laboratory study protocol
Once the coronary angiogram has been obtained, the cardiologist will assess whether or not
the patient is eligible based on angiographic criteria to continue in the study and be
randomized. If this is the case, randomization should take place immediately in the catheter
laboratory. All eligible patients will be included wherever possible to minimize selection
bias.
The main angiographic inclusion criterion is the presence of one or more non-critical
coronary stenoses ≥30% severity which are (1) amenable to revascularization, (2) associated
with normal coronary blood flow (TIMI grade III) and (3) in the opinion of the attending
cardiologist FFR measurement is feasible and may have diagnostic value. Although an
epicardial coronary stenosis of 70% is usually accepted as a threshold for
revascularization, a minimum stenosis severity of 30% is adopted for FFR measurement in our
study because stenosis severity may be visually underestimated. Inclusion of a stenosis >90%
severity is permissible provided the cardiologist believes FFR has the potential to
influence the treatment decision based on coronary and patient characteristics. Left main
stem disease is included and the upper limit for stenosis severity is 80%. The pressure wire
(Certus, St Jude Medical, Uppsala) will be used to provide an FFR value across all coronary
narrowings ≥30% severity as appropriate.
Randomization
Once the coronary angiogram has been acquired, the cardiologist will then confirm whether or
not the patient is eligible for randomization. In this case, before randomization the
cardiologist will initially state the treatment plan based on the available clinical
information including the angiogram. The treatment plan will then be recorded by the
research team. Next, randomization will then follow-on immediately using a web-based
computer randomization tool provided by the independent Clinical Trials Unit. Ineligible
patients will be entered into a registry.
FFR informed group: FFR will be measured by the cardiologist immediately after randomization
and the FFR result will used to guide treatment decisions based on a threshold of 0.80. An
FFR ≤ 0.80 should result in a treatment decision for revascularization by PCI or CABG
combined with optimal medical therapy and an FFR>0.80 should result in treatment with
optimal medical therapy alone. Changes in treatment compared to the treatment plan prior to
FFR disclosure will be recorded at the time.
Angiography-guided group and blinding: The patient and the clinical team responsible for the
patient, including the interventional cardiologists and nurses, will be blinded to FFR. The
RadiAnalyzer Xpress (St Jude Medical, Uppsala) will be turned away such that it is
impossible for the clinical team to see the data which will be collected by the research
team. The pressure wire recording will not be displayed on any other monitor in the catheter
laboratory. Quality control checks, such as assessments of equalized pressure recordings and
verification of hemodynamic changes with intravenous adenosine, will be conducted in the
usual way, with the guidance of the unblinded clinical research team. These steps will be
followed for all FFR measurements. Adherence to the blinding protocol, including any
non-protocol disclosure of FFR at any time, will be prospectively recorded and blinding
procedures will be monitored with site visits.
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