UNIPROT:P06889 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Sixty-one patients admitted with acute myocardial infarction, and a symptom's duration of less than 6 hr were randomized into two groups. Immediately after hospitalisation, members of the verum group (n = 32) received 500 mcg of selenium (as sodium selenite). Thereafter they received a daily dosage of 100 mg coenzyme Q10 (Bio-Quinone) and 100 mcg selenium (Bio-Selenium in the form of 1-seleno-methionine) for a period of one year. The control group (n = 29) were given matching placebo preparations. The groups were comparable as with respect to age, sex and medical treatment. Biochemical parameters showed a reduced concentration of CPK- and ASAT-level in the verum group during the acute phase (although not statistically significant). None of the patients in the verum group (i.e. on antioxidative treatment) showed prolongation of the frequency corrected QT-interval. In the control group, 40% revealed a prolongation of the QT-interval by more than 440 msec (p < 0.001). There were no significant differences, with respect to early complications. During the one-year follow-up period after myocardial infarction, six patients (20%) from the control group died from re-infarction whereas one patient from the verum group suffered a non-cardiac death.
Mol Aspects Med 1994
PMID:Coenzyme Q10 and antioxidants in acute myocardial infarction. 775 25

In patients with chronic heart failure (CHF), the addition of coenzyme Q10 to conventional therapy reduces the hospitalization rate for worsening of heart failure and the incidence of serious cardiovascular complications. The present study was planned to assess the hemodynamic mechanisms underlying this phenomenon. Cardiac hemodynamics was evaluated continuously using an ambulatory radionuclide detector (VEST) which allows a noninvasive monitoring of left ventricular function. Six patients wit CHF (mean ejection fraction (EF): 29%) clinically documented were studied. This study was organized as a randomized double-blind, placebo controlled, cross-over trial. The enrolled patients, after a washout period, underwent the first hemodynamic evaluation with VEST. Subsequently they were randomized to receive placebo or coenzyme Q10 for 4 weeks. At the end of this period they underwent the second VEST study. The third VEST study was performed after a further 4-week period with inverted treatment. Cardiac hemodynamics were evaluated during bicycle exercise. The EF in control conditions (CC) changed from 27 +/- 11%, at rest, to 24 +/- 8%, at peak exercise. During coenzyme Q10 treatment EF showed a significant increase both at rest (33 +/- 13%, P < 0.05 vs CC) and at peak exercise (30 +/- 12%, P < 0.05 vs CC). The same trends were recorded for the stroke volume and the cardiac output. Our results demonstrate that coenzyme Q10 improves cardiac hemodynamic response to exercise in patients with CHF and suggest that noninvasive monitoring of left ventricular function allows a more reliable assessment of therapy efficacy.
Mol Aspects Med 1994
PMID:Noninvasive evaluation of cardiac hemodynamics during exercise in patients with chronic heart failure: effects of short-term coenzyme Q10 treatment. 775 27

Over an eight year period (1985-1993), we treated 424 patients with various forms of cardiovascular disease by adding coenzyme Q10 (CoQ10) to their medical regimens. Doses of CoQ10 ranged from 75 to 600 mg/day by mouth (average 242 mg). Treatment was primarily guided by the patient's clinical response. In many instances, CoQ10 levels were employed with the aim of producing a whole blood level greater than or equal to 2.10 micrograms/ml (average 2.92 micrograms/ml, n = 297). Patients were followed for an average of 17.8 months, with a total accumulation of 632 patient years. Eleven patients were omitted from this study: 10 due to non-compliance and one who experienced nausea. Eighteen deaths occurred during the study period with 10 attributable to cardiac causes. Patients were divided into six diagnostic categories: ischemic cardiomyopathy (ICM), dilated cardiomyopathy (DCM), primary diastolic dysfunction (PDD), hypertension (HTN), mitral valve prolapse (MVP) and valvular heart disease (VHD). For the entire group and for each diagnostic category, we evaluated clinical response according to the New York Heart Association (NYHA) functional scale, and found significant improvement. Of 424 patients, 58 per cent improved by one NYHA class, 28% by two classes and 1.2% by three classes. A statistically significant improvement in myocardial function was documented using the following echocardiographic parameters: left ventricular wall thickness, mitral valve inflow slope and fractional shortening. Before treatment with CoQ10, most patients were taking from one to five cardiac medications. During this study, overall medication requirements dropped considerably: 43% stopped between one and three drugs. Only 6% of the patients required the addition of one drug. No apparent side effects from CoQ10 treatment were noted other than a single case of transient nausea. In conclusion, CoQ10 is a safe and effective adjunctive treatment for a broad range of cardiovascular diseases, producing gratifying clinical responses while easing the medical and financial burden of multidrug therapy.
Mol Aspects Med 1994
PMID:Usefulness of coenzyme Q10 in clinical cardiology: a long-term study. 775 28

The authors prepared an experimental animal model of ischemia and reperfusion of the limbs to evaluate in vivo the reactive oxygen species involvement and protective role of coenzyme Q10 in reperfusion injury. A group of male rabbits (untreated group) underwent clamping of abdominal aorta for 3 hr and then declamping; at intervals blood sampling was drawn for coenzyme Q10, vitamin E, lactic acid and creatine kinase assays. Another group of male rabbits (treated group) underwent the same ischemia period but before declamping coenzyme Q10 was administered intra aorta. In untreated group, coenzyme Q10 and vitamin E plasma levels decreased while lactic acid and creatine kinase plasma levels increased during reperfusion. These data demonstrate that, after only 3 hr of ischemia, the extremities show a biochemical reperfusion injury, and this involves an increased consumption of antioxidants such as coenzyme Q10 and vitamin E. In the treated group, the increase of creatine kinase plasma levels during reperfusion was not significant, while the decrease in vitamin E was more marked.
Mol Aspects Med 1994
PMID:Protective role in vivo of coenzyme Q10 during reperfusion of ischemic limbs. 775 29

The biosynthetic pathway of the CoQ polyisoprenoid side chain, starting from acetyl-CoA and proceeding through mevalonate and isopentenylpyrophosphate, is the same as that of cholesterol. We performed this study to evaluate whether vastatins (hypocholesterolemic drugs that inhibit HMG-CoA reductase) modify blood levels of ubiquinone. Thirty-four unrelated outpatients with hypercholesterolemia (IIa phenotype) were treated with 20 mg of simvastatin for a 6-month period (group S) or with 20 mg of simvastatin plus 100 mg CoQ10 (group US). The following parameters were evaluated at time 0, 45, 90, 135 and 180 days: total plasma cholesterol (TC), HDL-cholesterol, LDL-cholesterol (LDL-C), triglycerides (TG), apo A1, apo B and CoQ10 in plasma and platelets. In the S group, there was a marked decrease in TC and LDL-C (from 290.3 mg/dl to 228.7 mg/dl for TC and from 228.7 mg/dl to 167.6 mg/dl for LDL-C) and in plasma CoQ10 levels from 1.08 mg/dl to 0.80 mg/dl. In contrast, in the US group we observed a significant increase of CoQ10 in plasma (from 1.20 to 1.48 mg/dl) while the hypocholesterolemic effect was similar to that observed in the S group. Platelet CoQ10 also decreased in the S group (from 104 to 90 ng/mg) and increased in the US group (from 95 to 145 ng/mg). This study demonstrates that simvastatin lowers both LDL-C and apo B plasma levels together with the plasma and platelet levels of CoQ10, and that CoQ10 therapy prevents both plasma and platelet CoQ10 decrease, without affecting the cholesterol lowering effect of simvastatin.
Mol Aspects Med 1994
PMID:Exogenous CoQ10 supplementation prevents plasma ubiquinone reduction induced by HMG-CoA reductase inhibitors. 775 30

Alcohol metabolism may result in oxidant stress and free radical injury through a variety of mechanisms. Lovastatin may also produce oxidant stress by reducing levels of an endogenous antioxidant, coenzyme Q (CoQ). The separate and combined effects of ethanol, 20 EN% in a total liquid diet, and lovastatin, 67 mg/kg diet, on alpha-tocopherol, retinol palmitate, CoQ9 and thiobarbituric acid reactive (TBAR) material in liver from rats were determined. The effect of exogenous CoQ10 on these treatment groups was also determined. Food consumption, weight gain, liver lipid and TBAR material were similar between treatment groups. Compared to control animals, ethanol reduced retinol palmitate significantly, from 143 to 90 micrograms/g wet weight. Lovastatin had no effect on retinal palmitate nor did it act additively with ethanol. Ethanol decreased liver alpha-tocopherol from 28 to 12 micrograms/g wet weight and lovastatin diminished it to 12 micrograms; no additive effect was evident. Ethanol had no effect, but lovastatin decreased CoQ9 from 83 to 55 micrograms/g wet weight. Supplementation with CoQ10 did not modulate the effect of ethanol on retinal palmitate, but it did reverse the effect of lovastatin on CoQ9. Supplementary CoQ10 did not alter control levels of alpha-tocopherol, but it appeared to reverse most of the decrease in alpha-tocopherol attributable to ethanol or lovastatin separately. It only partially reversed the effect of ethanol and lovastatin combined on alpha-tocopherol, however. As expected, lovastatin had no effect on CoQ10 levels in supplemented animals. Ethanol, either separately or in combination with lovastatin, diminished liver stores of CoQ10 by almost 40%. We conclude that 20 EN% ethanol given in a liquid diet for 5 weeks is sufficient to lower retinol palmitate and that lovastatin reduces CoQ9. Both diminish alpha-tocopherol, an effect largely overcome by CoQ10 supplementation with either drug alone, but not with the combination. Since many individuals chronically consume the levels of ethanol represented by this experiment, and since a certain number of those also take lovastatin, further research into the possible clinical significance of these observations is warranted.
Mol Aspects Med 1994
PMID:Effects of ethanol, lovastatin and coenzyme Q10 treatment on antioxidants and TBA reactive material in liver of rats. 775 31

Two groups of children with acute lymphoblastic leukemia or non-Hodgkin lymphoma, treated with anthracyclines (ANT), were studied: group I, consisting of 10 patients, with coenzyme Q10 (CoQ) therapy; group II, consisting of 10 patients without CoQ therapy. The ANT cumulative dose was 240 +/- 20.0 mg/m2 in group I and 252.0 +/- 20.1 mg/m2 in group II. Echocardiographic study was performed at the beginning, at the cumulative dose of 180 mg/m2 and at the end of therapy with ANT. Percentage left ventricular fractional shortening (%LVFS) decreased from baseline (40.36 +/- 4.6) to end value (35.82 +/- 5.02) (P < 0.05) in group I; %LVFS decreased from baseline (39.89 +/- 4.37) to end value (33.43 +/- 3.46) (P < 0.002) in group II. Interventricular septum wall thickening decreased only in group II from baseline (46.10 +/- 10.1) to end therapy (27.00 +/- 18.54) (P < 0.01). Septum wall motion abnormalities were detected only in 2 patients of group II. These data demonstrate a protective effect of CoQ on cardiac function during therapy with ANT.
Mol Aspects Med 1994
PMID:Protective effect of coenzyme Q10 on anthracyclines cardiotoxicity: control study in children with acute lymphoblastic leukemia and non-Hodgkin lymphoma. 775 32

Coenzyme Q10 (CoQ10), vitamin E, triglycerides and conjugated dienes were measured in a group of 48 patients on chronic hemodialysis, in 15 uremic patients and in a control group of 10 normal subjects. CoQ10 levels were significantly lower (P < 0.001) in both hemodialytic and uremic patients compared with the normal group whereas triglycerides were significantly higher (P < 0.001) with respect to both normal subjects and uremic patients. Conjugated dienes were significantly higher (P < 0.001) in both hemodialytic and uremic patients with respect to normal subjects. The predialytic values of vitamin E were higher in hemodialytic patients with respect to both normal subjects and uremic patients whereas the postdialytic values were in the normal range. A restoration mechanism of vitamin E after hemodialytic treatment was hypothesized.
Mol Aspects Med 1994
PMID:Coenzyme Q10 levels, plasma lipids and peroxidation extent in renal failure and in hemodialytic patients. 775 33

Phosphorus magnetic resonance spectroscopy (31P-MRS) has emerged as a noninvasive reliable tool for in vivo study of human tissue bioenergetics. It detects and quantifies some phosphorylated compounds present in millimolar concentration inside the cell, including ATP, phosphocreatine (PCr) and inorganic phosphate (Pi). By 31P-MRS we studied brain and skeletal muscle energy metabolism of three patients with retinitis pigmentosa before and after oral coenzyme Q10 (CoQ10) (100 mg/day). Before treatment we found a low PCr content in the brains of all patients, accompanied by a high [Pi] and high [ADP]. In two of three patients CoQ10 treatment resulted in a larger brain energy reserve mainly shown by an increased [PCr]. Abnormal muscle mitochondrial function was found only in one patient as shown by a reduced rate of PCr resynthesis after exercise. In this patient CoQ10 treatment resulted in an increased rate of PCr resynthesis. Our observations indicate that CoQ10 can improve mitochondrial functionality in the brain and skeletal muscle of patients with retinitis pigmentosa.
Mol Aspects Med 1994
PMID:The use of phosphorus magnetic resonance spectroscopy to study in vivo the effect of coenzyme Q10 treatment in retinitis pigmentosa. 775 34

Thirty-two typical patients with breast cancer, aged 32-81 years and classified 'high risk' because of tumor spread to the lymph nodes in the axilla, were studied for 18 months following an Adjuvant Nutritional Intervention in Cancer protocol (ANICA protocol). The nutritional protocol was added to the surgical and therapeutic treatment of breast cancer, as required by regulations in Denmark. The added treatment was a combination of nutritional antioxidants (Vitamin C: 2850 mg, Vitamin E: 2500 iu, beta-carotene 32.5 iu, selenium 387 micrograms plus secondary vitamins and minerals), essential fatty acids (1.2 g gamma linolenic acid and 3.5 g n-3 fatty acids) and Coenzyme Q10 (90 mg per day). The ANICA protocol is based on the concept of testing the synergistic effect of those categories of nutritional supplements, including vitamin Q10, previously having shown deficiency and/or therapeutic value as single elements in diverse forms of cancer, as cancer may be synergistically related to diverse biochemical dysfunctions and vitamin deficiencies. Biochemical markers, clinical condition, tumor spread, quality of life parameters and survival were followed during the trial. Compliance was excellent. The main observations were: (1) none of the patients died during the study period. (the expected number was four.) (2) none of the patients showed signs of further distant metastases. (3) quality of life was improved (no weight loss, reduced use of pain killers). (4) six patients showed apparent partial remission.
Mol Aspects Med 1994
PMID:Apparent partial remission of breast cancer in 'high risk' patients supplemented with nutritional antioxidants, essential fatty acids and coenzyme Q10. 775 35

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