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Brazilian Journal of Pharmaceutical Sciences

versão On-line ISSN 2175-9790

Braz. J. Pharm. Sci. vol.45 no.4 São Paulo out./dez. 2009 



Coenzyme Q10 and its effects in the treatment of neurodegenerative diseases



Graciela Cristina dos SantosI; Lusânia Maria Greggi AntunesII, *; Antonio Cardozo dos SantosII; Maria de Lourdes Pires BianchiII

IDepartment of Food and Nutrition, Faculty of Pharmaceutical Sciences of Araraquara, State University "Júlio de Mesquita Filho"
IIDepartment of Clinical, Toxicological and Bromatological Analysis, Faculty of Pharmaceutical Sciences of Ribeirão Preto, University of São Paulo




According to clinical and pre-clinical studies, oxidative stress and its consequences may be the cause or, at least, a contributing factor, to a large number of neurodegenerative diseases. These diseases include common and debilitating disorders, characterized by progressive and irreversible loss of neurons in specific regions of the brain. The most common neurodegenerative diseases are Parkinson's disease, Huntington's disease, Alzheimer's disease and amyotrophic lateral sclerosis. Coenzyme Q10 (CoQ10) has been extensively studied since its discovery in 1957. It is a component of the electron transportation chain and participates in aerobic cellular respiration, generating energy in the form of adenosine triphosphate (ATP). The property of CoQ10 to act as an antioxidant or a pro-oxidant, suggests that it also plays an important role in the modulation of redox cellular status under physiological and pathological conditions, also performing a role in the ageing process. In several animal models of neurodegenerative diseases, CoQ10 has shown beneficial effects in reducing disease progression. However, further studies are needed to assess the outcome and effectiveness of CoQ10 before exposing patients to unnecessary health risks at significant costs.

Uniterms: Coenzyme Q10. Antioxidant. Oxidative stress. Neurodegenerative diseases.


De acordo com estudos clínicos e pré-clínicos, o estresse oxidativo e suas conseqüências podem ser a causa, ou, no mínimo, o fator que contribui para grande número de doenças degenerativas. Estas doenças incluem problemas comuns e debilitantes, caracterizados por perda progressiva e irreversível de neurônios em regiões específicas do cérebro. As doenças degenerativas mais comuns são doença de Parkinson, de Hutington, de Alzheimer e esclerose amiotrófica lateral. A Coenzima Q10 (CoQ10) tem sido intensamente estudada desde sua descoberta, em 1957. É um componente da cadeia de transporte eletrônico e participa da respiração aeróbica celular, gerando energia na forma de trifosfato de adenosina (ATP). A propriedade da CoQ10 de atuar como antioxidante ou pró-oxidante sugere papel importante na modulação do estado redox celular sob condições fisiológicas e patológicas, desempenhando, também, papel no processo de envelhecimento. Em vários modelos animais de doenças neurodegenerativas, a CoQ10 mostrou efeitos benéficos na redução do curso da doença. Entretanto, há necessidade de estudos adicionais para avaliar o efeito e a eficácia da CoQ10 antes de expor os pacientes a riscos de saúde desnecessários e de alto custo.

Unitermos: Coenzima Q10. Antioxidante. Estresse oxidativo. Doenças neurodegenerativas.




The Coenzyme Q10 (2,3-dimethoxy-5-methyl-6-decaprenil-1,4-benzoquinone) is a liposoluble substance also known as CoQ10, vitamin Q10, ubidecarenone or ubiquinone (Figure 1) (Bonakdar, Guarneri, 2005 ; Schoepp, 1999; Pepping, 1999). It can be obtained from the diet or supplements, but is also produced endogenously. It is found mainly in the mitochondria, the cellular organelles for energy production.



Meat, poultry and fish are the richest sources of CoQ10, and the daily intake of these foods provides between 2 to 20 mg, which does not significantly increase the levels of CoQ10 in blood and tissues. Small amounts are found in cereals, soybeans, nuts and vegetables, particularly spinach and broccoli (Kitano et al., 2006, Mason, 2005). The absorption of CoQ10 from the diet (or supplements) occurs in the small intestine and is influenced by the presence of food and beverages. It is better absorbed in the presence of foods rich in lipids. After being absorbed, the CoQ10 is transported to the liver where it is incorporated into lipoproteins and concentrated in tissues (Mason, 2005).

CoQ10 is produced from tyrosine in all cells of the body, but especially in the heart, liver, kidney and pancreas, where it begins its essential role in intracellular energy production. As all cellular activities depend on energy, CoQ10 is essential for the health of all organs and tissues (Ernster, Dallner, 1995). Several cofactors are involved in its synthesis, including vitamin B2, vitamin B6, folic acid, vitamin B12, niacin, panthotenic acid and vitamin C (Figure 2). The concentration of CoQ10 in human tissues reaches its peak at the age of twenty years, after which it progressively decreases.

CoQ10 can be found in most living organisms, and since its discovery in 1957 by Crane et al. and the identification of its chemical structure by Folkers et al. in 1958, it has been extensively studied for its key role in cellular energy production - it is involved in the transport of electrons and protons and in the synthesis of ATP in the mitochondrial membrane - and acts as an antioxidant scavenger of free radicals (Kitano et al. , 2006; Shinde, Patil, Tendolkar, 2005, Hughes et al., 2002, Nohl et al., 2001).

Because CoQ10 is not classified as a vitamin or mineral, no dietary reference value or established daily recommended levels are available. However, some signs and symptoms are associated with a lack of CoQ10, such as congestive heart failure, ischemic heart disease, cardiomyopathy, hypertension, hyperthyroidism and breast cancer (Quinzii, DiMauro, Hirano, 2007ª). However, it is unclear whether the lack of CoQ10 contributes to the development of these diseases or is caused by the diseases.

The deficiency may occur as a result of low ingestion or inadequate production caused by aging or due to deficiency of the nutrients needed for its synthesis. Genetic or acquired defects in its synthesis or metabolism, and interactions with medications such as beta-blockers, hydrochlorothiazide, methyldopa, statin and tricyclic antidepressants may also reduce levels of CoQ10 (Quinzii, Hirano, DiMauro, 2007b).

Coenzyme Q10 and aging

The property of CoQ10 to act both as a pro-oxidant and an antioxidant suggests that it may also be a modulator of cellular redox state under physiological or pathological conditions, and particularly, could play a role in the aging process (Sohal, Forster, 2007). During aging, pro-oxidant changes in cellular redox status take place, with a consequent increase of oxidative damage in molecules (Sohal, Mockett, Orr, 2002). This hypothesis refers to the imbalance between the generation of pro-oxidant and antioxidant defense, and the level of oxidative stress that increases during aging; the mitochondria play a critical role in this homeostatic disturbance (Sohal, Dubey, 1994). The elevation of the stress or oxidative damage due to increased production of O2.-/H2O2, and the decline in mitochondrial ability to synthesize ATP, reduces the functional capacity of several physiological systems (Sohal, Forster, 2007).

There is a hypothesis that CoQ10 is involved in these age-related changes because it is a carrier of electrons and is, therefore, involved in the oxidative phosphorylation system as a generator and sequester of reactive oxygen species (ROS).

The results of several studies in the literature on age-related changes in levels of CoQ10 do not support the existence of a common trend. Kalen, Appelkvist and Dallner (1989) reported loss in CoQ10 content (related to age) in human tissue homogenates. Beyer et al. (1985) studied age-related changes in the levels of CoQ10 in several tissues and found no differences in homogenates of brain and lung of rats. However, there was an increase in the liver and a decrease in heart, kidney and skeletal muscles. The differences between the studies may be due to age of animals or the procedures used for extraction and quantification of CoQ10, or, differences between species, lines or diets.

Matthews et al. (1998a) showed that the intake of CoQ10 by rats with twelve or twenty-four months of age increased its content in brain mitochondria and had a neuroprotective effect against acid 3-nitropropionic (3-NPA). Several studies in young rats have shown that administration of CoQ10 by feeding caused an increase in the quantity of CoQ10 in plasma and homogenates and mitochondria of liver, heart and skeletal muscle (Kwong et al., 2002; Kamzalov et al., 2003; Rebrin, Sohal, 2004).

Antioxidant role of Coenzyme Q10

The mitochondrial inner membrane contains CoQ10 and α-tocopherol, both possessing antioxidant properties. This raises questions on their respective roles in the sequestration of free radicals generated in the mitochondrial inner membrane. In solution, CoQ10 has been shown to inhibit lipid peroxidation in mitochondrial membrane depleted of α-tocopherol (Mellors, Tappell, 1966; Takayanagi et al., 1980). Current evidence suggests that α-tocopherol and ubiquinol act in combination to scavenge free radicals during auto oxidation of mitochondrial membrane (Stoyanovsky et al., 1995; Lass, Sohal, 1998; Sohal, 2004). The reduced form of CoQ10 is able to scavenge free radicals that can cause damage to DNA, proteins and lipids, as well as causing cardiovascular disease, and neurodegenerative diseases such as Alzheimer and Parkinson.

The intake of CoQ10 in the long term over a period spanning 3.5 to 25 months, had no effect on activities of main antioxidant enzymes such as catalase, glutathione peroxidase and superoxide dismutase in the liver, kidney, skeletal muscle or brain (Sohal, Forster, 2007).

The endogenous antioxidants are important to maintain the normal activities of cells and systems of the body. However, when exposed to alcohol, drugs, trauma, cold, infections, toxins, radiation, diet low in nutrients, or vigorous physical activity, the endogenous antioxidant defense cannot neutralize the oxidative stress, requiring supplementation of antioxidants from the diet (Kaliora, Dedoussis, Schmidt, 2006).

The mitochondrion is where most free radicals are produced in the cell. A small percentage of mitochondrial oxygen consumption results in the production of hydrogen peroxide (Somayajulu et al., 2005). Reactive oxygen species produced as subproducts of the mitochondrial electron transport chain are suppressed by antioxidants and converted into non-toxic compounds by enzyme scavengers of free radicals (Beal, 1999a; Sanders et al., 1993). However, accumulation of free radicals in tissues can result in dysfunction and cell death. Excessive cell death is a feature of many neurological disorders including stroke, ischemia, Parkinson's and Alzheimer's diseases.

Previous studies have indicated that neuronal cells are highly sensitive to reactive oxygen species such as free radicals (Kim, Won, Gwag, 2002). There is a hypothesis that mitochondrial dysfunction and the consequent production of ROS can induce the neuronal cell death that occurs in neurodegenerative diseases (Somayajulu et al., 2005; Kitazawa, Ananth, Kanthasamy, 2003; Christen, 2000; Behl, 1999; Piantadosi, Zhang , 1996; Coyle, Puttafarcken, 1993). Somayajulu et al. (2005) demonstrated that CoQ10 protects the cells from apoptosis, both morphologically and biochemically. The first evidence that CoQ10 can exert neuroprotective effects in the central nervous system in vivo was reported in 1994 by Beal et al.

Coenzyme Q10 and the Central Nervous System

The brain needs high energy and oxygen consumption (Floyd, 1999). As a result, it is also replete with readily oxidized amino acids and unsaturated fatty acids, with the easy production of free radicals (Murata, Ohtsuki, Terayama, 2008). This makes the brain vulnerable to oxidative damage, and several recent articles suggest that oxidative stress plays a major role in the onset of neurodegenerative diseases related to aging.

The key role of CoQ10 in oxidative phosphorylation emphasizes its importance in the metabolism of neurons, given the constant and high energy demand of these cells. The nervous system is exposed to oxidative stress, and this may emphasize the role of CoQ10 in the central nervous system (Littarru, 2006). From clinical and pre-clinical studies, it is clear that oxidative stress and its consequences - oxidative damage in lipids, proteins, nucleic acids, - may be the cause, or at least a contributory factor, of a large number of neurodegenerative diseases (Coyle, Puttfarken, 1993; Beal, 2005).

The neurodegenerative diseases include common and debilitating disorders, and are characterized by progressive and irreversible loss of neurons in specific regions of the brain. The most common neurodegenerative disorders are Parkinson's disease and Huntington´s disease, where the loss of neurons in the basal ganglia structures results in changes in the control of movement; Alzheimer's disease, in which the loss of neurons in the hippocampus and the cortex leads to deficiency in memory and cognitive capacity; and amyotrophic lateral sclerosis, in which muscle weakness results from the degeneration of motor, bulbar and cortical neurons (Littarru, 2006).

In several animal models of neurodegenerative diseases including amyotrophic lateral sclerosis, Huntington's disease and Parkinson's disease, CoQ10 has a beneficial effect, reducing the progression of disease (Shults et al., 2002; Kwong et al., 2002; Ferrante et al., 2002; Somayajulu et al., 2005).

Beal et al. (1994) injected malonic acid in striatum of laboratory animals, and found that this procedure induced depletion of ATP and an increase in lactic acid. The administration of CoQ10 in animals was able to mitigate the depletion of ATP induced by malonate while minimizing the increase in concentrations of lactate.

Beal and Matthews (1997a) also examined whether CoQ10 can exert antioxidant effects in brain tissue. They demonstrated that oral supplementation with CoQ10 (200 mg/kg/day) for one month significantly protected against the increase in the 2.5-dihydroxybenzoic acid (DHBA) induced by malonate. The DHBA is a biochemical marker for the generation of potent oxidative species such as hydroxyl radicals.

These data indicate that experimentally-induced lesion, as well as the changes caused by oxidative stress, can be neutralized by oral administration of CoQ10 in animals. It is well known that the administration of CoQ10 in young rats leads to a significant increase of CoQ10 in plasma and the liver (Beal, Matthews, 1997a, Zhang et al., 1995).

Beal et al. (1999a) found no increased concentrations of CoQ10 in the brain of young animals supplemented with CoQ10 and this could be due to saturation of the membrane by CoQ10 in animals of this age. Furthermore, we know that aging in rats and humans leads to a decrease of CoQ10 in several tissues, including the brain (Kallen, Appelkvist, Dallner, 1989; Beyer et al., 1985). Indeed, Matthews et al. (1998a) conducted a study with supplementation of CoQ10 in twelve-month-old rats and showed an increase in CoQ9 and CoQ10 in cerebral cortex. The extent of the increase (30-40%) almost restored the levels to those found in young animals.

Parkinson's disease

First described by James Parkinson in 1817, Parkinson's disease (PD) is a progressive neurological disorder characterized clinically by tremor, muscle rigidity, slowness and lack of movement and a disability of postural balance that leads to changes in gait and fall. It is one of the most common neurological conditions the cause of which remains unknown. The prevalence of PD is approximately 0.3% of the population and of these, 1% is over 60 years of age. The incidence rate is 150-200 per 100,000 persons per year, although this is increasing (de Lau, Breteler, 2006).

The main histopathological feature of PD is the selective loss of dopaminergic neurons of the substantia nigra in the central nervous system (Dawson, Dawson, 2003; Cookson, 2005). The tyrosine hydroxylase, a key enzyme for the synthesis of dopamine, is also deficient. From a biochemical point of view it is known that the activity of mitochondrial complex I is selectively reduced in the substantia nigra of PD patients (Parker, Boyson, Parks, 1998; Schapira et al., 1990). This defect can cause a "leakage" of electrons from mitochondria, leading to an accumulation of ROS (Reactive Oxygen-Derived Species) that damages proteins, lipids and nucleic acids (Jenner, 2003). Interestingly, this enzyme activity is reduced in platelets of patients with PD (Benecko, Strumper, Weiss, 1993). The brain of PD patients also shows evidence of impaired proteasomal function, a defect that results in increased oxidative stress and decreased removal of damaged polypeptides oxide (McNaught, Olanow, 2003; Halliwell, 2002; Farout, Friguet, 2006; Pope, Gomes, Rockwell, 2007).

Mitochondrial dysfunction and oxidative stress are considered important in the pathogenesis of PD. The initial hypothesis that the deficiency in mitochondrial complex I may be involved in the etiology of PD came from the discovery that the complex I mitochondrial inhibitor MPTP (1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine) causes a syndrome indistinguishable from PD and selective loss of dopaminergic cells in the substantia nigra (Langston et al., 1983).

The known position of CoQ10 in the respiratory chain, where it acts as electron acceptors for complexes I and II / III, led the researchers at the University of California, San Diego, to check the level of CoQ10 in the mitochondria of platelets isolated from patients with PD. The level of CoQ10 mitochondrial in these patients (141.8 ng/mg protein ± 11.3) was lower than in controls (216.3 ± 12.7). This difference was highly significant, and in addition, there was a significant correlation between concentrations of CoQ10 and the activities of complex I and complex II / III. It is important to emphasize that the platelets reflect certain biochemical processes that occur in the brain (Shults, Haas, Beal, 1999). Sohmiya et al. (2004) had observed some years before, a deficiency of CoQ10 in the plasma of PD patients.

In order to ascertain whether the treatment with CoQ10 could benefit patients with PD, Shults et al. (1999) first investigated whether oral administration of CoQ10 might be beneficial in a laboratory model of PD. MPTP is a chemical agent selectively toxic to dopaminergic neurons and the first to be impaired in PD. A group of one-year-old rats were treated with CoQ10 (200 mg/kg per day) and also received MPTP. The levels of dopamine in the striatum were significantly higher (37%) in the group of rats treated with CoQ10 and MPTP, compared to the group treated only with MPTP. Based on these observations, a preliminary study was conducted in fifteen PD patients supplemented with CoQ10 for a month. The complex I / citrate synthase in mitochondria isolated from platelets of patients after treatment with CoQ10 was higher than the corresponding activity before treatment, and similar to the activity found in the control group.

All these observations in laboratory animals and patients led to a study with a larger number of patients (80) to verify if CoQ10 could slow the progression of PD. This study reported that the intake of 1200 mg per day of CoQ10 for sixteen months was associated with 44% less functional decline in PD patients, including in daily activities (Shults, 2002). Another study in twenty-eight patients with PD also showed moderate improvement in symptoms with daily oral administration of 360 mg of CoQ10 (Muller et al., 2003). While these data are promising, they need to be confirmed in larger clinical trials before the use of CoQ10 can be recommended for PD, but support the idea that high levels of CoQ10 could yield therapeutic benefits.

Alzheimer's disease

Alzheimer's disease (AD) is a degenerative disease of the brain and the most common cause of dementia in the elderly, affecting approximately 200 million people worldwide and causing cognitive disabilities with gradual onset (Evans et al., 1989; Hebert et al., 2001). In general, the first clinical aspect is memory deficiency, where remote memories are preserved relatively well in the course of the disease. The patient's degree of alertness or lucidity is not affected until the disease is very advanced (Francis et al., 1999).

The pathophysiology of AD is complex and includes a defect in β-amyloid protein metabolism (Aβ), irregularities in neurotransmission, and the involvement of inflammatory, oxidative and hormonal pathways (Cutler, Sramek, 2001).

Oxidative stress, an imbalance between the formation of free radicals and the antioxidant system, plays a critical role in the pathogenesis of AD (Gary, Hsueh-Meei, 2005; Butterfield, 2004). Kawamoto et al. (2005) conducted a study involving oxidative stress and AD, and found that patients with AD compared with elderly controls, showed an increase in the production of TBARS (thiobarbituric acid reactive substances), as well as in the activities of NOS (nitric oxide synthase), SOD (superoxide dismutase) and Na / K-ATPase. However, no change was found in the basal content of cGMP (cyclic guanosine monophosphate). Thus, they concluded that there is a break in the modulation of systemic oxidative stress during aging, and that this disruption is more pronounced. As oxidative damage is involved in the etiology of neurologic complications, treatment with antioxidants has been used as a therapeutic approach in several types of neurodegenerative diseases, including AD (Ahmad et al., 2005; Ansari et al., 2004).

It has been shown that CoQ10 improves cognitive functions, regulates mitochondrial functions and facilitates the synthesis of ATP (McDonald, Sohal, Forster, 2005). CoQ10 significantly attenuates the depletion of ATP and malonate-induced increases of lactate in brain mitochondria of rats (Beal et al., 1994). Supplementation of CoQ10 in rats increased the endogenous content of CoQ10 in the brain and provided antioxidant protection against free radical generation (Kwong et al., 2002; Lenaz et al., 1999; Rauscher, Sanders, Watkins, 2001; Somayajulu et al., 2005).

Söderberg et al. (1992) found increased levels of CoQ10 in most brain regions of patients with Alzheimer's disease. A recent study by Bustus et al. (2000) found no significant difference in plasma levels of CoQ10 in patients with Alzheimer's disease and controls. According to Isharat et al. (2006), CoQ10 supplementation improves learning and memory deficits by possibly inhibiting oxidative stress, and also improves levels of ATP, being an important therapy in the treatment of AD.

Promising preliminary evidence from studies in humans suggests that supplementation with CoQ10 may reduce, but not cure, dementia in individuals with AD. Additional well-designed studies are needed to confirm these results before a recommendation can be made.

Huntington's disease

Huntington's disease (HD) is an inherited neurodegenerative disorder. It was given the name of the physician George Huntington, who described it in 1872. In 1993 the gene causing the disease was identified (Browne, Ferranti, Beal, 1999).

Huntington's disease is an autosomal dominant phenotype, with the gene called IT15 responsible for the disease, located at the short arm of chromosome 4. The mutant gene is constituted by abnormal repetitions of the sequence of nucleotides cytosine, adenosine and guanine (CAG), responsible for encoding glutamine (Beal, 1995). The number of CAG repetitions is considered normal up to thirty, while in HD the number of repetitions is usually greater than thirty-six. It has been observed that the larger number of repetitions of the trinucleotide CAG, the earlier the manifestation of the disease (Goldberg, Telenius, Hayden, 1994).

The mechanism by which mutations of this gene causes HD remains undefined, although evidence of animal models and clinical trials indicate a role of oxidative stress and impaired mitochondrial function (Kasparov et al., 2006). The gene defect may cause a slight reduction in the capacity of energy metabolism, leading to neuronal degeneration, primarily in the striatum and then in other regions of the brain (Jenkins et al., 1998). The impaired energy production leads to increased intracellular calcium and generation of free radicals, however the exact mechanism for the decreased capacity of energy in HD is unclear.

Clinically, this disease is characterized by psychiatric and behavioral disorders, cognitive dysfunction (thinking, hearing, memory) and progressive dementia. The prevalence of HD is of 3-7 per 100,000, and the annual incidence is 0.2-0.7 per 100,000 (Cardoso et al., 2006). The symptoms of the disease may appear at any stage of life, but in most cases, disease onset typically occurs between forty and fifty years of age with average survival of fifteen to twenty years (Duyao et al., 1993).

Patients with HD have elevated levels of lactate in the brain. The measurement of lactate production in the brains of HD patients done by H-MRS (Proton (H+) Magnetic Resonance Spectroscopy) has revealed that creatine, cyclocreatine, CoQ10 and nicotinamide - compounds that increase energy metabolism - could exert neuroprotective effects in this disease (Koroshetz et al., 1997; Matthews et al., 1998b; Beal, 1999b).

CoQ10 has been shown effective in reducing the damage produced by toxins that inhibit complex II, preventing the depletion of ATP and increases in lactate (Beal et al., 1994; Matthews et al., 1998a). CoQ10 also prolonged survival while delaying the onset of motor impairment in a HD model in transgenic mice (Ferrante et al., 2002).

The neuropathological and clinical symptoms of HD can be simulated in animal models, with the systemic administration of 3-nitropropionic acid (3-NP). Kasparov et al. (2006) studied the activity of creatine kinase (CK) and mitochondrial respiratory chain function in the brain of aged rats administered with 3-NP, with and without prior application of antioxidants CoQ10 + Vitamin E. They found that the content of CoQ10 in tissues decreased in rats that received 3-NP. Antioxidants CoQ10 + Vitamin E were effective in preventing the decrease of CoQ10 content in brain tissue, but failed to prevent the decline in function of the respiratory chain.

Pre-treatment with α-tocopherol caused no neuroprotective effect in an animal model of HD (Beal et al., 1988), and treatment with high doses of α-tocopherol was effective only in patients in early stages of the disease (Peyser et al., 1995). Moreover, pre-treatment with CoQ10 exerted neuroprotective effects in a variety of animal models of HD and the oral administration of CoQ10 significantly reduced the elevated levels of lactate in patients with HD (Beal, 1999b). Levels of CoQ10 in the serum of HD patients were significantly lower than in both healthy controls and patients with HD treated with CoQ10 (Andrich et al., 2004).

A six-month pilot test assessed the tolerability of CoQ10 (Feigin et al., 1996). Ten subjects with symptomatic HD received 600 mg of CoQ10 per day, in three doses. The individuals were assessed three times: before the administration of CoQ10; and after three and six months of treatment, using the Scale for the Assessment of Huntington's disease, the HD Functional Capacity Scale, and neuropsychological tests. All subjects completed the study, with some mild adverse effects including heartburn, fatigue, headache, and increased involuntary movements. When the results of motor and functional scales obtained before the administration of CoQ10 and after six months were compared, no significant effect was observed. However, this study was small and unable to detect such effects.

As mentioned previously, HD patients have high levels of lactate in the brain. The administration of 360 mg/d of CoQ10 for two to eight weeks was associated with decreased levels of lactate in the occipital cortex in fifteen out of eighteen subjects (Koroshetz et al., 1997). Following interruption of administration of CoQ10, levels returned to baseline values, indicating that these effects were due to CoQ10. These results regarding the ability of CoQ10 to change the levels of cortical lactate support the therapeutic potential of CoQ10 for HD treatment.

Amyotrophic lateral sclerosis

Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disease characterized by degeneration of motor neurons in the spinal cord, brainstem and motor cortex, resulting in progressive muscle weakness and atrophy, observed as loss of muscle mass with progressive difficulty in performing movements, and loss of muscle strength. The incidence of ALS is approximately one to two cases per 100,000 per year, with onset typically at around the age of sixty years, with survival of three to five years (Rowland, Shneider, 2001; Sorenson et al., 2002)

ALS can occur in sporadic or familial form, which corresponds to only ten percent of cases. The possible involvement of free radicals in the etiology of ALS is suggested by the discovery that mutations in the gene encoding the antioxidant enzyme superoxide dismutase Cu / Zn (SOD1) are associated with familial ALS (Rosen et al., 1993). In both cases (sporadic or familial), although the etiology of ALS is not well known, several recent studies suggest an increase in oxidative damage (Bogdanov et al., 2000; Beal et al., 1997b; Ferrante et al., 1997).

According to Murata, Ohtsuki and Terayama (2008), mitochondrial oxidative damage contributes to the pathogenesis of sporadic ALS. The concentrations of oxidized and reduced CoQ10 in the cerebrospinal fluid were measured by high performance liquid chromatography in thirty patients with ALS and seventeen controls without neurological diseases. The percentage of oxidized CoQ10 in the cerebrospinal fluid of patients with ALS was significantly higher than in controls.

High levels of oxidized CoQ10 in plasma were found in patients with sporadic ALS, consistent with oxidative stress (Sohmiya et al., 2005). Given the evidence of mitochondrial dysfunction and oxidative stress in the pathogenesis of ALS, CoQ10 has been studied as a possible therapeutic approach (Galpern, Cudkowicz, 2007). The development of non-toxic drugs to block the oxidative injury may interrupt the process of disease at an early stage.

Studies using animal models of ALS have suggested that CoQ10 may be effective in dealing with this problem. In a transgenic mice model with a SOD1 mutation, supplementation with 200 mg/kg of CoQ10 increased survival, suggesting a potential therapeutic role of CoQ10 in patients (Matthews et al., 1998a). Recently, a systematic review of candidate therapeutic agents for ALS was conducted, and CoQ10 has been identified as one of twenty agents prioritized for research in clinical trials (Traynor et al., 2006).



While data from pilot studies are encouraging, it is important to note that the results of these studies are not conclusive and more studies are needed before CoQ10 can be recommended as effective to patients, without exposing them to unnecessary risks and significant costs.



AHMAD, M.; SALEEM, S.; AHMAD, A. S.; YOUSUF, S.; ANSARI, M. A.; KHAN, M. B.; ISHRAT, T.; CHATURVEDI, R. K.; AGRAWAL, A. K.; ISLAM, F. Ginkgo biloba affords dose-dependent protection against 6-hydroxydopamine-induced parkinsonism in rats: neurobehavioural, neurochemical and immunohistochemical evidences. J. Neurochem., v.93, p.94-104, 2005.         [ Links ]

ANDRICH, J.; SAFT, C.; GERLACH, M.; SCHNEIDER, B.; ARZ, A.; KUHN, W.; MULLER, T. Coenzyme Q10 serum levels in Huntington´s disease. J. Neural. Transm. Suppl., v.68, p.111-116, 2004.         [ Links ]

ANSARI, M. A.; AHMAD, A. S.; AHMAD, M.; SALIM, S.; YOUSUF, S.; ISHRAT, T.; ISLAM, F. Selenium protects cerebral ischemia in rat brain mitochondria. Biol. Trace Elem. Res., v.101, p.73-86, 2004.         [ Links ]

BEAL, M. F. Mitochondria take center stage in aging and neurodegeneration. Ann. Neurol., v.58, p.495-505, 2005.         [ Links ]

BEAL, M. F.; KOWALL, N. W.; SWARTZ, K. J.; FERRANTE, R. J.; MARTIN, J. B. Systemic approaches to modifying quinolinic acid striatal lesions in rats. J. Neurosci., v.10, p.3901-3908, 1988.         [ Links ]

BEAL, M. F.; HENSHAW, R.; JENKINS, B. G.; ROSEN, B. R.; SCHULZ, J. B. Coenzyme Q10 and nicotinamide blocks striatal lesions produced by the mitochondrial toxin malonate. Ann. Neurol., v.36, p.882-888, 1994.         [ Links ]

BEAL, M. F. Aging, energy and oxidative stress in neurodege-nerative diseases. Ann. Neurol., v.38, p.357-366, 1995.         [ Links ]

BEAL, M. F.; MATTHEWS, R. T. Coenzyme Q10 in the central nervous system and its potential usefulness in the treatment of neurodegenerative diseases. Mol. Aspects Med., v.18, p.169-179, 1997a.         [ Links ]

BEAL, M. F.; FERRANTE, R. J.; BROWNE, S. E.; MATTHEWS, R. T.; KOWALL, N.W., BROWN, R.H. Increased 3-nitrotyrosine in both sporadic and familial amyotrophic lateral sclerosis. Ann. Neurol., v.42, p.644-654, 1997b.         [ Links ]

BEAL, M. F. Mitochondria, NO and neurodegeneration. Biochem. Soc. Symp., v.66, p.43-54, 1999a.         [ Links ]

BEAL, M. F. Coenzyme Q10 administration and its potential for treatment of neurodegenerative diseases. Biofactors, v.9, p.261-266, 1999b.         [ Links ]

BEHL, C. Alzheimer´s disease and oxidative stress: implications for novel therapeutic approaches. Prog. Neurobiol., v.57, p.301-323, 1999.         [ Links ]

BENECKE, R.; STRUMPER, P.; WEISS, H. Electron transfer complexes I and IV of platelets are abnormal in Parkinson´s disease but normal in Parkinson-plus syndromes. Brain, v.116, p.1451-1463, 1993.         [ Links ]

BEYER, R. E.; BURNETT, B. A.; CARTWRIGHT, K. J.; EDINGTON, D. W.; FALZON, M. J.; KNEITMAN, K. R.; KUHN, T. W.; RAMP, B. J.; RHEE, S. Y. S; ROSSENWASSER, M. J.; STEIN, M.; AN, L. C. I. Tissue coenzyme Q (ubiquinone) and protein concentration over the life span of the laboratory rat. Mech. Aging Dev., v.32, p.267-281, 1985.         [ Links ]

BOGDANOV, M.; BROWN JR., R. H.; MATSON, W.; SMART, R.; HAYDEN, D.; O' DONNELL, H.; FLINT BEAL, M.; CUDKOWICZ, M. Increased oxidative damage to DNA in ALS patients. Free Rad. Biol. Med., v.29, p.652-658, 2000.         [ Links ]

BONAKDAR, R. A.; GUARNERI, E. Coenzyme Q10. Am. Fam. Physician., v.72, p.1065-1070, 2005.         [ Links ]

BROWNE, S. E.; FERRANTI, R. J.; BEAL, M. F. Oxidative stress in Huntington´s disease. Brain Pathol., v.9, p.147-163, 1999. [Proceedings of the Symposium on Oxidative Stress in Neurological Disease]         [ Links ].

BUSTUS, F.; MOLINA, J. A.; JIMENEZ-JIMENEZ, F. J.; GARCIA-REDONDO, A.; GOMEZ-ESCALONILLA, C.; PORTA-ETESSAM, J.; BERBEL, A.; ZURDO, M.; BARCENILLA, B.; PARRILLA, G.; ENRIQUEZ-DE-SALAMANCA, R.; ARENAS, J. Serum levels of coenzyme Q10 in patients with Alzheimer´s disease. J. Neural. Transm., v.107, p.233-239, 2000.         [ Links ]

BUTTERFIELD, D. A. Proteomics: a new approach to investigate oxidative stress in Alzheimer's disease brain. Brain Res., v.1000, p.1-7, 2004.         [ Links ]

CARDOSO, F.; SEPPI, K.; MAIR, K. J.; WENNING, G. K.; POEWE, W. Seminar on choreas. Lancet Neurol., v.5, p.589-602, 2006.         [ Links ]

CRANE, F. L.; HATEFI, Y.; LESTER, R. L.; WIDMER, C. Isolation of a quinone from beef heart mitochondria. Biochem. Biophys. Acta, v.25, p.220-221, 1957.         [ Links ]

CHRISTEN, Y. Oxidative stress and Alzheimer´s disease. Am. J. Clin. Nutr., v.71, p.6215-6295, 2000.         [ Links ]

COOKSON, M. R. The biochemistry of Parkinson's disease. Annu. Rev. Biochem., v.74, p.29-52, 2005.         [ Links ]

COYLE, J. T.; PUTTAFARCKEN, P. Oxidative stress, glutamate and neurodegenerative disorders. Science, v.262, p.689-695, 1993.         [ Links ]

CUTLER, N. R.; SRAMEK, J. J. Review of the next generation of Alzheimer's disease therapeutics: challenges for drug development. Prog. Neuro-Psychopharmacol. Biol. Psychiat., v.25, p.27-57, 2001.         [ Links ]

DAWSON, T. M.; DAWSON, V. L. Molecular pathways of neurodegeneration in Parkinson's disease. Science, v.302, p.819-822, 2003.         [ Links ]

DE LAU, L. M. L.; BRETELER, M. M. B.; Epidemiology of Parkinson's disease. Lancet Neurol., v.5, p.525-535, 2006.         [ Links ]


ERNSTER, L.; DALLNER, G. Biochemical, physiological and medical aspects of ubiquinone function. Biochim. Biophys. Acta, v.1271, p.195-204, 1995.         [ Links ]

EVANS, D. A.; FUNKENSTEIN, H. H.; ALBERT, M. S.; SCHERR, P. A.; COOK, N. R.; CHOWN, M. J.; HEBERT, E.; HENNEKENS, C. H.; TAULOR, J. O. Prevalence of Alzheimer's disease in a community population of older persons: higher than previously reported. JAMA, J. Am. Med. Assoc., v.262, n.18, p.2551-2556, 1989.         [ Links ]

FEIGIN, A.; KIEBURTZ, K.; COMO, P.; HICKEY, C.; CLAUDE, K.; ABWENDER, D.; ZIMMERMAN, C.; STEINBERG, K.; SHOULSON, I. Assessment of coenzyme Q10 tolerability in Huntington's disease. Mov. Disord., v.11, p.321-323, 1996.         [ Links ]

FAROUT, L.; FRIGUET, B. Proteasome function in aging and oxidative stress: implications in protein maintenance failure. Antioxid. Redox Signal., v.8, p.205-216, 2006.         [ Links ]

FERRANTE, R. J.; BROWNE, S. E.; SHINOBU, L. A.; BOWLING, A. C.; BAIK, M. J.; MACGARVEY, U.; KOWALL, N. W.; BROWN JR, R. H.; BEAL, M. F. Evidence of increased oxidative damage in both sporadic and familial amyotrophic lateral sclerosis. J. Neurochem., v.69, p.2064-2074, 1997.         [ Links ]

FERRANTE, R. J.; ANDREASSEN, O. A.; DEDEOGLU, A.; FERRANTE, K. L.; JENKINS, B. G.; HERSCH, S. M.; BEAL, M. F. Therapeutic effects of coenzyme Q10 and remacemide in transgenic mouse models of Huntington's disease. J. Neurosci., v.22, p.1592-1599, 2002.         [ Links ]

FLOYD, R. A. Antioxidants, oxidative stress, and degenerative neurological disorders. Proc. Soc. Exp. Biol. Med., v.222, p.236-245, 1999.         [ Links ]

FRANCIS, P. T.; PALMER, A. M.; SNAPE, M.; WILCOCK, G. K. The cholinergic hypothesis of Alzheimer's disease: a review of progress. J. Neurol. Neurosurg. Psychiatry, v.66, p.137-147, 1999.         [ Links ]

GALPERN, W. R.; CUDKOWICZ, M. E. Coenzyme Q treatment of neurodegenerative diseases of aging. Mitochondrion, v.7, suppl., p.S146-S153, 2007.         [ Links ]

GARY, E. G.; HSUEH-MEEI, H. Oxidative stress in Alzheimer's disease. Neurobiol. Aging, v.26, p.575-578, 2005.         [ Links ]

GOLDBERG, Y. P.; TELENIUS, H.; HAYDEN, M. R. The molecular genetics of Huntington's disease. Curr. Opin. Neurol., v.7, p.325-32, 1994.         [ Links ]

HALLIWELL, B. Hypothesis: proteasomal dysfunction: a primary event in neurogeneration that leads to nitrative and oxidative stress and subsequent cell death. Ann. N. Y. Acad. Sci., v.962, p.182-194, 2002.         [ Links ]

HEBERT, L. E.; BECKETT, L. A.; SCHERR, P. A.; EVANS, D. A. Annual incidence of Alzheimer disease in the United States projected to the years 2000 through 2050. Alzheimer Dis. Assoc. Disord., v.15, p.169-173, 2001.         [ Links ]

HUGHES, K.; LEE, B. L.; FENG, X.; LEE, J.; ONG, C. N. Coenzyme Q10 and differences in coronary heart disease risk in Asian Indians and Chinese. Free Rad. Biol. Med., v.32, p.132-138, 2002.         [ Links ]

ISHRAT, T.; KHAN, M. B.; HODA, MD. N.; YOUSUF, S.; AHMAD, M.; ANSARI, M. A.; AHMAD, A. S.; ISLAM, F. Coenzyme Q10 modulates cognitive impairment against intracerebroventricular injection of streptozotocin in rats. Behav. Brain Res., v.171, p.9-16, 2006.         [ Links ]

JENKINS, B. G.; ROSAS, H. D.; CHEN, Y. C.; MAKABE, T.; MYERS, R.; MACDONALD, M.; ROSEN, B. R.; BEAL, M. F.; KOROSHETZ, W. J. H. NMR spectroscopy studies of Huntington´s disease: correlations with CAG repeat numbers. Neurology, v.50, p.1357-1365, 1998.         [ Links ]

JENNER, P. Oxidative stress in Parkinson's disease. Ann. Neurol., v.53, n.3, suppl., p.S26-S38, 2003.         [ Links ]

KALEN, A.; APPELKVIST, E. L.; DALLNER, G. Age related changes in the lipid composition of rat and human tissue. Lipids, v.24, p.579-584, 1989.         [ Links ]

KALIORA, A. C.; DEDOUSSIS, G. V. Z.; SCHMIDT, H. Dietary antioxidants in preventing atherogenesis. Atherosclerosis, v.187, p.1-17, 2006.         [ Links ]

KAMZALOV, S.; SUMIEN, N.; FORSTER, M. J.; SOHAL, R. S. Coenzyme Q intake elevates the mitochondrial and tissue levels of coenzyme Q and α-tocopherol in young mice. J. Nutr., v.133, p.3175-3180, 2003.         [ Links ]

KASPAROVÁ, S.; SUMBALOVÁ, Z.; BYSTRICKÝ, P.; KUCHARSKÁ, J.; LIPTAJ, T.; MLYNÁRIK, V.; GVOZDJÁKOVÁ, A. Effect of coenzyme Q10 and vitam E on brain energy metabolism in the animal model of Huntington´s disease. Neurochem. Int., v.48, p.93-99, 2006.         [ Links ]

KAWAMOTO, E. M.; MUNHOZ, C. D.; GLEZER, I.; BAHIA, V. S.; CARAMELLI, P.; NITRINI, R.; GORJÃO, R.; CURI, R.; SCAVONE, C.; MARCOURAKIS, T. Oxidative stress in platelets and erythrocytes in aging and Alzheimer´s disease. Neurobiol. Aging, v.26, p.857-864, 2005.         [ Links ]

KIM, Y. D.; WON, S. K.; GWAG, B. J. Analysis of mitochondrial free radical generation in models of neuronal disease. Free Rad. Biol. Med, v.33, p.715-723, 2002.         [ Links ]

KITANO, M.; HOSOE, K.; FUKUTOMI, N.; HIDAKA, T.; OHTA, R.; YAMAKAGE, K.; HARA, T. Evaluation of the mutagenic potential of ubidecarenone using three short-term assays. Food Chem. Toxicol., v.44, p.364-370, 2006.         [ Links ]

KITAZAWA, M.; ANANTHARAM, V.; KANTHASAMY, A. G. Dieldrin induces apoptosis by promoting caspase-3-dependent proteolytic cleavage of protein kinase Cd in dopaminergic cells: relevance to oxidative stress and dopaminergic degeneration. Neuroscience, v.119, p.945-964, 2003.         [ Links ]

KOROSHETZ, W. J.; JENKINS, B. G.; ROSEN, B. R.; BEAL, M. F. Energy metabolism defects in Hiuntington´s disease and effects of coenzyme Q10. Ann. Neurol., v.41, p.160-165, 1997.         [ Links ]

KWONG, L.; KAMZALOV, S.; REBRIN, I.; BAYNE, A. C. V.; JANA, C. K.; MORRIS, P.; FORSTER, M. J.; SOHAL, R. S. Effects of coenzyme Q10 administration on its tissue concentrations, mitochondrial oxidant generation, and oxidative stress in the rat. Free Rad. Biol. Med., v.33, p.627-638, 2002.         [ Links ]

LANGSTON, J. W.; BALLARD, P.; TETRUD, J. W.; IRWIN, I. Chronic Parkinsonism in humans due to a product of mepeidine-analog synthesis. Science, v.219, p.979-980, 1983.         [ Links ]

LASS, A.; SOHAL, R. S. Electron transport-linked ubiquinonedependent recycling of alpha-tocopherol inhibits autooxidation of mitochondrial membranes. Arch. Biochem. Biophys., v.352, p.229-236, 1998.         [ Links ]

LENAZ, G.; BOVINA, C.; FORMIGGINI, G.; CASTELLI, G. P. Mitochondria, oxidative stress, and antioxidant defences. Acta Biochim. Pol., v.46, p.1-21, 1999.         [ Links ]

LITTARRU, G. P. Coenzyme Q10: from biochemistry to medicine. The Metabolic Approach Forum. Avaiable at: <>. Accessed on: 10 oct. 2006.         [ Links ]

MASON, P. Potential uses for coenzyme Q10. Pharm. J., v.275, p.379-382, 2005.         [ Links ]

MATTHEWS, R. T.; YANG, S.; BROWNE, S.; BAIK, M.; BEAL, M. F. Coenzyme Q10 administration increases brain mitochondrial concentrations and exerts neuroprotective effects. Proc. Natl. Acad. Sci. USA, v.95, p.8892-8897, 1998a.         [ Links ]

MATTHEWS, R. T.; YANG, L.; JENKINS, B. G.; FERRANTE, R. J.; ROSEN, B. R.; KADDURAH-DAOUK, R.; BEAL, M. F. Neuroprotective effects of creatine and cyclocreatine in animal models of Huntington´s disease. J. Neurosci., v.18, p.156-163, 1998b.         [ Links ]

MCDONALD, S. R.; SOHAL, R. S.; FORSTER, M. J. Concurrent administration of coenzyme Q10 and alpha-tocopherol improves learning in aged mice. Free Rad. Biol. Med., v.38, p.729-736, 2005.         [ Links ]

MCNAUGHT, K. S.; OLANOW, C. W. Proteolytic stress: a unifying concept for the etiopathogenesisof Parkinson's disease. Ann. Neurol., v.53, p.S73-S86, 2003.         [ Links ]

MELLORS, A.; TAPPELL, A. L. The inhibition of mitochondrial peroxidation by ubiquinone and ubquinol. J. Biol. Chem., v.241, p.4353-4356, 1966.         [ Links ]

MULLER, T.; BUTTNER, T.; GHOLIPOUR, A. F.; KUHN, W. Coenzyme Q10 supplementation provides mild symptomatic benefit in patients with Parkinson´s disease. Neurosci. Lett., v.341, p.201-204, 2003.         [ Links ]

MURATA, T.; OHTSUKA, C.; TERAYAMA, Y. Increased mitochondrial oxidative damage in patients with sporadic amyotrophic lateral sclerosis. J. Neurol. Sci., v.267, p.66-69, 2008.         [ Links ]

NOHL, H.; KOZLOV, A. V.; STANIEK, K.; GILLE, L. The multiple functions of coenzyme Q. Bioorg. Chem., v.29, n.1, p.1-13, 2001.         [ Links ]

PAPA, L.; GOMES, E.; ROCKWELL, P. Reactive oxygen species induced by proteasome inhibition in neuronal cells mediate mitochondrial dysfunction and a caspase independent cell death. Apoptosis, v.12, p.1389-1405, 2007.         [ Links ]

PARKER JR., W. D.; BOYSON, S. J.; PARKS, J. K. Abnormalities of the electron transport chain in idiopathic Parkinson´s disease. An. Neurol., v.26, p.719-723, 1998.         [ Links ]

PEPPING, J. Coenzyme Q10. Am. J. Health Syst. Pharm., v.56, p.519-521, 1999.         [ Links ]

PEYSER, C. E.; FOLSTEIN, M.; CHASE, G. A.; STARKSTEIN, S.; BRANDT, J.; COCKRELL, J. R.; BLYSMA, F.; COYLE, J. T.; MCHUGH, P. R.; FOLSTEIN, S. E. Trial of D-a-tocopherol in Huntington´s disease. Am. J. Psychiat., v.152, p.1771-1775, 1995.         [ Links ]

PIANTADOSI, C. A.; ZHANG, J. Mitochondrial generation of reactive oxygen species after brain ischemia in the rat. Stroke, v.27, p.327-331, 1996.         [ Links ]

QUINZII, C. M.; DIMAURO, S.; HIRANO, M. Human coenzyme Q(10) deficiency. Neurochem. Res., v.32, p.723-727, 2007a.         [ Links ]

QUINZII, C. M.; HIRANO, M.; DIMAURO, S. CoQ10 deficiency diseases in adults. Mitochondrion, v.7, suppl., p.S122-S126, 2007b.         [ Links ]

RAUSCHER, F. M.; SANDERS, R. A.; WATKINS III, J. B. Effects of coenzyme Q10 treatment on antioxidant pathways in normal and streptozotocin-induced diabetic rats. Biochem. Mol. Toxicol., v.15, p.41-46, 2001.         [ Links ]

REBRIN, I.; SOHAL, R. S. Distribution and measurement of coenzyme Q. Methods Enzymol., v.378, p.146-151, 2004.         [ Links ]

ROSEN, D. R.; SIDDIQUE, T.; PATTERSON, D.; FIGLEWICZ, D. A.; SAPP, P.; HENTATI, A.; DONALDSON, D.; GOTO, J.; O'REGAN, J. P.; DENG, H. -X.; RAHMANI, Z.; KRIZUS, A.; MCKENNA-YASEK, D.; CAYABYAB, A.; GASTON, S. M.; BERGER, R.; TANZI, R. E.; HALPERIN, J. J.; HERZFELDT, B.; VAN DEN BERGH, R.; HUNG, W, -Y.; BIRD, T.; DENG, G.; MULDER, D. W.; SMYTH, C.; LAING, N. G.; SORIANO, E.; VANCE, M. A. P.; HAINES, J.; ROULEAU, G. A.; GUSELLA, J. S.; HORVITZ, H. R.; BROWN, R. H. Mutations in Cu/Zn superoxide dismutase gene are associated with familial amyotrophic lateral sclerosis. Nature, v.362, p.59-62, 1993.         [ Links ]

ROWLAND, L. P.; SHNEIDER, N. A. Amyotrophic lateral sclerosis. N. Engl. J. Med., v.344, p.1688-1700, 2001.         [ Links ]

SANDERS, S. P.; ZWEIER, J. L.; KUPPUSWAMY, P.; HARRISON, S. J.; BASSET, D. J.; GABRIELSON, E. W.; SYLVESTER, J. T. Hypoxic sheep pulmonary microvascular endothelial cells generate free radicals via mitochondrial electron transport. J. Clin. Invest., v.91, p.46-52, 1993.         [ Links ]

SCHAPIRA, A. H.; MANN, V. M.; COOPER, J. M.; DEXTER, D.; DANIEL, S. E.; JENNER, P.; CLARK, J. B.; MARSDEN, C. D. Anatomic disease specificity of NADH CoQ1 redutase (complex I) deficiency in Parkinson´s disease. J. Neurochem., v.55, p.2142-2145, 1990.         [ Links ]

SCHOEPP, G. Is coenzyme Q10 (ubiquinone) effective for the treatment of heart failure? Pharm. Pract., v.13, p.31-32, 1999.         [ Links ]

SHINDE, S.; PATIL, N.; TENDOLKAR, A. Coenzyme Q10: a review of essential functions. Internet J. Nutr. Wellness, v.1, n.2, 2005.         [ Links ]

SHULTS, C. W.; HAAS, R. H.; BEAL, M. F. A possible role of coenzyme Q10 in the etiology and treatment of Parkinson´s disease. BioFactors, v.9, p.267-272, 1999.         [ Links ]

SHULTS, C. W.; OAKES, D.; KIEBURTZ, K.; BEAL, M. F.; HAAS, R.; PLUMB, S.; JUNCOS, J. L.; NUTT, J.; SHOULSON, I.; CARTER, J.; KOMPOLITI, K.; PERLMUTTER, J. F.; REICH, S.; STERN, M.; WATTS, R. L.; KURLAN, R.; MOLHO, E.; HARRISON, M.; LEW, M.; PARKINSON STUDY GROUP. Effects of coenzyme Q10 in early Parkinson disease: evidence of slowing of the functional decline. Arch. Neurol., v.59, p.1541-1550, 2002.         [ Links ]

SODERBERG, M.; EDLUND, J. A.; ALAFUZOFF, I.; KRISTENSSON, K.; DALLNER, G. Lipid composition in different regions of the brain in Alzheimer's disease/senile dementia of Alzheimer's type. J. Neurochem., v.59, p.1646-1653, 1992.         [ Links ]

SOHAL, R. S. Coenzyme Q and vitamin E interactions. Methods Enzymol., v.378, p.146-151, 2004.         [ Links ]

SOHAL, R. S.; DUBEY, A. Mitochondrial oxidative damage, hidrogen peroxide release and aging. Free Rad. Biol. Med., v.16, p.621-626, 1994.         [ Links ]

SOHAL, R. S.; FORSTER, M. J. Coenzyme Q, oxidative stress and aging. Mitochondrion, v.7, suppl., p.S103-S111, 2007.         [ Links ]

SOHAL, R. S.; MOCKETT, R. J.; ORR, W. C. Mechanisms of aging: an appraisal of the oxidative stress hypothesis. Free Rad. Biol. Med., v.33, p.575-586, 2002.         [ Links ]

SOMAYAJULU, M.; MCCARTHY, S.; HUNG, M.; SIKORSKA, M.; BOROWY-BOROWSKI, H.; PANDEY, S. Role of mitochondria in neuronal cell death induced by oxidative stress; neuroprotection by Coenzyme Q10. Neurobiol. Dis., v.18, p.618-627, 2005.         [ Links ]

SOHMIYA, M.; TANAKA, M.; SUZUKI, Y.; TANINO, Y.; OKAMOTO, K.; YAMAMOTO, Y. An increase of oxidized coenzyme Q10 occurs in the plasma of sporadic ALS patients. J. Neurol. Sci., v.228, n.1, p.49-53, 2005.         [ Links ]

SOHMIYA, M.; TANAKA, M.; TAK, N. W.; YANAGISAWA, M.; TANINO, Y.; SUZUKI, Y.; OKAMOTO, K.; YAMAMOTO, Y. Redox status of plasma coenzyme Q10 indicates elevated systemic oxidative stress in Parkinson's disease. J. Neurol. Sci., v.223, n.2, p.161-166.         [ Links ]

SORENSON, E. J.; STALKER, A. P.; KURLAND, L. T.; WINDEBANK, A. J. Amyotrophic lateral sclerosis in Olmsted County, Minnesota, 1925 to 1998. Neurology, v.59, n.2, p.280-282, 2002.         [ Links ]

STOYANOVSKY, D. A.; OSIPOV, A. N.; QUINN, P. J.; KAGAN, V. E. Ubiquinone-dependent recycling of vitamin E radicals by superoxide. Arch. Biochem. Biophys., v.323, p.343-451, 1995.         [ Links ]

TAKAYANAGI, R.; TAKESHIGE, K.; MINAKAMI, P. NADH- abd NADPH-dependent lipid peroxidation in bovine heart submitochondrial particles. Dependence on the rate of electron flow in the respiratory chain and an antioxidant role of ubiquinol. Biochem. J., v.192, p.853-860, 1980.         [ Links ]

TRAYNOR, B. J.; BRUIJN, L.; CONWIT, R.; BEAL, F.; O´NEILL, G.; FAGAN, S. C.; CUDKOWICZ, M. E. Neuroprotective agents for clinical trials in ALS: a systematic assessment. Neurology, v.67, p.20-27, 2006.         [ Links ]

ZHANG, Y.; ABERG, F.; APPELKVIST, E-L.; DALLNER, G.; ERNSTER, L. Uptake of dietary coenzyme Q supplement is limited in rats. J. Nutr., v.125, p.446-453, 1995.         [ Links ]



Received for publication on 01th September 2008.
Accepted for publication on 31th March 2009.



* Correspondence: L. M. G. Antunes. Departamento Análises Clínicas, Toxicológicas e Bromatológicas, Faculdade de Ciências Farmacêuticas de Ribeirão Preto, Universidade de São Paulo - USP, Av do Café, s/n, Campus Universitário da USP - Ribeirão Preto/SP - CEP: 14040-903. E-mail:

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