Description

Two mechanisms are primarily involved in the pathophysiology: structural and functional impairment, which can affect both epicardial and microcirculatory arteries and may also be combined. Thus, from a clinical point of view, two basic endotypes are distinguished in ANOCA: 1) microvascular angina (MVA) due to structural damage of microcirculation (coronary microvascular dysfunction - CMD), or functional microvascular vasospasm (angina and ECG changes without epicardial vasospasm on acetylcholine testing) and 2) epicardial vasospastic angina (VSA) - angina, ECG changes and vasospasm on acetylcholine testing (Table 1).

1. Microvascular Angina (MVA) (FFR > 0,80, iFR > 0,89)
   • coronary microvascular dysfunction (CMD) (CFR < 2,0 (2,5), MRR < 2,1, IMR > 25)
   • microvascular vasospasm (angina + ECG changes + < 90% epicardial spasm during Ach testing)
2. Vasospastic Angina (VSA) (angina + ECG changes + > 90% epicardial spasm during Ach testing)
3. Non-coronary chest pain (negative thermodilution and Ach testing)

Table 1 - ANOCA endotypes. FFR - fractional flow reserve, iFR - instantaneous wave-free ratio, CFR - coronary flow reserve, MRR - microvascular resistance reserve, IMR - index of microcirculatory resistance, EKG - electrocardiogram, Ach - acetylcholine.

The clinical manifestation of ANOCA includes a wide range of symptoms that reduce the quality of life and are often misdiagnosed, mistreated, and not infrequently, leading to repeated hospitalizations and invasive investigations. At the same time, patients with both MVA and VSA have a poorer long-term prognosis. Direct assessment of the response of the coronary microcirculation to vasodilator stimuli and diagnosis of vasomotor abnormalities are crucial for accurate stratification and selection of treatment strategies for patients with ANOCA, resulting in reduced angina severity and improved quality of life compared to standard care. Comprehensive invasive coronary functional testing (CFT) is currently the only diagnostic method to establish a definitive diagnosis and characterize a specific ANOCA endotype, supported by professional societies' current recommendations.

CFT consists of a complete invasive assessment of epicardial and microcirculatory structural and functional disorders. It starts with coronary angiography (CA) to exclude structural epicardial CAD accompanied by testing of the hemodynamic significance of epicardial stenoses by a hyperemic or non-hyperemic index (i.e., fractional flow reserve (FFR) or instantaneous wave-free ratio (iFR)) if necessary. When there is no significant epicardial CAD, the protocol continues with coronary thermodilution to investigate microcirculatory function by measuring intracoronary blood flow and resistances by temperature-pressure intracoronary wire (PressureWire X, Abbott) during rest and hyperemia caused by saline solution infused by a dedicated microcatheter (RayFlow, HexaCath). Coroventis software calculates the coronary flow reserve (CFR) and microvascular resistance reserve (MRR) or index of microcirculatory resistance (IMR) when using bolus thermodilution. CMD occurs when CFR and MRR are reduced, or IMR is increased (Table 2). The last part of the CFT aims to test coronary vasoreactivity to an intracoronary bolus of Acetylcholine (Ach), which should cause vasodilatation in physiological circumstances; however, it may lead to vasoconstriction and vasospasm if endothelial dysfunction or imbalance between vasodilatation and vasoconstriction vascular pathways. The Ach test is positive for VSA when Ach induces symptoms typical for the patient (the reason for the invasive examination), ischemic EKG changes, and proven epicardial spasm by angiography after Ach bolus. When there are only typical symptoms and ischemic EKG changes, but without visible epicardial spasms on angiography, it is concluded as microvascular vasospasm (a sub-endotype of MVA). When all three parts of CFT are negative (CA for epicardial structural CAD, thermodilution for microvascular structural CAD, and Ach testing for vasospasm), the symptoms are suggested to be non-coronary or non-cardiac.

Abbreviation Parameter Methodology Pathology Calculation

1. CFR coronary flow reserve intracoronary Doppler, thermodilution < 2,0-2,5 Doppler: APVhyper/APVrest bolus thermodilution: Tmn,rest/Tmn,hyper cont. thermodilution: Qhyper/Qrest
2. IMR index of microcirculatory resistance bolus thermodilution > 25 Pd x Tmn during hyperemia
3. MRR microvascular resistance reserve continuous thermodilution < 2,1 (CFR/FFR) x (Pa,rest/ Pa,hyper) (Qhyper/Qrest) x (Pa,rest / Pd,hyper)
4. Rmikro absolute resistance continuous thermodilution > 500 WU Pd/Q

Table 2 - Microcirculatory indexes. CFR - coronary flow reserve, MRR - microvascular resistance reserve, IMR - index of microcirculatory resistance, Rmikro - absolute resistance, APV - average peak velocity, Tmn - mean transit time, Q - flow, Pd - distal pressure, FFR - fractional flow reserve, Pa - aortic pressure, WU - Wood Units.

Given all the evidence outlined above, a hypothesis has been formulated:

Specific ANOCA endotypes differ in prevalence, clinical presentation, and therapeutic management. A tailored approach based on leading pathophysiology would improve symptoms and quality of life. EAT plays an important role in the development and pathophysiology of CMD and vasospastic disorders.

The aim is to evaluate the practice of patient selection for the assessment of ANOCA endotypes, including indications, ischemia tests performed, medications prescribed, procedural aspects of microcirculation, and changes in evaluation and treatment following testing. Additionally, investigators seek insight into adverse cardiovascular events in these patients following invasive coronary physiology. Furthermore, the aim is to investigate the pathophysiology of microvascular dysfunction and coronary vasospastic disorders, specifically the relationship between EAT measured by CMR and CMD measured by invasive hemodynamic techniques.

Within this aim, the following specific goals will be addressed:

Aim 1: To assess the practice of patient selection for assessment of invasive coronary physiology, including vasospasm testing and estimation of microcirculation by measuring CFR and IMR or MRR.

Aim 2: To assess procedural aspects of invasive coronary physiology - how parameters mentioned above are measured in the catheterization laboratory.

Aim 3: To assess patients' treatment and changes after invasive coronary physiology measurements at each follow-up visit.

Aim 4: To compare the cardiovascular outcomes and additional procedures (stress testing, angiography, etc.) done after comprehensive invasive coronary physiology evaluation.

Aim 5: To correlate the volume of EAT measured by CMR with results of CFT, especially CFR, MRR, IMR, and vasospasms.

To address these specific goals, the investigators plan to employ the following experimental models and the following drugs.