Introduction

Lipoprotein (a) (Lp (a)) is one of the most atherogenous lipoproteins and its impact on atherogenesis has become of increasing scientific interest during recent years [1]. Many studies have shown that elevated Lp (a) concentrations have an important influence on the development of coronary heart disease (CHD) [24]. The structure of Lp (a) consisting of the Lp (a)-specific glycoprotein apolipoprotein-a (APO (a)) implies the pro-atherogenous and pro-thrombogenous characteristics [3] with increased risk of myocardial infarction and heart failure [5].

Our retrospective study in 31,734 patients over a 5-year period documented that an increasing Lp (a) concentration is associated with a higher incidence of CHD and severity of vascular disease (Table 1) as well as more myocardial infarctions, interventions and surgical myocardial revascularizations (Table 2).

Table 1 Incidence of coronary vessel disease associated with increasing Lp (a) levels
Table 2 Incidence of myocardial infarction, PCI and CABG under increasing Lp (a) levels

Current options of drug therapy are very limited. A significant reduction of Lp (a) concentrations is neither achieved by statins or ezetimibe nor by PCSK9 inhibitors [6, 7]. In contrast, high doses of nicotinic acid (niacin) (2–4 g) significantly reduce Lp (a) [8]. However, since 2013 this substance is not available any more in Europe due to its side effects.

Lipid apheresis seems to be the only therapeutic option providing a favourable effect on cardiac events and the progression of coronary heart disease.

Patients and methods

In a retrospective, single-centre observation study, the effectiveness of lipid apheresis in patients with high Lp (a) levels and angiographically documented coronary heart disease was evaluated on the basis of percutaneous coronary intervention (PCI). All patients undergoing lipid apheresis during the observation period with Lp (a) > 60 mg/dl prior to the first procedure were included. All patients fulfilled the criteria of the German federal authority to be eligible for lipid apheresis, and reimbursement had been approved by committees of regional associations of statutory health insurance physicians. Furthermore, all patients gave their informed consent to the scientific analysis of their data.

Twenty-three patients (male 18, age 60.04 ± 10.58 years) fulfilled the above criteria and were included in the study (Table 3). Apheresis was performed applying the heparin-induced extracorporeal LDL precipitation (HELP) (Plasmat-Futura®, B. Braun, Melsungen, Germany) and the polyacrylate adsorption of whole blood or plasmapheresis by means of double filtration (DALI® and MONET®, Fresenius Medical Care, Bad Homburg, Germany). During the weekly procedures, lipid status (Lp (a), total cholesterol, HDL cholesterol, LDL cholesterol, triglycerides) was obtained before and after the procedure. Reduction of LDL cholesterol and Lp (a) was 60–65% per procedure.

Table 3 Patient characteristics

Lipid status

Prior to the initiation of lipid apheresis, LDL cholesterol was 144.39 ± 92.01 mg/ld and Lp (a) 133.04 ± 39.68 mg/dl. 18 patients received the highest tolerated dosage of statins, 8 patients of them ezetimibe in addition. 5 patients had a statin intolerance.

Cardiovascular status

Fourteen of 23 patients had a coronary 3‑vessel disease (3-VD), 3 patients a 2-VD, 5 patients a 1-VD. One patient with a history of a TIA turned out to suffer from coronary sclerosis (0-VD). In 5 patients, CHD was associated with segmental occlusions and another 5 patients showed an additional involvement of the vascular periphery and the cerebrovascular region (Table 3). Patient age at first disease manifestation was low with 48.00 ± 9.41 years, in 10 patients first manifestation was accompanied by an acute coronary syndrome (ACS).

Prior to lipid apheresis, 49 PCI and 3 CABG procedures had been performed in patients with a haemodynamically relevant coronary stenosis. Lipid apheresis was initiated after a mean duration of 4.30 ± 4.95 years following first manifestation of CHD. Thereafter, all patients underwent non-invasive diagnosis on a routine basis every year and invasive diagnostic procedure every 2 years followed by PCI in case of a haemodynamically relevant stenosis (Table 3).

Results

At the time of the study, LDL cholesterol was 99.43 ± 36.53 mg/dl and Lp (a) 91.13 ± 33.02 mg/dl. In a time interval of 59.87 ± 49.49 months (median 51.00, range 1–153 months) 15 patients did not require a PCI. For the first time after initiation of lipid apheresis, 8 patients (7 pat 3‑VD, 1 pat 2‑VD) underwent PCI after 69.38 ± 71.67 months (median: 32.50, range 17–232 months) the total number of PCI being 14. Two of 3 patients with recurrent stenosis and multiple interventions had an in-stent restenosis. CABG was not necessary (Fig. 1).

Discussion

The present study was intended to document the influence of lipid apheresis on the incidence of PCI. The patient cohort with a high Lp (a) concentration was characterized by a diffuse, advanced CHD with a high proportion of segmental coronary occlusions. The additional high proportion of patients with cerebrovascular and peripheral vascular deterioration shows the vascular manifestations to be expected.

Regular lipid apheresis significantly reduced LDL cholesterol and Lp (a). In contrast to the multicentre prospective study evaluating cardiac events (MACE) after the initiation of lipid apheresis [9], our collective underwent PCI after documentation of a haemodynamically relevant stenosis as a sign of major disease progression. The significant decline in PCI procedures (71.43%) indicates the impact on the atherosclerotic process mainly induced by Lp (a) hyperlipoproteinaemia. This is of particular importance as it is a diffuse vascular disease of different vascular origin with a strong tendency to progression. At present, lipid apheresis has to be regarded as the most effective therapeutic procedure in secondary prevention.

Conclusion

Our single centre observation study in patients with markedly increased LDL cholesterol and Lp (a) values accompanied by an early manifestation of coronary heart disease and consecutive PCI or surgical myocardial revascularization showed that lipid apheresis reduced the incidence of PCI or surgical myocardial revascularization by 71.43%. This therapeutic option has to be part of secondary prevention.

Fig. 1
figure 1

Interventions (PCI/myocardial revascularization) before and after the initiation of lipid apheresis