Introduction

Peripheral arterial disease (PAD), coronary artery disease (CAD) and cerebrovascular disease (CVD) are different manifestations of atherosclerotic vascular disease. The whole spectrum of atherosclerotic cardiovascular diseases shares common cardiovascular risk factors such as smoking, diabetes, hypertension and hyperlipidemia and require identical risk factor management for primary and secondary prevention [1]. The term PAD is not well defined and sometimes used to summarize diseases of all extracranial and extracoronary arteries including carotid artery disease, mesenteric and renal artery disease, as well as upper and lower extremities arterial disease [2]. Most often, and also in this paper, the term PAD is used synonymously to lower extremities arterial disease, the most frequent manifestation of PAD [3, 4].

The fate of patients with PAD is determined by the prognosis of the affected extremity and by the total cardiovascular prognosis. Patients with intermittent claudication rarely progress to critical limb ischemia and are at low risk for amputation, which is estimated to be at 2 to 4% within 5 years after initial presentation. These patients, however, are ten times more likely to suffer a non-fatal or fatal cardiac or cerebrovascular event [5]. Patients that initially present with critical limb ischemia, i. e. with rest pain and/or ischemic foot lesions, are a different entity with both a very high one year mortality and amputation rate up to 30% each.

Besides the above mentioned predominant risk factors elevated levels of lipoprotein(a) have been identified as an important additional atherothrombotic agent that increases the risk of developing PAD and adversely influences the prognosis of patients with established PAD patients quoad extremitatem and quoad vitam [6]. This review will summarize and discuss current knowledge about the association and putative causal role of lipoprotein(a) for PAD and the effect of lipoprotein(a) lowering by lipoprotein apheresis and PAD itself and overall cardiovascular prognosis of PAD patients.

Peripheral arterial disease is a marker for very high cardiovascular risk

Current guidelines consider clinically manifest PAD as a risk equivalent to manifest CAD requiring identical treatment strategies and goals with respect to atherosclerotic risk factor management [1]. The overall cardiovascular risk associated with PAD, however, still seems to be underestimated as there is undertreatment of PAD compared with CAD patients with lipid-lowering, anti-hypertensive and antiplatelet drugs [7]. Recent data show that patients with symptomatic PAD even without concomitant CAD carry a higher risk of death and cardiovascular events compared with patients with CAD without clinically manifest PAD.

Pereg and colleagues [8] prospectively followed a cohort of nearly 10,000 patients for up to 10 years (mean follow-up 5.6 ± 2.3 years) who had undergone their first clinically driven coronary intervention (82.8% of patients) or peripheral vascular intervention (17.2% of patients). The PAD patients had a significantly worse long-term prognosis with a significantly increased all-cause mortality compared with the CAD patients (unadjusted hazard ratio 2.95, multivariately adjusted hazard ratio 1.86). This observation cannot be solely explained by undertreatment of PAD patients. Randomized controlled trials of novel lipid-lowering or antiplatelet drugs, in which PAD and CAD patients were included and in which all patients received optimal conventional treatment, confirmed the higher cardiovascular risk of PAD patients.

The “Further Cardiovascular Outcomes Research with PCSK9 Inhibition in patients with Elevated Risk” (FOURIER) trial was a randomized trial of the proprotein convertase subtilisin/kexin type 9 (PCSK9) inhibitor evolocumab versus placebo in nearly 28,000 patients with stable atherosclerotic vascular disease who were on optimal medical therapy including high-dose statin. The trial included 3642 patients with symptomatic PAD (1505 with no prior myocardial infarction or stroke) and 23,922 patients with prior myocardial infarction of stroke without known PAD [9]. In the placebo group, the 2.5-year event rate of the composite endpoint of cardiovascular death, myocardial infarction, stroke, hospitalization for unstable angina, or coronary revascularization was significantly higher in patients with symptomatic PAD (16.8%) compared with patients without PAD (12.1%, adjusted hazard ratio 1.57).

“Prevention of Cardiovascular Events in Patients with Prior Heart Attack Using Ticagrelor Compared to Placebo on a Background of Aspirin-Thrombolysis in Myocardial Infarction 54” (PEGASUS TIMI 54) was a trial of dual antiplatelet therapy using ticagrelor in stable post-myocardial infarction (MI) patients. All patients received optimal medical treatment of cardiovascular risk factors. The placebo group included 6633 post-MI patients without PAD and 404 post-MI patients who also had PAD [10]. During three years of follow-up the composite endpoint of cardiovascular death, myocardial infarction and stroke was significantly more frequent in the patients with PAD (19.3%) compared with the patients without PAD (8.4%, unadjusted hazard ratio 2.46, adjusted hazard ratio 1.6).

These two recent randomized trials emphasize the higher ischemic risk in patients with symptomatic PAD with and without concomitant CAD compared to patients with CAD without PAD even in patients who are under optimal conventional medical treatment. This suggests that the higher atherosclerotic burden in PAD compared with CAD and/or differences in the impact of different atherosclerotic risk factors in different manifestations of the disease may be responsible for the higher cardiovascular event rate in PAD patients.

Elevated lipoprotein(a) levels are a risk factor for peripheral arterial disease

Several case–control studies proposed an association between elevated lipoprotein(a) levels and the risk of suffering from PAD.

In the “Linz Peripheral Arterial Disease” (LIPAD) study from Lower Austria 213 patients with symptomatic PAD were matched to 213 controls for sex, age, and presence of diabetes [11]. Lipoprotein(a) concentrations were measured by a double-antibody enzyme-linked immunosorbent assay (ELISA), and apolipoprotein(a) isoform by sodium dodecyl sulfate (SDS) agarose gel electrophoresis under reducing conditions. Low molecular weight isoforms were defined as at least one allele with ≤22 kringle-IV repeats. PAD patients compared with controls showed significantly higher medium lipoprotein(a) serum concentrations and a higher frequency of low molecular weight apolipoprotein(a) phenotype. After adjustment for potential confounding factors, lipoprotein(a) concentrations above the 75th percentile of the entire cohort were a significant predictor of PAD with an odds ratio of 3.73, as was the low molecular weight apolipoprotein(a) phenotype (odds ratio 2.21). This association was consistently confirmed in several other case–control or cross sectional cohort studies in different populations including in total more than 10,000 subjects. The “Cardiovascular Disease in Intermittend Claudiation” (CAVASIC) and the “Kooperative Gesundheitsforschung in der Region Augsburg” (KORA F3 and KORA F4) studies included populations from southern Germany [12], a further cohort was studied in France [13], and the “Multi-Ethnic Study of Atherosclerosis” (MESA) included nearly 5000 European Americans, African Americans, Hispanic Americans and Chinese Americans [14].

The causality of elevated lipoprotein(a) for the development of PAD was then strongly suggested by three prospective cohort studies.

A substudy of the “European Prospective Investigation into Cancer and Nutrition” prospective population study (EPIC-Norfolk) included 25,639 female and male inhabitants of Norfolk, United Kingdom, aged between 29 and 79 years [15]. The baseline survey was performed between 1993 and 1997. Patients were followed until 2008. Outcomes were identified by linking a unique National Health Service number in the EPIC database with the East Norfolk Health Authority database. Mortality and hospitalizations for PAD and CAD were classified according to the respective International Classification of Diseases (ICD) codes. During 212,981 person–years at risk 2365 CAD and 596 PAD events occurred. Study participants in the highest sex-specific lipoprotein(a) quartile had an about 2‑fold increased hazard ratio for the developing of PAD compared to study participants in the other lipoprotein(a) quartiles. The hazard ratio remained largely unchanged after adjusting for several putative confounding factors including low-density lipoprotein(LDL)-cholesterol. Notably, the predictive value of lipoprotein(a) levels in the highest quartile were higher for PAD (adjusted hazard ratio 2.06) compared with CAD (adjusted hazard ratio 1.33).

The latter finding is consistent with data from the prospective “Scottish Heart Health Extended Cohort” [16]. This large prospective cohort recruited 15,737 healthy men and women across Scotland between 1984 and 1995, and followed them through 2009 for CAD and PAD diagnoses. The 20-year risk for PAD hospitalization and mortality was significantly determined by baseline lipoprotein(a) levels with an hazard ratio of 1.21. In contrast, baseline lipoprotein(a) levels were not significantly predictive for CAD risk in this cohort.

The above mentioned findings although apply to populations from other geographic origin, as baseline lipoprotein(a) levels were also predictive for incident PAD during 6‑year follow-up in a sample of more than 1000 Italian subjects over the age of 60 [17].

Taken together the above mentioned data strongly suggest that elevated lipoprotein(a) levels increase the risk of developing clinical relevant PAD that leads to hospitalization and mortality. Elevated lipoprotein(a) levels seem to be a more important risk factor for PAD compared with CAD (or stroke, the latter data not shown).

Prognostic impact of elevated lipoprotein(a) levels in patients with peripheral arterial disease

In patients with established symptomatic PAD elevated lipoprotein(a) levels also seem to be a risk factor for subsequent arterial events. Sanchez Monoz-Torreo et al. [18] prospectively followed a Spanish cohort of 1503 outpatients with symptomatic PAD for a mean of 36 months. During that time patients suffered from 122 myocardial infarctions, 118 strokes, 58 lower limb amputations, and 85 deaths. This event rate again indicates that patients with established PAD are at a very high cardiovascular and mortality risk. According to baseline lipoprotein(a) levels patients were separated into tertiles. Patients having lipoprotein(a) levels in the highest tertile above 50 mg/dL compared with patients in the lowest tertile below 30 mg/dL were shown to have an adjusted hazard ratio of 23.22 (95% confidence interval 12.17–44.29) for suffering a myocardial infarction, of 64.52 (95% confidence interval 29.13–142.93) for suffering a stroke, of 22.75 (95% confidence interval 9.25–55.97) for suffering a lower limb amputation, and of 32.92 (95% confidence interval 21.35–50.77) for any of these arterial events. These findings have to be confirmed in additional cohorts but indicate the high ongoing atherothrombotic risk of elevated lipoprotein(a) levels in patients with established atherosclerotic vascular disease.

Efficacy of lipoprotein(a) apheresis in patients with peripheral arterial disease

A causal relationship between elevated lipoprotein(a) levels and PAD that is strongly suggested by prospective cohort studies will finally be proven after lipoprotein(a) lowering therapies have shown to reduce the incidence and progression of PAD and other cardiovascular events in PAD patients. There is no effective pharmacological treatment to lower lipoprotein(a) levels clinically available at the moment, although RNA-targeted therapeutics to reduce lipoprotein(a) levels already have successfully completed phase II clinical trials [19]. Lipoprotein apheresis remains the only treatment option for patients with elevated lipoprotein(a) and progressive cardiovascular disease despite optimal medical treatment of all conventional cardiovascular risk factors. Lipoprotein apheresis has been shown to reduce the rate of cardiovascular events in patients with established coronary artery disease associated with high lipoprotein(a) levels [20,21,22,23].

Published data on the efficacy of lipoprotein apheresis in patients with PAD and elevated lipoprotein(a) are sparse, although PAD is highly prevalent in patients that are treated by lipoprotein(a) apheresis. Among 90 patients who started lipoprotein apheresis due to progressive cardiovascular disease and either isolated elevated lipoprotein(a) levels or a combination of elevated lipoprotein(a) and low-density lipoprotein cholesterol levels between 2008 and 2013 peripheral arterial disease was present in 44 and 53% of patients, respectively [24]. Among the 170 patients in the “Prospective Lipoprotein(a) Apheresis Registry Pro(a)Life” that represented around 60% of the German patients that were treated by lipoprotein(a) apheresis in 2011 [21] 30 lower limb peripheral arterial events had occurred in the two years before initiation of lipoprotein apheresis.

The latter registry followed these 170 patients and compared the cardiovascular event rates before and after initiation of lipoprotein(a) apheresis. In addition to a significant reduction of major cardiovascular events including myocardial infarction, percutaneous coronary intervention and coronary artery bypass grafting from 144 in the two years before to 31 in the two years after initiation of lipoprotein apheresis the rate of peripheral arterial events including peripheral arterial angioplasty, stenting or bypass surgery was reduced from 30 to 11, respectively. Furthermore, other non-coronary interventions such as carotid artery stenting or surgery or renal artery angioplasty or stenting was reduced from 7 to 1, respectively [21].

In a monocentric, retrospective, longitudinal cohort study 35 patients with isolated lipoprotein(a) elevation had been included, and the rate of cardiovascular events in the 6.8 ± 5.6 years before and 6.8 ± 4.9 years after initiation of chronic lipoprotein apheresis was compared. Besides a 90.4% reduction of major adverse cardiac events including cardiac death, non-lethal myocardial infarction, coronary bypass surgery and percutaneous coronary interventions a reduction of peripheral vascular events from 11 in the years before to 2 in the years after initiation of lipoprotein apheresis could be observed [25].

Poller and coworkers [26, 27] prospectively followed 10 patients who were treated by lipoprotein apheresis due to symptomatic PAD that required a revascularization procedure, had elevated lipoprotein(a) levels above 60 mg/dL and were on sufficient treatment of all other cardiovascular risk factors. Outcome measures were the rate of clinically driven revascularizations in the 12 months prior compared with the 24 months after initiation of lipoprotein apheresis as well as the ankle-brachial blood pressure index, the walking distance determined by a standardized treadmill test, as well as subjective grading of the mean pain level during everyday physical activity on a 10-point visual analogue scale (the higher the score the worse the pain). Consistent with the above mentioned study, the study also showed a significant reduction of clinical driven revascularizations from 35 procedures during 120 patient–months in the year before to 2 procedures per 229 patient–months in the two years after initiation of lipoprotein apheresis. Lipoprotein apheresis also led to a rapid and sustained improvement of PAD symptoms in all patients. This is indicated by a significant reduction of the pain level from 7.0 ± 1.5 points at baseline to 1.6 ± 0.7 after one and 1.1 ± 0.4 after two years of lipoprotein apheresis. Consistently, the mean walking distance increased from 87 ± 60 m at baseline gradually to 402 ± 119 after two years. This went along with a significant increase in the resting ankle-brachial index in the affected leg.

Taken together these data show that lipoprotein apheresis rapidly and significantly improves symptoms of PAD such as pain during physical activity and the walking distance and reduces the rate of clinically driven peripheral revascularizations.

Conclusions

Elevated lipoprotein(a) levels have been shown to be a risk factor for the development of cardiovascular disease in the coronary and cerebrovascular circulation. Although randomized controlled trials are missing and won’t be possible to perform due to ethical reasons within the near future longitudinal observational studies strongly suggest that the reduction of lipoprotein(a) levels by lipoprotein apheresis significantly and clinical relevantly reduces the incidence of cardiovascular events [20,21,22,23, 25]. There is increasing evidence from case–control studies, cross-sectional cohort studies and longitudinal prospective cohort studies that elevated lipoprotein(a) levels are a risk factor for the development of PAD and for a worse clinical outcome in PAD patients [11,12,13,14,15,16,17,18]. Furthermore, longitudinal observational studies indicated that lipoprotein apheresis also reduces the necessity for clinically driven revascularizations in patients with PAD [21, 23, 25,26,27]. Whether or not it also reduces the extremely high burden of overall cardiovascular morbidity and mortality in PAD patients that is higher compared with patients with isolated CAD [8, 9] has not been studied so far but seems to be biologically plausible.

Therefore it is good clinical practice that patients with PAD and progressive disease despite control of all conventional risk factors should be screened for elevated lipoprotein(a) levels. In addition patients with elevated lipoprotein(a) levels and coronary or cerebrovascular atherosclerosis should also be screened for the presence of PAD, either symptomatic or asymptomatic, as patients with polyvascular disease in the coronary and peripheral circulation are at higher risk compared to patients with isolated CAD [10].

PAD patients with elevated lipoprotein(a) levels and progressive disease as indicated by recurrent clinical events requiring revascularization or progression of the disease stage from asymptomatic to intermittent claudication or critical limb ischemia or from intermittent claudication to critical limb ischemia even without the necessity or technical ability for revascularization should be considered candidates for lipoprotein apheresis. In addition patients with elevated lipoprotein(a) levels and clinical overt coronary and cerebrovascular disease that are found to develop PAD should be considered as patients with progressive atherosclerotic vascular disease and considered candidates for lipoprotein apheresis [28].

Although randomized controlled trials have not been performed and therefore have not proven the clinical efficacy of lipoprotein apheresis this treatment option cannot be withheld in high risk patients based on current evidence. To broaden the knowledge on the efficacy of lipoprotein apheresis in patients with atherosclerotic cardiovascular disease including PAD and elevated lipoprotein(a) levels, however, it is reasonable and seems to be mandatory to include all patients that initiate lipoprotein apheresis in prospective clinical trials or registries such as the “European Multicenter Study on the Effect of Lipoprotein(a) Elimination by Lipoprotein Apheresis on Cardiovascular Outcomes” (MultiSelect) [29].