Nutraceuticals with Animal Origin
COENZYME Q 10 Typical Properties and Description
Coenzyme Q10 (CoQ10) is a vitamin-like substance that is present in the majority of human cells. CoQ10 is biosynthesized in the human body from tyrosine or pheny-lalanine and mevalonate [Schultz and Clarke 1999]. CoQ10 transports electrons in the oxidation-reduction reaction that drives the adenosine triphosphate (ATP) synthesis in mitochondria. In addition, CoQ10 provides stability, fl uidity, and regulates apoptosis in cell membranes [Lenaz et al. 1999; López-Lluch et al. 1999]. Despite that CoQ10 is syn-thesized in humans, supplementation of CoQ10 may be necessary in populations having CoQ10 defi ciency. The defi ciency of CoQ10 is linked to aging, certain type of diseases, genetic mutations, and 3-hydroxy-3-methyl-glutaryl (HMG)-CoA reductase inhibitors [Crane 2001]. CoQ10 is present in common dietary consumptions of meat, fi sh, veg-etables, and fruits [Lester and Crane 1959; Weber, Bysted, and Holmer 1997].
Structural Formula
See Figure 4.10 for the structural formula.
Functional Category
CoQ10 is benzoquinone with a long isoprenoid side chain (10 units). This side chain makes the molecule highly lipophilic, which is readily diffusible across the
Figure 4.10 The structure of CoQ10. H3CO
H3CO
O
H
O
10
membranes. During the electron transport, CoQ10 is reduced to ubisemiquinone and ubiquinol by accepting one and two electrons, respectively.
Applications in Nutraceuticals
In a randomized, double-blind study, 22 aerobically trained and 19 untrained human subjects were supplemented with placebo or CoQ10 supplement. The results from this study suggest that acute (single dose) and/or chronic (14 days) supple-mentation of CoQ10 may enhance the exercise performance in both the trained and untrained subjects [Cooke et al. 2008].
In an 11.5-year-old patient suffering from mitochondrial myopathy, it was observed that CoQ10 concentration in the skeletal muscle decreased to 46% of nor-mal average [Lalani et al. 2005]. The supplementation of CoQ10 resulted in complete recovery of myopathy. Furthermore, muscle biopsy specimens of 82 children showed CoQ10 defi ciency to be the best indicator for electron transport chain abnormality.
Therefore, the early identifi cation of CoQ10 defi ciencies in children and supplementa-tion of this agent may cure certain mitochondrial disorders [Miles et al. 2008].
In a randomized, double-blind, placebo-controlled trial involving 42 patients, it was observed that supplementation of CoQ10 (three times at 100 mg/day) reduced headache frequency and nausea [Sandor et al. 2005]. In another study, Hershey et al.
[2007] assessed CoQ10 levels in patients suffering from severe headaches. About 32.9%
of 1,550 patients were below the reference range of CoQ10 levels. The CoQ10-defi cient patients were suggested to intake 1–3 mg/kg/day CoQ10. In a subset of patients, sup-plementation with CoQ10 has resulted in improved CoQ10 levels, decreased headache frequency and disability, implying the potential application of CoQ10 for migraine.
In a multicenter, randomized, parallel-group, placebo-controlled, double-blind study, patients with Parkinson’s disease were supplemented with placebo or CoQ10 at 300, 600, or 1200 mg/day. In this study, it was observed that CoQ10 supplementa-tion is safe even at 1,200 mg/d, and the benefi cial effects were observed in a dose-dependent manner [Shults et al. 2002].
It is observed that dietary supplementation of 0.07–0.7% CoQ10 for 26 weeks in a rat model of metabolic syndrome had a benefi cial effect on increased oxidative and nitrative stress markers and infl ammatory markers. In addition, CoQ10 has reduced elevated blood pressure and serum levels, implying that CoQ10 may have a benefi cial effect in cardiovascular diseases in metabolic syndrome [Kunitomo et al. 2008].
Stability and Storage Conditions
CoQ10 should be stored at room temperature under atmosphere-, light-, and mois-ture-free conditions.
Interactions
HMG-CoA reductase inhibitors or statins are primarily used to treat hypercholesterolemia. It is evident that HMG-CoA reductase inhibitor reduces blood
CoQ10 concentrations. This is probably because CoQ10 and cholesterol share a similar biosynthetic pathway. In a mice model, it was shown that supplementation of CoQ10 during statin therapy reduces the oxidative stress caused by statin administration [Kettawan et al. 2007]. However, at this point in time, the coadministration of CoQ10 and statin to prevent myotoxicity remains questionable [Levy and Kohlhaas 2006].
There is an increasing amount of evidence showing that CoQ10 affects warfarin metabolism [Landbo and Almdal 1998]. Structurally CoQ10 is similar to vitamin K, which may explain its interaction with warfarin [Landbo and Almdal 1998]. It is spec-ulated that concurrent administration of CoQ10 (100 mg) and warfarin would increase the total clearance of S-warfarin and R-warfarin by 32 and 17%, respectively [Zhou, Zhou, and Chan 2005]. Therefore, patients using this combination of medication must be kept under close medical supervision.
Method of Manufacture
CoQ10 is available in the market in the form of soft-gel capsules, tablets, and powder.
Safety
According to the OSL risk assessment method, CoQ10 is considered to be safe at intake of up to 1,200 mg/day. In fact, much higher levels of CoQ10 have been tested, but the data are not suffi cient enough to provide a reasonable assurance of safety [Hathcock and Shao 2006].
Handling Precautions
CoQ10 should be handled at room temperature under inert conditions, away from light.
Regulatory Status
In the United States, CoQ10 holds GRAS status and is regulated as a dietary sup-plement. In the United Kingdom, CoQ10 is regulated as a dietary or food supplement.
Japan approved CoQ10 in 1974 as a prescription drug for the treatment of congestive heart failure [Tran et al. 2001].
Related Substances
Coenzyme Q is closely related to other quinones such as vitamin K, plastoquinone (present only in plants), and menaquinone (present only in bacteria). Plastoquinone and menaquinone play the equivalent role of ubiquinone, i.e., they transport elec-trons in oxidation-reduction reactions.
CONCLUSION
See Table 4.1 for details and an overview of what this chapter has discussed regarding nutraceuticals obtained from animal origin.
Table 4.1 Nomenclature, Chemical Abstracts Service (CAS) Number, and Empirical Formula or Molecular Formula of Nutraceuticals Obtained from Animal Origin
Category Synonyms Chemical Name CAS no.
Empirical Formula or
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