The theoretical physiological effects of aspirin in cardiovascular disease prevention
For a cardiovascular event to occur, the fibrous cap of an atheromatous lesion must rupture. This plaque rupture exposes highly pro-thrombotic material leading to thrombosis [
15‐
17]. Therefore, the prevention of thrombus formation or the prevention of propagation of thrombus once it exists will consequently prevent evolution into full vascular occlusion, hence the utility of anti-thrombotic agents.
Aspirin is a non-selective cyclo-oxygenase (COX) inhibitor. It blocks the production of thromboxane in platelets (by acetylation of COX in platelets) thereby inhibiting their aggregation, but it also blocks the synthesis of prostaglandins in the vascular wall that, in health, causes vasorelaxation, maintains renal function, and reduces adhesion of platelets to the vessel wall [
3,
18]. Furthermore, aspirin may be beneficial for atherosclerosis not only because of its antiplatelet action, but also by showing a direct effect on the atheroma plaque. Indeed, Redondo et al. have undoubtedly demonstrated that aspirin increases the stability of the atheroma plaque (or significantly inhibits plaque growth), this mediated by an increase in TGF-β secretion [
19,
20]. These properties of aspirin have consequently brought to explore the benefits of this drug in CVD prevention. However, the use of aspirin, especially in the long term, is not without some harmful effects that can even become fatal.
Adverse events with aspirin
The major drawback to continuous aspirin therapy is the risk of bleeding. The Antithrombotic Trialists’ Collaboration (ATTC) meta-analysis revealed that aspirin use increased the risk of major gastrointestinal (GI) and other extracranial bleeding by about 50 % (0.10 %/year vs. 0.07 %/year (risk ratio (RR) 1.54, 95 % confidence interval (CI):1.30–1.82;
p <0.0001) [
6]. Aspirin also increases the risk of hemorrhagic stroke. A meta-analysis of 16 placebo-controlled randomized controlled trials (RCTs), comprising a total of 55,462 patients, showed that treatment with aspirin was associated with a relative risk of hemorrhagic stroke of 1.84 (p < 0.001) [
21]. Likewise, The ATTC reported a statistically significant 22 % increased incidence of hemorrhagic stroke in patients on antiplatelet treatment [
22]. Moreover, De Beradis et al. [
23] in comparison with ATTC estimates, found a 5-time higher incidence of major bleeding events with an overall incidence rate of hemorrhagic events of 5.58 (95 % CI: 5.39–5.77) per 1000 person-years for aspirin users and 3.60 (95 % CI: 3.48–3.72) per 1000 person-years for those without aspirin use (incidence ratio rate (IRR) 1.55, 95 % CI: 1.48–1.63). In particular, the use of aspirin was associated with an excess risk of gastrointestinal (IRR 1.55, 95 % CI: 1.46–1.65) and intracranial bleeding (IRR 1.54, 95 % CI: 1.43–1.67) [
23]. In the recent Japanese Primary Prevention Project (JPPP) [
24], aspirin significantly increased the risk of extracranial hemorrhage requiring transfusion or hospitalization (0.86, 95 % CI: 0.67–1.11 for aspirin vs. 0.51, 95 % CI: 0.37–0.72 for no aspirin; hazard ratio (HR) 1.85, 95 % CI: 1.22–2.81;
p = 0.004).
Several other studies have also shown that the risk of bleeding is increased with aspirin therapy [
25‐
31]. It has been emphasized that this risk is higher in the primary prevention than in the secondary prevention population, but this difference is more than compensated by the lower baseline risk in primary prevention population [
26]. Likewise, the risk of bleeding is higher in individuals at higher cardiovascular risk over 10 years when compared with the low-risk population [
32]. Furthermore, some other factors likely to dreadfully increase the risk of bleeding have been identified: increased age, previous hospitalization for GI problems, helicobacter pylori infection, male sex, diabetes, hypertension, previous cardiovascular problems, alcohol use, concurrent use of nonsteroidal anti-inflammatory drugs (NSAIDs) or concomitant use of either antiplatelet agents or oral anticoagulants [
6,
23,
33,
34]. These risk factors are common in the general population and therefore, the individual patient’s risk of bleeding needs to be taken into consideration when deciding to put him/her on continuous aspirin therapy, especially in low-income settings where there may be lack of enough means and competence to handle such related harmful side effects [
14].
Some bleeding risk scores have been developed, especially in anticoagulated atrial fibrillation (AF) populations, such as the HEMORR
2HAGES score, the HAS-BLED score, and the less practical ATRIA score. We learn from Lip G’s review that the HAS-BLED score has been shown to outperform the other risk scores in predicting clinically relevant bleeding in multiple ‘real-world’ and trial cohorts [
35]. Additionally, the HAS-BLED score was the only tested score to have a significant (and good, c-statistic 0.75) predictive value for intracranial haemorrhage [
36]. The acronym HAS-BLED represents each of the bleeding risk factors and assigns 1 point for the presence of each of the following: hypertension (uncontrolled systolic blood pressure >160 mmHg), abnormal renal and/or liver function, previous stroke, bleeding history or predisposition, labile international normalized ratios, elderly, and concomitant drugs and/or alcohol excess [
37]. The HAS-BLED score ranges from 0 to 9, with scores of ≥ 3 indicating high risk of bleeding, for which caution and regular review of the anticoagulated AF patient are recommended [
35,
38]. In this regard, the applicability of such a score should be undertaken in primary prevention of CVD with aspirin, and patients at high risk of bleeding should not be prescribed aspirin in primary prevention of CVD.
Moreover, the standard dosage of aspirin (325 mg/day) is significantly associated with a higher risk of gastrointestinal bleeding (including fatal bleeds) than are low-doses (75–100 mg/day) [
39‐
41], though this risk is estimated to be twice as high as with no aspirin [
42]. Some papers have pointed-out that an increased consumption of proton pump inhibitors (PPIs) might be associated with a significant reduction in hospitalizations for gastrointestinal events during continuous aspirin therapy [
23,
43], but the cost-effectiveness of PPIs associated with aspirin use, specifically in resource-poor environments, needs a thorough clarification. Earnshaw et al. [
44] demonstrated that the addition of a PPI to aspirin is cost-effective only for men at increased risk for gastrointestinal bleeding. On the other hand, there have been some claims that using PPIs might increase the risk of cardiovascular events in patients treated with antiplatelet agents [
45]. However, it is questionable if the PPI used (omeprazole) was the cause of this increased risk of adverse cardiovascular events, or if omeprazole use was merely a mark of a more severe patient (omeprazole users tend to be older, more fragile and with more comorbidities, all factors increasing mortality). Other authors have proposed that aspirin could be substituted by another anti-thrombotic agent to reduce CVD risk while eliminating the bleeding risk, but two prospective clinical trials demonstrated for instance that the combination of aspirin and esomeprazole was superior to clopidogrel for the prevention of recurrent ulcer bleeding [
46,
47].
Aspirin use is also associated with an increased risk of dyspepsia, chronic kidney disease and renal dialysis, and age-related macular degeneration [
48]. There is some suggestion that low-dose aspirin (50 mg daily) might not slow carotid atheroma plaque growth [
49]. Consequently, any effect of aspirin on cardiovascular events needs to be balanced against the potential for harm. In primary CVD prevention where the risk of developing atherothrombotic events is generally low, it is therefore highly relevant to estimate the individual baseline risk of such events and carefully balance this against the risk of harmful events related to therapy.
Assessing the baseline risk in primary prevention of cardiovascular disease
Commonly-used tools to assess baseline risk are the Framingham coronary heart disease risk score [
32], the American College of Cardiology/American Heart Association (AHA/ACC) Task Force risk equations [
50], and the European Society of Cardiology ESC’s SCORE (Systematic Coronary Risk Evaluation) [
51]. The Framingham risk score (FRS) utilizes gender, age, total cholesterol, high-density lipoprotein cholesterol, systolic blood pressure, use of blood pressure lowering medications, and smoking status to predict the 10-year risk of developing a coronary event (composite of MI and coronary death). Individuals are categorized as low (<10 %), moderate (10 to 20 %), or high (>20 %) risk [
32]. Moreover, the SCORE system estimates the 10-year risk of a fatal atherosclerotic event: individuals are considered at low risk with a SCORE < 1 %, at moderate risk with a SCORE ≥ 1 % and <5 %, at high risk with a SCORE ≥ 5 % and <10 %, and at very high risk with a SCORE ≥ 10 % [
51]. The risk of total fatal and nonfatal events is higher than that of fatal events only. At a 5 % risk of fatal events, the total event risk is approximately 15 %. This 3-fold multiplier is somewhat smaller in the elderly, in whom a first event is more likely to be fatal [
51].
Additionally, the Coronary artery calcium (CAC) score has recently been tested to guide aspirin utilization for primary prevention of CVD. In fact, one can read from Miedema et al. [
11] that CAC score is a highly specific marker of the atherosclerotic plaque burden in the coronary arteries, and there is a nearly 10-fold higher risk of CHD events in patients with substantially elevated CAC. The same authors report that a CAC score of zero has been shown to be a powerful predictor of a favorable prognosis (low risk of CHD, CVD and all-cause mortality), even in the presence of traditional risk factors [
11,
52]. Furthermore, an analysis of 44,052 asymptomatic people showed that individuals with no cardiovascular risk factors but elevated CAC had higher mortality rates than individuals with multiple risk factors but zero CAC [
53]. Although CAC may be a promising risk assessment and reclassification tool, how this test should be used in routine clinical practice remains unclear, added to its relatively high cost ($100).
Another tool that has been used is the ankle brachial index (ABI) which is the ratio of systolic pressure at the ankle to the arm. It is used in the diagnosis of peripheral artery disease affecting the legs. A low ABI is associated with concomitant coronary and cerebrovascular disease [
54], and, in healthy individuals, with an increased risk of future vascular events, independently of cardiovascular risk factors [
55]. An ABI of 0.90 or less is often used as the cut point for identifying individuals at high risk of peripheral atherosclerosis. [
55]. In this regard, Fowkes et al. [
28] hypothesized that, because the ABI is a simple, inexpensive, noninvasive test, it could be used in population screening programs (for example in primary care settings or in the community) to identify a novel subgroup potentially amenable to preventive treatments.
However, as most of these aforementioned tools were developed in Caucasian populations, their application in other populations or ethnic groups is therefore problematic. In this regard, the INTERHEART risk score was developed based on data from 52 countries around the world [
56]. Yusuf et al. [
56] showed that the INTERHEART risk score, based on nine easily measureable and potentially modifiable risk factors, is associated with more than 90 % of the likelihood to accurately predict an acute MI, these results being consistent across all geographic regions and ethnic groups of the world, men and women, and young and old. More recently, McGorrian et al. [
57] modified the INTERHEART risk score into the INTERHEART Modifiable Risk Score (IHMRS), of which four risk score models were derived. Of these, the ‘non-laboratory-based’ score [
57], which does not include any lab-based measures of lipid profile, can be used in primary care settings especially in resource-poor countries where there is lack of laboratories [
14].
Consequently, more observational studies as well as direct randomized comparisons between all these commonly-used tools are urgently warranted to define which is the most reliable and cost-effective one to be used for primary CVD risk assessment, particularly in low-income settings [
58]. Besides, adoption of continuous aspirin use for primary CVD prevention must be underpinned by robust scientific evidence.
Published evidence for or against a beneficial effect of aspirin in primary prevention of cardiovascular disease
In 2009, the ATTC reviewed the benefit-risk profile of low-dose aspirin for primary CVD prevention in a comprehensive meta-analysis of 6 primary prevention trials that included nearly 95,000 men and women randomly assigned to aspirin at doses of 75–500 mg per day or placebo [
6]. Aspirin was associated with a 12 % proportional reduction in serious vascular events compared with no aspirin (annual event rate 0.51 % for aspirin vs. 0.57 % for no aspirin,
p <0.0001), mainly due to a reduction in first nonfatal MI (0.18 % vs. 0.23 % per year;
p <0.0001), and the proportional reductions were similar for women and men [
6]. Conversely, aspirin therapy did not seem to have an effect on stroke occurrence, and it was noticed just a small protective effect with regard to mortality, given 0 to 6 fewer deaths per 1000 persons treated over 10 years. However, as early mentioned, the downside was that aspirin increased major gastrointestinal and extracranial bleeding [
6]. Since bleeding risk appeared to be strongly related to the ischemic risk, the benefit of aspirin was judged to be overshadowed by the bleeding hazard.
More recent meta-analyses suggested beneficial effects for aspirin in the primary prevention of cardiovascular events [
8,
9,
30,
31,
59,
60]. Indeed, Bartolucci et al. [
59] reported in their meta-analysis that aspirin significantly decreased the risk of total cardiovascular events (OR 0.87, 95 % CI: 0.80–0.93;
p <0.001) and nonfatal MI (OR 0.81, 95 % CI: 0.67–0.99;
p = 0.042), compared with no aspirin, but there was a non-significant trend for decreased risk of stroke, cardiovascular mortality, and all-cause mortality. In the meta-analysis performed by Raju et al. [
60], primary prevention with aspirin was associated with a reduction in all-cause mortality (RR 0.94, 95 % CI: 0.88–1.00), MI (composite of fatal and nonfatal; RR, 0.83, 95 % CI: 0.69–1.00), ischemic stroke (RR 0.86 95 % CI: 0.75–0.98), and the composite of MI, stroke, and cardiovascular death (RR 0.88, 95 % CI: 0.83–0.94) in comparison with nonuse of aspirin. In another meta-analysis conducted by Seshasai et al. [
9], aspirin association with a significant reduction in the risk of cardiovascular events (OR, 0.90, 95 % CI: 0.85–0.96), was primarily accounted for by a large reduction in the risk of nonfatal MI (OR 0.80, 95 % CI: 0.67–0.96). No effect on fatal MI was observed, but a modest non-significant reduction was apparent for all-cause mortality [
9].
Moreover, the Multi-Ethnic Study of Atherosclerosis that involved 4229 participants who were not on aspirin at baseline and were free of diabetes mellitus revealed that participants with significant plaque in their arteries (i.e., CAC score ≥100) were estimated to be 2 to 4 times more prone to prevent a heart attack with aspirin use than to have a major bleed secondary to aspirin [
27]. On the contrary, participants with no calcified plaque (CAC score = 0) were estimated to be 2 to 4 times more likely to suffer a major bleed from aspirin use than to prevent a heart attack with aspirin [
27]. In the just-published JPPP that included 14,464 patients aged 60–85 years and presenting with either hypertension, dyslipidemia, or diabetes mellitus, low-dose aspirin (100 mg/day) significantly reduced incidence of nonfatal MI (0.30, 95 % CI: 0.19-0.47 for aspirin vs. 0.58, 95 % CI: 0.42–0.81 for no aspirin; HR 0.53, 95 % CI: 0.31–0.91;
p = 0.02) [
24]. Likewise, it was noticed a significant reduction in the incidence of transient ischemic attack (0.26, 95 % CI: 0.16–0.42 for aspirin vs. 0.49, 95 % CI: 0.35–0.69 for no aspirin; HR 0.57, 95 % CI: 0.32–0.99;
p = 0.04) [
24].
However, this study was terminated early, based on likely futility. In fact, it appeared on the whole that aspirin was unlikely to show a clinically important benefit in the overall population included in the study [
24]. The drug did not significantly reduce the risk of the composite outcome of cardiovascular death, nonfatal stroke, and nonfatal MI, and the risk of bleeding significantly increased with aspirin [
24]. In accordance with these findings, a systematic review conducted by Jones et al. [
61] showed no differences between aspirin and placebo groups for total and vascular mortality, MI, and stroke in patients with asymptomatic peripheral artery disease. In the same line, Brighton et al. [
62] showed no reduction in recurrent thromboembolic events with aspirin use of 100 mg/day even though there was a clear reduction in the occurrence of other serious cardiovascular events by 34 % (
p = 0.01) compared to the placebo group. In addition, no differences in bleeding or other serious adverse events were observed [
62]. The Aspirin for Asymptomatic Atherosclerosis trial did not show a significant reduction in fatal or non-fatal coronary event, stroke or revascularization among participants without clinical CVD identified with a low ABI and receiving aspirin in comparison with placebo [
28].
Overall, in large-scale trials of primary prevention in men and women without established CVD, and subsequent meta-analyses, aspirin significantly reduced the risk of a first MI, but this was less the case for stroke or cardiovascular death. But despite the apparent benefits of aspirin therapy for primary prevention of CVD, these benefits may be outweighed by the risk of major bleeding (see Table
1) [
6,
8,
9,
30,
31]. Indeed, a recent extensive systematic review of aspirin in primary prevention concluded that “there is a fine balance between benefits and risks from regular aspirin use in primary prevention of cardiovascular disease” [
31].
Table 1
Summarizing published evidence for or against a beneficial effect of aspirin in primary prevention of cardiovascular disease
The Antithrombotic Trialists’ Collaboration (ATTC) meta-analysis [ 6] | - A 12 % proportional reduction in serious vascular events, mainly due to a reduction in first nonfatal myocardial infarction | - No effect on stroke occurrence |
- Increase in the risk of major gastrointestinal and other extracranial bleeding by about 50 % |
- Small protective effect on mortality | - Increased incidence of hemorrhagic stroke (22 %) |
| - Significant decrease in the risk of cardiovascular events (notably nonfatal myocardial infarction) | No effect on fatal myocardial infarction |
- Modest non-significant reduction in all-cause mortality |
| Absolute risk reduction in myocardial infarction and ischemic stroke | Increased risk of hemorrhagic stroke |
| | High incidence of major bleeding events with an overall incidence rate of hemorrhagic events (gastrointestinal and intracranial bleeding episodes) |
The Japanese Primary Prevention Project (JPPP) [ 24] | - Significant reduction in the incidence of nonfatal myocardial infarction | - No significant diminution in the risk of the composite outcome of cardiovascular death, nonfatal stroke, and nonfatal myocardial infarction |
- Significant reduction in the incidence of transient ischemic attack |
- Increase in the risk of extracranial hemorrhage requiring transfusion or hospitalization |
The Multi-Ethnic Study of Atherosclerosis [ 27] | Estimated 2–4 fold increased likelihood to prevent a heart attack with aspirin use than to have a major bleed secondary to aspirin in participants with significant plaque in their arteries (i.e., CAC score ≥100). | Estimated 2–4 times increased probability to suffer a major bleed from aspirin use than to prevent a heart attack with aspirin in participants with no calcified plaque (CAC score = 0) |
The Aspirin for Asymptomatic Atherosclerosis trial [ 28] | | No significant reduction in fatal or non-fatal coronary event, stroke or revascularization among participants without clinical cardiovascular disease identified with a low ankle brachial index and receiving aspirin in comparison with placebo |
| Significant decrease in the risk of total cardiovascular events and nonfatal myocardial infarction | No effect on the reduction in the risk of stroke, cardiovascular mortality, and all-cause mortality |
| Reduction in all-cause mortality, myocardial infarction (composite of fatal and nonfatal), ischemic stroke, and the composite of myocardial infarction, stroke, and cardiovascular death | Increase in the risk of hemorrhagic stroke, major bleeding, and gastrointestinal bleeding |
| | No differences between aspirin and placebo groups for total and vascular mortality, myocardial infarction, and stroke in patients with asymptomatic peripheral artery disease |
| - Reduction in the occurrence of serious cardiovascular events (by 34 %) other than thromboembolic events | No reduction in recurrent thromboembolic events (with aspirin use of 100 mg/day) |
- No differences in bleeding or other serious adverse events |
The specific case of diabetes patients
Individuals with diabetes have a 2 to 4 fold increased risk of developing cardiovascular events than those of the same age and sex without diabetes [
63]. Haffner et al. [
63] have shown that the risk of future CHD events is similar for both diabetes subjects without prior CHD and non-diabetes subjects with previous CHD. Besides, a meta-analysis by the ATTC suggested that diabetes, in addition to being an independent CVD risk factor, also increased the risk of extracranial hemorrhage or bleeding [
6]. Conversely, Feigin et al. [
64] reported a protective effect of diabetes on the incidence of subarachnoid hemorrhages, which they justified by figuring out the high risk of death from other causes in the population with diabetes and therefore the chance of developing such hemorrhages was smaller than in individuals without diabetes.
The Early Treatment Diabetic Retinopathy Study (ETDRS) [
65] is the main study supporting the use of aspirin in primary prevention of diabetes patients. This multicenter, randomized clinical trial of aspirin versus placebo investigated the effects of aspirin (325 mg/day) in primary prevention on 3711 type 1 and type 2 diabetes patients aged 18–70 years old with various degrees of retinopathy, and showed that aspirin did not affect retinopathy progression, but was rather associated with a reduction in the incidence of fatal and nonfatal MI [
65]. Consistent with these findings, the Physicians’ Health Study [
66], a randomized double-blind placebo-controlled trial designed to determine whether aspirin decreased cardiovascular events in primary prevention in patients with diabetes, demonstrated a significant reduction in the risk of MI, though without conclusive evidence concerning stroke and total cardiovascular deaths.
Paradoxically, Simpson et al. [
41] carried-out a meta-analysis to examine the effect of dose on the association between aspirin and cardiovascular outcomes using data from 21 studies with 17,522 diabetes patients, and found that aspirin use was not associated with a statistically significant difference in mortality risk. More recently, Sasso et al. [
25] did not show a significant difference in the incidence of both fatal (
p = 0.225) and nonfatal CV events (
p = 0.573) between type 2 diabetes patients with nephropathy placed on aspirin vs. placebo. These findings are in keeping with other studies including the Japanese Primary Prevention of Atherosclerosis with Aspirin for Diabetes (JPAD) [
29], the Prevention and Progression of Arterial Disease and Diabetes (POPADAD) trial [
67], the Primary Prevention Project Trial [
68] and the meta-analysis of seven randomized clinical trials regrouping 11,000 patients and undertaken by Butalia et al. [
69]. On the whole, although aspirin may not necessarily increase the risk of bleeding in diabetes patients, recent available data suggest no benefit in terms of a reduction in vascular events.
Prescribe aspirin in primary prevention of CVD: a challenging decision
Currently, the worthwhile net clinical benefit of giving aspirin to healthy individuals is made difficult to assess by the imprecision of estimates of benefits and risks, especially for rare events, such as intracranial hemorrhage, and by the difficulty of weighing ischemic versus bleeding events [
70,
71]. In the setting of secondary cardiovascular prevention on the contrary, the benefit of treatment (saving major cardiovascular events) is clearly superior to the risk (inducing major bleeding) [
6].
The American Heart Association (AHA), the American College of Chest Physicians (ACAP), and the European Society of Cardiology (ESC) have formulated recommendations for the use of low-dose aspirin for primary cardiovascular prevention with some of them being conflicting (see Table
2). For instance, while the ACAP guidelines suggests daily low-dose aspirin for persons age 50 years or older without symptomatic CVD, ESC guidelines argues that aspirin is “not recommeded in individuals without cardiovascular or cerebrovascular disease” because of the increased risk of major bleeding. Despite certain inconsistences, all guidelines are clear that aspirin is inappropriate for patients with aspirin intolerance and those at increased risk of gastrointestinal bleeding or hemorrhagic stroke, which is usually evident from a previous history of such conditions. These aspirin contraindications are relatively uncommon, however and happily, and the benefits of CVD risk reduction typically outweigh the bleeding risks for most patients at high CVD risk. It is worth noting that aspirin doses of 75–162 mg per day are typically better tolerated and are as effective as higher doses in conferring cardiovascular protection [
72].
Table 2
Recommendations for low-dose aspirin therapy in cardiovascular disease primary prevention
American Heart Association/American Stroke Association [ 78, 79] | a) The use of aspirin for cardiovascular (including but not specific to stroke) prophylaxis is reasonable for people whose risk is sufficiently high (10-year risk >10 %) for the benefits to outweigh the risks associated with treatment. |
b) Aspirin can be useful for the prevention of a first stroke among women, including those with diabetes mellitus, whose risk is sufficiently high for the benefits to outweigh the risks associated with treatment. |
c) Aspirin might be considered for the prevention of a first stroke in people with chronic kidney disease (ie, estimated glomerular filtration rate <45 mL/min/1.73 m2). This recommendation does not apply to severe kidney disease (stage 4 or 5; estimated glomerular filtration rate <30 mL/min/1.73 m2). |
d) Aspirin is not useful for preventing a first stroke in low-risk individuals with or without diabetes. |
e) Use of aspirin for primary cardiovascular prevention is reasonable in diabetic patients whose 10-year risk of events is > 10 % (men age > 50 years and women age > 60 years with at least 1 additional risk factor: smoking, hypertension, dyslipidemia, albuminuria, or family history of premature cardiovascular events) and who are not at increased risk of bleeding (no history of gastrointestinal bleeding or peptic ulcer disease, no concurrent use of other medications that increase bleeding risk). |
f) Aspirin may be considered for diabetes patients at intermediate risk of cardiovascular events (younger patients with at least 1 risk factor, older patients with no risk factors, or patients with a 10-year risk of 5 to 10 %) |
American College of Chest Physicians [ 32, 80] | Aspirin is recommended for the primary prevention of cardiovascular events in all patients aged 50 years or older with or without symptomatic cardiovascular disease. |
Canadian Cardiovascular Society [ 81] | Aspirin is not recommended in men or women without evidence of manifest vascular disease. |
European Society of Cardiology [ 82] | Aspirin is not recommended in individuals without cardiovascular or cerebrovascular disease. |
Definitely, in primary CVD prevention, where the risk of developing atherothrombotic events for each individual patient is generally low, it is essential to estimate the individual baseline risk of such events and to carefully balance this against the side effects of therapy, in this case bleeding. The ability to prevent serious cardiovascular events and their associated sequelae with a single, inexpensive pill makes low-dose aspirin therapy a worth considering low cost option, specifically in impoverished areas. Therefore, tailoring aspirin therapy according to baseline risk has been proposed as the best practical guidance [
11,
34,
70,
73]. As such, a threshold risk level should be defined, above which recommending aspirin is expected to produce more benefit than risk, and assessed through the most accurate and country-specific risk factor estimates. In this regard, the ESC working group on thrombosis has proposed a threshold at a risk of major cardiovascular events (death, MI and stroke) ≥ 2 per 100 patient-years [
70].
Any decision to prescribe aspirin should be an “individual clinical judgment” that weighs the absolute benefit in reducing the risk of a first cardiovascular event against the absolute risk of major bleeding [
73]. The higher the absolute risk of CVD, the greater the net benefit from aspirin. This final decision to initiate continuous aspirin therapy for primary prevention of CVD should be made by health care providers [
73], especially Primary Care Physicians (PCPs) in resource-poor areas, and they must therefore be cognizant of their role in assessing the potential for benefit and subsequent risk of bleeding in individual patients prior to starting the treatment.
But mirroring previous findings, Fiscella et al. [
74] figured out that the use of aspirin in primary prevention of CVD is hindered by the clinician uncertainty in determining relative benefits and harms to patients. In fact, they found that aspirin was recommended for only 34 and 42 % of eligible men and women, likely reflecting the complexity of assessing patient eligibility, including weighing benefits and harms in the context of risk calculations and age-based risk cutoffs [
74]. In the absence of hand-based or online risk calculators, physicians often misjudge CVD global risk. It has therefore been suggested that incorporation of automated CVD risk assessments into electronic health records could improve clinicians’ estimation of risk and recommendation for prescribing [
75]. But the implementation of such a measure in resource-limited zones is questionable, given that in most of these areas patients health records are not yet computerized and local risk assessment tools are lacking [
14,
58]. In this regard, simple adapted tools must be developed and PCPs be continuously trained to use them.
Besides, engaging non-clinicians through expanded care teams and standing orders may also prove helpful in reducing the volume of decisions that rest solely with the clinician at the point of care [
74]. Indeed, sharing care with team members can enhance the concordance between published guidelines, use of risk models and actual practice [
76]. Additionally, the relevant information should be transferred to patients and, individual values and preferences be taken into account. Indeed, patient preferences may play a larger role, but consideration must also be given to clinical equivalence as many patients may be more willing to experience a bleeding event as opposed to suffering a heart attack [
27]. It has been stated that providing patients with global CVD risk assessments seems to improve patient intent to initiate CVD prevention [
77].
Lastly, therapeutic lifestyle changes should be emphasized or reinforced [
73]. In this line, populations should be sensitized on healthy and life-saving attitudes (healthy diets, physical activity, and smoking cessation among others). Further, other life-saving drugs such as statins could be considered with aspirin as an adjunct, or gastrointestinal protection be given in association with aspirin. But these measures have shown controversial results and their implementation in resource-constraints settings must be guided by cost-effective evidence.