Coenzyme Q10 Treatment Research Articles

The potential therapeutic effects of coenzyme Q10 on the sciatic nerve regeneration following short- and long-term injury

Aim: This study aims to investigate the effects of administering coenzyme Q10 (CoQ10) after both short-term and long-term sciatic nerve damage. Methods: Six groups of adult male Wistar albino rats were used. Sciatic nerve injury was performed on the rats in the short-term injury (STI) and long-term injury (LTI) groups for 15 and 60 s. For 21 days, the rats in the CoQ10, STI + CoQ10, and LTI + CoQ10 groups were also administered CoQ10 orally at a dose of 10 mg/kg of body weight; the control (Cont) group received no treatment. The nerve samples were evaluated by electrophysiology, the sciatic functional index (SFI), stereological investigations, and light and electron microscopic methods. Results: The number of myelinated axons was higher in the LTI group according to the Cont and the sham groups. The numbers of axons in the LTI and LTI + CoQ10 groups were higher than that in the STI and STI + CoQ10 groups. Latency and amplitude levels were significantly changed following STI and LTI treatment and CoQ10 treatment significantly improved the results following the injuries. SFI results showed highly significant differences between the Cont and STI, Cont and LTI, Cont and STI + CoQ10, STI + CoQ10 and LTI + CoQ10, and Cont and LTI + CoQ10 groups. Microscopic examinations indicated that LTI produced a significant change in the nerve structure than STI. CoQ10 ameliorated the degree of injury. Conclusions: Treatment with CoQ10 following sciatic nerve damage was more successful in the LTI than the STI group, and it may, therefore, effectively improve peripheral nerve regeneration, especially following LTI.

Evaluation of efficacy and safety of coenzyme Q10 in pediatric hemodialysis patients: a randomized controlled trial

BackgroundThere is evidence from clinical trials that coenzyme Q10 significantly improves mitochondrial function and decreases oxidative stress and cardiovascular disease in adult hemodialysis patients. However, we have never fully investigated its role in pediatric patients before. This study aimed to assess the effects of coenzyme Q10 supplementation on oxidative stress and inflammatory markers in pediatric hemodialysis patients. This was a prospective, randomized, double-blinded, placebo-controlled trial. Thirty-six pediatric hemodialysis patients were recruited and simply randomized to receive either oral coenzyme Q10 (3–5 mg/kg) daily or placebo daily for 12 weeks.ResultsUsing the Mann–Whitney test, children in the intervention group showed a significant reduction in the median percent change of blood urea nitrogen from baseline of − 58.18 versus − 9.6 in the placebo group (p = 0.002). The median percent change of serum malondialdehyde significantly decreased by − 55.68 in the intervention group, while it increased by 39.75 in the placebo group (p < 0.001). Additionally, the median percent change from baseline in serum tumor necrosis factor-α levels significantly decreased by − 46.69 in the intervention group and increased by 8.5 in the placebo group (p = 0.03).ConclusionSupplementation of oral coenzyme Q10 may have beneficial effects on oxidative stress and inflammatory markers in pediatric hemodialysis patients. This study emphasized the potential efficacy of an average coenzyme Q10 dose of 4 mg/kg/day in pediatric hemodialysis patients; this gives the green light for other researchers to confidently evaluate larger doses as an attempt to control the systemic inflammation in this patient population. Further research is needed to determine whether coenzyme Q10 treatment improves clinical outcomes such as infection, hospitalization, cardiovascular events, and mortality in pediatric hemodialysis patients.Trial Registration Clinical trials.gov, NCT05170893, Registered 28 December 2021, https://clinicaltrials.gov/study/NCT05170893?cond=NCT05170893&rank=1.Graphical abstract

Clinical follow-up of 2 families with glomerulopathy caused by COQ8B gene variants and literature review.

Primary coenzyme Q10 (CoQ10) deficiency is an autosomal recessive genetic disease caused by mitochondrial dysfunction. Variants in Coenzyme Q8B (COQ8B) can cause primary CoQ10 deficiency. COQ8B-related glomerulopathy is a recently recognized glomerular disease that most often presents as steroid-resistant nephrotic syndrome (SRNS) in childhood. The disease often progresses to kidney failure and the renal histopathology is most commonly focal segmental glomerulosclerosis (FSGS). Four SRNS cases (2 females and 2 males) from 2 unrelated families who were followed clinically for nearly 3 years. Clinical exome testing and analyses were performed by MyGenostics Laboratory in China to evaluate unexplained proteinuria given the strong family history of glomerular disease and histologic evidence of SRNS. Pathogenic variants were identified in COQ8B in the exome studies and confirmed by direct sequencing. Clinical exome sequencing revealed biallelic variants of the COQ8B gene in 2 families. In the Family 1, the oldest of three affected siblings died of renal failure at 11 years of age. Based on the results of genetic testing which identified a homozygous variant of COQ8B, the other two affected siblings with mild proteinuria and normal renal function were treated with CoQ10 oral supplementation at an early stage. Coenzyme Q10 treatment was effective in reducing proteinuria levels in both patients from Family 1 over the first 6 months and the two patients still have low-level proteinuria and normal renal function at nearly three years. In Family 2, clinical exome sequencing revealed a compoundheterozygous variants of COQ8B in a patient with biopsy- proven FSGS. His disease was unresponsive to prior treatment with glucocorticoids and cyclosporine. Oral CoQ10 was initiated based on his genetic diagnosis and was it was effective in reducing proteinuria over the first 5 months months of therapy. However after 1 year, his disease progressed tokidney failure. Kidney transplantation was performed at 5 years of age and his condition has been stable without rejection and no recurrence of disease. COQ8B gene variant-related glomerulopathy often presents as SRNS without obvious extrarenal manifestations. The histopathology is mainly FSGS and follows an autosomal recessive mode of inheritance. Some patients may benefit from early coenzyme Q10 supplementation. For patients whose disease progresses to kidney failure, kidney transplantation can be an effective treatment. For children with unexplained proteinuria and abnormal renal function, genetic testing should be performed early in the course of disease to guide therapy where possible and improve prognosis.

PDSS1 mutations-associated steroid-resistant nephrotic syndrome: case report and review of literature.

PDSS1 mutations hamper Coenzyme Q10 biosynthesis and cause a rare multisystem mitochondrial disease characterized by diverse clinical features and limited treatment options. To date, renal involvement has been reported in only one patient. We report a new female patient with compound heterozygous PDSS1 mutations and the clinical outcome following a trial of Coenzyme Q10 therapy. Our patient presented with developmental delay and regression at age three, which progressed to steroid-resistant nephrotic syndrome at age six, leading to stage 5 chronic kidney disease. Whole exome sequencing identified two pathogenic variants in the PDSS1 gene. High doses of Coenzyme Q10 therapy had no effect at this advanced stage of disease. Coenzyme Q10 treatment did not appear to improve the clinical outcome in this patient. Further data is needed to better understand the phenotypic spectrum of PDSS1-associated disruption, and the potential benefit of early Coenzyme Q10 therapy.

Protective effect and mechanism of CoQ10 in mitochondrial dysfunction in diquat-induced renal proximal tubular injury.

Coenzyme Q10 (CoQ10) plays an important role in improving mitochondrial function and has many beneficial effects on the kidney. However, whether CoQ10 protects against diquat (DQ)-induced acute kidney injury (AKI) remains unclear. In this study, we investigated the protective effects and mechanism of action of CoQ10 against DQ-induced AKI. Institute of Cancer Research (ICR) mice were intraperitoneally injected with DQ to induce AKI. The expression levels of serum creatinine (Cr), urea, and kidney injury molecule-1 (KIM-1) increased, those of aquaporin 1 (AQP-1) decreased, and those of mitochondrial reactive oxygen species (ROS) increased with increased depolarization of mitochondrial membranes and mitochondrial rupture. In contrast, treatment with CoQ10 significantly improved DQ-induced AKI. CoQ10 treatment reduced serum Cr, urea, and KIM-1 contents, increased the AQP-1 expression, and reduced ROS contents in mice with DQ poisoning. Our results suggest that AKI caused by DQ poisoning may be related to the disruption of mitochondrial homeostasis and that CoQ10 treatment protects against AKI caused by DQ poisoning by improving mitochondrial kinetic homeostasis. Thus, CoQ10 represents a new therapeutic option for the prevention and treatment of AKI caused by DQ poisoning.

Effects of alfa lipoic acid and coenzyme Q10 treatment on AFB1-induced oxidative, inflammatory, and DNA damages in rats

Food contamination with Aflatoxin B1 (AFB1) is a worldwide concern that adversely affects animal and human health. The study aimed to evaluate the protective effect of alpha lipoic acid (ALA) and/or co-enzyme Q10 (CQ10) against the harmful effects of AFB1 on the liver and kidneys. Fifty-six mature male Wistar Albino rats (180–200 g) were divided into seven groups, each with eight rats: (1) saline was given as a control, (2) ALA (100 mg/kg bw/day) was given by stomach gavage for fifteen days, and (3) CQ10 (10 mg/kg bw/day) was given by stomach gavage for fifteen days. Group (4) orally given AFB1 (2.5 mg/kg bw) on days 12th and 14th, (5) received AFB1 and ALA, (6) received AFB1 and CQ10, and (7) received AFB1, ALA, and CQ10, as previously described in the ALA, CQ10, and AFB1 groups. After the exposure to AFB1, a significant increase in liver markers (AST, ALT, ALP, and LDH) and renal function tests (BUN and creatinine) was observed compared with the control. ALA and/or CQ10 significantly reduced enzymes of liver and renal functions, as compared with AFB1. AFB1 exposure threw off the balance between oxidants and antioxidants. Still, ALA and/or CQ10 made oxidative stress (MDA, NO, and 8-OHdG) much lower and antioxidant activities (GSH, GSH-Px, SOD, and CAT) much higher. When we used the two together, the activities matched the control levels. Interestingly, this study shows that ALA and CQ10 significantly lowered IL-1β, IL-6, and TNF-α levels compared to the control values when used together after AFB1 exposure caused robust inflammation. Some CQ10 treatment parameters significantly outperformed those of ALA. ALA and CQ10 together worked better than either one alone to protect against AFB1-induced toxicity in the hepatic and renal parenchyma in terms of reducing inflammation, preventing DNA damage, and fighting free radicals.

Coenzyme Q10 ameliorates chemotherapy-induced cognitive impairment in mice: a preclinical study.

Among the three most used anticancer drugs, cyclophosphamide, Adriamycin, and 5-Fluorouracil (CAF), the most significant outcome is chemobrain, caused by increased oxidative stress, inflammatory insult, and mitochondrial dysfunction. In this study, endogenous antioxidant coenzyme Q10 (CoQ10) was evaluated for its neuroprotective effects in CICI. The chemobrain was induced in Swiss albino female mice by administering CAF (40 + 4 + 25mg/kg) intraperitoneal (i.p.) in three cycles (single injection per week) followed by treatment with CoQ10 (40mg/kg; p.o.) for up to 3weeks followed by behavioral, biochemical, molecular and histopathological analysis. Treatment with CoQ10 significantly improved cognition by improving exploring time in novel objects recognition test followed by increasing the time spent in the target quadrant in MWM test as compared to CAF-treated animals. Moreover, CoQ10 demonstrated antioxidant properties by reducing the expression of LPO while increasing levels of GSH, SOD, and catalase as compared to CAF-treated animals. While the levels of AChEs were significantly reduced after CoQ10 treatment in CAF-treated animals. In terms of its mechanism, it effectively counteracted the pro-inflammatory substances (TNF-α and IL-1β) triggered by CAF while also enhancing the levels of anti-inflammatory markers (IL-10 and Nrf2). Moreover, CoQ10 showed mitochondrial enhancers and it improved the level of Complex (I, II, and IV). Besides that, mitochondrial morphological analysis was done by TEM, and neuronal morphology along with quantification analysis was performed by H&E staining using Image J software to confirm the neuroprotective effect of CoQ10 over CAF-induced cognitive impairment. This study suggests CoQ10 can protect the mitochondria by imposing antioxidant, and anti-inflammatory properties, which could be a potential therapy for CICI.

Effects of coenzyme Q10 on orthodontic tooth movement and alveolar bone remodeling in rats.

To evaluate the effects of coenzyme Q10 (CoQ10) on alveolar bone remodeling and orthodontic tooth movement (OTM). An orthodontic appliance was placed in 42 female Sprague‒Dawley rats were divided into two groups: the orthodontic force (OF) group (n = 21) and the OF + CoQ10 (CoQ10) treatment group (n = 21). Each group was divided into 3 subgroups, and the rats were sacrificed on days 3, 7 and 14. The rats in CoQ10 and OF groups were administered 100mg/kg b.w./day CoQ10 (in 1 mL/b.w. soybean oil) and 1 mL b.w./day soybean oil, respectively, by orogastric gavage. The OTM was measured at the end of the experiment. The osteoclast, osteoblast and capillary numbers; vascular endothelial growth factor (VEGF), receptor activator nuclear kappa B ligand (RANKL) and osteoprotegrin (OPG) levels in tissue; and total antioxidant status (TAS) and total oxidant status (TOS) in blood were determined. Compared with the OF group, the CoQ10 treatment group exhibited decreased orthodontic tooth movement and osteoclast and capillary numbers. Indeed, the levels of VEGF and RANKL decreased, while the levels of OPG increased except on day 7. Additionally, the CoQ10 treatment group exhibited lower TOS and higher TAS on days 7 and 14 (p < 0.05). Histological findings showed that the morphology of osteoblasts changed in the CoQ10 group; however, there was no significant difference in the number of osteoblasts between the groups (p > 0.05). Due to its effect on oxidative stress and inflammation, CoQ10 regulates bone remodeling by inhibiting osteoclast differentiation, promoting osteoblast differentiation and reducing the amount of OTM. Considering that OTM may be slowed with the use of CoQ10, topics such as orthodontic treatment duration, orthodontic force activation and appointment frequency should be considered in treatment planning. It is predicted that the use of CoQ10 will support the effectiveness of treatment in clinical applications such as preventing relapse in orthodontic treatment by regulating bone modulation and anchorage methods that suppress/optimize unwanted tooth movement.

Anti-oxidant activity of coenzyme Q10 against AlCl3/D-galactose in albino rat induced cognitive dysfunctions: Behavioral, biochemical, and BACE-1/GSK-3β alterations.

The relationship between amyloid beta (Aβ) and oxidative stress (OS), both prominent factors in Alzheimer's disease-related neural degeneration, is deeply interconnected. The cleavage of the extracellular domain of Amyloid precursor protein (APP) and phosphorylating different substrates, respectively, the β-site amyloid precursor protein cleaving enzyme-1 (BACE-1) and Glycogen synthase kinase-3-beta (GSK-3β) enzymes initiate the synthesis of Aβ, which causes cognitive deficits in AD. This study aimed to explore the protective potential of Coenzyme Q10 (CoQ10). It also sought to uncover any synergistic effects when combined with donepezil, an acetylcholinesterase inhibitor, in treating Alzheimer's disease in male albino rats, focusing on the modulation of the BACE-1/GSK-3β pathway. The experiment involved 70 rats categorized into different groups: control, donepezil alone, CoQ10 alone, AD-model, donepezil co-treatment, CoQ10 co-treatment, and CoQ10+donepezil combination. Various assessments, such as cholinesterase activity, oxidative stress, serum iron profile, Brain Derived Neurotrophic Factor (BDNF), Tau protein, β-site amyloid precursor protein cleaving enzyme-1 (BACE-1), phosphatase and tensin homolog (Pten), and Glycogen synthase kinase-3-beta (GSK-3β), were conducted on behavioral and biochemical aspects. CoQ10 treatment demonstrated memory improvement, enhanced locomotion, and increased neuronal differentiation, mainly through the inhibition of the dual BACE-1/GSK-3β. These findings were substantiated by histological and immunohistological examinations of the hippocampus.

Coenzyme Q10 eyedrops conjugated with vitamin E TPGS alleviate neurodegeneration and mitochondrial dysfunction in the diabetic mouse retina.

Diabetic retinopathy (DR) is a leading cause of blindness and vision impairment worldwide and represents one of the most common complications among diabetic patients. Current treatment modalities for DR, including laser photocoagulation, intravitreal injection of corticosteroid, and anti-vascular endothelial growth factor (VEGF) agents, target primarily vascular lesions. However, these approaches are invasive and have several limitations, such as potential loss of visual function, retinal scars and cataract formation, and increased risk of ocular hypertension, vitreous hemorrhage, retinal detachment, and intraocular inflammation. Recent studies have suggested mitochondrial dysfunction as a pivotal factor leading to both the vascular and neural damage in DR. Given that Coenzyme Q10 (CoQ10) is a proven mitochondrial stabilizer with antioxidative properties, this study investigated the effect of CoQ10 eyedrops [in conjunction with vitamin E d-α-tocopheryl poly(ethylene glycol) 1000 succinate (TPGS)] on DR-induced neurodegeneration using a type 2 diabetes mouse model (C57BLKsJ-db/db mice). Utilizing a comprehensive electroretinography protocol, supported by immunohistochemistry, our results revealed that topical application of CoQ10 eyedrops conjugated with vitamin E TPGS produced a neuroprotective effect against diabetic-induced neurodegeneration by preserving the function and histology of various retinal neural cell types. Compared to the control group, mice treated with CoQ10 exhibited thicker outer and inner nuclear layers, higher densities of photoreceptor, cone cell, and rod-bipolar cell dendritic boutons, and reduced glial reactivity and microglial cell density. Additionally, the CoQ10 treatment significantly alleviated retinal levels of MMP-9 and enhanced mitochondrial function. These findings provide further insight into the role of mitochondrial dysfunction in the development of DR and suggest CoQ10 eyedrops, conjugated with vitamin E TPGS, as a potential complementary therapy for DR-related neuropathy.

Oral administration of coenzyme Q10 ameliorates memory impairment induced by nicotine-ethanol abstinence through restoration of biochemical changes in male rat hippocampal tissues

Substance abuse among adolescents has become a growing issue throughout the world. The significance of research on this life period is based on the occurrence of neurobiological changes in adolescent brain which makes the individual more susceptible for risk-taking and impulsive behaviors. Alcohol and nicotine are among the most available drugs of abuse in adolescents. Prolonged consumption of nicotine and alcohol leads to drug dependence and withdrawal which induce various dysfunctions such as memory loss. Coenzyme Q10 (CoQ10) is known to improve learning and memory deficits induced by various pathological conditions such as Diabetes mellitus and Alzheimer's disease. In the present study we investigated whether CoQ10 treatment ameliorates memory loss following a nicotine-ethanol abstinence. Morris water maze and novel object recognition tests were done in male Wistar rats undergone nicotine-ethanol abstinence and the effect of CoQ10 was assessed on at behavioral and biochemical levels. Results indicated that nicotine-ethanol abstinence induces memory dysfunction which is associated with increased oxidative and inflammatory response, reduced cholinergic and neurotrophic function plus elevated Amyloid-B levels in hippocampi. CoQ10 treatment prevented memory deficits and biochemical alterations. Interestingly, this ameliorative effect of CoQ10 was found to be dose-dependent in most experiments and almost equipotential to that of bupropion and naloxone co-administration. CoQ10 treatment could effectively improve memory defects induced by nicotine-ethanol consumption through attenuation of oxidative damage, inflammation, amyloid-B level and enhancement of cholinergic and neurotrophic drive. Further studies are required to assess the unknown side effects and high dose tolerability of the drug in human subjects.

The Effect of Coenzyme Q10 Supplementation on Bile Acid Metabolism: Insights from Network Pharmacology, Molecular Docking, and Experimental Validation.

Bile acids play a crucial role in lipid absorption and the regulation of lipid, glucose, and energy homeostasis. Coenzyme Q10 (CoQ10), a lipophilic antioxidant, has been recognized for its positive effects on obesity and related glycolipid metabolic disorders. However, the relationship between CoQ10 and bile acids has not yet been evaluated. This study assesses the impact of CoQ10 treatment on bile acid metabolism in mice on a high-fat diet using Ultra-Performance Liquid Chromatography-tandem Mass Spectrometry. CoQ10 reverses the reduction in serum and colonic total bile acid levels and alters the bile acid profile in mice that are caused by a high-fat diet. Seventeen potential targets of CoQ10 in bile acid metabolism are identified by network pharmacology, with six being central to the mechanism. Molecular docking shows a high binding affinity of CoQ10 to five of these key targets. Further analyses indicate that farnesoid X (FXR) receptor and Takeda G-protein coupled receptor 5 (TGR5) may be crucial targets for CoQ10 to regulate bile acid metabolism and exert beneficial effects. This study sheds light on the impact of CoQ10 in bile acids metabolism and offers a new perspective on the application of CoQ10 in metabolic health.

Efficacy of Kirin pill plus vitamin CE and coenzyme Q10 in the treatment of ovarian reserve hypofunction

Purpose: To investigate the efficacy of Kirin pill plus vitamin CE and coenzyme Q10 in the treatment of diminished ovarian reserve (DOR). &#x0D; Methods: 145 patients with ovarian reserve hypofunction hospitalized in Xiangyang Central Hospital, Xiangyang City, China from March 2019 to March 2022 were recruited and assigned randomly to receive either vitamin CE and coenzyme Q10 (control group), or vitamin CE and coenzyme Q10 plus Kirin pills (study group). The parameters/indices determined include menstrual recovery, clinical efficacy, sex hormone and serum anti-mullerian hormone (AMH) levels, changes in the number of ovarian sinus follicles, and levels of CD3+, CD4+ and CD8+ T cell. &#x0D; Results: There were no significant differences (p &gt; 0.05) observed among baseline data, pre-treatment sex hormones, serum AMH, ovarian antral follicle count, CD3+, CD4+, and CD8+ T cell levels. After the intervention, administration of the Kirin pill resulted in significantly lower serum follicle stimulating hormone (FSH) and FSH/luteinizing hormone (LH), elevated AMH levels, and better LH and estradiol (E2) levels in patients compared to the administration of vitamin CE and coenzyme Q10 (control group). The study group also showed superior ovarian reserve function and more ovarian basal sinus follicles than the control group (p &lt; 0.05). &#x0D; Conclusion: Kirin pill plus vitamin CE and coenzyme Q10 treatment regimen optimizes the ovarian reserve function of patients with DOR infertility by improving basal sex hormones, menstrual cycle and menstrual volume, AMH and ovarian basal sinus follicle count. Further clinical trials are required prior to application in clinical practice.

Mitochondrial Dysfunction due to Novel COQ8A Variation with Poor Response to CoQ10 Treatment: A Comprehensive Study and Review of Literatures.

COQ8A plays an important role in the biosynthesis of coenzyme Q10 (CoQ10), and variations in COQ8A gene are associated with primary CoQ10 deficiency-4 (COQ10D4), also known as COQ8A-ataxia. The current understanding of the association between the specific variant type, the severity of CoQ10 deficiency, and the degree of oxidative stress in individuals with primary CoQ10 deficiencies remains uncertain. Here we provide a comprehensive analysis of the clinical and genetic characteristics of an 18-year-old patient with COQ8A-ataxia, who exhibited novel compound heterozygous variants (c.1904_1906del and c.637C > T) in the COQ8A gene. These variants reduced the expression levels of COQ8A and mitochondrial proteins in the patient's muscle and skin fibroblast samples, contributed to mitochondrial respiration deficiency, increased ROS production and altered mitochondrial membrane potential. It isworthnotingthat the optimal treatment for COQ8A-ataxia remains uncertain. Presently, therapy consists of CoQ10 supplementation, however, it did not yield significant improvement in our patient's symptoms. Additionally, we reviewed the response of CoQ10 supplementation and evolution of patients in previous literatures in detail. We found that only half of patients could got notable improvement in ataxia. This research aims to expand the genotype-phenotype spectrum of COQ10D4, address discrepancies in previous reviews regarding the effectiveness of CoQ10 in these disorders, and help to establish a standardized treatment protocol for COQ8A-ataxia.

Protective effect of co-enzyme Q10 on testicular tissue and sperm parameters in adult male rats treated with Sunset Yellow FCF

Objective: To determine the protective effect of co-enzyme Q10 (CoQ10) on testicular tissue and sperm parameters in male rats treated with Sunset Yellow FCF. Methods: Sixty male Sprague-Dawley rats were randomly divided into 6 groups of the control, CoQ10 (10 mg/kg/day), low dose of Sunset Yellow (2.5 mg/kg), high dose of Sunset Yellow (70 mg/kg), low dose of Sunset Yellow (2.5 mg/kg) plus CoQ10, and high dose of Sunset Yellow (70 mg/kg) plus CoQ10. The drugs were administered via daily oral gavages for 6 weeks. At the end of the experiment, sperm analysis, stereological and histological assessments of the testis were carried out. Results: The normal morphology (by 41.1%) and progressive spermatozoa (by 74.8%), testicle volume (by 33.4%), lumen volume (by 38.3%), interstitial tissue volume (by 44.7%), seminiferous tubule volume (by 40.7%), and number of spermatogonia (by 53.9%) and Leydig cells (by 70.7%) reduced in the rats that received high doses of Sunset Yellow in comparison to the control group. Nonetheless, all these alterations were recovered by CoQ10 treatment in the CoQ10 plus high dose of Sunset Yellow group. Furthermore, low doses of Sunset Yellow did not affect different parameters of the testis and sperm. Conclusions: CoQ10 could, to some extent, prevent structural changes of the testis induced by the high dose of Sunset Yellow.

Dysregulation of mitochondrial dynamics mediated aortic perivascular adipose tissue-associated vascular reactivity impairment under excessive fructose intake

Excessive fructose intake presents the major risk factor for metabolic cardiovascular disease. Perivascular adipose tissue (PVAT) is a metabolic tissue and possesses a paracrine function in regulating aortic reactivity. However, whether and how PVAT alters vascular function under fructose overconsumption remains largely unknown. In this study, male Sprague-Dawley rats (8 weeks old) were fed a 60% high fructose diet (HFD) for 12 weeks. Fasting blood sugar, insulin, and triglycerides were significantly increased by HFD intake. Plasma adiponectin was significantly enhanced in the HFD group. The expression of uncoupling protein 1 (UCP1) and mitochondrial mass were reduced in the aortic PVAT of the HFD group. Concurrently, the expression of peroxisome proliferator-activated receptor-γ coactivator 1α (PGC-1α) and mitochondrial transcription factor A (TFAM) were suppressed. Furthermore, decreased fusion proteins (OPA1, MFN1, and MFN2) were accompanied by increased fission proteins (FIS1 and phospho-DRP1). Notably, the upregulated α-smooth muscle actin (α-SMA) and osteocalcin in the PVAT were concurrent with the impaired reactivity of aortic contraction and relaxation. Coenzyme Q10 (Q, 10 mg/100 mL, 4 weeks) effectively reversed the aforementioned events induced by HFD. Together, these results suggested that the dysregulation of mitochondrial dynamics mediated HFD-triggered PVAT whitening to impair aortic reactivity. Fortunately, coenzyme Q10 treatment reversed HFD-induced PVAT whitening and aortic reactivity.

The Spectrum of clinical manifestations in newborns with the COQ4 mutation: case series and literature review.

Coenzyme Q10 (CoQ10) plays an important role in the electron transport chain within the human mitochondrial respiratory chain. The manifestations of this deficiency exhibit a diverse range. This study investigates the clinical manifestations of primary coenzyme Q10 deficiency in neonates with the COQ4 mutation to improve the diagnosis of the disease and the prognosis through targeted treatment. We report 4 patients with primary coenzyme Q10 deficiency by COQ4 variants in neonates. A comprehensive literature search and review for original articles and case reports with COQ4 mutation published from January 1989 to November 2023 was performed through Pubmed. We review clinical manifestations, diagnostic approaches, and treatment monitoring in these and 20 previously reported patients. Within the cohort of four cases examined, three females and one male were identified from two distinct families. Specifically, case 1 and 2 consisted of monoamniotic twins. Cases 3 and 4 were siblings. A comprehensive review of 20 cases involving neonatal-onset COQ4 mutation was conducted. Half of the cases are Chinese. There was no statistically significant difference in the mortality between Chinese (9/12, 75%) and other regions (11/12, 91.7%) (P = 0.27). The survival time for the 24 cases was 60.0 ± 98.0 days (95% confidence interval CI: 0-252.0 days). The incidence of prenatal abnormalities in preterm infants was significantly higher than that in full-term infants (66.7% vs. 16.7%, P = 0.02). Hyperlactatemia was one of the most common manifestations, accounting for 75% of cases (18/24). Twenty of the 24 cases were diagnosed by whole exome sequencing. Only 9 patients received exogenous coenzyme Q10 treatment, and all the 4 surviving patients received coenzyme Q10 supplementation. The prognosis of COQ4 mutation in the neonatal period indicates a low survival rate and an poor prognosis. This may be due to the incomplete understanding of the mechanism of how COQ4 gene defects lead to coenzyme Q10 deficiency and why CoQ10 supplementation does not respond well to treatment. To improve the diagnostic rate, in addition to genetic testing, mitochondrial functional verification should be prioritized in southern China, where the incidence is relatively high. It will facilitate more in-depth mechanistic studies.

Protective Impact of Combined Perindopril and Coenzyme Q10 Treatment Against Cerebral Ischemia/Reperfusion Injury in Male Rats

Background: Cerebral ischemia is reason of death and disability worldwide with 11.6\% of all death and 5.7\% of the total disability. Thrombosis and embolism of a major cerebral artery, mainly the middle cerebral artery, account for over 70\% of stroke cases. The other major type of stroke is cerebral hemorrhage either intracerebral or subarachnoid hemorrhage. The oxygen requirements of the nervous tissue are excessively high bringing the brain highly susceptible to ischemia. The subsequent reperfusion after brain ischemia can precipitate more brain injury. Objectives: Assess the neuroprotective effects of perindopril and coenzyme Q10 in combination, as well as to speculate on their mechanism. Method: A total of forty-nine adult male Sprauge-dawley rats weighing between 200 and 300 g were randomly assigned to 7 groups: sham (no Bilateral common carotid artery occlusion (BCCAO)), control group (BCCAO for 30 minutes followed by reperfusion for an hour), vehicle-1 group (rat were pretreatment with oral 1% carboxymethylcellulose for seven days followed by control group), vehicle-2 group (seven days of oral distilled water pretreatment then as control group), perindopril group (rat were pretreatment with perindopril for then as control group), coenzyme Q10 group (rat were pretreatment with coenzyme Q10 for seven days then as control group), and combination group (rat were pretreatment with perindopril plus coenzyme Q10 for seven days then as control group). The brain tissues were separated in order to measure the size of the brain infarction, assess the histology, and measure the levels of cerebral IL-6, IL-10, TNF-\(\alpha\), ICAM-1, NF-\(\kappa\)B p65, and total antioxidant capacity. Results: The brain levels of IL-6, IL-10, ICAM-1, TNF-\(\alpha\), NF-\(\kappa\)B p65, and the cerebral infarct size were substantially increased in control and vehicle in relation to sham groups, while the total anti-oxidant capacity was considerably reduced. Perindopril and coenzyme Q10 treatment alone and in combination resulted in marked elevation in IL-10 and the total antioxidant capacity, with significant decrement in IL-6, ICAM-1, TNF-\(\alpha\), and NF-\(\kappa\)B p65 in respect to vehicle and control group. There was severe histopathological ischemic damage in control and vehicle groups which was remarkedly decreased by perindopril and coenzyme Q10 treatment alone and in combination pretreatment. Conclusions: Due to their anti-inflammatory and anti-oxidative characteristics, perindopril and coenzyme Q10, either separately or in combination, exhibit neuroprotective benefits in male rats that have been treated to cerebral ischemia/reperfusion injury.

The activator protein-1 complex governs a vascular degenerative transcriptional programme in smooth muscle cells to trigger aortic dissection and rupture.

Stanford type A aortic dissection (AD) is a degenerative aortic remodelling disease marked by an exceedingly high mortality without effective pharmacologic therapies. Smooth muscle cells (SMCs) lining tunica media adopt a range of states, and their transformation from contractile to synthetic phenotypes fundamentally triggers AD. However, the underlying pathomechanisms governing this population shift and subsequent AD, particularly at distinct disease temporal stages, remain elusive. Ascending aortas from nine patients undergoing ascending aorta replacement and five individuals undergoing heart transplantation were subjected to single-cell RNA sequencing. The pathogenic targets governing the phenotypic switch of SMCs were identified by trajectory inference, functional scoring, single-cell regulatory network inference and clustering, regulon, and interactome analyses and confirmed using human ascending aortas, primary SMCs, and a β-aminopropionitrile monofumarate-induced AD model. The transcriptional profiles of 93 397 cells revealed a dynamic temporal-specific phenotypic transition and marked elevation of the activator protein-1 (AP-1) complex, actively enabling synthetic SMC expansion. Mechanistically, tumour necrosis factor signalling enhanced AP-1 transcriptional activity by dampening mitochondrial oxidative phosphorylation (OXPHOS). Targeting this axis with the OXPHOS enhancer coenzyme Q10 or AP-1-specific inhibitor T-5224 impedes phenotypic transition and aortic degeneration while improving survival by 42.88% (58.3%-83.3% for coenzyme Q10 treatment), 150.15% (33.3%-83.3% for 2-week T-5224), and 175.38% (33.3%-91.7% for 3-week T-5224) in the β-aminopropionitrile monofumarate-induced AD model. This cross-sectional compendium of cellular atlas of human ascending aortas during AD progression provides previously unappreciated insights into a transcriptional programme permitting aortic degeneration, highlighting a translational proof of concept for an anti-remodelling intervention as an attractive strategy to manage temporal-specific AD by modulating the tumour necrosis factor-OXPHOS-AP-1 axis.

Neuroprotective effects of Coenzyme Q10 in ischemia-reperfusion injury via inflammation and oxidative stress reduction in adult male rats.

This study aimed to investigate the potential neuroprotective effects of coenzyme Q10 in cerebral ischemia-reperfusion injury-induced neuronal damage and explore the underlying mechanisms. Twenty-eight adult male rats, weighing approximately 200-300 grams, were randomly divided into four groups: the sham group (neck dissection without ischemia), the control group (30 minutes of bilateral common carotid artery ligation followed by one hour of reperfusion), the vehicle group (oral carboxymethylcellulose solution for seven days prior to bilateral common carotid artery ligation and reperfusion), and the treatment group (seven days of coenzyme Q10 pretreatment followed by bilateral common carotid artery occlusion and reperfusion). Histopathological analysis and measurement of brain infarct size were performed, and cerebral levels of IL-6, IL-10, TNF-α, ICAM-1, NF-κB p65, and total antioxidant capacity were assessed. These cerebral tissue levels and cerebral infarct size were significantly elevated in the control and vehicle groups compared to the sham group. Conversely, the total antioxidant capacity was significantly reduced in these groups. Coenzyme Q10 treatment resulted in a significant increase in IL-10 and total antioxidant capacity levels, along with a significant decrease in IL-6, ICAM-1, TNF-α, and NF-κB p65 levels. Histopathological analysis revealed a significant reduction in ischemic damage in the coenzyme Q10-treated group. Coenzyme Q10 has neuroprotective properties in rats subjected to cerebral ischemia/reperfusion injury, possibly through its anti-inflammatory and anti-oxidative effects.