“Coenzyme Q10”的意思、由来-开放百科全书

Coenzyme Q₁₀, also known as ubiquinone, ubidecarenone, coenzyme Q, and abbreviated at times to CoQ₁₀ {{IPAc-en|ˌ|k|oʊ|ˌ|k|juː|ˈ|t|ɛ|n}}, CoQ, or Q₁₀ is a coenzyme that is ubiquitous in animals and most bacteria (hence the name ubiquinone). It is a 1,4-benzoquinone, where Q refers to the quinone chemical group and 10 refers to the number of isoprenyl chemical subunits in its tail.

This fat-soluble substance, which resembles a vitamin, is present in all respiring eukaryotic cells, primarily in the mitochondria. It is a component of the electron transport chain and participates in aerobic cellular respiration, which generates energy in the form of ATP. Ninety-five percent of the human body's energy is generated this way.^[1]^[2] Therefore, those organs with the highest energy requirements—such as the heart, liver, and kidney—have the highest CoQ₁₀ concentrations.^[3]^[4]^[5]

There are three redox states of CoQ₁₀: fully oxidized (ubiquinone), semiquinone (ubisemiquinone), and fully reduced (ubiquinol). The capacity of this molecule to act as a two-electron carrier (moving between the quinone and quinol form) and a one-electron carrier (moving between the semiquinone and one of these other forms) is central to its role in the electron transport chain due to the iron–sulfur clusters that can only accept one electron at a time, and as a free-radical–scavenging antioxidant.

Deficiency and toxicity

There are two major factors that lead to deficiency of CoQ₁₀ in humans: reduced biosynthesis, and increased use by the body. Biosynthesis is the major source of CoQ₁₀. Biosynthesis requires at least 12 genes, and mutations in many of them cause CoQ deficiency. CoQ₁₀ levels also may be affected by other genetic defects (such as mutations of mitochondrial DNA, ETFDH, APTX, FXN, and BRAF, genes that are not directly related to the CoQ₁₀ biosynthetic process). The role of statins in deficiencies is controversial.^[6] Some chronic disease conditions (cancer, heart disease, etc.) also are thought to reduce the biosynthesis of and increase the demand for CoQ₁₀ in the body, but there are no definite data to support these claims.

Usually, toxicity is not observed with high doses of CoQ₁₀. A daily dosage up to 3,600 mg was found to be tolerated by healthy as well as unhealthy persons.^[7] Some adverse effects, however, largely gastrointestinal, are reported with very high intakes. The observed safe level (OSL) risk assessment method indicated that the evidence of safety is strong at intakes up to 1200 mg/day, and this level is identified as the OSL.^[8]

Clinical assessment

Although CoQ₁₀ may be measured in blood plasma, these measurements reflect dietary intake rather than tissue status. Currently, most clinical centers measure CoQ₁₀ levels in cultured skin fibroblasts, muscle biopsies, and blood mononuclear cells.^[6] Culture fibroblasts can be used also to evaluate the rate of endogenous CoQ₁₀ biosynthesis, by measuring the uptake of ¹⁴C-labelled p-hydroxybenzoate.^[9]

Inhibition by statins and beta blockers

CoQ₁₀ shares a biosynthetic pathway with cholesterol. The synthesis of an intermediary precursor of CoQ₁₀, mevalonate, is inhibited by some beta blockers, blood pressure-lowering medication,^[10] and statins, a class of cholesterol-lowering drugs.^[11] Statins can reduce serum levels of CoQ₁₀ by up to 40%.^[12]

Supplementation

CoQ₁₀ is not approved by the U.S. Food and Drug Administration (FDA) for the treatment of any medical condition.^[13] It is sold as a dietary supplement. In the U.S., supplements are not regulated as drugs, but as foods. How CoQ₁₀ is manufactured is not regulated and different batches and brands may vary significantly.^[13]

A 2004 laboratory analysis by ConsumerLab.com of CoQ₁₀ supplements on the market found that some did not contain the quantity identified on the product label. Amounts varied from "no detectable CoQ₁₀", to 75% of stated dose, and up to a 75% excess.^[14]

Generally, CoQ₁₀ is well tolerated. The most common side effects are gastrointestinal symptoms (nausea, vomiting, appetite suppression, and stomachaches), rashes, and headaches.^[15]

While there is no established ideal dosage of CoQ₁₀, a typical daily dose is 100–200 milligrams. Note that different supplement brands may have varying ingredients and strengths ^[16]

Heart disease

A 2014 Cochrane Collaboration meta-analysis found "no convincing evidence to support or refute" the use of CoQ₁₀ for the treatment of heart failure.^[17] However, a 2013 meta-analysis showed that "supplementation with CoQ₁₀ resulted in a pooled mean net change of 3.67% (95% CI: 1.60%, 5.75%) in the ejection fraction, and -0.30 (95% CI: -0.66, 0.06) in the New York Heart Association functional class".^[18] Evidence with respect to preventing heart disease in those who are otherwise healthy is poor.^[19] A 2016 Cochrane review concluded that CoQ₁₀ had no effects on blood pressure.^[20]

Migraine headaches

The Canadian Headache Society guideline for migraine prophylaxis recommends, based on low-quality evidence, that 300 mg of CoQ₁₀ be offered as a choice for prophylaxis.^[21]

Statin myopathy

CoQ₁₀ has been routinely used to treat muscle breakdown associated as a side effect of use of statin medications. A 2015 meta-analysis of randomized controlled trials found that CoQ₁₀ had no effect on statin myopathy.^[22] A 2018 meta-analysis concluded that there was preliminary evidence for oral CoQ₁₀ reducing statin-associated muscle symptoms, including muscle pain, muscle weakness, muscle cramps, and muscle tiredness.^[23]

Cancer

No large well-designed clinical trials of CoQ₁₀ in cancer treatment have been conducted.^[13] The US' National Cancer Institute identified issues with the few, small studies that have been done stating, "the way the studies were done and the amount of information reported made it unclear if benefits were caused by the CoQ₁₀ or by something else".^[13] The American Cancer Society has concluded, "CoQ₁₀ may reduce the effectiveness of chemo and radiation therapy, so most oncologists would recommend avoiding it during cancer treatment."^[24]

Dental disease

A 1995 review study found that there is no clinical benefit to the use of CoQ₁₀ in the treatment of periodontal disease.^[25] Most of the studies suggesting otherwise were outdated, focused on in vitro tests,^[26]^[27]^[28] had too few test subjects and/or erroneous statistical methodology and trial setup,^[29]^[30] or were sponsored by a manufacturer of the product.^[31]

Drug interactions

Coenzyme Q₁₀ has potential to inhibit the effects of warfarin (Coumadin), a potent anticoagulant, by reducing the INR, a measure of blood clotting. The structure of coenzyme Q₁₀ is very much similar to the structure of vitamin K, which competes with and counteracts warfarin's anticoagulation effects. Coenzyme Q₁₀ should be avoided in patients currently taking warfarin due to the increased risk of clotting.^[15]

Chemical properties

The oxidized structure of CoQ₁₀ is shown on the top-right. The various kinds of Coenzyme Q may be distinguished by the number of isoprenoid subunits in their side-chains. The most common Coenzyme Q in human mitochondria is CoQ₁₀. Q refers to the quinone head and 10 refers to the number of isoprene repeats in the tail. The molecule below has three isoprenoid units and would be called Q₃.

Biosynthesis

The initial two reactions occur in mitochondria, the endoplasmic reticulum, and peroxisomes, indicating multiple sites of synthesis in animal cells.^[32]

An important enzyme in this pathway is HMG-CoA reductase, usually a target for intervention in cardiovascular complications. The "statin" family of cholesterol-reducing medications inhibits HMG-CoA reductase. One possible side effect of statins is decreased production of CoQ₁₀, which may be connected to the development of myopathy and rhabdomyolysis. {{citation needed|date=May 2016}}

Genes involved include PDSS1, PDSS2, COQ2, and ADCK3 (COQ8, CABC1).^[33]

Increasing the endogenous biosynthesis of CoQ₁₀ has gained attention in recent years as a strategy to fight CoQ₁₀ deficiency.{{citation needed|date=January 2016}}

Absorption and metabolism

Absorption

CoQ₁₀ is a crystalline powder insoluble in water. Absorption follows the same process as that of lipids; the uptake mechanism appears to be similar to that of vitamin E, another lipid-soluble nutrient. This process in the human body involves secretion into the small intestine of pancreatic enzymes and bile, which facilitates emulsification and micelle formation required for absorption of lipophilic substances.^[34] Food intake (and the presence of lipids) stimulates bodily biliary excretion of bile acids and greatly enhances absorption of CoQ₁₀. Exogenous CoQ₁₀ is absorbed from the small intestine and is best absorbed if taken with a meal. Serum concentration of CoQ₁₀ in fed condition is higher than in fasting conditions.^[35]^[36]

Metabolism

Data on the metabolism of CoQ₁₀ in animals and humans are limited.^[42] A study with ¹⁴C-labeled CoQ₁₀ in rats showed most of the radioactivity in the liver two hours after oral administration when the peak plasma radioactivity was observed, but CoQ₉ (with only 9 isoprenyl units) is the predominant form of coenzyme Q in rats.^[37] It appears that CoQ₁₀ is metabolised in all tissues, while a major route for its elimination is biliary and fecal excretion. After the withdrawal of CoQ₁₀ supplementation, the levels return to normal within a few days, irrespective of the type of formulation used.^[44]

Pharmacokinetics

Some reports have been published on the pharmacokinetics of CoQ₁₀. The plasma peak can be observed 2–6 hours after oral administration, depending mainly on the design of the study. In some studies, a second plasma peak also was observed at approximately 24 hours after administration, probably due to both enterohepatic recycling and redistribution from the liver to circulation.^[34] Tomono et al. used deuterium-labeled crystalline CoQ₁₀ to investigate pharmacokinetics in humans and determined an elimination half-time of 33 hours.^[38]

Improving the bioavailability of CoQ₁₀

The importance of how drugs are formulated for bioavailability is well known. In order to find a principle to boost the bioavailability of CoQ₁₀ after oral administration, several new approaches have been taken; different formulations and forms have been developed and tested on animals and humans.^[39]

Reduction of particle size

Soft-gel capsules with CoQ₁₀ in oil suspension

A successful approach was to use the emulsion system to facilitate absorption from the gastrointestinal tract and to improve bioavailability. Emulsions of soybean oil (lipid microspheres) could be stabilised very effectively by lecithin and were used in the preparation of soft gelatin capsules. In one of the first such attempts, Ozawa et al. performed a pharmacokinetic study on beagles in which the emulsion of CoQ₁₀ in soybean oil was investigated; about twice the plasma CoQ₁₀ level than that of the control tablet preparation was determined during administration of a lipid microsphere.^[43] Although an almost negligible improvement of bioavailability was observed by Kommuru et al. with oil-based softgel capsules in a later study on dogs,^[44] the significantly increased bioavailability of CoQ₁₀ was confirmed for several oil-based formulations in most other studies.^[45]

Novel forms of CoQ₁₀ with increased water-solubility

Facilitating drug absorption by increasing its solubility in water is a common pharmaceutical strategy and also has been shown to be successful for CoQ₁₀. Various approaches have been developed to achieve this goal, with many of them producing significantly better results over oil-based softgel capsules in spite of the many attempts to optimize their composition.^[39] Examples of such approaches are use of the aqueous dispersion of solid CoQ₁₀ with the polymer tyloxapol,^[46] formulations based on various solubilising agents, such as hydrogenated lecithin,^[47] and complexation with cyclodextrins; among the latter, the complex with β-cyclodextrin has been found to have highly increased bioavailability.^[48]^[49] and also is used in pharmaceutical and food industries for CoQ₁₀-fortification.^[39] Also some other novel carrier systems, such as liposomes, nanoparticles or dendrimers, may be used to increase the bioavailability of CoQ₁₀.{{Citation needed|date=October 2010}}

History

CoQ₁₀ was first discovered by Fredrick L. Crane and colleagues at the University of Wisconsin–Madison Enzyme Institute in 1957.^[50]^[51] In 1958, its chemical structure was reported by Karl Folkers and coworkers at Merck. In the early 1970s, Gian Paolo Littarru and Karl Folkers observed that a deficiency of CoQ₁₀ was associated with human heart disease.^[52]^[53]^[54] The 1980s witnessed a steep rise in the number of clinical trials due to the availability of large quantities of pure CoQ₁₀ and methods to measure plasma and blood CoQ₁₀ concentrations. The redox functions of CoQ in cellular energy production and antioxidant protection are based on the ability to exchange two electrons in a redox cycle between ubiquinol (reduced CoQ) and ubiquinone (oxidized CoQ).^[55]^[56] The antioxidant role of the molecule as a free-radical scavenger was widely studied by Lars Ernster. Numerous scientists around the globe started studies on this molecule since then in relation to various diseases including cardiovascular diseases and cancer.

Dietary concentrations

Detailed reviews on occurrence of CoQ₁₀ and dietary intake were published in 2010.^[57] Besides the endogenous synthesis within organisms, CoQ₁₀ also is supplied to the organism by various foods. Despite the scientific community's great interest in this compound, however, a very limited number of studies have been performed to determine the contents of CoQ₁₀ in dietary components. The first reports on this aspect were published in 1959, but the sensitivity and selectivity of the analytical methods at that time did not allow reliable analyses, especially for products with low concentrations.^[57] Since then, developments in analytical chemistry have enabled a more reliable determination of CoQ₁₀ concentrations in various foods:

Meat and fish are the richest sources of dietary CoQ₁₀; levels over 50 mg/kg may be found in beef, pork, chicken heart, and chicken liver. Dairy products are much poorer sources of CoQ₁₀ compared to animal tissues. Vegetable oils also are quite rich in CoQ₁₀. Within vegetables, parsley and perilla are the richest CoQ₁₀ sources, but significant differences in their CoQ₁₀ levels may be found in the literature. Broccoli, grapes, and cauliflower are modest sources of CoQ₁₀. Most fruit and berries represent a poor to very poor source of CoQ₁₀, with the exception of avocados, which have a relatively high CoQ₁₀ content.^[57]

Intake

In the developed world, the estimated daily intake of CoQ₁₀ has been determined at 3–6 mg per day, derived primarily from meat.^[57]

Effect of heat and processing

See also

References

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