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Fractional flow reserve

Fractional flow reserve (FFR) is a physiological index used in interventional cardiology to evaluate the hemodynamic significance of coronary artery stenoses by measuring the ratio of maximum blood flow distal to a stenosis to the theoretical maximum flow in a normal vessel without stenosis. This guidewire-based technique, performed during invasive coronary angiography, assesses pressure differences across a lesion under conditions of maximal hyperemia, typically induced by intravenous or intracoronary adenosine, to determine if the stenosis causes myocardial ischemia. An FFR value of 0.80 or less indicates a functionally significant lesion warranting revascularization, while values above 0.80 support deferral of intervention in favor of medical therapy. Developed in the early 1990s by Nico H. J. Pijls and colleagues, FFR was first described as a lesion-specific functional measure to guide clinical decisions in cases of intermediate coronary stenoses where alone is inconclusive. The concept gained clinical validation through landmark trials, including the DEFER study (2007), which demonstrated the safety of deferring (PCI) for lesions with FFR greater than 0.75, and the trial (2009), which showed that FFR-guided PCI in multivessel reduced major adverse cardiac events compared to -guided PCI alone. Subsequent studies like FAME 2 (2012) established that FFR-guided PCI plus optimal medical therapy improved outcomes over medical therapy alone in stable ischemic heart with FFR-positive lesions. In current practice, FFR is recommended by major guidelines for assessing intermediate stenoses (typically 40-70% diameter narrowing) in stable ischemic heart disease, with a Class 1 recommendation from the 2021 /AHA/SCAI guidelines for guiding decisions to improve clinical outcomes and avoid unnecessary procedures. It is also reasonable in non-ST-elevation acute coronary syndromes when lesion significance is uncertain (Class IIa) and during concomitant cardiac surgeries for intermediate . While traditionally invasive, non-invasive variants like computed tomography-derived FFR (FFRCT) have emerged as adjuncts for pre-procedural planning, though invasive FFR remains the gold standard for its direct measurement accuracy. Overall, FFR has transformed coronary strategies by emphasizing functional over anatomical , leading to more personalized and evidence-based patient management.

Introduction

Definition and overview

Fractional flow reserve (FFR) is a physiological index that quantifies the functional severity of a coronary artery stenosis by representing the ratio of maximum myocardial blood flow through the stenotic vessel to the maximum flow that would occur in the absence of any stenosis. This ratio is clinically measured as the distal coronary pressure (Pd) divided by the proximal aortic pressure (Pa) during pharmacologically induced maximal hyperemia, providing a lesion-specific assessment independent of systemic hemodynamics. As an invasive diagnostic modality performed during , FFR helps determine whether a is hemodynamically significant and likely to cause myocardial ischemia, thereby informing decisions on or medical . It addresses limitations of , which primarily visualizes anatomical narrowing but poorly correlates with physiological impact. In the absence of , FFR equals 1.0, indicating unimpeded flow; values ≤0.80 signify ischemia-inducing lesions warranting , based on established clinical thresholds derived from physiological and outcome studies. FFR is especially useful for intermediate (40-70% diameter reduction on ), where angiographic appearance alone often fails to predict functional significance.

Historical development

The concept of fractional flow reserve (FFR) emerged in the early 1990s at Catharina Hospital in , , where cardiologists Nico H.J. Pijls and Bernard De Bruyne developed it as a solution to the limitations of coronary flow reserve (CFR), including its variability due to baseline hemodynamic conditions and microvascular resistance. Their work built on foundational pressure-flow relations established in animal models, aiming for a more reliable, lesion-specific index of coronary stenosis severity that could be measured during catheterization. The first clinical description of FFR appeared in 1993, when Pijls and De Bruyne proposed it as an index calculated from maximal hyperemic pressures distal and proximal to a , independent of baseline or collateral circulation. This seminal publication laid the groundwork for FFR as a practical tool for guiding coronary interventions () in intermediate lesions. Validation studies followed in the mid-1990s, with a key 1996 multicenter trial demonstrating FFR's strong correlation with quantitative assessments of impact on myocardial and its lack of dependence on resting states. These efforts established FFR's physiological validity across diverse patient cohorts. Technological advancements accelerated FFR's clinical feasibility in the late , as dedicated pressure-sensing guidewires became available; the Radi Medical Systems PressureWire, a sensor-tipped wire for real-time measurements, received FDA clearance in 1998. Adoption began in , where the technique originated and early evidence supported its use, before expanding to the in the early 2000s amid growing infrastructure. Post-2000s randomized trials marked FFR's shift from investigational tool to guideline-recommended practice, with the DEFER study (2002) showing safety in deferring for nonischemic lesions (FFR >0.75) and the FAME trial (2009) demonstrating reduced major adverse cardiac events through FFR-guided stenting. By the 2020s, FFR had achieved widespread integration into routine care, reflecting its established role in optimizing decisions. As of 2025, FFR remains a cornerstone in guidelines, with ongoing research validating its use in hybrid approaches.

Physiological basis

Coronary physiology fundamentals

The are the primary conduits for delivering oxygenated blood to the myocardium, ensuring that myocardial oxygen consumption is matched to supply under varying physiological conditions. This process is governed by autoregulation, a intrinsic that maintains relatively constant blood flow across a wide range of pressures, typically between 60 and 180 mmHg, by adjusting vascular tone in response to metabolic demands. Autoregulation is mediated through metabolic, myogenic, and endothelial factors, allowing the to adapt to changes in , contractility, and workload without compromising . Coronary stenoses, often due to atherosclerotic plaque buildup, disrupt this balance by increasing hydraulic resistance in the epicardial arteries, which can lead to reduced distal coronary pressure and inadequate myocardial , particularly during periods of heightened demand. The coronary vascular bed is functionally divided into epicardial conductance vessels (large arteries >500 μm in diameter that contribute minimal resistance, approximately 5-10% of total, under normal conditions) and microvascular resistance vessels (arterioles <500 μm that account for the majority of flow regulation through dilation and constriction). Fractional flow reserve (FFR) specifically evaluates the functional impact of epicardial stenoses by isolating their contribution to pressure loss, assuming minimal microvascular resistance during maximal vasodilation. Conventional coronary angiography provides only anatomical visualization of luminal narrowing but fails to assess physiological significance, as stenosis severity correlates poorly with inducible ischemia; for instance, up to 20-30% of intermediate stenoses (40-70% diameter reduction) do not cause flow limitation, while some appear less severe yet induce ischemia. This discrepancy arises because angiography underestimates diffuse disease, lesion eccentricity, and the interplay with microvascular function, leading to frequent mismatches between visual assessment and actual hemodynamic effects. Myocardial ischemia occurs when there is an imbalance between oxygen supply and demand, often unmasked during stress when myocardial oxygen requirements increase by 3-5 times baseline due to elevated heart rate and contractility, but coronary flow reserve is exhausted by stenotic resistance.00209-8/fulltext) Thresholds for ischemia typically manifest when subendocardial oxygen extraction exceeds 80-90% of delivery capacity, resulting in metabolic shifts like lactate production and diastolic dysfunction if perfusion fails to augment adequately.

Role of hyperemia in assessment

Hyperemia refers to the maximal vasodilation of the coronary microvasculature, which is induced during (FFR) assessment to simulate conditions of increased myocardial oxygen demand and thereby unmask the functional significance of epicardial stenoses. This state minimizes microvascular resistance, allowing for the highest possible coronary blood flow and isolating the hemodynamic impact of any stenosis on distal perfusion pressure. The physiological rationale for employing hyperemia lies in the differential response of normal and stenotic coronary arteries to vasodilatory stimuli. In a healthy vessel, adenosine or similar agents cause near-complete dilation of the arterioles, enabling maximal flow without significant pressure loss. However, in the presence of a stenosis, the fixed epicardial narrowing cannot dilate, leading to a pronounced translesional pressure gradient as flow attempts to increase; this gradient reflects the stenosis's ability to limit maximum achievable myocardial blood flow. By achieving this state, FFR measurements capture the relative flow reserve, providing a more accurate indicator of ischemia risk than resting conditions, where autoregulation masks subtle limitations. Common agents for inducing hyperemia include , administered either intravenously (typically 140 μg/kg/min) or intracoronarily (doses of 40–80 μg for the right coronary artery and 80–200 μg for the left), which remains the reference standard due to its reliable and reproducible vasodilation. Alternatives such as (10–20 mg intracoronary), (ATP), or (400 μg intravenous bolus) are also used, particularly when adenosine causes intolerable side effects, though they must achieve equivalent maximal dilation for valid results. Intravenous is preferred in many protocols for its sustained plateau phase, ensuring stable hyperemia throughout pressure recordings. Achieving near-maximal hyperemia is crucial because FFR's validity assumes minimized and constant microvascular resistance; suboptimal vasodilation can overestimate FFR values, underestimating stenosis severity and potentially leading to inappropriate deferral of revascularization. Studies confirm that maximal hyperemia enhances diagnostic accuracy to over 90% for identifying ischemia-causing lesions, as validated in foundational experimental work and clinical trials like .

Measurement and procedure

Step-by-step procedure

The procedure for measuring (FFR) is performed during invasive in patients with stable and intermediate coronary stenoses, typically defined as 40-70% diameter reduction by visual assessment or quantitative . Patient selection prioritizes those without recent , diffuse atherosclerosis, or serial lesions where FFR interpretation may be less reliable. Pre-procedure preparation includes administering unfractionated (at least 50 U/kg intravenously) for anticoagulation and an intracoronary nitrate (e.g., 200 μg or ) to achieve epicardial vasodilation, performed at least 2 minutes prior to measurement. Standard catheterization setup involves engaging the coronary ostium with a guiding catheter without side holes to avoid pressure damping, flushed with saline, and disengaged during hyperemia if it impedes flow. A 0.014-inch pressure-sensing guidewire, such as the PressureWire or WaveWire, is prepared by flushing with saline, calibrating, and laying flat to ensure accurate sensor function without drift. The wire is advanced through the guiding catheter under fluoroscopic guidance, with the pressure sensor positioned proximal to the tip, and crossed through the stenosis to the distal vessel, ideally in the distal two-thirds of the artery and at least 2-3 cm beyond the lesion, confirmed angiographically. Baseline pressures are equalized by positioning the sensor 1-2 mm beyond the guiding catheter tip, zeroing both the aortic (Pa) and distal coronary (Pd) pressure systems to atmospheric pressure, and verifying identical waveforms and values between the guiding catheter and wire; the catheter is disengaged for aorto-ostial lesions to prevent damping. Sensor drift is confirmed to be less than 5 mm Hg by comparing pressures after equalization. Hyperemia is induced to maximize coronary blood flow, using intravenous adenosine infused at 140 μg/kg/min via a central or large peripheral vein for at least 2 minutes to achieve steady-state maximal hyperemia, or intracoronary adenosine as a bolus of 100 μg for the right coronary artery or 200 μg for the left coronary artery, followed by 2-3 mL saline flush to minimize dead space delay. Simultaneous Pd and Pa tracings are recorded continuously for 1-4 minutes (intravenous) or 50-60 seconds (intracoronary) starting 30 seconds after any contrast injection, capturing baseline, peak hyperemia, and recovery phases, with the pressure scale adjusted to optimize waveform visualization on the console. Post-measurement, the wire is slowly pulled back under steady-state hyperemia (preferably with intravenous adenosine) over 15-20 seconds to assess for focal versus diffuse disease, using angiographic landmarks to document positions and bookmark key tracings. The wire is then withdrawn into the guiding catheter, pressures are re-equalized to confirm no drift, and coronary flow is restored by re-engaging the catheter if needed.

Equipment and technical requirements

The measurement of fractional flow reserve (FFR) relies on specialized intravascular pressure-sensing guidewires, typically 0.014-inch in diameter, equipped with sensors located 3 to 3.5 cm from the wire tip to capture distal coronary pressures accurately. These wires must navigate while maintaining guidewire-like torque and flexibility for safe advancement. Pressure sensors in FFR wires are primarily of two types: piezoresistive (also termed piezoelectric or electric) sensors, which detect pressure changes via strain on a resistive element, and optical (fiber-optic) sensors, which measure pressure-induced shifts in light wavelength using Fabry-Pérot interferometry. Piezoresistive sensors, common in systems like the PressureWire X (Abbott), are susceptible to minor thermal drift but offer robust signal transmission; optical sensors, as in the (Opsens Medical) or Comet Wire (Boston Scientific), provide greater stability against drift due to their non-electrical transduction. Alternative devices, such as the Navvus II microcatheter (Acist Medical Systems), use a 0.020-inch catheter with an optical sensor advanced over a standard guidewire, reducing the need for wire exchange in some cases. Console systems interface with the pressure wire to enable real-time monitoring of proximal (aortic) and distal pressures, often via wired or wireless connections, and include software for automated computation, waveform display, and data export in DICOM format. Examples include the OPTIS Imaging System (Abbott) and the Volcano s5i or Core systems (Philips), which integrate pressure data with angiographic imaging for comprehensive physiological assessment. These consoles ensure signal amplification, noise filtering, and storage of raw tracings for post-procedure verification. Standard 6F or 7F guiding catheters are used to engage the coronary ostium, providing a stable platform for wire advancement and proximal pressure measurement; non-side-hole catheters are preferred to avoid damping artifacts during hyperemia. Adequate vessel opacification with iodinated contrast is essential for angiographic confirmation of wire position, typically achieved via hand injections through the guiding catheter. Technical quality requires rigorous sensor calibration and validation: the wire is zeroed to atmospheric pressure prior to insertion, and pressures are equalized electronically with the sensor positioned 1-2 mm beyond the catheter tip to confirm a 1:1 Pd/Pa ratio. Post-measurement drift assessment involves pulling the wire back to the guiding catheter tip and verifying Pd approximates Pa within 1 mmHg or a Pd/Pa ratio change of less than 0.02; excessive drift necessitates repeat measurements or wire replacement. Measures to prevent damping include saline flushing of the system to eliminate air bubbles and avoiding excessive wire coiling in the catheter.

Calculation and interpretation

Mathematical equation

The fractional flow reserve (FFR) is mathematically defined as the ratio of the maximum myocardial blood flow in the presence of an epicardial coronary stenosis to the maximum flow that would be present in the absence of such a stenosis, providing a lesion-specific index of functional severity. This is quantified using pressure measurements obtained during maximal hyperemia, where FFR approximates the relative flow impairment caused by the stenosis. The core equation for FFR, derived from pressure measurements, is given by: \text{FFR} = \frac{P_d - P_v}{P_a - P_v} where P_d is the mean coronary pressure distal to the stenosis, P_a is the mean aortic pressure proximal to the stenosis, and P_v is the central venous pressure, all measured at maximal hyperemia. In clinical practice, P_v is typically negligible (often <5 mmHg) and thus omitted, simplifying the formula to \text{FFR} \approx \frac{P_d}{P_a}. This approximation holds because venous pressure contributes minimally to the overall pressure gradient under hyperemic conditions. The derivation of this equation draws from an analogy to in fluid dynamics, where blood flow (Q) through the coronary circulation is proportional to the pressure gradient divided by total resistance (R): Q = \frac{\Delta P}{R}. At maximal hyperemia, microvascular resistance (R_m) is minimized and assumed constant across the myocardium supplied by the vessel, while epicardial resistance proximal to the stenosis is negligible. Thus, the maximum flow with stenosis (Q_s) relates to the normal maximum flow (Q_n) as Q_s = Q_n \cdot \frac{P_d - P_v}{P_a - P_v}, leading directly to FFR = Q_s / Q_n = \frac{P_d - P_v}{P_a - P_v}. This assumes the stenosis is the primary flow-limiting factor and that pressure serves as a reliable surrogate for flow under these conditions. Key assumptions underlying the equation include that the assessment is lesion-specific (isolating the impact of a single stenosis), with no significant influence from collateral flow or diffuse disease, and that the microvasculature is normal and fully vasodilated. The formula has been validated experimentally against direct flow measurements, such as positron emission tomography (PET), demonstrating strong correlation between pressure-derived FFR and relative myocardial perfusion reserve in both animal models and humans. A rare variation accounts explicitly for elevated P_v (e.g., in right heart failure), but this adjustment is seldom required due to its negligible effect in most patients.

Clinical thresholds and values

The standard clinical threshold for fractional flow reserve (FFR) is ≤0.80, which indicates hemodynamically significant stenosis likely to cause myocardial ischemia. The original validation study reported sensitivity of 88% and specificity of 100% for an FFR threshold of ≤0.75 when compared to noninvasive stress testing. Values above 0.80 are generally considered nonischemic, supporting deferral of revascularization with high negative predictive value exceeding 95%. A gray zone exists between 0.75 and 0.85, where FFR measurements exhibit greater variability and less clear prognostic implications, necessitating clinical judgment that incorporates patient symptoms, lesion characteristics, and overall risk profile; within this range, lower values (closer to 0.75) are associated with incrementally higher risk of adverse outcomes compared to higher values (closer to 0.85). In cases of serial or diffuse involving tandem or multiple lesions, FFR pullback maneuvers are employed during the procedure to differentiate focal pressure drops attributable to specific stenoses from diffuse microvascular or epicardial resistance, thereby identifying the dominant lesion for targeted intervention. Prognostically, lesions with FFR >0.80 that are deferred from are linked to low annual rates of major adverse cardiac events (), typically 1-2% per year, reflecting minimal risk of death, , or urgent .

Clinical rationale and applications

Functional assessment of stenoses

Coronary angiography, while the gold standard for visualizing coronary anatomy, frequently over- or underestimates the functional significance of stenoses in causing myocardial ischemia. For instance, lesions appearing as 50-70% stenoses on angiography may not impair blood flow under stress, as visual assessment relies on two-dimensional projections that fail to account for , , or downstream microvascular resistance. This discrepancy arises because angiography measures luminal narrowing but does not quantify the or flow limitation induced by the stenosis, leading to inappropriate in up to 40% of cases based on angiographic severity alone. Fractional flow reserve (FFR) addresses these shortcomings by providing a lesion-specific functional evaluation that directly measures the translesional loss during maximal hyperemia, reflecting the 's impact on myocardial . This is influenced by the 's —such as its minimal area, , and —as well as the downstream vascular bed, allowing FFR to distinguish hemodynamically significant lesions from those that are anatomically severe but functionally benign. By isolating the contribution of a single in serial or multivessel disease, FFR offers precise, physiology-based insights that cannot, enabling clinicians to assess true ischemic potential without relying on subjective visual interpretation. FFR integrates effectively with intravascular ultrasound (IVUS) and optical coherence tomography (OCT) to provide a comprehensive evaluation, where these imaging modalities detail plaque composition, burden, and vessel wall characteristics that correlate with but do not fully predict FFR values. For example, IVUS can quantify plaque volume and minimal lumen area, while OCT identifies lipid-rich or thin-cap fibroatheroma features; together, they complement FFR's functional data by revealing structural vulnerabilities that may influence pressure gradients, such as increased plaque burden associated with lower FFR. This multimodal approach enhances diagnostic accuracy, particularly in ambiguous cases where anatomical imaging alone is inconclusive. FFR is particularly valuable for assessing intermediate stenoses (typically 40-70% narrowing on ), where its measurement guides whether the is ischemia-causing, as supported by trials like demonstrating improved outcomes with FFR-guided decisions. In post-percutaneous coronary intervention () optimization, targeting an FFR value greater than 0.90 ensures adequate restoration of flow, as values below this threshold post-stenting are linked to higher rates of adverse events due to residual pressure losses.

Guidance for revascularization decisions

Fractional flow reserve (FFR) plays a pivotal role in guiding decisions by providing physiological evidence of ischemia, enabling clinicians to differentiate between medical therapy, (PCI), or coronary artery bypass grafting (CABG) in patients with . Unlike alone, which assesses anatomical severity, FFR evaluates the functional impact of stenoses, helping to avoid unnecessary interventions in non-ischemic lesions while targeting those that compromise myocardial perfusion. This approach aligns with recommendations to use FFR for intermediate stenoses (40-70% diameter reduction) to inform treatment strategies. Deferring in lesions with FFR values greater than 0.80 is a safe strategy that reduces major adverse cardiac events compared to routine angiography-guided . Meta-analyses of clinical studies have demonstrated that FFR-based deferral is associated with lower rates of death, , and repeat over long-term follow-up, with event rates similar to those in patients without significant stenoses. This deferral threshold of 0.80, established through physiological principles, allows for optimized medical management without compromising outcomes. In multivessel coronary disease, FFR facilitates lesion-specific decision-making by identifying hemodynamically significant stenoses, thereby avoiding stenting of non-ischemic lesions and reducing procedural complexity. By assessing each vessel individually during the same procedure, FFR guides selective to culprit lesions, potentially decreasing the number of stents placed and minimizing risks such as restenosis or . This targeted approach is particularly valuable in complex anatomies, where may overestimate the need for complete . FFR application in acute coronary syndromes is context-dependent, with limited utility in ST-elevation (STEMI) due to microvascular stunning that can underestimate lesion significance in the culprit artery. In contrast, FFR is more reliable and preferred in non-ST-elevation (NSTEMI) for evaluating both culprit and non-culprit lesions, as microvascular function is relatively preserved, allowing accurate of ischemia to guide staged . Post-PCI FFR measurement is recommended to confirm physiological and ensure adequate improvement in coronary , with values ideally exceeding 0.88-0.90 indicating optimal deployment and resolution of ischemia. Routine assessment after intervention predicts long-term outcomes, such as reduced target vessel failure, and can identify residual pressure drops due to edge dissections or underexpansion, prompting immediate adjustments. This confirmatory step enhances procedural efficacy and patient prognosis.

Evidence from key studies

DEFER study

The DEFER study, conducted in 2000, was a prospective, single-center randomized trial involving 325 patients with intermediate coronary stenoses (diameter reduction >50% by visual assessment) but without documented ischemia on noninvasive testing within the preceding two months. Patients underwent measurement of fractional flow reserve (FFR) during diagnostic angiography; those with FFR ≤0.75 were assigned to percutaneous coronary intervention (PCI) as the reference group (n=144), while those with FFR >0.75 were randomized to either deferral of PCI (Defer group, n=91) or immediate PCI (Perform group, n=90). The primary endpoint was a composite of major adverse cardiac events (MACE), including cardiac death, acute myocardial infarction, and any further revascularization, assessed over a planned follow-up of 24 months in the original report, with extended 5-year data subsequently analyzed. At 5-year follow-up, event-free survival (freedom from ) was 80% in the Defer group, 73% in the Perform group, and 63% in the reference group, with a statistically significant difference between the reference group and the combined Defer/Perform groups (p=0.03). The rate of cardiac death or was notably low at 3.3% in the deferred group, compared to 7.9% in the Perform group and 15.7% in the reference group (overall p=0.002), demonstrating an annual event rate of less than 1% for deferred lesions with FFR ≥0.75. These findings indicated that deferring in functionally nonsignificant stenoses did not increase adverse events and was at least as safe as performing . Limitations of the DEFER study included its single-center design, lack of blinded core laboratory assessment for , and focus primarily on the safety of deferral rather than broader strategies. Additionally, the trial predated widespread use of drug-eluting stents and targeted mostly single-vessel disease, limiting direct applicability to multivessel scenarios. The DEFER study provided foundational evidence supporting the safety of deferring revascularization for lesions with FFR >0.75, establishing this threshold as a reliable guide for clinical decision-making in intermediate stenoses and influencing subsequent FFR adoption in practice.

FAME and FAME 2 studies

The Fractional Flow Reserve versus Angiography for Multivessel Evaluation (FAME) trial, published in 2009, was a multicenter randomized controlled study involving 1,005 patients with multivessel coronary artery disease undergoing percutaneous coronary intervention (PCI). Patients were assigned to either FFR-guided PCI, where only lesions with FFR ≤0.80 were stented, or angiography-guided PCI, where stenting decisions were based on visual assessment of stenosis severity. The primary endpoint was the 1-year rate of major adverse cardiac events (MACE), defined as death, myocardial infarction, or repeat revascularization, which occurred in 13.2% of the FFR-guided group compared to 18.3% in the angiography-guided group (p=0.02). The FFR strategy also led to fewer stents per patient (1.9 versus 2.7; p<0.001) and a lower rate of death or myocardial infarction (7.3% versus 11.1%; p=0.04), without increasing procedural complications. Subgroup analyses in the FAME trial demonstrated consistent benefits of FFR guidance across key patient characteristics, including those with diabetes (approximately 25% of participants) and varying age groups, with no significant interactions for the primary endpoint. The study was supported by unrestricted grants from Radi Medical Systems (now part of ) and limited funding from Medtronic, raising some concerns about potential industry influence, though the design and analysis were investigator-led. These findings established FFR as a valuable tool for optimizing PCI in multivessel disease by reducing unnecessary interventions. The FAME 2 trial, reported in 2012 with long-term follow-up in 2018, enrolled 1,220 patients with stable angina and at least one stenosis of 50% or greater by angiography; 888 were randomized to FFR-guided plus optimal medical therapy (OMT) versus OMT alone, while 332 with FFR >0.80 formed a registry arm. The primary endpoint was a composite of death, , or urgent . The trial was terminated early after a mean follow-up of 7 months due to significant benefit in the PCI arm (4.3% versus 12.7%; hazard ratio [HR] 0.32, 95% 0.19-0.53; p<0.001), as advised by the data safety monitoring board. At 2 years, the endpoint rate remained lower with PCI (8.1% versus 19.5%; HR 0.39, 95% 0.26-0.60; p<0.001), and 5-year results confirmed sustained benefit (13.9% versus 27.0%; HR 0.46, 95% 0.34-0.63; p<0.001), primarily driven by reduced urgent revascularizations. Subgroup analyses in FAME 2 showed consistent treatment effects across diabetes status, age, and other factors, with greater relative benefit in lesions with FFR <0.65. Economic evaluations indicated cost savings with FFR-guided PCI, with an incremental cost-effectiveness ratio of $17,300 per quality-adjusted life-year at 2 years and $1,600 at 3 years, due to fewer subsequent procedures despite initial PCI costs. Funded primarily by St. Jude Medical (now Abbott), the trial faced criticisms for industry sponsorship and early termination, which limited power for hard endpoints like death or myocardial infarction, where differences were not significant.

Comparisons with instantaneous wave-free ratio (iFR)

Instantaneous wave-free ratio (iFR) is a non-hyperemic index of coronary stenosis severity, defined as the ratio of distal to proximal coronary pressure (Pd/Pa) measured during the wave-free period in late diastole, a specific diastolic interval where microvascular resistance is naturally low and minimal, eliminating the need for adenosine-induced hyperemia. Two pivotal randomized trials, DEFINE-FLAIR and iFR-SWEDEHEART, both published in 2017, directly compared iFR-guided with fractional flow reserve (FFR)-guided percutaneous coronary intervention (PCI) in patients with stable angina or acute coronary syndromes. In DEFINE-FLAIR, 2,492 patients undergoing diagnostic angiography for suspected coronary artery disease were randomized to iFR or FFR guidance; at 1 year, the primary endpoint of major adverse cardiac events (MACE; death, nonfatal myocardial infarction, or unplanned revascularization) occurred in 6.8% of the iFR group versus 7.0% in the FFR group, meeting criteria for noninferiority (difference -0.2 percentage points; 95% CI, -2.3 to 1.8; P<0.001 for noninferiority). iFR guidance was associated with shorter procedural time (median 40.5 vs. 45.0 minutes; P=0.001) and fewer adverse procedural symptoms (3.1% vs. 30.8%; P<0.001). Similarly, iFR-SWEDEHEART enrolled 2,037 patients and found 1-year MACE rates of 6.7% with iFR versus 6.1% with FFR (P=0.007 for noninferiority), confirming iFR's noninferiority while reducing patient discomfort from adenosine (3.0% vs. 68.3%; P<0.001). Economic analyses from DEFINE-FLAIR indicated iFR guidance yielded average 1-year cost savings of $896 per patient compared to FFR, primarily due to avoided adenosine use and shorter procedures. Despite these similarities, FFR and iFR measurements show discordance in approximately 20% of cases, often in borderline or "gray zone" values where clinical decisions may differ. The standard iFR threshold for ischemia is 0.89, analogous to FFR's 0.80, but discordance typically arises in lesions with iFR 0.86-0.93 or FFR 0.75-0.85. To address this, a hybrid iFR-FFR approach has been proposed: measure iFR first, proceeding to FFR only if iFR falls in the gray zone (e.g., 0.86-0.93), thereby minimizing adenosine use while resolving ambiguity in about 60-70% of discordant cases. Long-term follow-up from both trials at 5 years showed no significant differences in MACE rates, supporting noninferiority. For DEFINE-FLAIR (as of 2024 data), 5-year MACE was 21.1% with iFR versus 18.4% with FFR (HR 1.18, 95% CI 0.99-1.42; P=0.06); however, all-cause mortality was higher with iFR (9.0% vs. 6.2%; HR 1.56, 95% CI 1.16-2.09; P=0.01). For iFR-SWEDEHEART, 5-year MACE was 21.5% versus 19.9% (HR 1.09, 95% CI 0.90-1.33).

Advantages and limitations

Advantages

Fractional flow reserve (FFR) offers superior physiological specificity compared to angiography alone, providing a direct assessment of lesion-induced ischemia by measuring the pressure ratio across a stenosis under hyperemia. This approach accurately identifies hemodynamically significant stenoses, reclassifying approximately 30-65% of intermediate lesions (40-70% diameter stenosis) that angiography might otherwise misinterpret, thereby reducing unnecessary percutaneous coronary interventions (PCI) by about 30%. FFR-guided strategies demonstrate strong prognostic value, with long-term follow-up showing a 20-30% reduction in major adverse cardiac events (MACE), including death, myocardial infarction, and repeat revascularization, compared to angiography-guided approaches. This benefit arises from targeting only functionally significant lesions, avoiding overtreatment of non-ischemic stenoses and improving patient outcomes over 2-5 years. In terms of efficiency, FFR is lesion-specific, requiring only targeted measurements that typically take 5-10 minutes per lesion, integrating seamlessly into standard catheterization procedures without significantly extending overall lab time. It is also cost-effective, yielding savings of $1,200-2,000 per patient primarily through fewer stents implanted, as evidenced by reduced procedural and follow-up costs in clinical practice. FFR maintains a high safety profile, with major complication rates ranging from 0.1% to 1%, including rare instances of vessel perforation, dissection, or thrombosis during wire advancement or adenosine administration. By standardizing physiological evaluation, FFR enhances equity in clinical decision-making, minimizing subjective angiographic interpretations and promoting consistent, evidence-based revascularization choices across diverse patient populations.

Limitations and contraindications

Fractional flow reserve (FFR) assessment is an invasive procedure that necessitates cardiac catheterization, exposing patients to the risks associated with vascular access, such as bleeding, hematoma formation, and arterial dissection, albeit at low rates comparable to standard angiography. The induction of maximal hyperemia, typically via adenosine administration, introduces additional patient discomfort and potential adverse effects; common transient symptoms include chest pain or discomfort in approximately 35% of cases, dyspnea in about 35%, and flushing in 37%, while serious complications like ventricular fibrillation occur in roughly 0.2% of procedures. These side effects, though usually self-limiting, can limit patient tolerance and necessitate careful monitoring during the procedure. FFR measurement carries specific contraindications and cautions due to physiological and procedural risks. In acute myocardial infarction, microvascular dysfunction can impair the accuracy of hyperemic response, leading to unreliable FFR values and potential underestimation of lesion significance; thus, it is generally avoided in the acute phase. Assessment of left main coronary artery stenoses is considered high-risk because wire manipulation may provoke ischemia or hemodynamic instability in this critical territory, warranting alternative imaging or non-invasive approaches. Similarly, severe aortic stenosis complicates FFR interpretation due to altered coronary flow dynamics from left ventricular hypertrophy and reduced compliance, often resulting in falsely elevated FFR values that mask true stenosis severity. Technical challenges further limit the reliability of FFR. Pressure wire drift, where the distal sensor position shifts relative to the proximal guide, can introduce measurement errors exceeding 0.05 in FFR value, potentially misclassifying lesion significance in up to 10-15% of cases if not detected and corrected via pullback maneuvers. Inadequate hyperemic response to occurs in approximately 10% of patients, often due to factors like caffeine intake or endothelial dysfunction, leading to overestimation of FFR and false-negative results for ischemia. Operator dependency is a notable issue, as improper wire positioning, suboptimal dosing, or failure to equalize pressures can cause variability in readings, emphasizing the need for standardized protocols to minimize errors. Beyond procedural aspects, FFR has inherent limitations in clinical evaluation. It primarily assesses hemodynamic significance of stenoses under hyperemia but does not evaluate plaque composition or vulnerability, such as thin-cap fibroatheromas, which may pose thrombotic risk independent of flow limitation. Additionally, in low-volume centers, the procedure incurs higher costs, ranging from $800 to $1,500 per case, driven by equipment amortization, specialized training, and lower procedural efficiency compared to high-volume facilities.

Current guidelines

ACC/AHA recommendations

In the 2021 ACC/AHA/SCAI Guideline for Coronary Artery Revascularization, fractional flow reserve (FFR) receives a Class 1 recommendation (Level of Evidence: A) for assessing intermediate coronary stenoses (40%-69% diameter stenosis) in patients with stable ischemic heart disease (SIHD) to guide decisions on (PCI). Specifically, in patients with SIHD undergoing , stenoses should be evaluated using FFR (or instantaneous wave-free ratio [iFR]), with recommended for lesions showing FFR ≤0.80 (or iFR ≤0.89) and deferral considered reasonable for FFR >0.80 (or iFR >0.89). This physiological assessment is preferred over alone, supported by Level A evidence from the trials demonstrating reduced with FFR-guided compared to -guided approaches in multivessel disease. The 2014 ACC/AHA focused update on stable ischemic heart disease provided a Class IIa recommendation (Level of Evidence: B) for using FFR to evaluate the hemodynamic significance of angiographically intermediate or indeterminate lesions, aiding decisions on whether PCI would be beneficial or safely deferred, particularly in multivessel . These principles were integrated into the 2023 / Guideline for the Management of Patients With Chronic Coronary Disease, which endorses FFR-guided (FFR ≤0.80) as superior to medical therapy alone for reducing in stable , including multivessel cases, while noting low event rates with medical therapy for FFR >0.80 (or iFR >0.89). The 2023 guideline further highlights FFR's cost-effectiveness in guiding , with an incremental cost-effectiveness ratio of approximately $1,600 per at 3 years. The 2025 ACC/AHA/ACEP/NAEMSP/SCAI Guideline for maintains prior recommendations on physiological guidance like FFR for non-culprit lesions where uncertainty exists. By 2025, ACC/AHA guidance has emphasized FFR's role in (ACS) subsets, informed by trials like FULL REVASC, which evaluated FFR-guided complete of nonculprit lesions in STEMI patients but did not show a significant benefit over usual care. Additionally, in patients undergoing transcatheter implantation (TAVI) with concomitant , FFR assessment of intermediate lesions post-TAVI is supported for guiding , as evidenced by the FAITAVI trial demonstrating reduced mortality and ischemia-driven without increased bleeding risk. This aligns with broader ACC/AHA preferences for physiological over angiographic guidance in such high-risk scenarios.

ESC guidelines

The (ESC) endorses fractional flow reserve (FFR) as a key physiological tool for guiding in both chronic coronary syndromes () and acute coronary syndromes (ACS), emphasizing its role in assessing intermediate coronary stenoses to improve clinical outcomes. In the 2024 ESC Guidelines for the management of chronic coronary syndromes, physiological assessment using FFR or (iFR) receives a Class I recommendation with Level A evidence for evaluating the functional significance of intermediate stenoses (typically 50–90% diameter reduction) identified on invasive coronary , particularly to determine the need for in patients with suspected . This approach is preferred over alone to avoid unnecessary interventions and is supported by high-quality randomized trial data demonstrating reduced major adverse cardiac events. The 2018 ESC/EACTS Guidelines on myocardial revascularization highlight FFR's utility in optimizing multivessel (), recommending its use (Class I, Level A) to assess intermediate stenoses and defer when FFR exceeds 0.80, as this threshold indicates non-hemodynamically significant lesions with low risk of future events. This guidance aims to personalize therapy in stable ischemic heart disease, balancing procedural risks with evidence-based benefits. Regarding ACS, the 2023 Guidelines for the management of acute coronary syndromes assign a IIb recommendation (Level B) to FFR-guided of non-culprit lesions during the in ST-elevation (STEMI) patients with multivessel disease, allowing for staged or immediate based on FFR values to mitigate ischemia without routine application in the hyperacute phase. These guidelines reinforce FFR's role in non-ST-elevation ACS (NSTE-ACS) for evaluating non-infarct-related artery stenoses, promoting its selective use to support complete strategies informed by trials like COMPLETE and . The 2024 ESC guidelines highlight the role of (CT-FFR) as an emerging tool for functional assessment in chronic coronary syndromes.

Emerging developments

Non-invasive FFR (FFR-CT)

Non-invasive fractional flow reserve derived from (FFR-CT) represents a computational approach to assess coronary artery physiology without catheterization. It utilizes standard (CCTA) images to generate a three-dimensional model of the , applying (CFD) to simulate blood flow under hyperemic conditions. This simulation incorporates patient-specific anatomy, allometric scaling laws for vessel tapering, and assumptions about microvascular resistance to estimate pressure drops across stenoses, yielding FFR values along the entire epicardial vasculature. Developed by HeartFlow, Inc., this method was granted de novo FDA clearance in December 2014 for evaluating stable symptomatic patients with suspected (CAD). Clinical validation has demonstrated FFR-CT's diagnostic accuracy against invasive FFR, with a per-vessel accuracy of 81.9% (95% CI, 79.4%-84.4%) in a of multiple studies. Higher confidence thresholds, such as FFR-CT values below 0.53 or above 0.93, achieve up to 95% accuracy, supporting its role in ruling out or confirming ischemia. In real-world application, the ADVANCE registry enrolled over 5,000 patients across 38 sites and found that FFR-CT altered planned management in 65% of cases compared to CCTA alone, often reclassifying stenoses and guiding referrals more precisely. This reclassification contributed to lower rates of invasive coronary (ICA), with only 40% of patients recommended for ICA despite 72% showing obstructive disease on CCTA, and high revascularization rates (72.6%) among those who proceeded. Key advantages of FFR-CT include reducing unnecessary cath referrals and improving procedural efficiency. In the randomized trial, an on-site FFR-CT strategy decreased the proportion of patients undergoing ICA without obstructive CAD from 46.2% to 28.3%, while maintaining similar clinical outcomes. By providing lesion-specific functional data, it helps avoid invasive testing in low-risk cases and optimizes planning for those needing intervention. However, limitations persist due to its reliance on CCTA, which involves (typically 3-5 mSv) and (70-100 mL), posing risks for patients with renal impairment or radiation sensitivity. Additionally, heavy coronary can degrade image quality through blooming artifacts, potentially affecting model accuracy in up to 25% of severely calcified cases, though FFR-CT generally outperforms anatomic assessment alone in such scenarios.

Future research directions

Ongoing research into hybrid approaches combining instantaneous wave-free ratio (iFR) and (FFR) seeks to address discordance between these indices, which occurs in approximately 20% of cases and may influence decisions. (AI) algorithms are being explored to resolve such discrepancies by integrating physiological data from both metrics, potentially improving diagnostic accuracy in intermediate lesions. For instance, the WiFi II study proposes a hybrid quantitative flow ratio (QFR)-FFR strategy with a grey zone of 0.78–0.87 to guide interventions, warranting further validation in larger cohorts. The FAST III trial (NCT04931771), a multicenter randomized involving 2,228 patients with enrollment completed in 2024, evaluates whether a virtual FFR (vFFR)-guided strategy is non-inferior to wire-based FFR in terms of clinical outcomes, offering insights into wire-free hybrid assessments that could incorporate iFR elements for broader applicability; primary results are expected in 2025. Integration of and () with FFR is advancing analysis, particularly for diffuse through virtual pullback assessments. Systems like AutocathFFR employ on standard images to estimate FFR in without pressure wires, enabling rapid evaluation of tandem or diffuse lesions. Similarly, QFR-derived pullback (PPG) indices use to quantify distribution along the vessel, predicting adverse events with a of 2.7 for high-PPG cases at two years. These tools facilitate from two or three angiographic views, as in FFRangio, which generates volumetric reconstructions for whole-tree and supports planning in complex anatomies. Reduced-order modeling further accelerates computations by 25-fold compared to traditional methods, with mean absolute errors below 0.05. Broader applications of FFR are under investigation beyond . The FLASH-RENAL trial (NCT06447740), currently recruiting, randomizes patients with atherosclerotic to FFR-guided stenting versus optimal medical therapy if FFR <0.80, aiming to assess control and renal function preservation. In post-coronary artery bypass grafting (CABG) settings, future FFR use may increase arterial grafts and hybrid procedures by deferring non-significant lesions preoperatively, potentially reducing wait times and re-intervention rates; non-invasive FFR-CT could aid in detecting graft failures for re-do decisions. Long-term studies are extending FFR outcome data to 10 years, emphasizing diverse populations for global equity. The DANAMI-3-PRIMULTI trial's 10-year follow-up in STEMI patients with multivessel showed FFR-guided complete reduced the composite of death, , or ( 0.76; 95% CI 0.60–0.94) compared to infarct-artery-only treatment, with an absolute risk reduction of 13%. Recent all-comer trials, including PIONEER-IV (NCT04923191) and FAVOR III (NCT03729739), have demonstrated the non-inferiority of angiography-derived QFR guidance compared to wire-based FFR or usual care in outcomes. The FAVOR III trial, published in 2024, found QFR-guided non-inferior to FFR-guided for 12-month target vessel failure (8.2% vs. 9.6%; difference -1.5%, 95% CI -4.7 to 1.7). Similarly, PIONEER-IV results from September 2025 confirmed non-inferiority of QFR to usual care (including FFR/iFR) for patient-oriented composite endpoints at . These findings support broader adoption of wire-free physiological assessments in diverse patient populations.

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