FormalPara Key Points

Several anti-inflammatory and urate-lowering drugs used in gout have been found to have a favorable effect on cardiovascular (CV) outcomes.

Colchicine is first-line therapy in both gout and pericarditis. It has also demonstrated benefit in the prevention of ischemic events in patients with stable coronary artery disease (CAD) and recent myocardial infarction (MI), postpericardiotomy syndrome and postoperative atrial fibrillation.

Allopurinol may have a potential cardioprotective effect, particularly in the reduction of blood pressure and prevention of MI.

CV outcomes with febuxostat are non-inferior to allopurinol and the long-term use of febuxostat is not associated with increased death or CV mortality.

The CV effects of newer gout drugs such as arhalofenate, verinurad, and rilonacept need to be evaluated.

1 Introduction

Gout is a chronic inflammatory arthritis that affects 9.2 million adults in the US and is characterized by monosodium urate crystal deposition in the joints, secondary to elevated urate levels [1]. Evidence suggests that hyperuricemia and gout are independently linked to an increased risk of coronary artery disease (CAD), heart failure (HF), and cardiovascular (CV) mortality [2]. Patients with recent myocardial infarction (MI) and active gout have worse survival compared with patients with MI who are receiving treatment for gout [3]. Interestingly, not all urate-lowering therapies (ULTs) improve CV outcomes. The URic acid Right for heArt Health Study Group (URRAH) confirmed the independent association of serum uric acid levels and fatal MI. Indeed, they demonstrated a prognostic uric acid cut-off of 5.26 as a predictor for fatal MI in women [4]. Colchicine, which is a commonly used gout medication, has long been used in various pericardial diseases, including pericarditis, pericardial effusion, and effusive constrictive pericarditis. It has shown reductions in long-term CV adverse events in patients with recent MI and stable ischemic heart disease (SIHD). While the outcomes of the COLCOT (Colchicine Cardiovascular Outcomes Trial) trial generated interest, more research is required to fully incorporate colchicine into clinical practice [5,6,7]. Similarly, allopurinol and febuxostat have shown conflicting evidence with respect to CV outcomes.

2 Literature Search

We searched two databases—PubMed and Cochrane—for English-language studies from database inception until June 2020, using the keywords ‘colchicine’, ‘cardiovascular’, ‘allopurinol’, ‘febuxostat’, ‘gout therapy’, ‘heart failure’, and ‘major adverse cardiovascular events’. We also searched for meta-analyses, observational studies, practice guidelines, and reviews. Importance was given to randomized controlled trials and recent high-quality reviews.

3 Inflammation and Uric Acid in Atherosclerosis

Initially thought to be primarily cholesterol-induced, the atherosclerotic process is now known to be the result of a complex interplay between endothelial injury, inflammation, and conventional metabolic risk factors such as dyslipidemia, hypertension, and diabetes (Fig. 1).

Fig. 1
figure 1

A brief outline of inflammation in atherosclerosis. IFN interferon, IL interleukin, LDL low-density lipoprotein, ROS reactive oxygen species, Th1 T-helper 1, VCAM-1 vascular cell adhesion molecule 1, NLRP3 nucleotide oligomerization domain-, leucine-rich repeat-, pyrin domain-containing protein

Hyperuricemia is prevalent in CV diseases such as hypertension, ischemic heart disease (IHD) and HF. However, it is unclear whether hyperuricemia is responsible for CV morbidity or is a marker of a more advanced disease. Uric acid itself has antioxidant and oxidizing properties, and its production from purines is catalyzed by xanthine oxidase (XO), which generates reactive oxygen species during the reaction, as shown in Fig. 2 [8]. Uric acid also promotes oxidation of low-density lipoprotein (LDL), which has an important role in plaque initiation and propagation. Additionally, decreased nitric oxide (which effects vasodilation, platelet aggregation inhibition, and intimal proliferation) levels have been demonstrated with elevated uric acid, possibly due to uric acid-mediated inhibition of insulin-induced nitric oxide synthase [9].

Fig. 2
figure 2

A simplified representation of the role of uric acid in atherogenesis and cardiovascular disease. Other proposed mechanisms, not represented here, are activation of the renin–angiotensin–aldosterone system and insulin resistance. LDL low-density lipoprotein, ROS reactive oxygen species, VCAM-1 vascular cell adhesion molecule 1, XO xanthine oxidase

4 Management and Pharmacotherapies in Gout

The treatment of a gout flare involves monotherapy with non-steroidal anti-inflammatory drugs (NSAIDS) or cyclooxygenase-2 inhibitors, colchicine, or corticosteroids individualized for each patient (American College of Rheumatology [ACR] level A recommendation). These drugs target synovial neutrophil infiltration and suppress the acute inflammatory response. Colchicine is recommended for use within 36 h of a flare and a loading dose of 1.2 mg followed by 0.6 mg 1 h later effectively reduces pain by about 50%. For severe gout flares, colchicine can be used in combination with NSAIDs, oral corticosteroids, or intralesional corticosteroid injections. Thereafter, it can be continued prophylactically at a dose of 0.6 mg one to two times daily. Pharmacological properties of colchicine are detailed in Table 1 [6]. Patients presenting with frequent flares, history of urolithiasis, glomerular filtration rate < 60 mL/min/1.73 m2 or higher, or presence of tophi should be started on ULT; however, all patients with gout should be made aware of the benefits of, and offered, ULT at diagnosis. The current ACR level A-recommended ULTs include the XO inhibitors, allopurinol, and febuxostat. Probenecid, a uricosuric, is a level B-recommended ULT in patients with intolerance to allopurinol or febuxostat. In refractory gout, a recombinant uricase (pegloticase) is the level A ACR-recommended drug [7]. Pharmacotherapies in gout are summarized in Tables 1 and 2, with mechanism outlined in Fig. 3 [9, 10].

Table 1 Pharmacology of colchicinea
Table 2 Pharmacology of drugs used for the chronic management of gout
Fig. 3
figure 3

Mechanism of urate-lowering drugs. AMP adenosine monophosphate, GMP guanosine monophosphate, IMP inosine monophosphate

5 Cardiovascular Outcome and Expanded Use of Colchicine

5.1 Colchicine

Colchicine is widely used in the management of pericarditis. Colchicine for 3 months is recommended as first-line therapy along with NSAIDs (European Society of Cardiology [ESC] class IA recommendation) for acute pericarditis. The addition of colchicine results in a lower rate of symptom persistence at 72 h, effective reduction in pericarditis recurrence, and rates of hospitalization due to pericarditis. Colchicine is also indicated in the setting of pericardial effusion (with systemic inflammation) and effusive constrictive pericarditis (ESC recommendation class I, level of evidence C) [10].

Recent evidence suggests potential benefit of colchicine in atherogenesis and secondary prevention of CAD via inhibition of cytokine production. The anti-inflammatory action of colchicine is summarized in Fig. 4 [11]. The COLCOT trial demonstrated a significant reduction in the primary composite endpoint of death from CV causes, resuscitated cardiac arrest, MI, stroke, or urgent rehospitalization for angina leading to coronary revascularization in patients with recent MI (mean of 13.5 days after MI), when treated with low-dose colchicine (0.5 mg once daily) compared with the placebo group (hazard ratio [HR] 0.77, 95% confidence interval [CI] 0.61–0.96; p = 0.02) at a median follow-up of 22.6 months [5]. Another study noted colchicine significantly reduced coronary artery plaque volume (− 40.9% vs. − 17.0% in placebo; p = 0.008) and high-sensitivity C-reactive protein (hsCRP; − 37.3% vs. 14.6% in placebo; p < 0.001) in patients with recent acute coronary syndrome (ACS) [12]. In contrast, the results of the Low-Dose Colchicine (LoDoCo)-MI trial did not demonstrate a significantly increased likelihood of achieving a CRP level < 2 mg/L or lower absolute levels of CRP 30 days after an acute MI in the colchicine group compared with the placebo group [13]. Emerging evidence is encouraging considering the cost effectiveness and safety profile of colchicine. Larger trials with a longer follow-up period in other patient subgroups could potentially solidify the role of colchicine as add-on therapy in the secondary prevention of MI (Fig. 5).

Fig. 4
figure 4

Schematic representation of the mechanism of the anti-inflammatory effects of colchicine. IL interleukin, MMP matrix metalloproteinase, NLRP3 nucleotide oligomerization domain-, leucine-rich repeat-, pyrin domain-containing protein

Fig. 5
figure 5

Summary of major cardiovascular outcomes of the drugs. ACS acute coronary syndrome, CAD coronary artery disease, AF atrial fibrillation, MI myocardial infarction, BP blood pressure, CV cardiovascular, SGLT 2 sodium glucose transporter-2

Nascent data on colchicine in ACS are also available; in vitro, colchicine has been shown to have antiplatelet activity, while, in vivo, reduced rates of in-stent stenosis and stabilization of coronary plaques post-ACS have been demonstrated [14]. Use of colchicine in ST elevation MI presenting within 12 h of symptom onset and treated with primary percutaneous coronary intervention (PCI) demonstrated a smaller infarct size (18.3 vs. 23.2 mL/1.73 m2 in placebo; p = 0.019), lower neutrophil level, and lower hsCRP level [15]. Additionally, decreased cytokine levels in coronary sinus, right atrium, and aortic root was demonstrated in ACS patients (treated with PCI) after administration of colchicine 1.5 mg [16]. In another study evaluating 400 patients undergoing PCI, the administration of colchicine 1.8 mg prior to PCI improved the levels of hsCRP and IL-6 but did not reduce the risk of PCI-induced myocardial injury [17].

The LoDoCo trial studied the effect of low-dose colchicine as an add-on therapy to statins and antiplatelet agents in 532 patients with stable CAD followed for a median of 3 years. A significant reduction in the primary outcome (ACS, cardiac arrest, and ischemic stroke) was observed in the colchicine group compared with the placebo group (HR 0.33, 95% CI 0.18–0.59; p < 0.001) [18]. The potential benefit of colchicine in the prevention of future ischemic events was confirmed by the results of the LoDoCo2 trial. The trial randomized 5522 patients with catheterization or imaging-proven chronic CAD to receive daily colchicine or placebo and followed them for a median of 28.6 months. They demonstrated a significant reduction in primary outcome measures, including CV mortality, MI, ischemia-driven revascularization and stroke, for colchicine compared with placebo (6.8% vs. 9.6%; HR 0.69, 95% CI 0.57–0.83; p < 0.001). The caveat is a trend towards increased non-cardiac mortality in the colchicine group that warrants further investigation [19]. Two retrospective observational studies found a significantly lower risk of CV events in people with gout treated with colchicine compared with those who did not receive colchicine [20, 21].

In addition, colchicine is efficacious for prophylaxis in postoperative or postablative atrial fibrillation (AF) [22]. A meta-analysis evaluated five RCTs with 1412 patients and found that compared with placebo, prophylactic colchicine reduced the incidence of postoperative AF by 30%, as well as decreased the length of stay [23]. Colchicine is also beneficial in postpericardiotomy syndrome, with supportive evidence from major trials [24, 25]. Furthermore, Colchicine Coronavirus SARS-CoV2 Trial (COLCORONA) is an ongoing phase 3 RCT with an aim to evaluate the effect of 30-day treatment with colchicine on the mortality rate and pulmonary complications of COVID-19. The results of this trial would shed light on the potential utility of colchicine in the pandemic [26]. COVID-19 is associated with elevated inflammatory mediators, including IL-6, IL-8, IL-10 and tumor necrosis factor-α [27]. In addition, the severe acute respiratory syndrome coronavirus 2 (SARS-CoV2) virus is thought to stimulate NLRP3 inflammasome activation, and the anti-inflammatory action of colchicine has been hypothesized to be from NLRP3 inhibitions. Previous studies have demonstrated a beneficial effect of colchicine on CRP, IL-1b, and IL-6 in chronic inflammatory conditions [27]. An open-label RCT evaluated the role of colchicine in COVID-19 patients by assessing time to clinical deterioration, time to CRP elevation, and differences in maximum high-sensitivity cardiac troponin (hs-cTn) recorded in the control and colchicine groups. They found that hs-cTn and CRP levels were comparable in the two groups, however time to clinical deterioration was improved (14% in controls vs. 1.8% in colchicine; odds ratio [OR] 0.11, 95% CI 0.01–0.96; p = 0.046). Major study limitations were the open-label design and a small population size [28].

5.2 Xanthine Oxidase Inhibitors

5.2.1 Allopurinol

This urate-lowering agent has several observed CV effects. In an RCT in 65 patients with CAD, allopurinol resulted in increased exercise capacity, time to ST depression, and time to chest pain [29]. In another trial, allopurinol reduced the left ventricular mass by a mean of 5.2 g, compared with 1.3 g in the placebo group [30]. Larger population-based and case–control studies have corroborated these findings, indicating a possible cardioprotective benefit of allopurinol. The study by de Abajo et al. found that the protective effect of allopurinol appeared to increase with greater duration of treatment and higher dose (> 300 mg compared with < 300 mg) [31,32,33]. The observational study by Singh et al. also found increasing duration of colchicine to be protective for MI in the elderly, as seen from analysis of Medicare claims [34]. In addition to its protective role in CAD, allopurinol has also been shown to reduce blood pressure. In a meta-analysis including 738 participants, the allopurinol group had significantly lower systolic and diastolic blood pressure (by 3.3 mmHg and 1.3 mmHg, respectively) compared with controls [35]. Another meta-analysis compared XO inhibitors with placebo/no treatment and found that allopurinol ≤ 300 mg daily did not significantly reduce the risk of major adverse cardiovascular events (MACE) and mortality, but reduced the risk of hypertension (OR 0.54, 95% CI 0.37–0.80) and total events (OR 0.60, 95% CI 0.44–0.82) [36]. Moreover, it is suggested that XO inhibition with allopurinol may improve endothelial function, leading to vasodilation and improved blood flow in HF. Since this effect is seen in patients with both hyperuricemia and normouricemia, it may be related to a direct reduction in XO-mediated oxidative stress rather than its hypouricemic effect [37]. The ALL HEART trial is a current trial studying MACE in 5215 patients in the UK with IHD treated with allopurinol 600 mg daily compared with the placebo group, and will further help determine the role of allopurinol in CV disease [38].

5.2.2 Febuxostat

In animal studies, another XO inhibitor, febuxostat, demonstrated potential scavenger-like activity for oxidative radicals, with improvement in myocardial structure and a reduction in the expression of inflammatory markers on myocytes [39]. Pretreatment with febuxostat was noted to interrupt mitochondria-dependent apoptosis and subsequent cardiomyocyte injury with reduced endothelial dysfunction in the left atrium [40]. However, Hays et al. found no benefit on coronary endothelial function in patients with prior CAD after 6 weeks of treatment with febuxostat [41].

In the early trials that compared febuxostat and allopurinol for the treatment of gout, there were a numerically greater incidence of CV events in the febuxostat arms compared with the allopurinol arms, although the differences were not statistically significant [42,43,44,45]. As a result, the US FDA mandated the CARES trial, a postmarketing RCT in which 6190 patients were randomized to either febuxostat or allopurinol, and followed for a median of 32 months. Although the primary endpoint of composite of CV death, non-fatal MI, non-fatal stroke, and unstable angina requiring revascularization was similar in both groups (10.8% in the febuxostat group and 10.4% in the allopurinol group), CV mortality was significantly higher in the febuxostat group (HR 1.34, CI 95% 1.03–1.73) [46]. In response to these observations, the FDA issued a black-box warning that restricted the use of febuxostat to people with gout who have failed or cannot tolerate maximally titrated allopurinol doses. It is essential that health care professionals counsel patients about CV risk with febuxostat prior to prescribing [47]. However, the CARES trial had several limitations that make interpretation challenging; for example, a high attrition rate (45%), high medication discontinuation rate (57%), lack of a placebo-control group, and the majority of deaths (85%) occurred after study medication had been discontinued. Rheumatologists have commented that the findings of the CARES trial do not support first-line use of febuxostat, and remind practitioners that there is evidence to support efficacy of both allopurinol dose escalation in the majority of patients with gout and uricosuric therapy [48]. The biological plausibility of the febuxostat increasing risk has also been questioned and raises the possibility that the findings could be explained by allopurinol reducing risk rather than febuxostat increasing risk. In a recently published European trial—the Febuxostat versus Allopurinol Streamlined Trial (FAST)—6128 patients followed for a median period of 1467 days were randomized to either allopurinol or febuxostat to study the primary endpoint of major adverse cardiovascular events. In contrast to the CARES trial, febuxostat was found to be non-inferior to allopurinol (HR 0·85; 95% CI 0.70–1.03; p < 0.0001) [49].

Some of the subsequent studies however have shown variable outcomes. A recent observational study comparing febuxostat and allopurinol with controls showed a similar incidence of major adverse CV events in both groups, while patients receiving febuxostat had a lower incidence of HF hospitalization [50]. Further information from the LEAF-CHF (Effect of urate LowEring Agent Febuxostat in Chronic Heart Failure patients with hyperuricemia) trial, in which patients with HF (left ventricular ejection fraction < 40%) and hyperuricemia (7.0–10.0 mg/day) are randomized to febuxostat or placebo, with a primary endpoint of difference in plasma B-type natriuretic peptide (BNP) from baseline to 24 weeks, may help elucidate the effect of febuxostat in HF [51]. A population-based cohort study evaluated febuxostat versus allopurinol in 99,744 elderly patients (≥ 65 years of age) and found that the primary outcome of composite of hospitalization for MI or stroke was similar in both groups at 1 year. However, there was a trend towards increased all-cause mortality in the group that used febuxostat for more than 3 years [52]. Additionally, a meta-analysis in a Taiwanese population showed no significant difference in CV outcome and mortality with febuxostat versus allopurinol [53]. In a recent study, febuxostat failed to show a halt in the progression of atherosclerosis, as measured by the carotid intimal thickness, after 24 months of treatment [54].

6 Future Directions

Newer drugs are emerging for the treatment of gout and it is too early to comment on their effect on CV morbidity or mortality. A phase I study has shown that a selective uric acid reabsorption inhibitor called verinurad lowered serum urate without any major adverse effects in healthy males, but unclear CV safety [55].

Another potential drug class, IL-1 antagonist therapy, is being evaluated in current trials. A recent animal study showed beneficial cardiac effects of anakinra on the myocardium, while rilonacept, a newer IL-1 antagonist, has limited data regarding the CV safety [56]. Arhalofenate, a partial agonist on peroxisome proliferator-activated receptor (PPAR)-γ was initially developed as an antidiabetic drug and was serendipitously found to have modest uric acid-lowering properties in addition to anti-ILβ activity. A randomized, double-blind study on arhalofenate did not reveal any specific CV adverse effect, but more research is required [57]. Several ongoing studies on gout therapies are listed in Tables 3 and 4.

Table 3 Recent cardiovascular outcomes trials of drugs used in the management of gout
Table 4 Ongoing trials on drugs used in gout and other rheumatological diseases

Sodium glucose cotransporter (SGLT)-2 inhibitors, a prominent antidiabetic drug class with extended benefit in HF patients, have also shown a reduction in serum uric acid levels, which could contribute to the CV mortality benefit seen with this class of drugs. By increasing renal urate losses, this drug class decreases serum uric by about 0.60–0.75 mg/dL, making it a potential add-on agent for use in patients with diabetes and hyperuricemia. Several randomized studies have reported a decrease in MACE and HF rehospitalization with SGLT-2 inhibitors [58].

7 Conclusion

The recent advancements in atherosclerosis pathophysiology indicate that inflammation plays a significant role. With trials such as COLCOT and LoDoCo showing benefit of colchicine in CAD, there is a possibility of expansion of our current armamentarium in secondary prevention of CAD. However, further study is needed to change practice and to evaluate the utility of colchicine in ACS. Early data have shown CV benefits of certain other gout medications, but there are no current FDA-approved indications in cardiology. Febuxostat, earlier thought to have a poor cardiovascular outcome compared with allopurinol, was found to be non-inferior to allopurinol and with no increase in mortality in the recent FAST trial. Overall, more evidence is required to definitively endorse clinical use of these drug classes in CAD.