Lipoprotein(a) levels in chronic renal disease states, dialysis and transplantation

Non-genetic influences on lipoprotein(a) concentrations

An elevated level of lipoprotein(a) [Lp(a)] is a genetically regulated, independent, causal risk factor for cardiovascular disease. However, the extensive variability in Lp(a) levels between individuals and population groups cannot be fully explained by genetic factors, emphasizing a potential role for non-genetic factors. In this review, we provide an overview of current evidence on non-genetic factors influencing Lp(a) levels with a particular focus on diet, physical activity, hormones and certain pathological conditions. Findings from randomized controlled clinical trials show that diets lower in saturated fats modestly influence Lp(a) levels and often in the opposing direction to LDL cholesterol. Results from studies on physical activity/exercise have been inconsistent, ranging from no to minimal or moderate change in Lp(a) levels, potentially modulated by age and the type, intensity, and duration of exercise modality. Hormone replacement therapy (HRT) in postmenopausal women lowers Lp(a) levels with oral being more effective than transdermal estradiol; the type of HRT, dose of estrogen and addition of progestogen do not modify the Lp(a)-lowering effect of HRT. Kidney diseases result in marked elevations in Lp(a) levels, albeit dependent on disease stages, dialysis modalities and apolipoprotein(a) phenotypes. In contrast, Lp(a) levels are reduced in liver diseases in parallel with the disease progression, although population studies have yielded conflicting results on the associations between Lp(a) levels and nonalcoholic fatty liver disease. Overall, current evidence supports a role for diet, hormones and related conditions, and liver and kidney diseases in modifying Lp(a) levels.

Elevated Plasma Lipoprotein(a) Levels and Hypoalbuminemia in Peritoneal Dialysis Patients

Plasma lipoprotein(a), Lp(a), is strongly and independently associated with atherosclerosis, and levels are elevated in hemodialysis (HD) patients and in some studies of those on peritoneal dialysis (PD). We hypothesized that protein losses and hypoalbuminemia could stimulate hepatic Lp(a) synthesis, and this effect would be accentuated in PD patients with malnutrition. The PD subjects (n=24) had higher plasma Lp(a) levels than those (n=10) on HD (median 34.4 vs 21.0 mg/dl, p<0.05), and values exceed normal in 62.5% vs 20% of the subjects (p<0.03), respectively. The serum albumin levels inversely correlated with concentrations of Lp(a) and apolipoprotein B, as well as the apolipoprotein B/AI ratio. In conclusion, plasma Lp(a) concentrations are frequently elevated in PD as well as HD patients. Measuring Lp(a) levels is useful in identifying patients at increased atherogenic risk, which may not be reflected in routine lipid profiles. The negative correlation between plasma Lp(a) and albumin levels suggests that the latter may be linked pathophysiologically to hepatic Lp(a) production. The association of hypoalbuminemia with higher Lp(a) values is of particular concern because malnutrition frequently occurs in PD patients.

Serum lipoprotein(a) levels and diabetic nephropathy among Japanese patients with type 2 diabetes mellitus

AIMS

We aimed to evaluate the association between serum lipoprotein(a) [Lp(a)] levels and diabetic nephropathy among Japanese patients with type 2 diabetes mellitus.

METHODS

This study included 581 patients with type 2 diabetes mellitus. Serum Lp(a) levels were divided into four groups; the cut-off points were at the 30th, 60th, and 90th percentile values on the basis of the distribution for all subjects. Diabetic nephropathy was defined as present when the urinary albumin-creatinine ratio was ≥33.9mg/mmol creatinine and/or the estimated glomerular filtration rate was <30ml/min/1.72m(2). Adjustment was made for age, sex, body mass index, hemoglobin A1c, duration of diabetes mellitus, current drinking, current smoking, hypertension, dyslipidemia, coronary heart disease, and stroke.

RESULTS

Higher serum Lp(a) levels were significantly associated with a higher prevalence of diabetic nephropathy: the adjusted odds ratios (95% confidence intervals) for diabetic nephropathy in relation to serum Lp(a) levels of ≤6, 7-15, 16-38, and ≥39mg/dl were 1.00 (reference), 2.74 (1.08-7.00), 3.31 (1.28-8.54), and 4.80 (1.57-14.60), respectively (P for trend=0.004).

CONCLUSIONS

The results suggest that serum Lp(a) levels may be positively associated with diabetic nephropathy among Japanese patients with type 2 diabetes mellitus.

Lipoprotein (a): impact by ethnicity and environmental and medical conditions

Levels of lipoprotein (a) [Lp(a)], a complex between an LDL-like lipid moiety containing one copy of apoB, and apo(a), a plasminogen-derived carbohydrate-rich hydrophilic protein, are primarily genetically regulated. Although stable intra-individually, Lp(a) levels have a skewed distribution inter-individually and are strongly impacted by a size polymorphism of the LPA gene, resulting in a variable number of kringle IV (KIV) units, a key motif of apo(a). The variation in KIV units is a strong predictor of plasma Lp(a) levels resulting in stable plasma levels across the lifespan. Studies have demonstrated pronounced differences across ethnicities with regard to Lp(a) levels and some of this difference, but not all of it, can be explained by genetic variations across ethnic groups. Increasing evidence suggests that age, sex, and hormonal impact may have a modest modulatory influence on Lp(a) levels. Among clinical conditions, Lp(a) levels are reported to be affected by kidney and liver diseases.

Lipoprotein (a) in chronic renal failure: effect of maintenance hemodialysis

BACKGROUND

Coronary artery disease accounts for significant morbidity and mortality in patients with chronic kidney disease (CKD). Besides the higher prevalence of traditional risk factors, several uremia-related factors may play a role in accelerated atherosclerosis, such as elevated levels of lipoprotein (a) (Lp(a)). The effect of maintenance hemodialysis (MHD) on Lp(a) levels is not well understood. The present work was carried out to study the Lp(a) levels in Stage 4 and Stage 5 CKD patients as well as the effect of MHD on Lp(a) levels in patients with Stage 5 CKD.

METHODS

The study subjects included 15 patients with Stage 4 CKD, 15 patients with Stage 5 CKD, and 15 age- and sex-matched healthy controls. Plasma Lp(a) was measured by ELISA in all the subjects at the time of entry into the study and after 4 weeks of MHD in patients with Stage 5 CKD. Patients on MHD were dialyzed two to three times weekly for 4 hr during each session.

RESULTS

Mean Lp(a) levels were significantly higher in patients with CKD than in control patients. In patients with Stage 4 CKD, the Lp(a) level was 34.0 +/- 19.5 mg/dL, whereas in Stage 5 CKD the level was 49.0 +/- 30.9 and in healthy controls it was 22.2 +/- 16.4. In patients with Stage 5 CKD, 4 weeks of MHD led to a significant fall in Lp(a) levels by 23.6% (P < 0.001).

CONCLUSIONS

The results of this study show that increases in Lp(a) levels start early during the course of CKD and become more pronounced with increased severity of disease. Initiation of MHD lowers Lp(a) levels and may have a long-term beneficial effect on cardiovascular morbidity and mortality.

Effects of Soy Consumption on Serum Lipids and Apoproteins in Peritoneal Dialysis Patients: A Randomized Controlled Trial

Background

Lipid abnormalities, particularly high serum concentration of lipoprotein(a) [Lp(a)], are one of the major risk factors for cardiovascular disease (CVD) in peritoneal dialysis (PD) patients. The present study was designed to investigate the effects of soy consumption on serum lipids and apoproteins, especially Lp(a), in PD patients.

Methods

This study was a randomized clinical trial in which 40 PD patients (20 males, 20 females) were randomly assigned to either the soy or the control group. Patients in the soy group received 28 g/day textured soy flour (containing 14 g of soy protein) for 8 weeks, whereas patients in the control group received their usual diet, without any soy. At baseline and the end of week 8 of the study, 5 mL of blood was collected from each patient after a 12- to 14-hour fast and serum triglyceride, total cholesterol, low density lipoprotein-cholesterol (LDL-C), high density lipoprote-incholesterol (HDL-C), apoprotein B100 (apo B100), apoprotein AI (apo AI), and Lp(a) were measured.

Results

In the present study, serum Lp(a) concentrations were above the normal range in 86% of the PD patients. Mean serum Lp(a) concentration was reduced significantly, by 41%, in the soy group at the end of week 8 compared to baseline ( p < 0.01); the reduction was also significant compared to the control group ( p < 0.05). During the study, mean serum Lp(a) concentration did not change significantly in the control group. There were no significant differences between the two groups in mean changes in serum triglyceride, total cholesterol, HDL-C, LDL-C, apo B100, or apoAI.

Conclusion

The results of our study indicate that soy consumption reduces serum Lp(a) concentration, which is a risk factor for cardiovascular disease in peritoneal dialysis patients.

Effect of apolipoprotein E polymorphism on serum lipid, lipoproteins, and atherosclerosis in hemodialysis patients

Atherosclerosis and cardiovascular disease are the main causes of death in hemodialysis patients. Possession of the apolipoprotein E4 (ApoE4) allele has been associated with increased levels of serum lipids and with coronary and carotid artery atherosclerosis. We investigated the possible relationship between ApoE polymorphism and atherosclerosis risk factors in hemodialysis patients. Two hundred sixty-nine hemodialysis patients (115 women, 154 men) were included in our study. The mean patient age and mean hemodialysis duration were 45.8 +/- 15.3 years and 52.6 +/- 40.6 months, respectively. Testing was done on all patients to determine ApoE genotype and serum levels of total cholesterol (T-Cho), low-density lipoprotein (LDL-C), high-density cholesterol (HDL-C), triglyceride (TG), lipoprotein (a) (Lp[a]), intact parathormone (iPTH), and fibrinogen. ApoE genotype was identified with the polymerase chain reaction. Ultrasonographic measurement of carotid artery intima media thickness (IMT) was used to diagnose atherosclerosis. We also analyzed ApoE polymorphism and risk factors such as age, gender, duration of hemodialysis, smoking, and hypertension in relation to the presence of atherosclerosis. Serum T-Cho and LDL-C levels were higher in patients with the ApoE4/3 phenotype than in those with ApoE3/3 and ApoE3/2 phenotypes (P < 0.05). However, there was no statistically significant link between ApoE polymorphism and serum levels of TG, HDL-C, or Lp(a) (P > 0.05). Apart from a relationship with age and duration of hemodialysis (P < 0.05), we found no significant association between atherosclerosis and ApoE polymorphism or the other risk factors analyzed (P > 0.05). In conclusion, although ApoE polymorphism significantly affects serum levels of T-Cho and LDL-C in hemodialysis patients, this study indicates that ApoE polymorphism is not associated with the presence of atherosclerosis in these individuals. The high incidence of atherosclerosis in these patients underlines the need for further research on other possible causative factors.

Changes in lipoprotein(a) concentration after orthotopic heart transplantation

BACKGROUND

Elevated concentrations of lipoprotein(a) have been considered an important risk factor in the development of premature cardiovascular disease and have been proposed as a risk factor in the development of accelerated cardiac allograft vasculopathy after orthotopic heart transplantation.

METHODS

We prospectively measured lipoprotein(a), fasting cholesterol, and triglyceride concentrations before (n = 38), 6 months (n = 38), and 1 year (n = 21) after orthotopic heart transplantation. The mean age of the patients was 52 +/- 2 years. Eighty-seven percent of the patients were men, 82% were white, and 61% had ischemic cardiomyopathy.

RESULTS

Mean lipoprotein(a) concentration was lower 6 months after transplantation than it was before the operation (23 +/- 3 mg/dL vs 17 +/- 3 mg/dL; P =.014) and remained low 1 year after transplantation (23 +/- 3 mg/dL vs 18 +/- 4 mg/dL; P = not significant). In contrast, mean cholesterol concentration was higher 6 months after transplantation (171 +/- 8 mg/dL vs 221 +/- 8 mg/dL; P <.001) and 1 year (171 +/- 8 mg/dL vs 205 +/- 10 mg/dL; P <.01) than it was before transplantation. Triglyceride concentration was higher 1 year after transplantation than it was before the operation (146 +/- 13 mg/dL vs 184 +/- 20 mg/dL; P =.017).

CONCLUSIONS

Lipoprotein(a) concentrations decrease during the 6 months after transplantation and stay low for at least 1 year after the operation. Additional studies are needed to ascertain the effect these changes in lipoprotein(a) concentration on the development of cardiac allograft vasculopathy.

Lipoprotein(a) serum concentrations and apolipoprotein(a) phenotypes in mild and moderate renal failure

High lipoprotein(a) (Lp(a)) serum concentrations and the underlying apolipoprotein(a) (apo(a)) phenotypes are risk factors for cardiovascular disease in the general population as well as in patients with renal disease. Lp(a) concentrations are markedly elevated in patients with end-stage renal disease. However, nothing is known about the changes of Lp(a) depending on apo(a) size polymorphism in the earliest stages of renal impairment. In this study, GFR was measured by iohexol technique in 227 non-nephrotic patients with different degrees of renal impairment and was then correlated with Lp(a) serum concentrations stratified according to low (LMW) and high (HMW) molecular weight apo(a) phenotypes. Lp(a) increased significantly with decreasing GFR. Such an increase was dependent on apo(a) phenotype. Only renal patients with HMW apo(a) phenotypes expressed higher median Lp(a) concentrations, i.e., 6.2 mg/dl at GFR >90 ml/min per 1.73 m2, 14.2 at GFR 45 to 90 ml/min per 1.73 m2, and 18.0 mg/dl at GFR <45 ml/min per 1.73 m2. These values were markedly different when compared with apo(a) phenotype-matched control subjects who had a median level of 4.4 mg/dl (ANOVA, linear relationship, P < 0.001). In contrast, no significant differences were observed at different stages of renal function in patients with LMW apo(a) phenotypes when compared with phenotype-matched control subjects. The elevation of Lp(a) was independent of the type of primary renal disease and was not related to the concentration of C-reactive protein. Multiple linear regression analysis found that the apo(a) phenotype and GFR were significantly associated with Lp(a) levels. Non-nephrotic-range proteinuria modified the association between GFR and Lp(a) levels. In summary, an increase of Lp(a) concentrations, compared with apo(a) phenotype-matched control subjects, is seen in non-nephrotic patients with primary renal disease even in the earliest stage when GFR is not yet subnormal. This change is found only in subjects with HMW apo(a) phenotypes, however.

Lipoprotein(a) plasma concentrations after renal transplantation: a prospective evaluation after 4 years of follow-up

The highly atherogenic lipoprotein(a) [Lp(a)] is significantly elevated in patients with renal disease. It is discussed controversially whether Lp(a) concentrations decrease after renal transplantation and whether the mode of immunosuppressive therapy influences the Lp(a) concentrations. In a prospective study the Lp(a) concentrations before and on average 48 months after renal transplantation were measured in 145 patients. The determinants of the relative changes of Lp(a) concentrations were investigated in a multivariate analysis. Patients treated by CAPD showed a larger decrease of Lp(a) than hemodialysis patients, reflecting their markedly higher Lp(a) levels before transplantation. The relative decrease of Lp(a) was higher with increasing Lp(a) concentrations before transplantation in combination with an increasing molecular weight of apolipoprotein(a) [apo(a)]. That means that the relative decrease of Lp(a) is related to the Lp(a) concentration and the apo(a) size polymorphism. With increasing proteinuria and decreasing glomerular filtration rate, the relative decrease of Lp(a) became less pronounced. Neither prednisolone nor cyclosporine (CsA) had a significant impact on the Lp(a) concentration changes. Azathioprine (Aza) was the only immunosuppressive drug which had a dose-dependent influence on the relative decrease of Lp(a) levels. These data clearly demonstrate a decrease of Lp(a) following renal transplantation which is caused by the restoration of kidney function. The relative decrease is influenced by Aza but not by CsA or prednisolone.

Decreased urinary apolipoprotein (a) excretion in patients with impaired renal function

BACKGROUND

Plasma lipoprotein (a) [Lp(a)] levels are elevated in patients with kidney disease and are strongly associated with premature cardiovascular disease and stroke.

METHODS

As the kidney is suggested to play an important role in apolipoprotein (a) [apo(a)] catabolism and as apo(a) fragments appear in urine, we determined plasma Lp(a) levels and urinary apo(a) excretion in relation to kidney function in a large cohort of renal patients. A total of 368 renal patients with normal or different degrees of impaired renal function and 163 healthy control subjects matched for age and sex were investigated. Plasma Lp(a) and urinary apo(a) were analysed immunochemically.

RESULTS

Renal patients were found to have significantly elevated total cholesterol and low-density lipoprotein (LDL)-C values but lower high-density lipoprotein (HDL)-C values than control subjects. Plasma Lp(a) values were significantly higher only in patients with creatinine clearance < 70 mL min-1. There was a significant correlation between urinary apo(a) and plasma Lp(a) in patients and control subjects. Urinary apo(a) excretion was significantly lower in patients than in control subjects and showed no correlation with urinary protein excretion.

CONCLUSION

Although it is unlikely that impaired renal excretion of apo(a) fragments largely contributes to increased plasma Lp(a) levels in patients suffering from impaired kidney function, these data suggest that urinary apo(a) excretion is significantly decreased in renal patients and that this might contribute to increased plasma Lp(a) levels in this patient group.

Early elevation of lipoprotein(a) levels in chronic renal insufficiency

Serum lipoprotein(a) [Lp(a)] concentrations in chronic renal failure patients were investigated in relation to the degree of renal insufficiency, treatment by maintenance hemodialysis, and correction of uremia by renal transplantation with or without cyclosporin immunosuppression. Fast serum levels of Lp(a) (mg/100 mL) were determined in 34 chronic renal failure patients not in need of maintenance dialysis (16 with serum creatinine 2.0-4.0 mg/100 mL; 18 with serum creatinine higher than 4.0 mg/100 mL), 40 patients treated by hemodialysis, 55 successful renal transplant recipients (28 under cyclosporin treatment and 27 receiving no cyclosporin), and 34 healthy controls. Age and sex distributions were similar among groups. Pregnant women; non-White individuals; subjects with obesity, diabetes, nephrotic syndrome, and hepatic and thyroid diseases; and those treated with oral contraceptives or lipid-lowering drugs were excluded from the study. Compared to controls, median Lp(a) was increased in nondialyzed renal failure patients (11 vs. 47.5 p < 0.001) and this was the only lipid abnormally observed in the group. There was no significant difference in Lp(a) levels between nondialized renal failure patients with serum creatinine 2.0-4.0 and > 4.0 mg/100 mL (47 vs. 49, NS). Moreover, Pearson correlation coefficient (r = 0.01, NS) showed that Lp(a) values were not related to serum creatinine in nondialyzed patients, In hemodialysis subjects Lp(a) concentrations (median = 29) were intermediate between those observed in nondialyzed patients and controls but the differences were not significant. Lp(a) levels in renal transplant patients treated with cyclosporin (median = 6) and not receiving cyclosporin (median = 13) were similar and did not differ from controls. Serum Lp(a) increases and attains maximum levels with mild/moderate reduction in renal function, and does not seem to change through late renal failure stages or in relation to the introduction of maintenance hemodialysis treatment. Correction of uremia by successful renal transplant caused normalization of Lp(a) levels regardless of the use of cyclosporin. Increased Lp(a) levels may be the earliest and more consistent lipid alteration seen in predialysis renal failure.

Plasminogen activator inhibitor-1 activity in chronic renal disease and dialysis

The activity of plasminogen activator inhibitor-1 (PAI-1), an inhibitor of fibrinolysis, is associated with insulin resistance (IR) and the risk of venous and arterial thrombotic cardiovascular disease (CVD) in the general population, and may behave as an acute-phase reactant. PAI-1 activity was measured in 124 patients with chronic renal disease, and its relationship with alterations in metabolic, lipid, and cytokine parameters and the prevalence of CVD complications was explored. Patients with chronic renal disease not requiring dialysis were divided into a low proteinuric ([LP]n = 30) or high proteinuric ([HP]n = 31) group and compared with patients on continuous ambulatory peritoneal dialysis ([CAPD]n = 32) or hemodialysis([HD]n = 31) and with 31 healthy controls. Patients on HD had significantly lower PAI-1 activity than HP, CAPD, and control groups, but no group had significantly higher values than the controls (AU/mL: 7.4 +/- 3.8 HD, 11.2 +/- 8.4 CAPD, 9.4 +/- 5.4 LP, 12.1 +/- 8.0 HP, 11.4 +/- 6.6 controls, P = .04). Interleukin-6 (IL-6), the mediator of the acute-phase response, was determined in a subset of patients and was significantly increased in HD, CAPD, and LP groups compared with the controls (median, pg/mL: 4.6 HD, 4.0 CAPD, 2.9 LP, 2.4 HP, and 1.5 controls, P < .001), but did not correlate with PAI-1. PAI-1 independently correlated with body mass index (BMI), triglycerides, and lipoprotein(a) [Lp(a)] in stepwise regression for all patients. Dividing the whole patient group by tertiles of triglycerides and BMI, increased PAI-1 was confined to the subgroup of patients with both obesity (BMI > 26.7 kg/m2) and hypertriglyceridemia (triglycerides > 2.5 mmol/L). These data suggest that PAI-1 activity in chronic renal disease and dialysis was more strongly associated with the common metabolic abnormalities of obesity and hypertriglyceridemia than with renal disease status, dialysis, or a chronic inflammatory state. This study does not support but does not exclude a major role for increased PAI-1 activity in CVD risk in chronic renal disease.

Decrease in lipoprotein(a) after renal transplantation is related to the glucocorticoid dose

Serum lipoprotein(a) [Lp(a)] concentrations and apolipoprotein(a) phenotypes were determined in 46 patients with end-stage renal disease both before as well as 1 week and 1, 3 and 6 months after renal transplantation. Immunosuppressive therapy consisted of cyclosporin A, prednisone and azathioprine. Before transplantation median Lp(a) levels did not differ between the patients and a healthy control group. A highly significant decrease (P < 0.001) in Lp(a) levels was observed in both male and female patients 1 week after transplantation. This marked reduction in Lp(a) occurred at a time when patients were receiving the highest doses of corticosteroids. As steroid doses were gradually tapered, Lp(a) concentrations subsequently increased, although at 6 months levels were still significantly reduced (P < 0.01) in women. No significant correlation was observed between Lp(a) and whole-blood cyclosporin levels, nor was there any correlation with the azathioprine dose. The reduction in Lp(a) concentrations was seen for all apo(a) phenotypes observed in the study.

Factors influencing plasma lipid profiles including lipoprotein (a) concentrations in renal transplant recipients

Fasting plasma cholesterol, triglycerides, high-density lipoprotein (HDL) and apoprotein (apo) B were elevated in 214 nondiabetic renal transplant recipients when compared to a reference group. Apo (a) was slightly but not significantly lower in transplant recipients (median 118 mg/dl, range 16-1680 vs 130 mg/dl, 10-1176) and this difference could be predicted from Lp (a) isoform analysis. Cholesterol, triglyceride, apo B and apo (a) concentrations correlated negatively with creatinine clearance but none of these parameters showed a significant association with proteinuria. Patients treated with steroids had higher plasma HDL concentrations than those receiving cyclosporin monotherapy (P < 0.01). The use of diuretics was associated with raised triglycerides (P < 0.001) and cholesterol (P < 0.01) and with reduced HDL (P < 0.01) whilst patients receiving beta-blockers had significantly higher triglycerides (P < 0.01) and lower HDL levels (P < 0.02). In multiple regression analysis, age (P < 0.01), creatinine clearance (P < 0.05) and diuretic therapy (P < 0.005) were independent risk factors for increased cholesterol whilst apo (a) levels correlated negatively with creatinine clearance (P < 0.005). These results suggest that impaired renal function, steroids and non-immunosuppressive drugs contribute to lipid abnormalites in renal transplant recipients.

Lipoprotein(a) in renal disease

Lipoprotein(a) [Lp(a)] is a genetically determined risk factor for atherosclerotic vascular disease. Several studies have described a correlation between high Lp(a) plasma levels and coronary heart disease, stroke, and peripheral atherosclerosis. In healthy individuals Lp(a) plasma concentrations are almost exclusively controlled by the apolipoprotein(a) [apo(a)] gene locus on chromosome 6q2.6-q2.7. More than 30 alleles at this highly polymorphic gene locus determine a size polymorphism of apo(a). There exists an inverse correlation between the size (molecular weight) of apo(a) isoforms and Lp(a) plasma concentrations. Average Lp(a) levels are high in individuals with low molecular weight isoforms and low in those with high molecular weight isoforms. Mean Lp(a) plasma levels are elevated over controls in patients with renal disease. Patients with nephrotic syndrome exhibit excessively high Lp(a) plasma concentrations, which can be reduced with antiproteinuric treatment. The mechanism underlying this elevation is unclear, but the general increase in protein synthesis caused by the liver due to high urinary protein loss is a likely explanation. Patients with end-stage renal disease (ESRD) also have elevated Lp(a) levels. These are even higher in patients treated by continuous ambulatory peritoneal dialysis than in those receiving hemodialysis. Lipoprotein(a) concentrations decrease to values observed in controls matched for apo(a) type following renal transplantation. This clearly demonstrates the nongenetic origin of Lp(a) elevation in ESRD. Both the increase in ESRD and the decrease following renal transplantation are apo(a) phenotype dependent. Only patients with high molecular weight phenotypes show the described changes in Lp(a) levels. In patients with low molecular weight types the Lp(a) concentrations remain unchanged during both phases of renal disease. As in the general population, Lp(a) is a risk factor for cardiovascular events in ESRD patients. In this patient group the apo(a) phenotype seems to be equally or better predictive of the degree of atherosclerosis than is Lp(a) concentration. Further prospective studies will be necessary to confirm these observations. Whether Lp(a) also plays a key role in the pathogenesis and progression of renal diseases needs further study. Controversial data on the role of the kidney in Lp(a) metabolism result from insufficient sample sizes of several studies. Due to the broad range and skewed distribution of Lp(a) plasma concentrations, large study groups must be investigated to obtain reliable results.

Reduction of lipoprotein(a) following treatment with lovastatin in patients with unremitting nephrotic syndrome

Pharmocologic treatment of the hyperlipidemia associated with the nephrotic syndrome with lovastatin has been previously shown to be safe and effective. However, there is no information on the effect of lovastatin treatment on plasma lipoprotein(a) [Lp(a)] levels in patients with the nephrotic syndrome. We administered lovastatin (40 to 80 mg/day) to 20 adult patients with unremitting nephrotic syndrome for 8 weeks to assess its effect on plasma Lp(a) and other plasma lipid concentrations. Apoprotein(a) (apo(a)) phenotype was determined in all patients. Patients were grouped according to their plasma Lp(a) levels. Those with elevated plasma Lp(a) (> or = 30 mg/dL) were placed in group I and those with normal Lp(a) levels (< 30 mg/dL) were placed in group II. Mean total cholesterol and LDL cholesterol were similarly and significantly reduced in groups I and II (-35.9% and -43.3%, P < 0.0005, P < 0.0005 group I, and -31.0% and -42.0%, P < 0.02, P < 0.03 group II, respectively). The median reduction in plasma Lp(a) was -32% (P < 0.003) in nephrotic patients in group I, whereas the median decline in plasma Lp(a) levels in nephrotic patients in group II was only -8.0% (P = 0.052). The overall frequency of the high molecular weight (M(r)) apo(a) phenotype S4 was 70% in nephrotic patients. There was no correlation between plasma Lp(a) and apo(a) phenotype. Treatment with lovastatin results in a favorable response in terms of total and low-density lipoprotein cholesterol lowering in patients with the nephrotic syndrome; however, plasma Lp(a) levels are uniformly and significantly reduced only in nephrotic patients with elevated baseline plasma Lp(a) concentrations. There was no correlation between plasma Lp(a) concentration and other lipid and biochemical parameters.

Lipoprotein(a) levels in patients receiving renal replacement therapy: methodologic issues and clinical implications

Lipoprotein(a) [Lp(a)] is a genetically determined risk factor for vascular disease and a potential link between coagulation, lipoproteins, and the development of atherosclerosis. Its role in the vascular complications of patients with chronic renal disease is unclear. We review methodologic issues involved in measuring Lp(a), particularly as they relate to studies of patients with chronic renal disease. The accurate measurement of Lp(a) is difficult because all the commercially available assays are sensitive to apolipoprotein(a) isoform size, Lp(a) behaves like an acute phase reactant, and levels vary markedly among ethnic groups. The results of 12 studies that included data on median Lp(a) levels in controls and patients receiving renal replacement therapy were analyzed. Although there was variation among studies, most found elevated levels of Lp(a) in patients receiving hemodialysis (range of medians, 9.0 to 38.4 mg/dL) compared with controls (range of medians, 4.7 to 19.7 mg/dL). With the exception of one study, Lp(a) levels also were elevated in patients receiving continuous ambulatory peritoneal dialysis compared with controls and patients receiving hemodialysis. In one study, an elevated Lp(a) level in patients receiving hemodialysis correlated with subsequent development of vascular events. A separate study associated the occurrence of vascular access occlusion with Lp(a) level. Following renal transplantation, Lp(a) levels decreased in all four studies, which included data before and after transplantation. Although variability in results were seen, Lp(a) levels appear to be elevated in patients receiving renal replacement therapy. Renal transplantation at least partially reverses this effect. The variability in results is probably related to methodologic difficulties in measuring Lp(a) and failure to segregate ethnic groups in study design and analysis.(ABSTRACT TRUNCATED AT 250 WORDS)

Cyclosporin A has divergent effects on plasma LDL cholesterol (LDL-C) and lipoprotein(a) [Lp(a)] levels in renal transplant recipients. Evidence for renal involvement in the maintenance of LDL-C and the elevation of Lp(a) concentrations in hemodialysis patients

Cardiovascular disease is the major cause of mortality in renal transplant recipients. Plasma levels of low-density lipoprotein cholesterol (LDL-C) are often elevated following renal transplantation, and the immunosuppressant cyclosporin A has been implicated as a predisposing factor for posttransplantation hyperlipidemia. Lipoprotein(a) [Lp(a)] is an LDL-like lipoprotein particle; elevated levels of Lp(a) provide an independent and significant risk factor for cardiovascular disease. Plasma concentrations of Lp(a) vary greatly among individuals, and the mechanisms that govern changes in their levels in transplant patients are unknown. The effect(s) of cyclosporin A on Lp(a) was studied in two groups of renal transplantation patients. In group I plasma lipoproteins including Lp(a) were measured before and after successful renal transplantation; this group received both prednisone and cyclosporin A for immunosuppression. Group II patients were studied after renal transplantation and received prednisone alone for immunosuppression. Following surgery, group I patients demonstrated increased plasma concentrations of LDL-C (mean +/- SEM range, 111 +/- 6 to 142 +/- 17 mg/dL; P < .005). In contrast, plasma Lp(a) levels for this group were markedly decreased after renal transplantation (median, 34.3 to 19.7 mg/dL). Patients not treated with cyclosporin A (group II) exhibited mean LDL-C and median Lp(a) levels (118 +/- 42 and 33.1 mg/dL, respectively) that were remarkably similar to those observed before renal transplantation (group I). These data confirm that hyperlipidemia following renal transplantation is associated with cyclosporin A therapy and show that this drug has opposing effects on plasma Lp(a) and LDL-C accumulations.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure and possible biological roles of Lp(a)

Lipoprotein(a) [Lp(a)] is a plasma macromolecular complex that is assembled from low-density lipoproteins (LDL) and a large hydrophilic glycoprotein, named apolipoprotein(a) [apo(a)], linked by a disulfide bond to apolipoprotein B-100. Apo(a) is formed by different structural domains one of which is present in multiple copies, the number of which is determined by variation in the hypervariable apo(a) gene. Sequence homology of apo(a) with plasminogen may explain the competition of Lp(a) for some physiological functions of plasminogen in the coagulation and fibrinolytic cascade in vitro. There is evidence that high plasma levels of Lp(a) may have atherogenic and/or thrombogenic potential. More work will have to be done to understand the exact role of Lp(a) in atherogenesis, to evaluate the potential synergy between Lp(a) and LDL in promoting coronary artery disease, and to assess the therapeutic benefits of a reduction of Lp(a) levels.

Effects of erythropoietin therapy on the lipid profile in end-stage renal failure

To evaluate the effects of erythropoietin (EPO) therapy on the lipid profile in end-stage renal failure, we undertook a prospective study in patients on both hemodialysis (HD) and continuous ambulatory peritoneal dialysis (CAPD). One hundred and twelve patients (81 HD, 31 CAPD) were enrolled into the study. Lipid parameters [that is, total cholesterol and the LDL and HDL subfractions, triglycerides, lipoprotein (a), apoproteins A and B], full blood count, iron studies, B12, folate, blood urea, aluminium and serum parathyroid hormone were measured prior to commencement of EPO therapy. Ninety-five patients were reassessed 5.2 +/- 0.3 (mean +/- SEM) months later and 53 patients underwent a further assessment 13.1 +/- 0.6 months after the commencement of EPO, giving an overall follow-up of 10.0 +/- 0.6 months in 95 patients. As expected, EPO treatment was associated with an increase in hemoglobin (7.7 +/- 0.1 vs. 9.9 +/- 0.2 g/dl; P < 0.001) and a decrease in ferritin (687 +/- 99 vs. 399 +/- 69 micrograms/liter; P < 0.01). A significant fall in total cholesterol occurred (5.8 +/- 0.1 vs. 5.4 +/- 0.2 mmol/liter; P < 0.05) in association with a fall in apoprotein B (1.15 +/- 0.04 vs. 1.04 +/- 0.06; P < 0.05) and serum triglycerides (2.26 +/- 0.14 vs. 1.99 +/- 0.21; P < 0.05) during the course of the study. Other lipid parameters did not change, although there was a trend towards improvement.(ABSTRACT TRUNCATED AT 250 WORDS)

Lipoprotein(a) and treatment of chronic renal disease

OBJECTIVES

To compare lipoprotein(a) [Lp(a)] and albumin concentrations in patients with chronic renal disease receiving different forms of treatment and to determine, if any, the relationship between these variables.

DESIGN

A prospective cross-sectional, case-controlled study.

SETTING

A tertiary referral nephrology and dialysis unit.

SUBJECTS

Forty-four consecutive non-diabetic patients with chronic renal failure treated by renal transplantation (n = 18), haemodialysis (n = 18), continuous ambulatory peritoneal dialysis (CAPD; n = 8), and 30 healthy controls from subjects drawn from University personnel were studied.

INTERVENTIONS

Fasting morning venous blood was analysed for Lp(a), albumin, total cholesterol and glucose concentrations.

MAIN OUTCOME MEASURES

Comparison of plasma levels of these variables between the sub-groups.

RESULTS

Concentrations (median; 95% CI) of Lp(a) were significantly (P < 0.05) higher (38.4 mg dl-1; range 15.4-72.0) and of albumin lower (31.6 g l-1; range 28-35.2) in the CAPD group compared with both control subjects and other groups of chronic renal disease patients.

CONCLUSIONS

The elevated Lp(a) concentrations seen only in association with reduced albumin concentrations in CAPD patients suggest a regulatory role for albumin with albumin losses stimulating production of Lp(a).

Lipoprotein(a) in nephrotic syndrome

Lipoprotein(a) [LP(a)] is an independent risk factor for cardiovascular disease, and it has also been speculated that it promotes thrombosis. Recent studies have shown that patients with gross proteinuria have greatly increased plasma levels of Lp(a), but the genesis is obscure. In the present study, plasma Lp(a) levels were measured in 31 patients with nephrotic syndrome (NS), 24 patients with IgA nephropathy and 43 healthy control subjects. Lp(a) levels were significantly elevated in NS (median 49.0 mg/dl), in contrast to the control subjects and patients with IgA nephropathy (median 7.0 and 9.7 mg/dl, respectively). Plasma Lp(a) levels fell markedly in 10 of 10 NS patients after remission. In NS, Lp(a) levels correlated directly with serum cholesterol levels (P < 0.05) and indirectly with plasma orosomucoid levels (P < 0.05), but not with serum albumin, triglycerides, HDL cholesterol, urinary protein excretion or GFR. In addition, Lp(a) tended to be higher in NS patients with edema (median 54.3 mg/dl) than in patients without edema (19.0 mg/dl; P = 0.06). Nine NS patients were further evaluated with plasma ANP levels and urinary sodium excretion. Plasma Lp(a) correlated directly with ANP (P < 0.01) and indirectly with urinary sodium excretion (P < 0.05). Excellent correlations were found between Lp(a) and VLDL cholesterol and VLDL triglycerides, respectively, suggesting a close link between Lp(a) and triglyceride-rich lipoproteins in nephrosis.

Prealbumin and lipoprotein(a) in hemodialysis: relationships with patient and vascular access survival

The high morbidity and mortality of hemodialysis patients has led to a search for early markers of risk. Because cardiovascular and nutritional risk are prevalent in this population, we examined the prognostic value of the serum levels of two markers of risk in the general population: (1) lipoprotein(a) [Lp(a)], a low-density lipoprotein-like particle linked to myocardial infarction and coronary bypass stenosis, and (2) prealbumin, a marker of visceral protein status, with a shorter half-life than that of serum albumin. Baseline demographics, clinical information, dialysis prescription, and serum biochemistry measurements of 125 hemodialysis patients followed for up to 14 months were recorded on enrollment. Vascular access events and deaths were recorded prospectively. The hypotheses tested were that increased serum Lp(a) levels would predict cardiovascular mortality and vascular access stenosis and thrombosis, and that reduced serum prealbumin levels would predict mortality risk independently of established risk predictors. Cross-sectional analysis of serum Lp(a) demonstrated a skewed distribution with a median value of 38.3 mg/dL (upper tertile, > or = 57 mg/dL). Lipoprotein(a) was significantly higher in black patients (P < 0.001) and was significantly correlated (P < 0.005) with total cholesterol and apoprotein B (apoB), but not with a history of prior coronary disease. Serum prealbumin was strongly correlated with serum albumin (r = 0.49, P < 0.001). However, prealbumin correlated (P < 0.001) more strongly with other serum nutrition markers (total cholesterol, apoB, creatinine, urea) than did serum albumin. Fourteen-month cumulative survival was 80%. Age, diabetes, and serum levels of albumin, prealbumin, creatinine, total cholesterol and apoB, but not Lp(a), were correlated with survival in univariate analysis. Using the Cox proportional hazards model, independent predictors of mortality risk were prealbumin less than 15 mg/dL versus higher values (relative risk [RR] = 4.48, P < 0.01), apoB (RR = 0.97 per 1 mg/dL increase, P < 0.02), creatinine less than 10 mg/dL versus higher values (RR = 3.51, P = 0.04), and age (RR = 1.04 per year, P = 0.10). Thirty-eight patients experienced at least one vascular access thrombosis (n = 33) or stenosis (n = 5) during the study. Patients with Lp(a) > or = 57 mg/dL had decreased vascular access event-free survival compared with patients with Lp(a) less than 57 mg/dL (56% v 73%, P < 0.06). This trend was increased in magnitude and statistically significant for white and Hispanic patients (31% v 79%, P < 0.01).(ABSTRACT TRUNCATED AT 400 WORDS)

Lipoprotein metabolism and renal failure

Lipoprotein metabolism is altered in the majority of patients with renal insufficiency and renal-failure, but may not necessarily lead to hyperlipidemia. The dyslipoproteinemia of renal disease has characteristic abnormalities of the apolipoprotein (apo) profile and lipoprotein composition. It develops during the asymptomatic stages of renal insufficiency and becomes more pronounced as renal failure advances. The qualitative characteristics of renal dyslipoproteinemia are not modified substantially by dialysis treatment. Patients with chronic renal disease may therefore be exposed to dyslipoproteinemia for long periods of time. The characteristic plasma lipid abnormality is a moderate hypertriglyceridemia. The alterations of lipoprotein metabolism affect both the apoB-containing very low-density and intermediate-density, and low-density lipoproteins and the apoA-containing high-density lipoproteins. The main underlying abnormality of lipoprotein transport is a decreased catabolism of the apoB-containing lipoproteins caused by decreased activity of lipolytic enzymes and altered lipoprotein composition. There is an increase of intact or partially metabolized, triglyceride-rich, apoB-containing lipoproteins with a disproportionate elevation of apoC-III and, to a lesser extent, apoE, resulting in a marked increase of the intermediate-density lipoproteins and an enrichment of triglycerides, apoC-III, and apoE in the low-density lipoproteins. In high-density lipoproteins there are decreases in the concentrations of cholesterol, apolipoproteins A-I and A-II, and the high-density lipoprotein-2 to high-density lipoprotein-3 ratio. These abnormalities result in a characteristic decrease of the apoA-I to apoC-III ratio and anti-atherogenic index apoA-I/apoB. The pathophysiologic links between the renal insufficiency and the abnormalities of lipoprotein transport are still poorly defined. Changes in the action of insulin on lipolytic enzymes, possibly mediated via increased levels of parathyroid hormone, have been suggested to play a contributory role. The clinical consequences of a defective lipoprotein transport may be related to the atherogenic character of lipoprotein abnormalities. Renal dyslipoproteinemia may contribute to the development of atherosclerotic vascular disease and progression of glomerular and tubular lesions with subsequent deterioration of renal function. Dietary and/or pharmacologic intervention may ameliorate the uremic dyslipoproteinemia, but the long-term clinical effects of such treatment have yet to be established.