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Background: In recent years, studies have been conducted on the role of coenzyme Q10 in improvement of sport performance and also cardiovascular health. The present study investigate effect of coenzyme Q10 supplementation combined with swimming aerobic exercises on Heart Rate Deflection Point (HRDP) and VO2max in active women.

Materials and Methods: A number of 32 trained women with the average age of 21/25 ± 0.86 years and Body Mass Index (BMI) of 20/127± 1.06 kg/square meter were selected randomly and were divided into eight -member each groups: Control, Supplement, Supplement – Exercise and Exercise. The subjects participated in four-week consumption of coenzyme Q10 and swimming exercises (three sessions in a week).The consumption rate of coenzyme Q10 100 mg/kg/d was in the form of capsule that subjects took it during lunchtime. Before and after a four-week period, the subjects performed an incremental exhaustive test on treadmill, using respiratory gas analyzer to determine HRDP and VO2max. It should be noted that data analysis was conducted using One-Way Variance Analysis Test (ANOVA) in P<0.05 significant level.

Results: Based on paired T-Test results, despite HRDP had increased in each four groups but the significant increase was observed only among groups in VO2max (P=0.008) based on ANOVA Test (P<0.05).

Conclusion: Although positive changes were observed inside the group after passage of four weeks, coenzyme Q10 supplementation combined with swimming aerobic exercise had not any significant effect on HRDP only increased VO2max.

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Background: Gentamicin (GM) is one the aminoglycoside antibiotics which isroutinelyused to treatinfections gram-negative, either alone or insynergistic withbeta-lactamantibioticsused. However, frequent useleads toserious side effectssuch asrenal toxicity, ototoxicity. Coenzyme Q₁₀ has antioxidant, anti-inflammatory and vasodilatory properties. According to these properties of Coenzyme Q₁₀ and tissue damage mechanism in GM induced-nephrotoxicity, in this study, the effects of these two substances for the co-treatment and post -treatment on renal injury induced by gentamicin were investigated.

Materials and Methods:  Experiments has been done on 77 male Wistar rats in weight range of 200 to 250 g. Animals were divided randomly into 5 groups of 7 numbers. Renal nephrotoxicity induced by i.p injection of gentamicin (100mg/kg) Therapeutic effect of coenzyme Q₁₀ (10mg/kg)in the two protocols co-treatment  and post-treatmentwas investigated.The animals after the last injectionon the ninth day of co-treatment andthe seventeenth day of post-treatmentwere placed into individual metabolic cages so as to collection urine and urine volume was measured gravimetrically. Afteranesthesia, systolic blood pressure and renal blood flow was measured. Then blood sampling was done. Amount of urea, creatinin, sodium, potassium and osmolarity was measured in plasma and urine samples. Left kidney, for doing histological experiments in 10% buffered formaldehyde and right kidney for biochemical experiments in fluid nitrogen was preserved.

Results: Co-treatment with Coenzyme Q10 significantly decreased fractional excretion of sodium (6.37±1.33 %; p<0.001) and decreased fractional excretion of potassium(219.14±83.8 %; p<0.001) MDA levels (2.13 ±0.24µmol/gkw; p<0.001), and significantly increased renal blood flow (6.38 ±0.1ml/min: p<0.01) and FRAP levels (24.44±0.42mmol/gkw; p<0.001). Post-treatment with coenzyme Q10 significantly decreased fractional excretion of sodium (3.58 ±0.57 %; p<0.001), potassium (111.77±29.4%; p<0.001) and MDA levels (3.08 ±0.12µmol/gkw; p<0.001) and significantly increased renal blood flow (6.74±0.15ml/min: p<0.001) and FRAP levels (24.34±0.75mmol/gkw; p<0.001) that is reduced by gentamicin.

Conclusion: According to the results, this study showed thatpost- treatment with coenzyme Q₁₀more protective effect on the kidney tissue andAnda greater increase inantioxidant defensecreated.

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Background and Aim Oxidative stress is the main factor in the development and progression of diabetes and its related complications. There is growing evidence that antioxidants supplementation can improve oxidative stress induced in diabetes. The present investigation was conducted to study the effects of Coenzyme Q10 (CoQ10) on the Oxidative Stress Index (OSI) in diabetic rats.
Methods and Materials A total of 30 male rats were divided into five groups: saline, sesame oil (as a vehicle), CoQ10-treated (10 mg/kg/day), diabetic (induced with streptozotocin: 55 mg/kg), and CoQ10-treated diabetic (10 mg/kg/d). Then, we measured the Malondialdehyde (MDA), Total Oxidant Status (TOS), and Total Antioxidant Capacity (TAC) levels in the rats’ liver homogenate. Additionally, the OSI was calculated.
Ethical Considerations The Research Ethics Committee of Arak University of Medical Sciences approved this study (Code: IR.ARAKMU.REC.1397.119).
Results results showed a significant decrease in the level of liver MDA (P=0.022), TOS (P=0.03), and OSI (P=0.028) in the CoQ10-treated diabetic group compared to the diabetic rats. No significant change was observed in the total thiol group (P=0.25) and TAC (P=0.77) level in diabetic rats’ livers treated with CoQ10 compared to diabetic rats. 

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Background and Aim: Exercise aerobic is associated with increased creatine kinase and blood lactate immediately after exercise, leading to increased muscle damage and undesirable changes in many cellular markers including serum creatine kinase. In such situations, consuming nutrients and supplements such as coenzyme Q10 may prevent metabolic stress damage by increasing buffering power. However, comprehensive studies have not been performed on the effects of this nutrient on the index of muscle injury and fatigue caused by exercise.
Methods & Materials: For this purpose, 20 inactive volunteer men were randomly divided into two groups of 10-person Coenzyme Q10 supplement (2.5 mg/kg body weight) and quasi-drug (2.5 mg/kg body weight Dextrose). All subjects participated in the Bruce test exercise contract after 14 days of supplementation. Blood sampling was performed in four stages including baseline, after supplementation, immediately after exercise and two hours after exercise. Creatine kinase, lactate and cortisol indices of both groups were measured during these four stages. Data were analyzed by means of standard deviation and repeated measures ANOVA, Bonferroni post hoc and Independent T-test using SPSS V. 17 at the significant level of 0.05.
Ethical Considerations: This article has been approved by the ethics committee of Tabriz School of Medical Sciences with the ethics code IRCT 201203104663N8.
Results: The results showed that 14 days of Coenzyme Q10 supplementation had a significant effect on cortisol level (P<0.05). In addition, one session of exhausting aerobic activity increased creatinine kinase and lactate (P<0.05). On the other hand, creatinine kinase did not differ significantly after exercise (P>0.05). 
Conclusion: According to the results of the present study, 14-day supplementation of Coenzyme Q10 may reduce the cellular damage induced by exhaustive aerobic activity in inactive men and prevent an increase in blood lactate levels.