Cholesterol Explained

Cholesterol is the principal sterol of all higher animals, distributed in body tissues, especially the brain and spinal cord, and in animal fats and oils.[1]

Cholesterol is biosynthesized by all animal cells and is an essential structural component of animal cell membranes. In vertebrates, hepatic cells typically produce the greatest amounts. In the brain, astrocytes produce cholesterol and transport it to neurons.[2] It is absent among prokaryotes (bacteria and archaea), although there are some exceptions, such as Mycoplasma, which require cholesterol for growth.[3] Cholesterol also serves as a precursor for the biosynthesis of steroid hormones, bile acid[4] and vitamin D.

Elevated levels of cholesterol in the blood, especially when bound to low-density lipoprotein (LDL, often referred to as "bad cholesterol"), may increase the risk of cardiovascular disease.

François Poulletier de la Salle first identified cholesterol in solid form in gallstones in 1769. In 1815, chemist Michel Eugène Chevreul named the compound "cholesterine".[5] [6]

Etymology

The word cholesterol comes from Ancient Greek chole- 'bile' and stereos 'solid', followed by the chemical suffix -ol for an alcohol.

Physiology

Cholesterol is essential for all animal life. While most cells are capable of synthesizing it, the majority of cholesterol is ingested or synthesized by hepatocytes and transported in the blood to peripheral cells. The levels of cholesterol in peripheral tissues is dictated by a balance of uptake and export.[7] Under normal conditions, brain cholesterol is separate from peripheral cholesterol, i.e., the dietary and hepatic cholesterol do not cross the blood brain barrier. Rather, astrocytes produce and distribute cholesterol in the brain.[8]

De novo synthesis, both in astrocytes and hepatocytes, occurs by a complex 37-step process. This begins with the mevalonate or HMG-CoA reductase pathway, the target of statin drugs, which encompasses the first 18 steps. This is followed by 19 additional steps to convert the resulting lanosterol into cholesterol.[9] A human male weighing 68 kg (150 lb) normally synthesizes about 1 gram (1,000 mg) of cholesterol per day, and his body contains about 35 g, mostly contained within the cell membranes.

Typical daily cholesterol dietary intake for a man in the United States is 307 mg.[10] Most ingested cholesterol is esterified, which causes it to be poorly absorbed by the gut. The body also compensates for absorption of ingested cholesterol by reducing its own cholesterol synthesis.[11] For these reasons, cholesterol in food, seven to ten hours after ingestion, has little, if any effect on concentrations of cholesterol in the blood. Surprisingly, in rats, blood cholesterol is inversely correlated with cholesterol consumption. The more cholesterol a rat eats the lower the blood cholesterol.[12] During the first seven hours after ingestion of cholesterol, as absorbed fats are being distributed around the body within extracellular water by the various lipoproteins (which transport all fats in the water outside cells), the concentrations increase.[13]

Plants make cholesterol in very small amounts.[14] In larger quantities they produce phytosterols, chemically similar substances which can compete with cholesterol for reabsorption in the intestinal tract, thus potentially reducing cholesterol reabsorption.[15] When intestinal lining cells absorb phytosterols, in place of cholesterol, they usually excrete the phytosterol molecules back into the GI tract, an important protective mechanism. The intake of naturally occurring phytosterols, which encompass plant sterols and stanols, ranges between ≈200–300 mg/day depending on eating habits.[16] Specially designed vegetarian experimental diets have been produced yielding upwards of 700 mg/day.[17]

Function

Membranes

Cholesterol is present in varying degrees in all animal cell membranes, but is absent in prokaryotes.[18] It is required to build and maintain membranes and modulates membrane fluidity over the range of physiological temperatures. The hydroxyl group of each cholesterol molecule interacts with water molecules surrounding the membrane, as do the polar heads of the membrane phospholipids and sphingolipids, while the bulky steroid and the hydrocarbon chain are embedded in the membrane, alongside the nonpolar fatty-acid chain of the other lipids. Through the interaction with the phospholipid fatty-acid chains, cholesterol increases membrane packing, which both alters membrane fluidity[19] and maintains membrane integrity so that animal cells do not need to build cell walls (like plants and most bacteria). The membrane remains stable and durable without being rigid, allowing animal cells to change shape and animals to move.

The structure of the tetracyclic ring of cholesterol contributes to the fluidity of the cell membrane, as the molecule is in a trans conformation making all but the side chain of cholesterol rigid and planar.[20] In this structural role, cholesterol also reduces the permeability of the plasma membrane to neutral solutes,[21] hydrogen ions, and sodium ions.[22]

Substrate presentation

Cholesterol regulates the biological process of substrate presentation and the enzymes that use substrate presentation as a mechanism of their activation. Phospholipase D2 (PLD2) is a well-defined example of an enzyme activated by substrate presentation.[23] The enzyme is palmitoylated causing the enzyme to traffic to cholesterol dependent lipid domains sometimes called "lipid rafts". The substrate of phospholipase D is phosphatidylcholine (PC) which is unsaturated and is of low abundance in lipid rafts. PC localizes to the disordered region of the cell along with the polyunsaturated lipid phosphatidylinositol 4,5-bisphosphate (PIP2). PLD2 has a PIP2 binding domain. When PIP2 concentration in the membrane increases, PLD2 leaves the cholesterol-dependent domains and binds to PIP2 where it then gains access to its substrate PC and commences catalysis based on substrate presentation.

Signaling

See main article: Cholesterol signaling.

Cholesterol is also implicated in cell signaling processes, assisting in the formation of lipid rafts in the plasma membrane, which brings receptor proteins in close proximity with high concentrations of second messenger molecules.[24] In multiple layers, cholesterol and phospholipids, both electrical insulators, can facilitate speed of transmission of electrical impulses along nerve tissue. For many neuron fibers, a myelin sheath, rich in cholesterol since it is derived from compacted layers of Schwann cell or oligodendrocyte membranes, provides insulation for more efficient conduction of impulses.[25] Demyelination (loss of myelin) is believed to be part of the basis for multiple sclerosis.

Cholesterol binds to and affects the gating of a number of ion channels such as the nicotinic acetylcholine receptor, GABAA receptor, and the inward-rectifier potassium channel.[26] Cholesterol also activates the estrogen-related receptor alpha (ERRα), and may be the endogenous ligand for the receptor.[27] [28] The constitutively active nature of the receptor may be explained by the fact that cholesterol is ubiquitous in the body. Inhibition of ERRα signaling by reduction of cholesterol production has been identified as a key mediator of the effects of statins and bisphosphonates on bone, muscle, and macrophages. On the basis of these findings, it has been suggested that the ERRα should be de-orphanized and classified as a receptor for cholesterol.

As a chemical precursor

Within cells, cholesterol is also a precursor molecule for several biochemical pathways. For example, it is the precursor molecule for the synthesis of vitamin D in the calcium metabolism and all steroid hormones, including the adrenal gland hormones cortisol and aldosterone, as well as the sex hormones progesterone, estrogens, and testosterone, and their derivatives.[29]

Epidermis

The stratum corneum is the outermost layer of the epidermis.[30] It is composed of terminally differentiated and enucleated corneocytes that reside within a lipid matrix, like "bricks and mortar."[31] Together with ceramides and free fatty acids, cholesterol forms the lipid mortar, a water-impermeable barrier that prevents evaporative water loss. As a rule of thumb, the epidermal lipid matrix is composed of an equimolar mixture of ceramides (≈50% by weight), cholesterol (≈25% by weight), and free fatty acids (≈15% by weight), with smaller quantities of other lipids also being present. Cholesterol sulfate reaches its highest concentration in the granular layer of the epidermis. Steroid sulfate sulfatase then decreases its concentration in the stratum corneum, the outermost layer of the epidermis.[32] The relative abundance of cholesterol sulfate in the epidermis varies across different body sites with the heel of the foot having the lowest concentration.

Metabolism

Cholesterol is recycled in the body. The liver excretes cholesterol into biliary fluids, which are then stored in the gallbladder, which then excretes them in a non-esterified form (via bile) into the digestive tract. Typically, about 50% of the excreted cholesterol is reabsorbed by the small intestine back into the bloodstream.

Biosynthesis and regulation

Biosynthesis

Almost all animal tissues synthesize cholesterol from acetyl-CoA. All animal cells (exceptions exist within the invertebrates) manufacture cholesterol, for both membrane structure and other uses, with relative production rates varying by cell type and organ function. About 80% of total daily cholesterol production occurs in the liver and the intestines;[33] other sites of higher synthesis rates include the brain, the adrenal glands, and the reproductive organs.

Synthesis within the body starts with the mevalonate pathway where two molecules of acetyl CoA condense to form acetoacetyl-CoA. This is followed by a second condensation between acetyl CoA and acetoacetyl-CoA to form 3-hydroxy-3-methylglutaryl CoA (HMG-CoA).[34]

This molecule is then reduced to mevalonate by the enzyme HMG-CoA reductase. Production of mevalonate is the rate-limiting and irreversible step in cholesterol synthesis and is the site of action for statins (a class of cholesterol-lowering drugs).

Mevalonate is finally converted to isopentenyl pyrophosphate (IPP) through two phosphorylation steps and one decarboxylation step that requires ATP.

Three molecules of isopentenyl pyrophosphate condense to form farnesyl pyrophosphate through the action of geranyl transferase.

Two molecules of farnesyl pyrophosphate then condense to form squalene by the action of squalene synthase in the endoplasmic reticulum.

Oxidosqualene cyclase then cyclizes squalene to form lanosterol.

Finally, lanosterol is converted to cholesterol via either of two pathways, the Bloch pathway, or the Kandutsch-Russell pathway.[35] [36] [37] [38] [39] The final 19 steps to cholesterol contain NADPH and oxygen to help oxidize methyl groups for removal of carbons, mutases to move alkene groups, and NADH to help reduce ketones.

Konrad Bloch and Feodor Lynen shared the Nobel Prize in Physiology or Medicine in 1964 for their discoveries concerning some of the mechanisms and methods of regulation of cholesterol and fatty acid metabolism.[40]

Regulation of cholesterol synthesis

Biosynthesis of cholesterol is directly regulated by the cholesterol levels present, though the homeostatic mechanisms involved are only partly understood. A higher intake of food leads to a net decrease in endogenous production, whereas a lower intake of food has the opposite effect. The main regulatory mechanism is the sensing of intracellular cholesterol in the endoplasmic reticulum by the protein SREBP (sterol regulatory element-binding protein 1 and 2).[41] In the presence of cholesterol, SREBP is bound to two other proteins: SCAP (SREBP cleavage-activating protein) and INSIG-1. When cholesterol levels fall, INSIG-1 dissociates from the SREBP-SCAP complex, which allows the complex to migrate to the Golgi apparatus. Here SREBP is cleaved by S1P and S2P (site-1 protease and site-2 protease), two enzymes that are activated by SCAP when cholesterol levels are low.

The cleaved SREBP then migrates to the nucleus and acts as a transcription factor to bind to the sterol regulatory element (SRE), which stimulates the transcription of many genes. Among these are the low-density lipoprotein (LDL) receptor and HMG-CoA reductase. The LDL receptor scavenges circulating LDL from the bloodstream, whereas HMG-CoA reductase leads to an increase in endogenous production of cholesterol.[42] A large part of this signaling pathway was clarified by Dr. Michael S. Brown and Dr. Joseph L. Goldstein in the 1970s. In 1985, they received the Nobel Prize in Physiology or Medicine for their work. Their subsequent work shows how the SREBP pathway regulates the expression of many genes that control lipid formation and metabolism and body fuel allocation.

Cholesterol synthesis can also be turned off when cholesterol levels are high. HMG-CoA reductase contains both a cytosolic domain (responsible for its catalytic function) and a membrane domain. The membrane domain senses signals for its degradation. Increasing concentrations of cholesterol (and other sterols) cause a change in this domain's oligomerization state, which makes it more susceptible to destruction by the proteasome. This enzyme's activity can also be reduced by phosphorylation by an AMP-activated protein kinase. Because this kinase is activated by AMP, which is produced when ATP is hydrolyzed, it follows that cholesterol synthesis is halted when ATP levels are low.[43]

Plasma transport and regulation of absorption

See also: Blood lipids.

As an isolated molecule, cholesterol is only minimally soluble in water, or hydrophilic. Because of this, it dissolves in blood at exceedingly small concentrations. To be transported effectively, cholesterol is instead packaged within lipoproteins, complex discoidal particles with exterior amphiphilic proteins and lipids, whose outward-facing surfaces are water-soluble and inward-facing surfaces are lipid-soluble. This allows it to travel through the blood via emulsification. Unbound cholesterol, being amphipathic, is transported in the monolayer surface of the lipoprotein particle along with phospholipids and proteins. Cholesterol esters bound to fatty acid, on the other hand, are transported within the fatty hydrophobic core of the lipoprotein, along with triglyceride.[44]

There are several types of lipoproteins in the blood. In order of increasing density, they are chylomicrons, very-low-density lipoprotein (VLDL), intermediate-density lipoprotein (IDL), low-density lipoprotein (LDL), and high-density lipoprotein (HDL). Lower protein/lipid ratios make for less dense lipoproteins. Cholesterol within different lipoproteins is identical, although some is carried as its native "free" alcohol form (the cholesterol-OH group facing the water surrounding the particles), while others as fatty acyl esters, known also as cholesterol esters, within the particles.[44]

Lipoprotein particles are organized by complex apolipoproteins, typically 80–100 different proteins per particle, which can be recognized and bound by specific receptors on cell membranes, directing their lipid payload into specific cells and tissues currently ingesting these fat transport particles. These surface receptors serve as unique molecular signatures, which then help determine fat distribution delivery throughout the body.[44]

Chylomicrons, the least dense cholesterol transport particles, contain apolipoprotein B-48, apolipoprotein C, and apolipoprotein E (the principal cholesterol carrier in the brain[45]) in their shells. Chylomicrons carry fats from the intestine to muscle and other tissues in need of fatty acids for energy or fat production. Unused cholesterol remains in more cholesterol-rich chylomicron remnants, and taken up from here to the bloodstream by the liver.[44]

VLDL particles are produced by the liver from triacylglycerol and cholesterol which was not used in the synthesis of bile acids. These particles contain apolipoprotein B100 and apolipoprotein E in their shells, and can be degraded by lipoprotein lipase on the artery wall to IDL. This arterial wall cleavage allows absorption of triacylglycerol and increases the concentration of circulating cholesterol. IDL particles are then consumed in two processes: half is metabolized by HTGL and taken up by the LDL receptor on the liver cell surfaces, while the other half continues to lose triacylglycerols in the bloodstream until they become cholesterol-laden LDL particles.[44]

LDL particles are the major blood cholesterol carriers. Each one contains approximately 1,500 molecules of cholesterol ester. LDL particle shells contain just one molecule of apolipoprotein B100, recognized by LDL receptors in peripheral tissues. Upon binding of apolipoprotein B100, many LDL receptors concentrate in clathrin-coated pits. Both LDL and its receptor form vesicles within a cell via endocytosis. These vesicles then fuse with a lysosome, where the lysosomal acid lipase enzyme hydrolyzes the cholesterol esters. The cholesterol can then be used for membrane biosynthesis or esterified and stored within the cell, so as to not interfere with the cell membranes.[44]

LDL receptors are used up during cholesterol absorption, and its synthesis is regulated by SREBP, the same protein that controls the synthesis of cholesterol de novo, according to its presence inside the cell. A cell with abundant cholesterol will have its LDL receptor synthesis blocked, to prevent new cholesterol in LDL particles from being taken up. Conversely, LDL receptor synthesis proceeds when a cell is deficient in cholesterol.[44]

When this process becomes unregulated, LDL particles without receptors begin to appear in the blood. These LDL particles are oxidized and taken up by macrophages, which become engorged and form foam cells. These foam cells often become trapped in the walls of blood vessels and contribute to atherosclerotic plaque formation. Differences in cholesterol homeostasis affect the development of early atherosclerosis (carotid intima-media thickness).[46] These plaques are the main causes of heart attacks, strokes, and other serious medical problems, leading to the association of so-called LDL cholesterol (actually a lipoprotein) with "bad" cholesterol.[43]

HDL particles are thought to transport cholesterol back to the liver, either for excretion or for other tissues that synthesize hormones, in a process known as reverse cholesterol transport (RCT).[47] Large numbers of HDL particles correlates with better health outcomes,[48] whereas low numbers of HDL particles is associated with atheromatous disease progression in the arteries.[49]

Metabolism, recycling and excretion

Cholesterol is susceptible to oxidation and easily forms oxygenated derivatives called oxysterols. Three different mechanisms can form these: autoxidation, secondary oxidation to lipid peroxidation, and cholesterol-metabolizing enzyme oxidation. A great interest in oxysterols arose when they were shown to exert inhibitory actions on cholesterol biosynthesis.[50] This finding became known as the "oxysterol hypothesis". Additional roles for oxysterols in human physiology include their participation in bile acid biosynthesis, function as transport forms of cholesterol, and regulation of gene transcription.[51]

In biochemical experiments radiolabelled forms of cholesterol, such as tritiated-cholesterol are used. These derivatives undergo degradation upon storage and it is essential to purify cholesterol prior to use. Cholesterol can be purified using small Sephadex LH-20 columns.[52]

Cholesterol is oxidized by the liver into a variety of bile acids.[53] These, in turn, are conjugated with glycine, taurine, glucuronic acid, or sulfate. A mixture of conjugated and nonconjugated bile acids, along with cholesterol itself, is excreted from the liver into the bile. Approximately 95% of the bile acids are reabsorbed from the intestines, and the remainder are lost in the feces.[54] The excretion and reabsorption of bile acids forms the basis of the enterohepatic circulation, which is essential for the digestion and absorption of dietary fats. Under certain circumstances, when more concentrated, as in the gallbladder, cholesterol crystallises and is the major constituent of most gallstones (lecithin and bilirubin gallstones also occur, but less frequently).[55] Every day, up to 1 g of cholesterol enters the colon. This cholesterol originates from the diet, bile, and desquamated intestinal cells, and can be metabolized by the colonic bacteria. Cholesterol is converted mainly into coprostanol, a nonabsorbable sterol that is excreted in the feces.

Although cholesterol is a steroid generally associated with mammals, the human pathogen Mycobacterium tuberculosis is able to completely degrade this molecule and contains a large number of genes that are regulated by its presence.[56] Many of these cholesterol-regulated genes are homologues of fatty acid β-oxidation genes, but have evolved in such a way as to bind large steroid substrates like cholesterol.[57] [58]

Dietary sources

Animal fats are complex mixtures of triglycerides, with lesser amounts of both the phospholipids and cholesterol molecules from which all animal (and human) cell membranes are constructed. Since all animal cells manufacture cholesterol, all animal-based foods contain cholesterol in varying amounts.[59] Major dietary sources of cholesterol include red meat, egg yolks and whole eggs, liver, kidney, giblets, fish oil, and butter.[60] Human breast milk also contains significant quantities of cholesterol.[61]

Plant cells synthesize cholesterol as a precursor for other compounds, such as phytosterols and steroidal glycoalkaloids, with cholesterol remaining in plant foods only in minor amounts or absent.[62] Some plant foods, such as avocado, flax seeds and peanuts, contain phytosterols, which compete with cholesterol for absorption in the intestines, and reduce the absorption of both dietary and bile cholesterol.[63] A typical diet contributes on the order of 0.2 gram of phytosterols, which is not enough to have a significant impact on blocking cholesterol absorption. Phytosterols intake can be supplemented through the use of phytosterol-containing functional foods or dietary supplements that are recognized as having potential to reduce levels of LDL-cholesterol.[64]

Medical guidelines and recommendations

In 2015, the scientific advisory panel of U.S. Department of Health and Human Services and U.S. Department of Agriculture for the 2015 iteration of the Dietary Guidelines for Americans dropped the previously recommended limit of consumption of dietary cholesterol to 300 mg per day with a new recommendation to "eat as little dietary cholesterol as possible" and acknowledging an association between a diet low in cholesterol and reduced risk of cardiovascular disease.[65]

A 2013 report by the American Heart Association and the American College of Cardiology recommended focusing on healthy dietary patterns rather than specific cholesterol limits, as they are hard for clinicians and consumers to implement. They recommend the DASH and Mediterranean diet, which are low in cholesterol.[66] A 2017 review by the American Heart Association recommends switching saturated fats for polyunsaturated fats to reduce cardiovascular disease risk.[67]

Some supplemental guidelines have recommended doses of phytosterols in the 1.6–3.0 grams per day range (Health Canada, EFSA, ATP III, FDA). A meta-analysis demonstrated a 12% reduction in LDL-cholesterol at a mean dose of 2.1 grams per day.[68] The benefits of a diet supplemented with phytosterols have also been questioned.[69]

Clinical significance

Hypercholesterolemia

See main article: Hypercholesterolemia and Lipid hypothesis. According to the lipid hypothesis, elevated levels of cholesterol in the blood lead to atherosclerosis which may increase the risk of heart attack, stroke, and peripheral artery disease. Since higher blood LDL – especially higher LDL concentrations and smaller LDL particle size – contributes to this process more than the cholesterol content of the HDL particles,[70] LDL particles are often termed "bad cholesterol". High concentrations of functional HDL, which can remove cholesterol from cells and atheromas, offer protection and are commonly referred to as "good cholesterol". These balances are mostly genetically determined, but can be changed by body composition, medications, diet,[71] and other factors.[72] A 2007 study demonstrated that blood total cholesterol levels have an exponential effect on cardiovascular and total mortality, with the association more pronounced in younger subjects. Because cardiovascular disease is relatively rare in the younger population, the impact of high cholesterol on health is larger in older people.[73]

Elevated levels of the lipoprotein fractions, LDL, IDL and VLDL, rather than the total cholesterol level, correlate with the extent and progress of atherosclerosis.[74] Conversely, the total cholesterol can be within normal limits, yet be made up primarily of small LDL and small HDL particles, under which conditions atheroma growth rates are high. A post hoc analysis of the IDEAL and the EPIC prospective studies found an association between high levels of HDL cholesterol (adjusted for apolipoprotein A-I and apolipoprotein B) and increased risk of cardiovascular disease, casting doubt on the cardioprotective role of "good cholesterol".[75] [76]

About one in 250 individuals can have a genetic mutation for the LDL cholesterol receptor that causes them to have familial hypercholesterolemia.[77] Inherited high cholesterol can also include genetic mutations in the PCSK9 gene and the gene for apolipoprotein B.[78]

Elevated cholesterol levels are treatable by a diet that reduces or eliminates saturated fat, trans fats, and high cholesterol foods,[79] often followed by one of various hypolipidemic agents, such as statins, fibrates, cholesterol absorption inhibitors, monoclonal antibody therapy (PCSK9 inhibitors), nicotinic acid derivatives or bile acid sequestrants. There are several international guidelines on the treatment of hypercholesterolemia.[80]

Human trials using HMG-CoA reductase inhibitors, known as statins, have repeatedly confirmed that changing lipoprotein transport patterns from unhealthy to healthier patterns significantly lowers cardiovascular disease event rates, even for people with cholesterol values currently considered low for adults.[81] Studies have shown that reducing LDL cholesterol levels by about 38.7 mg/dL with the use of statins can reduce cardiovascular disease and stroke risk by about 21%.[82] Studies have also found that statins reduce atheroma progression.[83] As a result, people with a history of cardiovascular disease may derive benefit from statins irrespective of their cholesterol levels (total cholesterol below 5.0 mmol/L [193 mg/dL]),[84] and in men without cardiovascular disease, there is benefit from lowering abnormally high cholesterol levels ("primary prevention").[85] Primary prevention in women was originally practiced only by extension of the findings in studies on men,[86] since, in women, none of the large statin trials conducted prior to 2007 demonstrated a significant reduction in overall mortality or in cardiovascular endpoints.[87] Meta-analyses have demonstrated significant reductions in all-cause and cardiovascular mortality, without significant heterogeneity by sex.[88]

Risk for heart disease
LevelInterpretation
mg/dLmmol/L
< 200< 5.2Desirable level
(lower risk)
200–2405.2–6.2Borderline high risk
> 240> 6.2High risk

The 1987 report of National Cholesterol Education Program, Adult Treatment Panels suggests the total blood cholesterol level should be: < 200 mg/dL normal blood cholesterol, 200–239 mg/dL borderline-high, > 240 mg/dL high cholesterol.[89] The American Heart Association provides a similar set of guidelines for total (fasting) blood cholesterol levels and risk for heart disease:[79] Statins are effective in lowering LDL cholesterol and widely used for primary prevention in people at high risk of cardiovascular disease, as well as in secondary prevention for those who have developed cardiovascular disease.[90] The average global mean total Cholesterol for humans has remained at about 4.6 mmol/L (178 mg/dL) for men and women, both crude and age standardized, for nearly 40 years from 1980 to 2018, with some regional variations and reduction of total Cholesterol in Western nations.[91]

More current testing methods determine LDL ("bad") and HDL ("good") cholesterol separately, allowing cholesterol analysis to be more nuanced. The desirable LDL level is considered to be less than 100 mg/dL (2.6 mmol/L).[92] [93]

Total cholesterol is defined as the sum of HDL, LDL, and VLDL. Usually, only the total, HDL, and triglycerides are measured. For cost reasons, the VLDL is usually estimated as one-fifth of the triglycerides and the LDL is estimated using the Friedewald formula (or a variant): estimated LDL = [total cholesterol] − [total HDL] − [estimated VLDL]. Direct LDL measures are used when triglycerides exceed 400 mg/dL. The estimated VLDL and LDL have more error when triglycerides are above 400 mg/dL.[94]

In the Framingham Heart Study, each 10 mg/dL (0.6 mmol/L) increase in total cholesterol levels increased 30-year overall mortality by 5% and CVD mortality by 9%. While subjects over the age of 50 had an 11% increase in overall mortality, and a 14% increase in cardiovascular disease mortality per 1 mg/dL (0.06 mmol/L) year drop in total cholesterol levels. The researchers attributed this phenomenon to a different correlation, whereby the disease itself increases risk of death, as well as changes a myriad of factors, such as weight loss and the inability to eat, which lower serum cholesterol.[95] This effect was also shown in men of all ages and women over 50 in the Vorarlberg Health Monitoring and Promotion Programme. These groups were more likely to die of cancer, liver diseases, and mental diseases with very low total cholesterol, of 186 mg/dL (10.3 mmol/L) and lower. This result indicates the low-cholesterol effect occurs even among younger respondents, contradicting the previous assessment among cohorts of older people that this is a marker for frailty occurring with age.[96]

Hypocholesterolemia

Abnormally low levels of cholesterol are termed hypocholesterolemia. Research into the causes of this state is relatively limited, but some studies suggest a link with depression, cancer, and cerebral hemorrhage. In general, the low cholesterol levels seem to be a consequence, rather than a cause, of an underlying illness. A genetic defect in cholesterol synthesis causes Smith–Lemli–Opitz syndrome, which is often associated with low plasma cholesterol levels. Hyperthyroidism, or any other endocrine disturbance which causes upregulation of the LDL receptor, may result in hypocholesterolemia.[97]

Testing

The American Heart Association recommends testing cholesterol every 4–6 years for people aged 20 years or older.[98] A separate set of American Heart Association guidelines issued in 2013 indicates that people taking statin medications should have their cholesterol tested 4–12 weeks after their first dose and then every 3–12 months thereafter.[99] For men ages 45 to 65 and women ages 55 to 65, a cholesterol test should occur every 1–2 years, and for seniors over age 65, an annual test should be performed.

A blood sample after 12-hours of fasting is taken by a healthcare professional from an arm vein to measure a lipid profile for a) total cholesterol, b) HDL cholesterol, c) LDL cholesterol, and d) triglycerides.[1] Results may be expressed as "calculated", indicating a calculation of total cholesterol, HDL, and triglycerides.[1]

Cholesterol is tested to determine for "normal" or "desirable" levels if a person has a total cholesterol of 5.2 mmol/L or less (200 mg/dL), an HDL value of more than 1 mmol/L (40 mg/dL, "the higher, the better"), an LDL value of less than 2.6 mmol/L (100 mg/dL), and a triglycerides level of less than 1.7 mmol/L (150 mg/dL).[1] Blood cholesterol in people with lifestyle, aging, or cardiovascular risk factors, such as diabetes mellitus, hypertension, family history of coronary artery disease, or angina, are evaluated at different levels.

Cholesteric liquid crystals

Some cholesterol derivatives (among other simple cholesteric lipids) are known to generate the liquid crystalline "cholesteric phase". The cholesteric phase is, in fact, a chiral nematic phase, and it changes colour when its temperature changes. This makes cholesterol derivatives useful for indicating temperature in liquid-crystal display thermometers and in temperature-sensitive paints.

Stereoisomers

Cholesterol has 256 stereoisomers that arise from its eight stereocenters, although only two of the stereoisomers have biochemical significance (nat-cholesterol and ent-cholesterol, for natural and enantiomer, respectively),[100] [101] and only one occurs naturally (nat-cholesterol).

See also

Notes and References

  1. Web site: Cholesterol . MedlinePlus, National Library of Medicine, US National Institutes of Health . 23 August 2023 . 10 December 2020.
  2. Wang . Hao . Kulas . Joshua A. . Wang . Chao . Holtzman . David M. . Ferris . Heather A. . Hansen . Scott B. . Regulation of beta-amyloid production in neurons by astrocyte-derived cholesterol . Proceedings of the National Academy of Sciences . 17 August 2021 . 118 . 33 . 10.1073/pnas.2102191118. 34385305 . 8379952 . 2021PNAS..11802191W . free .
  3. Razin S, Tully JG . Cholesterol requirement of mycoplasmas . Journal of Bacteriology . 102 . 2 . 306–110 . May 1970 . 4911537 . 247552 . 10.1128/JB.102.2.306-310.1970 .
  4. Hanukoglu I . Steroidogenic enzymes: structure, function, and role in regulation of steroid hormone biosynthesis . The Journal of Steroid Biochemistry and Molecular Biology . 43 . 8 . 779–804 . December 1992 . 22217824 . 10.1016/0960-0760(92)90307-5 . 112729 .
  5. Chevreul ME . 1816 . Recherches chimiques sur les corps gras, et particulièrement sur leurs combinaisons avec les alcalis. Sixième mémoire. Examen des graisses d'homme, de mouton, de boeuf, de jaguar et d'oie . Chemical researches on fatty substances, and particularly on their combinations o filippos ine kapios with alkalis. Sixth memoir. Study of human, sheep, beef, jaguar and goose fat . French . Annales de Chimie et de Physique . 2 . 339–372 [346] . Je nommerai cholesterine, de χολη, bile, et στερεος, solide, la substance cristallisée des calculs biliares humains, ... . I will name cholesterine – from χολη (bile) and στερεος (solid) – the crystalized substance from human gallstones ... .
  6. Olson RE . Discovery of the lipoproteins, their role in fat transport and their significance as risk factors . The Journal of Nutrition . 128 . 2 Suppl . 439S–443S . February 1998 . 9478044 . 10.1093/jn/128.2.439S . free .
  7. Luo . Jie . Yang . Hongyuan . Song . Bao-Liang . Mechanisms and regulation of cholesterol homeostasis . Nature Reviews Molecular Cell Biology . April 2020 . 21 . 4 . 225–245 . 10.1038/s41580-019-0190-7. 31848472 . 209392321 .
  8. Hansen . Scott B. . Wang . Hao . The shared role of cholesterol in neuronal and peripheral inflammation . Pharmacology & Therapeutics . September 2023 . 249 . 108486 . 10.1016/j.pharmthera.2023.108486. 37390970 . 259303593 .
  9. Bae . Soo-Han . Lee . Joon No . Fitzky . Barbara U. . Seong . Jekyung . Paik . Young-Ki . May 1999 . Cholesterol Biosynthesis from Lanosterol . . 274 . 21 . 14624–14631 . 10.1074/jbc.274.21.14624 . 10329655 . free.
  10. Web site: National Health and Nutrition Examination Survey . United States Center for Disease Control . 2012-01-28.
  11. Lecerf JM, de Lorgeril M . Dietary cholesterol: from physiology to cardiovascular risk . The British Journal of Nutrition . 106 . 1 . 6–14 . July 2011 . 21385506 . 10.1017/S0007114511000237 . free .
  12. Angel . A . Farkas . J . Regulation of cholesterol storage in adipose tissue. . Journal of Lipid Research . September 1974 . 15 . 5 . 491–9 . 10.1016/S0022-2275(20)36769-9 . 4415522. free .
  13. Dubois C, Armand M, Mekki N, Portugal H, Pauli AM, Bernard PM, Lafont H, Lairon D . 6 . Effects of increasing amounts of dietary cholesterol on postprandial lipemia and lipoproteins in human subjects . Journal of Lipid Research . 35 . 11 . 1993–2007 . November 1994 . 10.1016/S0022-2275(20)39946-6 . 7868978 . free .
  14. Journal of Chemical Education . Behrman EJ, Gopalan V . Cholesterol and Plants . Scovell WM . 82 . 12 . 2005 . 1791 . 10.1021/ed082p1791. 2005JChEd..82.1791B .
  15. John S, Sorokin AV, Thompson PD . Phytosterols and vascular disease . Current Opinion in Lipidology . 18 . 1 . 35–40 . February 2007 . 17218830 . 10.1097/MOL.0b013e328011e9e3 . 29213889 .
  16. Jesch ED, Carr TP . Food Ingredients That Inhibit Cholesterol Absorption . Preventive Nutrition and Food Science . 22 . 2 . 67–80 . June 2017 . 28702423 . 5503415 . 10.3746/pnf.2017.22.2.67 .
  17. Agren JJ, Tvrzicka E, Nenonen MT, Helve T, Hänninen O . Divergent changes in serum sterols during a strict uncooked vegan diet in patients with rheumatoid arthritis . The British Journal of Nutrition . 85 . 2 . 137–139 . February 2001 . 11242480 . 10.1079/BJN2000234 . free .
  18. Biochemistry, 7th ed., J. M. Berg, J. L. Tymoczko, & L. Stryer, 2010, p. 350.
  19. Book: Sadava D, Hillis DM, Heller HC, Berenbaum MR . Cell Membranes . Life: The Science of Biology . 9th . Freeman . San Francisco . 2011 . 105–114 . 978-1-4292-4646-0 .
  20. Ohvo-Rekilä H, Ramstedt B, Leppimäki P, Slotte JP . Cholesterol interactions with phospholipids in membranes . Progress in Lipid Research . 41 . 1 . 66–97 . January 2002 . 11694269 . 10.1016/S0163-7827(01)00020-0 .
  21. Yeagle PL . Modulation of membrane function by cholesterol . Biochimie . 73 . 10 . 1303–1310 . October 1991 . 1664240 . 10.1016/0300-9084(91)90093-G .
  22. Haines TH . Do sterols reduce proton and sodium leaks through lipid bilayers? . Progress in Lipid Research . 40 . 4 . 299–324 . July 2001 . 11412894 . 10.1016/S0163-7827(01)00009-1 . 32236169 .
  23. Petersen EN, Chung HW, Nayebosadri A, Hansen SB . Kinetic disruption of lipid rafts is a mechanosensor for phospholipase D . Nature Communications . 7 . 13873 . December 2016 . 27976674 . 5171650 . 10.1038/ncomms13873 . 2016NatCo...713873P .
  24. Incardona JP, Eaton S . Cholesterol in signal transduction . Current Opinion in Cell Biology . 12 . 2 . 193–203 . April 2000 . 10712926 . 10.1016/S0955-0674(99)00076-9 .
  25. Book: Pawlina W, Ross MW . Supporting Cells of the Nervous System . Histology: a text and atlas: with correlated cell and molecular biology . 5th . Lippincott Williams & Wilkins . Philadelphia . 2006 . 339 . 978-0-7817-5056-1 .
  26. Levitan I, Singh DK, Rosenhouse-Dantsker A . Cholesterol binding to ion channels . Frontiers in Physiology . 5 . 65 . 2014 . 24616704 . 3935357 . 10.3389/fphys.2014.00065 . free .
  27. Wei W, Schwaid AG, Wang X, Wang X, Chen S, Chu Q, Saghatelian A, Wan Y . 6 . Ligand Activation of ERRα by Cholesterol Mediates Statin and Bisphosphonate Effects . Cell Metabolism . 23 . 3 . 479–491 . March 2016 . 26777690 . 4785078 . 10.1016/j.cmet.2015.12.010 .
  28. Book: Zuo H, Wan Y . Nuclear Receptors in Skeletal Homeostasis . Forrest D, Tsai S . Nuclear Receptors in Development and Disease. https://books.google.com/books?id=ZvupDQAAQBAJ&pg=PA88 . 2017. Elsevier Science. 978-0-12-802196-5. 88 .
  29. Payne AH, Hales DB . Overview of steroidogenic enzymes in the pathway from cholesterol to active steroid hormones . Endocrine Reviews . 25 . 6 . 947–70 . December 2004 . 15583024 . 10.1210/er.2003-0030 . free .
  30. Book: Elias PM, Feingold KR . Stratum Corneum Barrier Function: Defintions and Broad Concepts . Elias PM . Skin barrier . 2006 . Taylor & Francis . New York . 978-0824758158.
  31. Merleev AA, Le ST, Alexanian C, Toussi A, Xie Y, Marusina AI, Watkins SM, Patel F, Billi AC, Wiedemann J, Izumiya Y, Kumar A, Uppala R, Kahlenberg JM, Liu FT, Adamopoulos IE, Wang EA, Ma C, Cheng MY, Xiong H, Kirane A, Luxardi G, Andersen B, Tsoi LC, Lebrilla CB, Gudjonsson JE, Maverakis E . 6 . Biogeographic and disease-specific alterations in epidermal lipid composition and single-cell analysis of acral keratinocytes . JCI Insight . 7 . 16 . August 2022 . 35900871 . 9462509 . 10.1172/jci.insight.159762 .
  32. Elias PM, Williams ML, Maloney ME, Bonifas JA, Brown BE, Grayson S, Epstein EH . Stratum corneum lipids in disorders of cornification. Steroid sulfatase and cholesterol sulfate in normal desquamation and the pathogenesis of recessive X-linked ichthyosis . The Journal of Clinical Investigation . 74 . 4 . 1414–1421 . October 1984 . 6592175 . 425309 . 10.1172/JCI111552 .
  33. News: How it's made: Cholesterol production in your body . Harvard Health Publishing . 2018-10-18. en-US.
  34. Web site: Biosynthesis and Regulation of Cholesterol (with Animation). PharmaXChange.info. 17 September 2013. 19 September 2013. 7 January 2018. https://web.archive.org/web/20180107234818/http://pharmaxchange.info/press/2013/09/biosynthesis-and-regulation-of-cholesterol-animation/. dead.
  35. Web site: Cholesterol metabolism (includes both Bloch and Kandutsch-Russell pathways) (Mus musculus) – WikiPathways . www.wikipathways.org . 2 February 2021.
  36. Singh P, Saxena R, Srinivas G, Pande G, Chattopadhyay A . Cholesterol biosynthesis and homeostasis in regulation of the cell cycle . PLOS ONE . 8 . 3 . e58833 . 2013 . 23554937 . 3598952 . 10.1371/journal.pone.0058833 . free . 2013PLoSO...858833S .
  37. Web site: Kandutsch-Russell pathway . pubchem.ncbi.nlm.nih.gov . 2 February 2021 . en.
  38. Book: Berg J . Biochemistry . 2002 . WH Freeman . New York . 978-0-7167-3051-4 . registration .
  39. Book: Rhodes CM, Stryer L, Tasker R . Biochemistry . 4th . W.H. Freeman . San Francisco . 1995 . 280, 703 . 978-0-7167-2009-6 .
  40. Web site: The Nobel Prize in Physiology or Medicine, 1964. Nobel Prize, Nobel Media .
  41. Espenshade PJ, Hughes AL . Regulation of sterol synthesis in eukaryotes . Annual Review of Genetics . 41 . 401–427 . 2007 . 17666007 . 10.1146/annurev.genet.41.110306.130315 .
  42. Brown MS, Goldstein JL . The SREBP pathway: regulation of cholesterol metabolism by proteolysis of a membrane-bound transcription factor . Cell . 89 . 3 . 331–340 . May 1997 . 9150132 . 10.1016/S0092-8674(00)80213-5 . 17882616 . free .
  43. Book: Tymoczko JL, Berg T, Stryer L, Berg JM . Biochemistry . W.H. Freeman . San Francisco . 2002 . 726–727 . 978-0-7167-4955-4 . registration .
  44. Book: Patton KT, Thibodeau GA . Anatomy and Physiology . 2010 . Mosby/Elsevier . 978-9996057762 . 7th .
  45. Mahley RW . Apolipoprotein E: from cardiovascular disease to neurodegenerative disorders . Journal of Molecular Medicine . 94 . 7 . 739–746 . July 2016 . 27277824 . 4921111 . 10.1007/s00109-016-1427-y .
  46. Weingärtner O, Pinsdorf T, Rogacev KS, Blömer L, Grenner Y, Gräber S, Ulrich C, Girndt M, Böhm M, Fliser D, Laufs U, Lütjohann D, Heine GH . 6 . The relationships of markers of cholesterol homeostasis with carotid intima-media thickness . PLOS ONE. 5 . 10 . e13467 . October 2010 . 20976107 . 2956704 . 10.1371/journal.pone.0013467 . Federici M . 2010PLoSO...513467W . free .
  47. Lewis GF, Rader DJ . New insights into the regulation of HDL metabolism and reverse cholesterol transport . Circulation Research . 96 . 12 . 1221–1232 . June 2005 . 15976321 . 10.1161/01.RES.0000170946.56981.5c .
  48. Gordon DJ, Probstfield JL, Garrison RJ, Neaton JD, Castelli WP, Knoke JD, Jacobs DR, Bangdiwala S, Tyroler HA . 6 . High-density lipoprotein cholesterol and cardiovascular disease. Four prospective American studies . Circulation . 79 . 1 . 8–15 . January 1989 . 2642759 . 10.1161/01.CIR.79.1.8 . free .
  49. Miller NE, Thelle DS, Forde OH, Mjos OD . The Tromsø heart-study. High-density lipoprotein and coronary heart-disease: a prospective case-control study . Lancet . 1 . 8019 . 965–968 . May 1977 . 67464 . 10.1016/s0140-6736(77)92274-7 . 140204202 .
  50. Kandutsch AA, Chen HW, Heiniger HJ . Biological activity of some oxygenated sterols . Science . 201 . 4355 . 498–501 . August 1978 . 663671 . 10.1126/science.663671 . 1978Sci...201..498K .
  51. Russell DW . Oxysterol biosynthetic enzymes . Biochimica et Biophysica Acta (BBA) - Molecular and Cell Biology of Lipids . 1529 . 1–3 . 126–35 . December 2000 . 11111082 . 10.1016/S1388-1981(00)00142-6 .
  52. Hanukoglu I, Jefcoate CR . Pregnenolone separation from cholesterol using Sephadex LH-20 mini-columns. Journal of Chromatography A . 190 . 1 . 1980 . 256–262 . 10.1016/S0021-9673(00)85545-4 .
  53. Javitt NB . Bile acid synthesis from cholesterol: regulatory and auxiliary pathways . FASEB Journal . 8 . 15 . 1308–1311 . December 1994 . 8001744 . 10.1096/fasebj.8.15.8001744 . free . 20302590 .
  54. Wolkoff AW, Cohen DE . Bile acid regulation of hepatic physiology: I. Hepatocyte transport of bile acids . American Journal of Physiology. Gastrointestinal and Liver Physiology . 284 . 2 . G175–G179 . February 2003 . 12529265 . 10.1152/ajpgi.00409.2002 .
  55. Marschall HU, Einarsson C . Gallstone disease . Journal of Internal Medicine . 261 . 6 . 529–542 . June 2007 . 17547709 . 10.1111/j.1365-2796.2007.01783.x . 8609639 . free .
  56. Wipperman MF, Sampson NS, Thomas ST . Pathogen roid rage: cholesterol utilization by Mycobacterium tuberculosis . Critical Reviews in Biochemistry and Molecular Biology . 49 . 4 . 269–293 . 2014 . 24611808 . 4255906 . 10.3109/10409238.2014.895700 .
  57. Thomas ST, Sampson NS . Mycobacterium tuberculosis utilizes a unique heterotetrameric structure for dehydrogenation of the cholesterol side chain . Biochemistry . 52 . 17 . 2895–2904 . April 2013 . 23560677 . 3726044 . 10.1021/bi4002979 .
  58. Wipperman MF, Yang M, Thomas ST, Sampson NS . Shrinking the FadE proteome of Mycobacterium tuberculosis: insights into cholesterol metabolism through identification of an α2β2 heterotetrameric acyl coenzyme A dehydrogenase family . Journal of Bacteriology . 195 . 19 . 4331–4341 . October 2013 . 23836861 . 3807453 . 10.1128/JB.00502-13 .
  59. Book: Lipid analysis: isolation, separation, identification, and structural analysis of lipids. Christie WW . Oily Press. 2003. 978-0-9531949-5-7. Ayr, Scotland .
  60. Web site: Cholesterol content in foods, rank order per 100 g; In: USDA Food Composition Databases. United States Department of Agriculture. 2019. 4 March 2019.
  61. Jensen RG, Hagerty MM, McMahon KE . Lipids of human milk and infant formulas: a review . The American Journal of Clinical Nutrition . 31 . 6 . 990–1016 . June 1978 . 352132 . 10.1093/ajcn/31.6.990 . free .
  62. Sonawane PD, Pollier J, Panda S, Szymanski J, Massalha H, Yona M, Unger T, Malitsky S, Arendt P, Pauwels L, Almekias-Siegl E, Rogachev I, Meir S, Cárdenas PD, Masri A, Petrikov M, Schaller H, Schaffer AA, Kamble A, Giri AP, Goossens A, Aharoni A . 6 . Plant cholesterol biosynthetic pathway overlaps with phytosterol metabolism . Nature Plants . 3 . 1 . 16205 . December 2016 . 28005066 . 10.1038/nplants.2016.205 . 5518449 .
  63. De Smet E, Mensink RP, Plat J . Effects of plant sterols and stanols on intestinal cholesterol metabolism: suggested mechanisms from past to present . Molecular Nutrition & Food Research . 56 . 7 . 1058–1072 . July 2012 . 22623436 . 10.1002/mnfr.201100722 .
  64. Web site: Scientific opinion on the substantiation of health claims related to plant sterols and plant stanols and maintenance of normal blood cholesterol concentrations. 2010. European Food Safety Authority, Journal.
  65. Web site: 2015-2020 Dietary Guidelines health.gov . 2023-08-23 . health.gov.
  66. Carson JA, Lichtenstein AH, Anderson CA, Appel LJ, Kris-Etherton PM, Meyer KA, Petersen K, Polonsky T, Van Horn L . 6 . Dietary Cholesterol and Cardiovascular Risk: A Science Advisory From the American Heart Association . Circulation . 141 . 3 . e39–e53 . January 2020 . 31838890 . 10.1161/CIR.0000000000000743 . free .
  67. Sacks FM, Lichtenstein AH, Wu JH, Appel LJ, Creager MA, Kris-Etherton PM, Miller M, Rimm EB, Rudel LL, Robinson JG, Stone NJ, Van Horn LV . 6 . Dietary Fats and Cardiovascular Disease: A Presidential Advisory From the American Heart Association . Circulation . 136 . 3 . e1–e23 . July 2017 . 28620111 . 10.1161/CIR.0000000000000510 . 367602 . free .
  68. Ras RT, Geleijnse JM, Trautwein EA . LDL-cholesterol-lowering effect of plant sterols and stanols across different dose ranges: a meta-analysis of randomised controlled studies . The British Journal of Nutrition . 112 . 2 . 214–219 . July 2014 . 24780090 . 4071994 . 10.1017/S0007114514000750 .
  69. Weingärtner O, Böhm M, Laufs U . Controversial role of plant sterol esters in the management of hypercholesterolaemia . European Heart Journal . 30 . 4 . 404–409 . February 2009 . 19158117 . 2642922 . 10.1093/eurheartj/ehn580 .
  70. Brunzell JD, Davidson M, Furberg CD, Goldberg RB, Howard BV, Stein JH, Witztum JL . Lipoprotein management in patients with cardiometabolic risk: consensus statement from the American Diabetes Association and the American College of Cardiology Foundation . Diabetes Care . 31 . 4 . 811–822 . April 2008 . 18375431 . 10.2337/dc08-9018 . free .
  71. Web site: More evidence for Mediterranean diet . https://web.archive.org/web/20201029150758/https://www.heartuk.org.uk/healthy-diets/healthy-diets . 29 October 2020 . Department of Health (UK), NHS Choices . 8 March 2011 . 11 November 2015 .
  72. Durrington P . Dyslipidaemia . Lancet . 362 . 9385 . 717–731 . August 2003 . 12957096 . 10.1016/S0140-6736(03)14234-1 . 208792416 .
  73. Lewington S, Whitlock G, Clarke R, Sherliker P, Emberson J, Halsey J, Qizilbash N, Peto R, Collins R . 6 . Blood cholesterol and vascular mortality by age, sex, and blood pressure: a meta-analysis of individual data from 61 prospective studies with 55,000 vascular deaths . Lancet . 370 . 9602 . 1829–1839 . December 2007 . 18061058 . 10.1016/S0140-6736(07)61778-4 . 54293528 .
  74. Web site: Detection, Evaluation and Treatment of High Blood Cholesterol in Adults (Adult Treatment Panel III) Final Report . National Institutes of Health. National Heart, Lung and Blood Institute . 1 September 2002 . 2008-10-27.
  75. van der Steeg WA, Holme I, Boekholdt SM, Larsen ML, Lindahl C, Stroes ES, Tikkanen MJ, Wareham NJ, Faergeman O, Olsson AG, Pedersen TR, Khaw KT, Kastelein JJ . 6 . High-density lipoprotein cholesterol, high-density lipoprotein particle size, and apolipoprotein A-I: significance for cardiovascular risk: the IDEAL and EPIC-Norfolk studies . Journal of the American College of Cardiology . 51 . 6 . 634–642 . February 2008 . 18261682 . 10.1016/j.jacc.2007.09.060 .
  76. Robinson JG, Wang S, Jacobson TA . Meta-analysis of comparison of effectiveness of lowering apolipoprotein B versus low-density lipoprotein cholesterol and nonhigh-density lipoprotein cholesterol for cardiovascular risk reduction in randomized trials . The American Journal of Cardiology . 110 . 10 . 1468–1476 . November 2012 . 22906895 . 10.1016/j.amjcard.2012.07.007 .
  77. Akioyamen LE, Genest J, Shan SD, Reel RL, Albaum JM, Chu A, Tu JV . Estimating the prevalence of heterozygous familial hypercholesterolaemia: a systematic review and meta-analysis . BMJ Open . 7 . 9 . e016461 . September 2017 . 28864697 . 5588988 . 10.1136/bmjopen-2017-016461 .
  78. Web site: Familial Hypercholesterolemia (FH). www.heart.org. en. 2019-08-02.
  79. Web site: Prevention and Treatment of High Cholesterol (Hyperlipidemia) . American Heart Association . 23 August 2023 . 2023.
  80. Mannu GS, Zaman MJ, Gupta A, Rehman HU, Myint PK . Update on guidelines for management of hypercholesterolemia . Expert Review of Cardiovascular Therapy . 10 . 10 . 1239–1249 . October 2012 . 23190064 . 10.1586/erc.12.94 . 5451203.
  81. Kizer JR, Madias C, Wilner B, Vaughan CJ, Mushlin AI, Trushin P, Gotto AM, Pasternak RC . 6 . Relation of different measures of low-density lipoprotein cholesterol to risk of coronary artery disease and death in a meta-regression analysis of large-scale trials of statin therapy . The American Journal of Cardiology . 105 . 9 . 1289–1296 . May 2010 . 20403481 . 2917836 . 10.1016/j.amjcard.2009.12.051 .
  82. Grundy SM, Stone NJ, Bailey AL, Beam C, Birtcher KK, Blumenthal RS, Braun LT, de Ferranti S, Faiella-Tommasino J, Forman DE, Goldberg R, Heidenreich PA, Hlatky MA, Jones DW, Lloyd-Jones D, Lopez-Pajares N, Ndumele CE, Orringer CE, Peralta CA, Saseen JJ, Smith SC, Sperling L, Virani SS, Yeboah J . 6 . 2018 AHA/ACC/AACVPR/AAPA/ABC/ACPM/ADA/AGS/APhA/ASPC/NLA/PCNA Guideline on the Management of Blood Cholesterol: A Report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines . Circulation . 139 . 25 . e1082–e1143 . June 2019 . 30586774 . 7403606 . 10.1161/CIR.0000000000000625 .
  83. Nicholls SJ . Rosuvastatin and progression of atherosclerosis . Expert Review of Cardiovascular Therapy . 6 . 7 . 925–933 . August 2008 . 18666843 . 10.1586/14779072.6.7.925 . 46419583 .
  84. MRC/BHF Heart Protection Study of cholesterol lowering with simvastatin in 20,536 high-risk individuals: a randomised placebo-controlled trial . Lancet . 360 . 9326 . 7–22 . July 2002 . 12114036 . 10.1016/S0140-6736(02)09327-3 . 35836642 . Heart Protection Study Collaborative Group .
  85. Shepherd J, Cobbe SM, Ford I, Isles CG, Lorimer AR, MacFarlane PW, McKillop JH, Packard CJ . 6 . Prevention of coronary heart disease with pravastatin in men with hypercholesterolemia. West of Scotland Coronary Prevention Study Group . The New England Journal of Medicine . 333 . 20 . 1301–1307 . November 1995 . 7566020 . 10.1056/NEJM199511163332001 . free .
  86. Grundy SM . Should women be offered cholesterol lowering drugs to prevent cardiovascular disease? Yes . BMJ . 334 . 7601 . 982 . May 2007 . 17494017 . 1867899 . 10.1136/bmj.39202.399942.AD .
  87. Kendrick M . Should women be offered cholesterol lowering drugs to prevent cardiovascular disease? No . BMJ . 334 . 7601 . 983 . May 2007 . 17494018 . 1867901 . 10.1136/bmj.39202.397488.AD .
  88. Brugts JJ, Yetgin T, Hoeks SE, Gotto AM, Shepherd J, Westendorp RG, de Craen AJ, Knopp RH, Nakamura H, Ridker P, van Domburg R, Deckers JW . 6 . The benefits of statins in people without established cardiovascular disease but with cardiovascular risk factors: meta-analysis of randomised controlled trials . BMJ . 338 . b2376 . June 2009 . 19567909 . 2714690 . 10.1136/bmj.b2376 .
  89. Report of the National Cholesterol Education Program Expert Panel on Detection, Evaluation, and Treatment of High Blood Cholesterol in Adults. The Expert Panel . Archives of Internal Medicine . 148 . 1 . 36–69 . January 1988 . 3422148 . 10.1001/archinte.148.1.36 .
  90. Alenghat FJ, Davis AM . Management of Blood Cholesterol . JAMA . 321 . 8 . 800–801 . February 2019 . 30715135 . 6679800 . 10.1001/jama.2019.0015 .
  91. Web site: Mean total cholesterol trends Global estimates . World Health Organization . 27 April 2024.
  92. Web site: How To Get Your Cholesterol Tested. American Heart Association. 2023. 23 August 2023 .
  93. Web site: About cholesterol . 20 March 2023 . US Centers for Disease Control and Prevention. 23 August 2023 .
  94. Warnick GR, Knopp RH, Fitzpatrick V, Branson L . Estimating low-density lipoprotein cholesterol by the Friedewald equation is adequate for classifying patients on the basis of nationally recommended cutpoints . Clinical Chemistry . 36 . 1 . 15–19 . January 1990 . 2297909 . 10.1093/clinchem/36.1.15 . free .
  95. Anderson KM, Castelli WP, Levy D . Cholesterol and mortality. 30 years of follow-up from the Framingham study . JAMA . 257 . 16 . 2176–2180 . 24 April 1987 . 3560398 . 10.1001/jama.1987.03390160062027 .
  96. Ulmer H, Kelleher C, Diem G, Concin H . Why Eve is not Adam: prospective follow-up in 149650 women and men of cholesterol and other risk factors related to cardiovascular and all-cause mortality . Journal of Women's Health . 13 . 1 . 41–53 . 2004 . 15006277 . 10.1089/154099904322836447 .
  97. Rizos CV, Elisaf MS, Liberopoulos EN . Effects of thyroid dysfunction on lipid profile . The Open Cardiovascular Medicine Journal . 5 . 1 . 76–84 . 24 February 2011 . 21660244 . 3109527 . 10.2174/1874192401105010076 . free.
  98. Web site: How To Get Your Cholesterol Tested . American Heart Association . 2013-07-10.
  99. Web site: Getting a grasp of the Guidelines . American College of Cardiology . Stone NJ, Robinson J, Goff DC . 2013 . 2 April 2014 . https://web.archive.org/web/20140707122736/http://www.cardiosource.org/News-Media/Publications/Cardiology-Magazine/2013/12/Getting-a-Grasp-of-the-Guidelines.aspx . 7 July 2014 . dead.
  100. Westover EJ, Covey DF, Brockman HL, Brown RE, Pike LJ . Cholesterol depletion results in site-specific increases in epidermal growth factor receptor phosphorylation due to membrane level effects. Studies with cholesterol enantiomers . The Journal of Biological Chemistry . 278 . 51 . 51125–51133 . December 2003 . 14530278 . 2593805 . 10.1074/jbc.M304332200 . free .
  101. Kristiana I, Luu W, Stevenson J, Cartland S, Jessup W, Belani JD, Rychnovsky SD, Brown AJ . 6 . Cholesterol through the looking glass: ability of its enantiomer also to elicit homeostatic responses . The Journal of Biological Chemistry . 287 . 40 . 33897–33904 . September 2012 . 22869373 . 3460484 . 10.1074/jbc.M112.360537 . free .