Hypercholesterolemia (literally: high blood cholesterol) is the presence of high levels of cholesterol in the blood. It is not a disease but a metabolic derangement that can be secondary to many diseases and can contribute to many forms of disease, most notably cardiovascular disease. It is closely related to the terms “hyperlipidemia” (elevated levels of lipids) and “hyperlipoproteinemia” (elevated levels of lipoproteins). Familial hypercholesterolemia is a rare genetic disorder that can occur in families, wherein those affected cannot properly metabolise cholesterol.
Signs and symptoms

Elevated cholesterol does not lead to specific symptoms unless it has been longstanding. Some types of hypercholesterolemia lead to specific physical findings: xanthoma (thickening of tendons due to accumulation of cholesterol), xanthelasma palpabrum (yellowish patches around the eyelids) and arcus senilis (white discoloration of the peripheral cornea).

Longstanding elevated hypercholesterolemia leads to accelerated atherosclerosis; this can express itself in a number of cardiovascular diseases:[2]

* Angina pectoris (chest pain on exertion)
* Myocardial infarction (heart attack)
* Transient ischemic attacks (TIAs, “mini-strokes”)
* Stroke
* Peripheral artery disease (PAD)

Diagnosis

When measuring cholesterol, it is important to measure its subfractions before drawing a conclusion on the cause of the problem. The subfractions are LDL, HDL and VLDL. In the past, LDL and VLDL levels were rarely measured directly due to cost concerns. VLDL levels are reflected in the levels of triglycerides (generally about 45% of triglycerides is composed of VLDL). LDL was usually estimated as a calculated value from the other fractions (total cholesterol minus HDL and VLDL); this method is called the Friedewald calculation; specifically: LDL ~= Total Cholesterol - HDL - (0.2 x Triglycerides).

Less expensive (and less accurate) laboratory methods and the Friedewald calculation have long been utilized because of the complexity, labor and expense of the electrophoretic methods developed in the 1970s to identify the different lipoprotein particles which transport cholesterol in the blood. In 1980, the original methods, developed by research work in the mid-1970s costed about $5,000, in US 1980 dollars, per blood sample/person.

With time, more advanced laboratory analyses have been developed which do measure LDL and VLDL particle sizes and levels, and at far lower cost. These have partly been developed and become more popular as a result of the increasing clinical trial evidence that intentionally changing cholesterol transport patterns, including to certain abnormal values compared to most adults, often has a dramatic effect on reducing, even partially reversing, the atherosclerotic process. With ongoing research and advances in laboratory methods, the prices for more sophisticated analyses have markedly decreased, to less than $100, US 2004, by some labs, and with simultaneous increases in the accuracy of measurement for some of the methods.

Screening

Screening for a disease refers to testing for a disease, such as hypercholesterolemia, in patients who have no signs or symptoms of the disease.

In patients without any other risk factors, moderate hypercholesterolemia is often not treated. According to Framingham Heart Study, people with an age greater than 50 years have no increased overall mortality with either high or low serum cholesterol levels. There is, however, a correlation between falling cholesterol levels over the first 14 years and mortality over the following 18 years (11% overall and 14% CVD death rate increase per 1 mg/dL per year drop in cholesterol levels). This, however, does not mean that a decrease in serum levels is dangerous, as there has not yet been a recorded heart attack in the study in a person with a total cholesterol below 150 mg/dL.

Treatment

Clinical Evidence has summarized treatment for both primary prevention and secondary prevention. Two factors to consider when choosing therapy are the patient’s risk of coronary disease and their lipoprotein pattern.

Risk of coronary disease. To calculate the benefit of treatment, there are two online calculators that can estimate baseline risk. Combining the baseline risk with the relative risk reduction of a treatment can lead to the absolute risk reduction of number needed to treat. For example, one of the calculators projects that a patient had a 10% risk of coronary disease over ten years. As noted below, the relative risk reduction of a statin is 30%. Thus, after 4-7 years of treatment with a statin, a patient’s risk will drop to 7%. This equates to an absolute risk reduction of 3%, or a number needed to treat of 33. Thirty three such patients must be treated for 4-7 years for one to benefit.

Lipoprotein patterns. (See hyperlipoproteinemia for details) The treatment depends on the type of hypercholesterolemia. Clinical trials, starting in the 1970s, have repeatedly and increasingly found that normal cholesterol values do not necessarily reflect healthy cholesterol values. This has increasingly lead to the newer concept of dyslipidemia, despite normo-cholesterolemia. Thus there has been increasing recognition of the importance of “lipoprotein subclass analysis” as an important approach to better understand and change the connection between cholesterol transport and atherosclerosis progression. Fredrickson Types IIa and IIb can be treated with diet, statins (most prominently rosuvastatin, atorvastatin, simvastatin, or pravastatin), cholesterol absorption inhibitors (ezetimibe), fibrates (gemfibrozil, bezafibrate, fenofibrate or ciprofibrate), vitamin B3 (niacin), bile acid sequestrants (colestipol, cholestyramine), LDL apheresis and in hereditary severe cases liver transplantation.

Multiple clinical trials, each, by design, examining only one of multiple relevant issues, have increasingly examined the connection between these issues and atherosclerosis clinical consequences. Some of the better recent randomized human outcome trials include ASTEROID, ASCOT-LLA, REVERSAL, PROVE-IT, CARDS, Heart Protection Study, HOPE, PROGRESS, COPERNICUS, and especially a newer research approach utilizing a synthetically produced and IV administered human HDL, the Apo A-I Milano Trial

Medications

Many primary physicians and heart specialists will initially prescribe medication in combination with diet and exercise. According to various resources, statins are the most commonly used and effective forms of medication for the treatment of high cholesterol. The U.S. Preventive Services Task Force (USPSTF) estimated that after 5 to 7 years of treatment, the relative risk reduction by statins on coronary heart disease events is decreased by approximately 30%. More recently, a meta-analysis reported an almost identical relative risk reduction of 29.2% in low risk patients treated for 4.3 years. A relative risk reduction of 19% in coronary mortality was found in a meta-analysis of patients at all levels of risk.