Coenzyme Q10

Synonym(s): CoQ10, Q10, ubiquinol, ubiquinone
Nutrient group: vitaminoids

Sources and physiological effects

Dietary sources 
Coenzyme Q10 is a fat-soluble, endogenous substance that is supplied via the diet and can also be produced by the human body itself. In the course of physiological changes, the endogenous synthesis rate may be limited or physiological needs may be increased, requiring additional exogenous supply. About 5 – 10 mg coenzyme Q10 are supplied through the daily diet. Although the fat-soluble substance can be found in many foods, the concentration in foods is usually low. The best sources of coenzyme Q10 are meat and certain fish (e.g. sardines, mackerels), wheat germ, soybeans, walnuts and almonds
Physiological effects
Energy metabolism
  • Essential for the electron transfer of the mitochondrial respiratory chain for energy production (ATP)
Antioxidant
  • Participation as redox partner in antioxidative processes
  • Reduction of lipid peroxidation and increase of oxidation resistance of lipids such as LDL cholesterol
Cell membranes
  • Stabilization of cell membranes by controlling ion channels
  • Increase of membrane fluidity and vitality
Immune system
  • Increase in phagocytosis activity of macrophages and stimulation of granulocyte proliferation

Recommended intake

Increased need
Persons over 40 years, low-fat diet, weight  reduction diets, bronchial asthma, burnout, chronic fatigue syndrome, diabetes mellitus, fibromyalgia, cardiovascular diseases, statin therapy, migraine, Alzheimer's disease, Parkinson's disease, malabsorption due to disorders of bile function and gastrointestinal disorders
Special groups at risk of deficiency
Seniors, persons under statin therapy, competitive athletes, smokers
Safety of ubiquinone:
Observed safe level (OSL): 1200 mg/d
Kaneka® Ubiquinon 900 mg/d was classified as safe and harmless in healthy individuals.
Kaneka® Ubiquinon 900 mg/d was classified as safe and harmless in healthy individuals.  
Safety of ubiquinol:
300 mg/d per day were declared safe and harmless in a study.

Detailed information

The physiological significance of coenzyme Q10

Coenzyme Q10 (ubiquinone) is a substance similar to vitamin E in the body. Its tasks are in two main areas: electron transfer in the mitochondrial respiratory chain and participation as a redox partner in antioxidative processes. Coenzyme Q10 is therefore involved in ATP synthesis is fundamental for the generation of energy in the cells. Suboptimal processes in the citrate cycle of the mitochondria lead to an insufficient supply of biochemical forms of energy, which manifest themselves symptomatically in the tissues and at the organ level. The skeletal muscles and the heart muscle are primarily affected (1). Coenzyme Q10 contributes to strengthening the immune defense, promotes the integrity and stabilization of cell membranes and prevents induced ageing processes of the cell organs through the central tasks of antioxidative protection of biological membranes. 
 

Coenzyme Q10 – a conditionally essential nutrient

Coenzyme Q10 is an endogenous substance that can be synthesized by the human body itself and is also supplied by the diet. Coenzyme Q10 is not considered as an essential nutrient in healthy people. However, in altered physiological states, where the synthesis rate is limited or the need is increased, an exogenous supply may be necessary. Coenzyme Q10 is therefore classified as a conditionally essential nutrient (2), the supplementation of which is necessary in the case of certain diseases and increased demand. These include heart disease, diabetes mellitus, neurodegenerative diseases, cancer, ageing processes, competitive sports and increased oxidative stress (3). 
 

Ubiquinone - Ubiquinol

Coenzyme Q10 exists in two biochemical forms, ubiquinone and reduced ubiquinol. Both compounds are ingested with food and both exist in the body. The reduced (non-oxidized) ubiquinol is the more active form of coenzyme Q10 than ubiquinone, which has to be converted into the active form of ubiquinol in the body via several enzymatic steps. This process is influenced by selenium and zinc status and can be restricted with increasing age or in the case of disease. 
 

Increased bioavailability and mitochondrial performance of ubiquinol

Ubiquinol has two additional hydrogen groups compared to ubiquinone, which increases the polarity of the benzoquinone ring. This fact could be responsible for the observed superior bioavailability of ubiquinol. In a study with Biogena coenzyme Q10 active Gold Ubiquinol, the active reduced form showed a greatly improved uptake rate. After just one month, the Q10 plasma levels of participants supplemented with 50 mg/d ubiquinol were almost twice as high as those of participants receiving 120 mg/d ubiquinone (4). The results of the performance tests showed that the higher plasma values also lead to a better mitochondrial performance and an increased energy supply. Here, too, the ubiquinol group was far superior to the ubiquinone group in all parameters (5). Further studies show that in cardiac patients who do not respond sufficiently to ubiquinone supplementation and show unsatisfactory clinical improvements, supplementation with active ubiquinol can achieve both a significant increase in plasma levels as well as an increase in heart function and a favorable clinical result (5). 
 

Statin induced coenzyme Q10 depletion

Coenzyme Q10 is particularly important in the treatment of statin-induced side effects. The cholesterol-lowering statins inhibit the biosynthesis of mevalonic acid from 3-hydroxy-3-methylglutaryl-coenzyme-A and therefore interrupt the biosynthesis of cholesterol produced from mevalonic acid. Since mevalonic acid is also essential for endogenous coenzyme Q10 synthesis, this process also leads to a reduced endogenous supply of coenzyme Q10 (6). In clinical studies and therapeutic practice, many patients taking statins or HMG-CoA reductase inhibitors (e.g. Simvastin, Lovastin, Pravastin) experience a significant decrease in coenzyme Q10 plasma levels (<12 µg/ml) (7). Treatment with atorvastatin, for example, reduced coenzyme Q10 levels in patients from 0.81 (+/- 0.21) to 0.46 (+/- 0.10) µg/ml (8). The importance of coenzyme Q10 for mitochondrial energy metabolism suggests that the impairment of coenzyme Q10 status probably plays a decisive role in the development of statin-induced side effects. These include myalgia and myopathies such as muscle pain, muscle fatigue or reduced muscle performance as well as increased occurrence of ligament injuries and the tendency to cramps and inflammation of the tendons. Since coenzyme Q10 is essential for the formation of ATP in the mitochondrial respiratory chain, Q10 depletion may lead to performance disorders of skeletal and cardiac muscles (9). In a clinical study, a 40 % reduction in muscle pain was achieved after 30 days of daily supplementation with100 mg coenzyme Q10 (10).
 

Heart function, cardiological diseases and blood pressure

Coenzyme Q10 is essential for the energy metabolism of the heart muscle. In cardiological diseases such as heart failure and ischemic heart diseases, Q10 levels in the heart muscle are significantly lower. This energetic depletion of tissue can be counteracted by regular daily supplementof 60 – 500 mg Q10 (11). Coenzyme Q10 is generally recommended as an adjuvant in chronic heart disease. Clinical studies show that 60 – 75 % of patients treated with coenzyme Q10 experienced a significant improvement in performance. A significant increase in life expectancy was observed in patients with heart failure (12). Supplementation with coenzyme Q10 in this indication framework is now a clinical standard in many countries and is recommended as a safe and well-tolerated adjuvant measure (13). A meta-analysis confirms the potential of coenzyme Q10 as an effective treatment for hypertension without side effects. Both systolic and diastolic blood pressure have been significantly reduced by Q10 supplementation (14). 
 

Protection against atherosclerotic changes and statin-related myopathies

Due to its strong antioxidant properties, coenzyme Q10 is an important substance in the prevention and treatment of arteriosclerosis. After a myocardial infarction, Q10 supplementations demonstrates a significant reduction in reactive free radicals and thus a reduction in the risk of further atherothrombosis (15)(7)(16)(17).
 

Coenzyme Q10 in migraine prevention and tinnitus treatment

The use of coenzyme Q10 in migraine represents a new therapeutic field. Clinical studies suggest that coenzyme Q10 status in pediatric and adult migraine patients is below normal levels. Supplementation with 1 - 3 mg coenzyme Q10/kg body weight leads to a significant reduction in migraine frequency and intensity (19). This is confirmed by earlier studies, which have observed a reduction in migraine attacks of over 50% with coenzyme Q10 substitution of 150 mg/day over 3 months (19). There is also initial evidence of a possible therapeutic use of coenzyme Q10 in tinnitus aurium. A subgroup of subjects who had previously been found to have a reduced coenzyme Q10 status had significant improvements in tinnitus symptoms after Q10 supplementation (20). 
 

Aging processes and performance

With increasing age, the Q10 concentration in various tissues decreases significantly due to limited self-synthesis. The heart is primarily affected, but also the musculature. Since reduced ATP synthesis and the resulting reduced energy production seem to be responsible for the generally declining performance of the human body, it is assumed that the maintenance of coenzyme Q10 concentrations can counteract an age-related drop in performance and aging processes in general. In addition to improvements in ATP synthesis and antioxidant action, this is achieved by regulation of gene expression, which is responsible for the age-related change in the number and length of muscle fibers (21). In addition, coenzyme Q10 can slow the diminishing adaptation of aging tissue to stress and maintain an adequate response to stressors. This has been demonstrated in clinical studies for the heart tissue and other organs (22).
 

Coenzyme Q10 in idiopathic infertility

A number of studies have shown that supplementation with ubiquinol significantly increases sperm count and mobility. In a double-blind, placebo-controlled study, 228 men with idiopathic infertility, i.e. infertility without known cause, were given 200 mg ubiquinol per day or one placebo for 26 weeks. The subsequent examination showed that the quality of semen fluid in the intervention group had improved significantly, both in terms of increasing sperm density and improving sperm motility and sperm morphology (23). Another study investigated the effect of coenzyme Q10 administration on the partner's pregnancy rate. 287 men with idiopathic infertility were given 300 mg coenzyme Q10 twice daily for 12 months. The results were promising: both sperm concentration and sperm mobility improved significantly. After completion of supplementation, and a further 12 months of follow-up a significant increase (34.1%) in the partner's pregnancy rate was observed. Q10 administration improved semen quality with a positive effect on the pregnancy rate in this study (24).
 

Coenzyme Q10 – therapeutic use for periodontopathies

Various clinical studies in patients with periodontitis and gingivitis confirm a reduction in the coenzyme Q10 content and thus an energy impoverishment of the affected tooth tissue (25). Oral supplementation and topical application with a Q10 oral spray show significant improvements in inflammatory processes, bleeding, periodontal pocket depth and tooth mobility after 6 weeks of treatment. 
 

Complementary use in oncology

Lower coenzyme Q10 levels can often be observed in cancer patients. Studies show that tumor patients can benefit from Q10 supplements. In a case study, 84 patients with breast cancer and elevated tumor markers received tamoxifen and coenzyme Q10, niacin and riboflavin, with a significant decrease in tumor markers (23). In a 9-year pilot study of 41 end-stage cancer patients, oral treatment with Q10 and an antioxidant mix improved their chances of survival, 76% of patients lived longer than predicted (26).
 

Coenzyme Q10 in Chronic Fatigue Syndrome and Long COVID

Due to the symptomatic parallels of long covid syndrome to chronic fatigue syndrome (CFS), both coenzyme Q10/ubiquinol and NADH (nicotinamide adenine dinucleotide) play an essential component as part of the electron transport chain responsible for mitochondrial ATP production. CFS has been shown to show disturbances in CoQ10 and NADH levels, as well as redox status. In a study of 207 patients by Castro-Marrero et al, administration of 200 mg CoQ10 and 20 mg NADH over a 12-week period resulted in a reduction in cognitive fatigue ("brainfog") and general fatigue perception, as well as an improvement in quality of life and sleep (27).
 

Bioidentical, 100 % natural all-trans-coenzyme Q10

Coenzyme Q10 is available on the market in different qualities, which is why reputable suppliers look for a high-quality and safe sources. The Japanese company Kaneka® has been one of the world's leading coenzyme Q10 producers for 25 years and has further consolidated its position as an innovative and reliable Q10 supplier with a new, hitherto unique manufacturing process. Kaneka® coenzyme Q10 is biosynthesised by special yeast cells from which a bioidentical coenzyme Q10 can be extracted. The Kaneka® coenzyme Q10 is thus completely similar to the natural all-trans-coenzyme Q10 found in foods and is free of synthetic cis isomers. All steps of the manufacturing process meet pharmaceutical GMP standards, ensure reliable and consistent substrate quality and are certified as kosher. Kaneka® coenzyme Q10 was also tested for toxicological safety and was classified as a safe and well-tolerated substance in doses of up to 900 mg/day in healthy volunteers (28).
 

NutriGellets® technology - a new era in micronutrient production

NutriGellets® are specially produced pearls made from fish gelatine, in which the active substances are evenly stored and distributed. Even sensitive active substances such as ubiquinol are protected by the gelatine matrix and can be introduced into a transparent uncoloured capsule shell. This means that the capsules only contain ubiquinol as an active substance; auxiliary substances, colorings and preservatives can be dispensed with altogether. In addition, NutriGellets® technology optimizes the bioavailability of active substances. The natural polymer structure of gelatine ensures an even distribution of the active ingredients and an increase in surface area. The matrix dissolves in the aqueous environment and warmth of the small intestine, the active substances are then dispersed very finely and evenly. The oily substances form a stable emulsion and can be easily absorbed by the body. 

Reference values

Parameter Substrate Reference value Description
Coenzyme Q10 Blood (EDTA) Preventive:
1.0 - 1.2 mg/l
therapeutic:
> 2.5 mg/l
Competitive athlete: >3,0 mg/l
in neurodegenerative diseases:
>4.0 mg/l
Individual parameter
Coenzyme Q10 (cholesterol corrected) Blood (serum) > 0.200 Individual parameter
Nutrigenetics
Characteristic gene sites and their effects on vitamin requirements
Gene rsNumber

risk SNP

 

Recommended nutrients

TXN

rs2301241

T

Thioredoxin (TXN) plays an important role in the physiological redox system. Due to a reduced efficiency less vitamin C and coenzyme Q10 is recycled. Vitamin E as an important antioxidant can additionally compensate for adverse effects (29).

Vitamin E, Coenzyme Q10 and Vitamin C

 

Deficiency symptoms

Impact on Symptoms
General health Fatigue, weakness, chronic fatigue syndrome
Muscle Muscle weakness, muscle aches
Cardiovascular system Disturbances of cardiac bioenergetics
Endothelial Dysfunctions
Free radical-associated diseases Increased risk of Alzheimer's disease, tumors, Parkinson's disease
Mitochondrial Dysfunction Increased laboratory parameters for nitrosative stress (pyruvate/lactate, citrulline, methylmalonic acid)

Indications

Effect Indication Dosage
Physiological effects
at a low intake
For migraine prophylaxis 100 – 300 mg Ubiquinone/d or
60 mg Ubiquinol/d

To accompany statin medication
To avoid statin induced side effects, especially myopathies

100 – 300 mg Ubiquinone/d or
60 mg Ubiquinol/d
Complementary therapy for cardiological diseases such as heart failure, angina pectoris or after a myocardial infarction 100 – 500 mg Ubiquinone/d or
60 – 120 mg Ubiquinol/d
To improve antioxidant status in diabetes mellitus and to reduce risk arteriosclerotic and neurodegenerative diseases 100 – 300 mg Ubiquinone/d or
60 mg Ubiquinol/d
To maintain performance with increasing age and in competitive 100 – 300 mg Ubiquinone/d or
60 mg Ubiquinol/d
Complementary therapy for cancer 100 – 500 mg Ubiquinone/d or
60 – 120 mg Ubiquinol/d

Administration

General mode of administration
 
When
Coenzyme Q10 should be taken with meals to improve absorption.
Side effects
In rare cases gastrointestinal complaints (diarrhea, nausea) or skin irritations can occur with long-term high-dose ingestion.
Contraindications 
No contraindications are known to date. 

Interactions

Drug interactions 
Cholesterol-lowering medication
(statins)
Statins inhibit coenzyme Q10 biosynthesis, supplementation of coenzyme Q10 can significantly reduce side effects.
Anthracycline
(e.g. doxorubicin, daunorubicin) 
Increases demand for coenzyme Q10 through increased formation of free radicals, pre-administration may reduce anthracycline-induced cardiac and liver toxicity.
Parkinsons disease medication
(levodopa, methyl dopa)
Increased formation of free radicals reduces coenzyme Q10 levels, leading to respiratory chain disorders.
Anticoagulants

 

(Marcoumar®)

In vitro, the structural relationship between coenzyme Q10 and menaquinone (vitamin K2) impairs the effect of vitamin K antagonists.
Betablocker
(e.g. metoprolol, timololol)
Coenzyme Q10 supports the effectiveness of beta blockers.
Neuroleptics, tricyclic antidepressants
(e.g. phenothiazines)
Inhibition of mitochondrial coenzyme Q10–dependent enzyme systems of the respiratory chain, reduction of cardiac side effects.
Oral antidiabetics
(sulfonylureas)
Stabilization of blood sugar levels improved by coenzyme Q10 improved.
Nutrient interactions
Trace elements Selenium is essential for the conversion of ubiquinone to ubiquinol.
Amino acids Coenzyme Q10 improves the effect of L-carnitine.
Vitamins Vitamin E is regenerated by coenzyme Q10 (vitamin E saving effect).

Description and related substances

Description
Fat-soluble endogenous substance
Related Substances 

ubiquinone and ubiquinol

 

References

References

1) Haller, R. G. 2012. Metabolic and Mitochondrial Myopathies. Muscle: 1031–1041. doi:10.1016/b978-0-12-381510-1.00075-2.
2) Kendler, B. S. 2006. Supplemental Conditionally Essential Nutrients in Cardiovascular Disease Therapy. The Journal of Cardiovascular Nursing 21, Nr. 1: 9–16. doi:10.1097/00005082-200601000-00004. 
3) Dhanasekaran, M. 2005. The Emerging Role of Coenzyme Q-10 in Aging, Neurodegeneration, Cardiovascular Disease, Cancer and Diabetes Mellitus. Current Neurovascular Research 2, Nr.5 (January):447–459. doi:10.2174/156720205774962656. 
4) Sinnißbichler, T. 2010. Ubiquinon und Ubiquinol im Vergleich Leistungssteigerung durch verschiedene Coenzym Q 10-Formen und Q10- Applikationen. Biogena Inside. 
5) Langsjoen, P. H. 2008. Supplemental ubiquinol in patients with advanced congestive heart failure. BioFactors 32, Nr. 1-4: 119–128. doi:10.1002/biof.5520320114. 
6) Gröber, U. 2006. statininduzierte Coenzym Q10 Depletion. OM Zs.f.Orthomol.Med. 2:35-36. 
7) Levy, H. B. et al. 2006. Considerations for Supplementing with Coenzyme Q10 During Statin Therapy. Annals of Pharmacotherapy 40, Nr. 2: 290–294. doi:10.1345/aph.1g409. 
8) Mabuchi, H. et al. 2005. Reduction of Serum Ubiquinol-10 and Ubiquinone-10 Levels by Atorvastatin in Hypercholesterolemic Patients. Journal of Atherosclerosis and Thrombosis 12, Nr. 2: 111–119. doi:10.5551/jat.12.111. 
9) Anon. 2015. Coenzyme Q10 and statin-related myopathy. Drug and Therapeutics Bulletin 53, Nr. 5: 54–56. doi:10.1136/dtb.2015.5.0325. 
10) Howard, W. 2008. Effect of Coenzyme Q10 on Myopathic Symptoms in Patients Treated With Statins. Yearbook of Medicine 2008: 512–513. doi:10.1016/s0084-3873(08)79288-5. 
11) Gröber, U. 2005. Coenzym Q10. OM Zs f Orthomol Med. 3:23-44 
12) Diet, H. et al. 2003. Handbuch der Orthomolekularen Medizin. Prävention und Therapie durch körpereigene Substanzen. 
13) Tran, M. et al. 2001. Role of Coenzyme Q10in Chronic Heart Failure, Angina, and Hypertension. Pharmacotherapy 21, Nr.7:797–806. doi:10.1592/phco.21.9.797.34564. 
14) Rosenfeldt, F. L. et al. 2007. Coenzyme Q10 in the treatment of hypertension: a meta-analysis of the clinical trials. Journal of Human Hypertension (August). doi:10.1038/sj.jhh.1002138. 
15) Singh, R. B. et al. 2003. Effect of coenzyme Q10 on risk of atherosclerosis in patients with recent myocardial infarction. Vascular Biochemistry: 75–82. doi:10.1007/978-1-4615-0298-2_11. 
16) Lamperti, C. et al. 2005. Muscle Coenzyme Q10 Level in Statin-Related Myopathy. Archives of Neurology 62, Nr. 11 (January): 1709. doi:10.1001/archneur.62.11.1709. 
17) Gröber, U. 2006. Statin- induzierte Coenzym Q10-Depletion. OM Zs f Orthomol Med. 2:35-6. 
18) Hershey, A. D. et al. 2007. Coenzyme Q10 Deficiency and Response to Supplementation in Pediatric and Adolescent Migraine. Headache: The Journal of Head and Face Pain 47, Nr. 1. doi:10.1111/j.1526-4610.2007.00652.x. 
19) Shoeibi, A. et al. 2016. Effectiveness of coenzyme Q10 in prophylactic treatment of migraine headache: an open-label, add-on, controlled trial. Acta Neurologica Belgica. doi:10.1007/s13760-016-0697-z. 
20) Balough, B. 2008. A pilot clinical trial of the effects of coenzyme Q10 on chronic tinnitus aurium. Yearbook of Otolaryngology-Head and Neck Surgery 2008: 33. doi:10.1016/s1041-892x(08)79252-7. 
21) Linnane, A. W. et al. 2002. Human Aging and Global Function of Coenzyme Q10. Annals of the New York Academy of Sciences 959, Nr. 1: 396–411. doi:10.1111/j.1749-6632.2002.tb02110.x. 
22) Rosenfeldt, F. et al. 2004. Response of the Senescent Heart to Stress: Clinical Therapeutic Strategies and Quest for Mitochondrial Predictors of Biological Age. Annals of the New York Academy of Sciences 1019, Nr. 1: 78–84. doi:10.1196/annals.1297.016. 
23) Gaby, A. R. 2013. Re: Effects of the Reduced Form of Coenzyme Q10 (Ubiquinol) on Semen Parameters in Men with Idiopathic Infertility: A Double-Blind, Placebo Controlled, Randomized Study. The Journal of Urology 190, Nr. 1: 364–366. doi:10.1016/j.juro.2013.01.086. 
24) Safarinejad, M. R. 2011. The effect of coenzyme Q10 supplementation on partner pregnancy rate in infertile men with idiopathic oligoasthenoteratozoospermia: an open-label prospective study. International Urology and Nephrology 44, Nr.3:689–700. doi:10.1007/s11255-011-0081-0. 
25) Mcree, J. T. et al. 1993. Therapy with Coenzyme Q10 for Patients with Periodontal Disease. 1. Effect of Coenzyme Q10 on Subgingival Microorganisms. Journal Of Dental Health 43, Nr.5:659–666. doi:10.5834/jdh.43.659. 
26) Hertz, N. et al. 2009. Improved Survival in Patients with End-Stage Cancer Treated with Coenzyme Q10 and other Antioxidants: A Pilot Study. Journal of International Medical Research 37, Nr.6:1961–1971. doi:10.1177/147323000903700634. 
27) Castro-Marrero, J. et al. 2021. Effect of Dietary Coenzyme Q10 Plus NADH Supplementation on Fatigue Perception and Health-Related Quality of Life in Individuals with Myalgic Encephalomyelitis/Chronic Fatigue Syndrome: A Prospective, Randomized, Double-Blind, Placebo-Controlled Trial.  Nutrients. 13(8): 2658.
28) Ikematsu, H. et al. 2006. Safety assessment of coenzyme Q10 (Kaneka Q10) in healthy subjects: A double-blind, randomized, placebo-controlled trial. Regulatory Toxicology and Pharmacology 44, Nr.3:212–218. doi:10.1016/j.yrtph.2005.12.002.
29) Mansego M. L., et al. 2015. The nutrigenetic influence of the interaction between dietary vitamin E and TXN and COMT gene polymorphisms on waist circumference: a case control study. J Transl Med. 13:286. 

References Interactions
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Gröber, U. Mikronährstoffe: Metabolic Tuning –Prävention –Therapie, 3. Auflage. Stuttgart: WVG Wissenschaftliche Verlagsgesellschaft Stuttgart, 2011. 
Gröber, U. Arzneimittel und Mikronährstoffe: Medikationsorientierte Supplementierung, 3. aktualisierte und erweiterte Auflage. Stuttgart: WVG Wissenschaftliche Verlagsgesellschaft Stuttgart, 2014.

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