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Query: UMLS:C0020473 (
hyperlipidemia
)
15,891
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We determined the most effective dosage of pentaerythritol tetranicotinate (niceritrol) to reduce plasma lipoprotein(a) [
Lp(a)
] levels in 44 Japanese patients (16 men and 28 women; mean age, 59.2 +/- 10.8 years) with
hyperlipidemia
types IIa, IIb, and IV. Patients received oral niceritrol at a dosage of 750 mg (3 tablets)/d for 8 weeks, followed by 1,500 mg (6 tablets)/d for 8 weeks. Administration of niceritrol 750 mg/d for 8 weeks decreased total and low-density lipoprotein (LDL) cholesterol in patients with type IIa
hyperlipidemia
and decreased triglycerides in patients with type IV
hyperlipidemia
, but did not affect
Lp(a)
. However, niceritrol 1,500 mg/d for 8 weeks decreased
Lp(a)
in patients with initial
Lp(a)
levels greater than 30 mg/dL in addition to decreasing total and LDL cholesterol and triglycerides. These results suggest that the effective dosage of niceritrol to reduce the serum
Lp(a)
concentration in Japanese hyperlipidemic patients with a high
Lp(a)
level (> or = 30 mg/dL) is greater than 1,500 mg/d.
...
PMID:Pentaerythritol tetranicotinate (niceritrol) decreases plasma lipoprotein(a) levels. 910 34
Hyperlipidemia
and elevated lipoprotein (a) (Lp[a]) levels have been linked to the development and progression of premature atherosclerosis. Our study concerned 2 white male patients (aged 36 and 42 years) with heterozygous familial hypercholesterolemia and extremely elevated
Lp(a)
concentrations that were resistant to diet regimens and lipid-lowering drugs. The patients were treated with low-density lipoprotein (LDL) apheresis for 59 months (Liposorber system, Kaneka, Japan) and 19 months (immunoadsorption system, special
Lp(a)
columns; Lipopak; Pocard, Russia), respectively. The concentration of
Lp(a)
decreased on average by 50%, total cholesterol by 27%, LDL cholesterol by 41%, triglycerides by 43%, and fibrinogen by 16%. High-density lipoprotein (HDL) cholesterol increased by approximately 4%. Before treatment with LDL apheresis, each patient had suffered 3 myocardial infarctions, and had had 4 and 6 coronary angiographies with 2 and 4 percutaneous transluminal angioplasties (PTCAs), respectively. Since treatment with LDL apheresis, no myocardial infarctions or cardiac complaints were observed. In the course of treatment, both patients reported an increased performance. Available data suggest that LDL apheresis may be effective in the treatment of patients, the only risk factor for premature atherosclerosis being extremely elevated
Lp(a)
concentrations.
...
PMID:Low-density lipoprotein apheresis in the treatment of two patients with coronary heart disease and extremely elevated lipoprotein (a) levels. 913 21
A 34-year-old male with a history of angina pectoris suddenly developed weakness in the right upper and lower limbs, and consulted our hospital. Computed tomography (CT) and magnetic resonance imaging (MRI) suggested cerebral infarction. Cerebral angiography revealed stenosis at the M1 portion of the left middle cerebral artery. Hypertension, diabetes, tobacco or
hyperlipidemia
were not considered as risk factors for cerebral infarction. The lipoprotein (a) [
Lp(a)
] level was high. In the present case, medication with a nicotinic acid agent, niceritrol, for hyperlipoproteinemia and low density lipoprotein (LDL) apheresis were performed. Concerning family history, the patient's mother and younger sister had hyperlipoproteinemia. Recent studies have reported that increased
Lp(a)
levels are an independent risk factor even in cerebral infarction and coronary artery disease. Measurement of
Lp(a)
levels and treatment for increased Lp (a) levels may be important.
...
PMID:[Juvenile cerebral infarction with familial hyperlipoproteinemia (a)--case report]. 916 61
Plasma levels of lipoprotein(a) [
Lp(a)
], tissue plasminogen activator (tPA) and plasminogen activator inhibitor type 1 (PAI-1) were assessed in addition to anthropometry and levels of glucose, total cholesterol, triglycerides, high-density lipoprotein (HDL), low-density lipoprotein (LDL) and apo A1 and B in 73 patients (36 men and 37 women) with primary
hyperlipidaemia
(group NDHL) in Kuwait.
Lp(a)
levels (212 mg L-1, 8-600 mg L-1, median and range) were similar to those obtained in a matched group of 32 non-insulin-dependent diabetes mellitus (NIDDM) patients with
hyperlipidaemia
(218 mg L-1, 50-610 mg L-1) and slightly higher, although not significantly so (P = 0.06), than levels seen in 68 healthy normolipidaemic control subjects (182 mg L-1, 70-488 mg L-1). tPA levels (8.4 ng mL-1, 3.8-18.4 ng mL-1, median and range) in group NDHL were lower than in the diabetic group (11.4 ng mL-1, 5.2-14.2 ng mL-1) but higher than in the healthy control subjects (7.4 ng mL-1, 2.8-12.6 ng mL-1). PAI-1 levels in group NDHL (40.4 ng mL-1, 8.6-55 ng mL-1, median and range) were higher than in the control subjects (32.5 ng mL-1, 14.6-46.4 ng mL-1) but lower than in diabetic patients (43.8 ng mL-1, 15.6-55 ng mL-1).
Hyperlipidaemia
phenotype (hypercholesterolaemia or hypertriglyceridaemia) did not influence tPA and PAI-1 levels, but
Lp(a)
levels were significantly lower with hypertriglyceridaemia. Gender, cigarette smoking and racial origin (Kuwaitis, other Arabs or South Asians) did not affect
Lp(a)
, tPA and PAI-1 levels, but tPA levels were higher in postmenopausal subjects. Low-density lipoprotein (LDL) levels (whether in total cholesterol or as apo B) correlated significantly (P < 0.05) with
Lp(a)
levels. tPA levels were correlated with age and the plasma levels of glucose and uric acid (P < 0.05); this correlation with glucose may explain the high levels associated with diabetes, whereas the age association might account not only for the differences observed between group NDHL and the younger control group but also for the higher levels in the postmenopausal women. PAI-1 levels correlated with tPA and triglyceride (TG) levels in the groups of subjects (normo- and hyperlipidaemic). In the normolipidaemic control group, the significant associations of tPA and PAI-1 were with body mass, expressed as the body mass index or the waist-hip ratio. These results suggest that different factors influence the plasma levels of the prothrombotic factors
Lp(a)
, tPA and PAI-1 in healthy control subjects and in patients with
hyperlipidaemia
. In the latter,
hyperlipidaemia
phenotype, age, glycaemic status and uric acid levels are important determinants of the levels of these prothrombotic variables, whereas in the healthy, young control population, body mass was the single important association with tPA and PAI-1.
...
PMID:Lipoprotein(a), tissue plasminogen activator and plasminogen activator inhibitor 1 levels in hyperlipidaemic patients in Kuwait. 917 44
Lp(a)
levels are genetically determined and remain stable without major changes throughout lives. However, when an individual's
Lp(a)
levels are observed over a one-year period, they show spontaneous variation. The rate of intraindividual variation in
Lp(a)
was observed in 16 patients with hypertension,
hyperlipidemia
and/or glucose intolerance in a chronic stable state who regularly visited the hospital clinic once a month, at least 10 times during the year, and in whom a total of 42 blood and clinical chemistry tests including serum lipids,
Lp(a)
and apoproteins were performed. The rate of annual intraindividual variation of
Lp(a)
averaged out as 16.6%. The rate was 18.8% for isoform S4 (n = 10), 18.6% for S3 (n = 3), and although small in number of subjects, other isoforms showed minor variation rates. There was a significant negative correlation between the rate of variation (y%) and LP(a) level (xmg/dl) r = -0.605, p < 0.05, y = -0.461 x +29.8). Therefore, when
Lp(a)
was high, the rate of variation (SD%) was low. This was consistent with the finding that the rates of variation were low for isoforms S2, S3S4 and F, whose molecular weights were low, accompanied by high
Lp(a)
levels. On the other hand, when the relationship between
Lp(a)
level and the amount of variation (SD mg/dl) was examined, there was no correlation between the two, since the amounts of variation were almost constant at a level of 3.8 mg/dl, regardless of
Lp(a)
level. The annual variation of
Lp(a)
level was found to be related to three groups of factors based on comparison of the variations among WHO phenotypes of hyperlipidemias, univariate correlation analysis with the clinical parameters tested, and multivariate analysis: the first group of factors was related to structure and metabolism of very low-density lipoprotein such as triglycerides, phospholipids, apo C-II, C-III, E, A-II and uric acid; the second group was related to thrombosis centering on platelets; and the third group involved those in the acute phase reactions represented by 1 hr and 2 hr erythrocyte sedimentation rates.
...
PMID:Intraindividual variations in lipoprotein (a) levels and factors related to these changes. 922 16
The plasma levels of blood coagulation and fibrinolytic factors and the serum levels of lipids were measured in 62 subjects (22 normolipidemia and 40
hyperlipidemia
) to investigate whether
hyperlipidemia
may affect the hemostatic system. Prothrombin, factors VII, IX and X were elevated in hyperlipidemic patients. The positive correlations were found between factors VII, IX and X, and triglyceride. The significant correlations were also found between VII and IX, and total cholesterol. Plasma levels of thrombin-antithrombin III complex (TAT), which reflects activation of coagulation system, were slightly but significantly higher in type IIb
hyperlipidemia
, although they were within normal range. Plasma levels of active plasminogen activator inhibitor (PAI) in type IIb and IV were significantly higher than in normals. A significant correlation was found between active PAI and triglyceride (r = 0.76, p < 0.0001). After the administration of fat emulsion to 18 patients with various diseases, which induced artificial hypertriglyceridemia, PAI levels as well as triglyceride levels significantly increased. These results suggest that hypertriglyceridemia may increase the synthesis and/or release of PAI, inducing a hypofibrinolytic condition, which could lead to thrombosis. It has been established that lipoprotein (a) [
Lp(a)
], which has a molecular structure homology to plasminogen, impairs fibrinolysis by its competitive inhibition of adsorption of plasminogen to vascular endothelial surface and/or fibrin. We assayed plasma levels of
Lp(a)
and parameters of blood coagulation and fibrinolysis in 168 patients with type II diabetes mellitus and 48 normal controls. In the diabetics, the levels of
Lp(a)
as well as levels of tissue-type plasminogen activator (t-PA) antigen and PAI activity were significantly higher than normal controls. Furthermore, it was shown that
Lp(a)
had a weakly negative correlation with t-PA antigen in the diabetics. These results suggest that an elevated level of
Lp(a)
may decrease release of t-PA, although the underlying mechanism remains unsolved.
...
PMID:Hyperlipidemia and hemostatic system. 922 30
Accurate diagnosis of
hyperlipidaemia
is necessary for the effective treatment. Measurements in serum or plasma obtained after an overnight fast of over 16 hours should include total cholesterol, triglycerides and HDL-cholesterol concentrations; LDL-cholesterol can be calculated using the Friedelwald's formula. Lipoprotein electrophoresis is used to define different phenotypes of hyperlipoproteinaemia according to the Fredrickson's classification. More sophisticated tests include apolipoprotein analysis, determination of
Lp(a)
concentration, activities of enzymes involved in lipid metabolism and genetic studies. Secondary causes of
hyperlipidaemia
, including liver, kidney, endocrine disorders should be excluded using the laboratory methods.
...
PMID:[Laboratory diagnosis of lipid imbalance]. 924 12
Disorders of the lipoprotein metabolism are an important cause of premature coronary artery disease and myocardial infarction. Of the genetic lipoprotein disorders, elevation of apoprotein (apo) B containing lipoproteins is the most frequent one in the western population. We aimed to define the prevalence of genetic lipoprotein disorders and other risk factors in a population from a country with a low average cholesterol levels. We examined 48 consecutive patients with premature myocardial infarction below age 55, their 78 siblings and age and body mass index matched controls for familial lipoprotein disorders. The patients with premature myocardial infarction had higher triglyceride, low-density lipoprotein, apo B, lipoprotein (Lp) (a) and lower apo A1 levels then controls (p < 0.05). Of the nonlipid risk factors, 67% smoked, 8% had diabetes mellitus, 17% had hypertension and 58% a family history of premature coronary artery disease. Fifty percent of these patients with premature myocardial infarction had a familial lipoprotein disorder. Familial excess of
Lp(a)
was the most frequent lipoprotein abnormality present in 16% of the patients followed by familial combined
hyperlipidemia
. We conclude that,
Lp(a)
increase was the most frequent familial lipoprotein abnormality in this population. The frequency of familial lipoprotein disorders in this population emphasises the need to screen siblings of patients with premature myocardial infarction.
...
PMID:Elevated Lp(a) is the most frequent familial lipoprotein disorder leading to premature myocardial infarction in a country with low cholesterol levels. 926 42
Although the genetic background is the most important determinant of lipoprotein (a) (
Lp(a)
) concentration other factors, such as coexistent dyslipidaemia, could modify its levels. We undertook the present study to examine the serum
Lp(a)
concentration in various dyslipidaemias and to reveal any correlation of serum
Lp(a)
concentration with the other lipid parameters in a large group of dyslipidaemic Greek patients. A total of 242 patients followed as outpatients in our lipid clinic were studied. The patients were stratified into four main groups. Patients with cholesterol levels greater than 5.17 mmol/L but normal triglycerides were regarded as hypercholesterolaemic (n=85), patients with triglycerides greater than 2.25 mmol/L but normal cholesterol levels as hypertriglyceridaemic (n=51), patients with both increased cholesterol and triglyceride levels as having mixed
hyperlipidaemia
(n=62), and finally patients with decreased (<0.90 mmol/L) high-density lipoprotein (HDL) cholesterol but normal cholesterol and triglyceride levels as having primary hypoalphalipoproteinaemia (n=44). Hypercholesterolaemic patients exhibited the highest serum
Lp(a)
levels, while hypertriglyceridaemic patients exhibited the lowest. Patients with mixed
hyperlipidaemia
had intermediate serum
Lp(a)
concentration, which was significantly higher than that of hypertriglyceridaemic patients but significantly lower than that of hypercholesterolaemic patients. Interestingly, patients with low serum HDL-cholesterol levels presented with low serum
Lp(a)
concentration similar to that of hypertriglyceridaemic patients. In hypercholesterolaemic patients no correlation was found between serum total and low-density lipoprotein (LDL) cholesterol nor apolipoprotein B (apoB) levels and
Lp(a)
concentration. On the contrary, in hypertriglyceridaemic patients an inverse correlation was observed between serum triglycerides and
Lp(a)
concentration. After dividing the hypertriglyceridaemic patients into one group with elevated (>1.3 g/L) serum apoB levels (n=32) and another group with normal apoB levels (n=19), we found that the median serum
Lp(a)
concentration was three times higher in hyperapoB patients compared to patients with normal apoB levels. We conclude that serum
Lp(a)
levels are different in various types of primary
hyperlipidaemia
and are modulated according to the type of lipid elevation.
...
PMID:Lipoprotein (a) concentrations in patients with various dyslipidaemias. 937 87
The aim of this study was to estimate the coexistence of risk factors for coronary heart disease (CHD) in hyperlipidemic patients. Studies were performed in 1002 (601 women, 401 men) subjects who referred to our outpatient clinic among 12 months. Hypercholesterolemia was the predominant lipid disorder found in 66% of patients, mixed
hyperlipidemia
in 31.8%, and hypertriglyceridemia only in 2.2%. Overweight and obesity remain a major health burden among our patients: BMI > or = 25 was observed in 66%. Hypertension was recognized in 37.5% of subjects, and diabetes mellitus in 11.2%, 17% were long-term smokers. Familial aggregation of
hyperlipidemia
was observed in 15.7% of subjects, and more than 44% had a positive family history of cardiovascular disease. Low HDL cholesterol levels (< 35 mg/dl) were seen frequently in men (24.7%) and rare in women (7%).
Lp(a)
excess (> or = 30 mg/dl) was observed in 12% of patients. Myocardial infarction (MI) had already 11.7% subjects (7% women, 18.7% men). In these patients CHD risk factors were observed more frequently. The higher apo B and
Lp(a)
levels and lower HDL cholesterol levels were recognized in the patients who suffered from MI. More than 83% of our hyperlipidemic patients had coexistence CHD risk factors. The multiple coexisting risk factors cause the high risk for CHD and they require intensive correction.
...
PMID:[Risk factors for coronary heart disease in 1002 patients with hyperlipidemia]. 941 22
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