Cardiovascular disease is the leading cause of death across the world, predominantly related to atherosclerosis [1]. Diabetes mellitus is one of the major risk factors for premature atherosclerotic coronary artery disease (CAD). Patients with diabetes mellitus are also susceptible to microvascular dysfunction. Endothelium-dependent vasodilation and microvascular coronary flow are frequently abnormal in patients with diabetes [2] and both are partly responsible for the observed increased cardiac morbidity and mortality in patients with diabetes mellitus.

Safety trials of contemporary hypoglycaemic treatments for type-2 diabetes mellitus have demonstrated beneficial reductions in cardiovascular outcomes [3‐6]. One class of drugs—the incretin hormone, Glucagon-like peptide (GLP)-1, stimulates glucose-dependent insulin release and suppresses glucagon resulting in hypoglycaemia [7]. GLP-1, as well as its analogues, such as semaglutide and liraglutide, also improve long-term cardiovascular outcomes with reduction in myocardial infarction and cardiovascular death for patients with diabetes [3, 6, 8]. GLP-1 has been shown to improve left ventricular function during ischaemia–reperfusion injury [9, 10]. However, the underlying mechanism of these of target GLP-1 effects is not well understood [11], although the GLP-1 receptor is expressed in heart tissue and in particular on vascular smooth muscle cells [12].

Adenosine is a naturally occurring compound that binds to A2A and A2B receptors in the microcirculation [13], exerting a potent vasodilatory effect in vessels below 150 µm [14]. Our previous work has shown that GLP-1 causes coronary microvascular vasodilatation and increases coronary flow velocity in humans [15]. Animal studies have shown that alogliptin, an inhibitor of dipeptidyl peptidase (DPP)-4, a ubiquitous enzyme responsible for the degradation of active GLP-1(7–36) to GLP-1(9–36), exerts its cardioprotective effect on infarct size reduction via an adenosine receptor-dependent pathway [16]. A similar adenosine-dependent mechanism may be responsible for the cardioprotective effect of GLP-1 in humans, although this has not yet been explored.

We have undertaken a mechanistic study to explore whether GLP-1 causes coronary microvascular vasodilatation via an adenosine-mediated pathway in humans.

This study demonstrates that GLP-1 does not increase circulating adenosine levels, and that GLP-1-induced reduction in Tmn and BMR at rest was not attenuated by co-administration of the adenosine receptor antagonist theophylline. This indicates that GLP-1 exerts an adenosine-independent vasodilatatory effect.

GLP-1 receptor agonists are associated with improved long-term cardiovascular outcomes [6, 23] and a variable reduction in infarct size in previous human studies [8, 9, 24, 25]. Adenosine is a naturally occurring vasodilator and is a cellular mediator of cardioprotective ischaemic conditioning (IC) [26] by directly activating phospholipase C and/or protein kinase C (PKC) via adenosine 1 receptors (A1R), which are widely present in myocardial tissue [27, 28]. GLP-1 activates protein kinase A (PKA) along with other physiologically active metabolites at a cellular level [29]. The cross talk between PKC and PKA is well established and activation of PKA could in theory result in reduction of the activation threshold of PKC, thus potentiating the cardiac effects of adenosine [30, 31]. This PKC and PKA interaction has been postulated to be the underlying physiological mechanism of adenosine-mediated cardioprotection by GLP-1 in an animal model [16].

We have previously shown that GLP-1 attenuates ischaemia-induced LV dysfunction and the derived cardioprotection, but unlike conditioning is not associated with a potassium adenosine tri-phasphate (KATP) channel-dependent pathway [10] and is also independent of changes in cardiac substrate use [9]. More recently, we have shown that GLP-1 is a coronary vasodilator, possibly resulting indirectly from lusitropic forces “opening” the myocardial microcirculation in diastole as a result of ventricular–microcirculatory interactions [15, 32, 33]. Although in the same study we confirmed GLP-1 receptor(R) expression on ventricular myocytes, others have suggested that GLP-1R expression is confined to atrial cardiomyocytes [34] and vascular smooth muscle [12]. Therefore, we were keen to explore if GLP-1 could cause vasodilatation via an adenosine-mediated effect on the microcirculation, indirectly improving ventricular function via the Gregg effect [32].

We clearly demonstrate in this study that GLP-1 vasodilatation is unlikely to be the mediated by adenosine. GLP-1 increases basal coronary flow velocity and reduces BMR irrespective of theophylline. GLP-1 exhausts vasodilatory capacity, such that response to exogenous adenosine is blunted as measured by a reduction in CFR and RRR. Theophylline has been used to investigate adenosine-mediated effect of other therapies; it is a potent adenosine receptor inhibitor at levels achieved in our study [35]. In addition, the adenosine levels remained unchanged after GLP-1 infusion.

Coronary microvascular dysfunction (CMD) is associated with worse clinical outcomes [36] and microvascular injury at the time of elective PCI is associated with procedure-related myocardial infarction and a worse prognosis [37]. GLP-1 improves coronary flow after stenting [15], decreases periprocedural left ventricular dysfunction and stunning [8, 38, 39], and improves immediate as well as long-term cardiovascular outcomes after revascularization for coronary ischemia [24]. GLP-1 and its analogues should be further investigated for symptomatic as well as prognostic benefit in patients with CMD. Furthermore; GLP-1 has the potential to be a much simpler addition to the currently utilized armamentarium of cardioprotective strategies for patients at high risk of peri-procedural cardiovascular events [11].

There are several limitations in our study. Firstly, this was not a randomized controlled trial but was performed in two phases by block allocation to understand the mechanistic effects of GLP-1 on coronary physiology. However, the patients were unselected and sequentially recruited if eligible, and we believe this prevented significant bias. Second, we studied the coronary vasodilatory effects of GLP-1 following PCI. Coronary physiology may not be stable at this time due to reactive hyperaemia and microvascular stunning [15, 40]; however, we mitigated this by waiting for reactive hyperaemia to dissipate before making our measurements. Third, we used a surrogate for coronary flow—Tmn measured by a pressure wire based coronary thermodilution technique. This is a well-validated and accurate technique, that is comparable to other measures of coronary flow velocity [17, 18]. Fourth, we did not perform invasive measurements to confirm our previously published protective effects of GLP-1 on peri-procedural LV dysfunction and also assumed Pv to be 5 mmHg in our patients; this was for logistical reasons. Fifth, patients with diabetes were under-represented in our study and the GLP-1 effect in this group needs confirming. Finally, we only measured adenosine levels in the latter two prospectively-recruited GT and T groups due to logistical reasons. Endogenous adenosine levels did not correlate with resting coronary flow velocity. The reason for this is unclear but may be due to difficulties in assaying adenosine and also that the sample site was at the level of the coronary ostium rather than at the microcirulation. Theophylline is reported to increase local serum catecholamine levels by off-target effects, which may also blunt adenosine mediated vasodilatation [41]. It is also possible that different batches of Stop solution may explain some of the intergroup differences in adenosine levels, although patient-level changes in adenosine level were assayed with the same Stop solution and remain valid.

The coronary vasodilatory effect of GLP-1 appears to be independent of adenosine. Further studies are required to understand the mechanism of the cardioprotective effects of GLP-1.