1. Introduction

Diabetes mellitus (DM) is a disease of global prevalence, and its incidence is steadily increasing [1]. DM can be categorized into four clinically distinct types including type 1 diabetes (T1D), type 2 diabetes (T2D), gestational diabetes (GD), and other specific types, which together affect 425 million people worldwide [2,3]. T1D is a heterogeneous disease characterized by immune-mediated destruction of pancreatic beta cells, resulting in complete insulin deficiency. T1D accounts for 5–10% of the overall cases of diabetes and its progression is majorly driven by both genetics and environmental factors. In contrast, T2D is far more prevalent and constitutes 90–95% of total DM diagnoses. Its development is primarily attributed to insulin resistance, the pathology of which is correlated with lifestyle and environmental changes that have perturbed metabolic pathways, resulting in the elevation of pathophysiological processes associated with T2D susceptibility. Without better interventions, T2D is expected to affect 700 million people in the next several decades [2]. Another class of DM that develops explicitly during second or third trimester of pregnancy, leading to insulin resistance, is GD. Also, in few individuals, specific types of diabetes develop due to other causes, e.g., pre-existing diseases such as pancreatitis and cystic fibrosis, or to the administration of medications like glucocorticoids [3]. DM patients display an increased risk of developing adverse cardiovascular diseases (CVDs) such as valvular heart disease (VHD), ischemic heart disease (IHD), coronary artery disease (CAD), and diabetic cardiomyopathy (DCM), which account for 50.3% of all deaths in diabetic patients [4,5]. Additionally, microvascular (neuropathy, nephropathy, and retinopathy) and macrovascular complications (coronary heart disease, cerebrovascular disease, and peripheral artery disease) are also significant comorbidities affecting 12% of diabetic patients worldwide [5,6]. Considering the consistent increase in diabetes cases and the associated cardiac and vascular complications, it is imperative that we improve our understanding of these underlying pathophysiological mechanisms to develop better diagnostic tools and preventive measures for complications in diabetic patients.

Mitochondria serve as the cell’s powerhouse, as they are the major sites of energy production within the cell. Over the past few years, there has been a significant surge in publications addressing oxidative stress and impairment of mitochondrial homeostasis in diabetes pathogenesis [7,8]. T2D is a chronic heterogeneous disease associated with hyperglycemia, accumulation of advanced glycation end-products (AGEs), elevated fatty acid levels and dyslipidemia, inflammation, elevated production of reactive oxygen species (ROS), and impaired mitochondrial function [9,10,11]. In addition, an immense body of research has focused on ROS-induced damage in endothelial, cardiac, and other cell types, leading to the onset of diabetes-related secondary complications [12,13]. For instance, high levels of glucose, free fatty acids and lipid metabolites such as ceramide in both animal models of diabetes, and in T2D patients, is often deemed to elevate oxidant production, affecting components of the mitochondrial electron transport chain(ETC) to augment ROS production and result in oxidative stress [14,15,16,17,18,19,20]. In fact, this elevated fatty acid level-induced ROS is also found to contribute to DCM development via impairment of mitochondrial function and activation of sensitive proteases that cleave structural proteins, resulting in loss of sarcomere integrity and distortion of the structure of cardiomyocytes (CMs) [21,22,23]. Additionally, dysregulation in peroxisome proliferator-activated receptors (PPARs) expression, responsible for fatty acids (FAs) oxidation in animal models of diabetes, has been reported to enhance mitochondrial ROS generation, mitochondrial respiratory dysfunction, and apoptosis in diabetic complications [24,25,26,27,28]. Moreover, a multitude of studies suggest that oxidative stress may modulate the expression signature of numerous long noncoding RNAs (lncRNAs), contributing to diabetes disease pathogenesis [29,30]. Therefore, it is essential to seek valuable diagnostic biomarkers of oxidative stress and relevant strategies to mitigate mitochondrial oxidative stress to prevent diabetes disease development. To gain insight into the role oxidative stress, mitochondrial dysfunction, and relevance of lncRNAs play in the pathogenesis and diagnosis of DM, as well as applications of conventional and emerging antioxidant modalities in diabetic complications, we used PubMed and Google scholar databases to search literature systematically up to December 2022.

This review presents an overview of the role of oxidative stress and the methods to assess it in diabetes-related complications. Additionally, we discuss the emergence of lncRNA as biomarkers of oxidative stress and their role in modulating redox balance and mitochondrial function in diabetes-related vascular complications. Finally, we discuss the challenges of conventional antioxidants and the potential use of mitochondrial-targeted antioxidants (MTAs) to combat mitochondrial dysfunction and oxidative stress as a therapeutic strategy that may prevent diabetic complications.

2. Implication of Oxidative Stress in Diabetes Related Complication

2.1. Oxidative Stress and Mitochondria

Oxidative stress refers to the state of redox imbalance between the intracellular production of oxidants, and their neutralization by enzymatic and non-enzymatic antioxidants under physiological or stress conditions [31,32,33]. ROS is a collective term used to define the direct and downstream products formed upon one- or two-electron reduction of molecular oxygen (O₂) [34]. Many ROS are free radicals, including superoxide radical anion (O₂^•−), hydroxyl radical (^•OH), peroxyl radicals (ROO^•), alkoxyl radicals (RO^•), nitrogen dioxide (^•NO₂) and carbonate radical anion (CO₃^•−). Non-radical ROS include hydrogen peroxide (H₂O₂), organic peroxides (ROOH), hypohalous acid (HOCl, HOBr), and peroxynitrite (ONOO⁻) acting as oxidizing, halogenating and/or nitrating species [34,35].

ROS are produced via enzymatic reactions in mitochondria, endoplasmic reticulum (ER), peroxisomes, microsomes, and by NADPH oxidase (NOX) complexes in cellular membranes [36]. Among different intracellular sources of ROS, mitochondria are considered a substantial contributor due to the “electron leak” from the ETC [37,38]. Under aerobic conditions, cells utilize mitochondria as essential organelles to generate energy in the form of adenosine triphosphate (ATP) via a process known as oxidative phosphorylation (OXPHOS). This process involves oxidation of energetic substrates and a transfer of electrons via ETC complexes to reduce O₂ to water (H₂O) at complex IV of the ETC. Mitochondrial complexes I-III are not capable of 4-electron reduction of O₂ to H₂O, and the transfer of electrons to O₂ at these complexes results in the formation of O₂^•− [37]. While O₂^•− is likely to be primarily produced by the redox centers of the respiratory chain including complex I (NADH: ubiquinone oxidoreductase) and complex III (ubiquinone: cytochrome c oxidoreductase; cytochrome bc1 complex other potential sources include associated metabolic enzymes like xanthine oxidase (XO), and α-ketoglutarate dehydrogenase [37,38,39,40,41,42,43,44,45]. Of note, the production of O₂^•− within the mitochondria is relatively higher in its resting stage, favored by the high protonmotive force (Δp), NADH/NAD⁺ ratio and reduced coenzyme Q (CoQ) pools [37]. Upon formation, O₂^•− can quickly react with cellular targets such as aconitases or may be converted to other forms of ROS, including the reaction with ^•NO to form ONOO⁻, or superoxide dismutase-catalyzed or non-enzymatic dismutation to H₂O₂. H₂O₂ can be further converted to ^•OH in the presence of transition metal ions, or to an array of oxidizing, halogenating or nitrating species in the presence of peroxidases [39].

Prominent non-mitochondrial sources of O₂^•− include the NOX family of transmembrane enzymes NOX isoforms 1–5, and dual oxidases (Duox) 1 and 2 responsible for the generation of O₂^•− and/or H₂O₂ via catalyzing the transfer of electrons to O₂ from NADPH [46,47]. Additionally, accumulating lines of evidence have indicated a positive correlation between protein misfolding-induced ROS generation mediated via protein disulfide isomerase (PDI)-endoplasmic reticulum oxidoreductase (ERO)-1, glutathione (GSH)/glutathione disulfide (GSSG), NADPH oxidase 4 (Nox4), and NADPH-P450 reductase (NPR) in the ER lumen [48,49,50]. Moreover, extracellular sources like ionizing radiation, toxic chemicals (e.g., paraquat), pollutants, and drugs (e.g., Adriamycin, bleomycin) can also stimulate cellular production of ROS [51,52,53].

Under normal physiological conditions, 0.2–2.0% of the total O₂ consumed by the mitochondria may be reduced to O₂^•−/H₂O₂ [54,55]. This fraction may further increase under pathological conditions [56,57]. Increased production of ROS may result in modification of various cellular components, resulting in cellular dysfunction and death. Cellular targets of ROS include proteins, lipids, and DNA [58]. Oxidative stress-induced lipid peroxidation forms lipid radicals, peroxyl radical and hydroperoxide, eventually resulting in several low-molecular-weight decomposition products, such as acrolein, malondialdehyde (MDA), and 4-hydroxy-2-nonenal (4HNE). ROS may interact directly with protein amino acids (e.g., oxidation of cysteine thiol group, oxidation and nitration of tyrosine, oxidation of tryptophan), or proteins may be modified by the above-mentioned products of lipid peroxidation. Oxidative post-translational modification of cellular proteins may be involved in redox signaling but may also lead to protein inactivation and/or degradation [59,60]. Interaction of ROS with DNA may result in modification of individual nucleotide bases, single-strand breaks, and cross-linking [61].

Under pathological conditions such as glucolipotoxicity, as seen in DM, mitochondria produce excessive ROS that alter mitochondrial dynamics [62]. In the mammalian cell, mitochondrial dynamics comprise mitochondria fission regulated by fission 1 protein (Fis1) and dynamin-related protein 1(Drp1), whereas mitochondrial fusion is modulated by mitofusin2 (Mfn2) and optic atrophy protein 1 (OPA1) [63,64]. Numerous studies have illustrated that oxidative stress developed during DM leads to mitochondrial dysfunction because of dysregulation between fission/fusion and regulatory factors, increasing the production of ROS, which is associated with diabetic complications [65,66]. Furthermore, unbalanced fission/fusion can affect various biological processes, such as apoptosis, leading to different pathological complications. For instance, some studies showed that increased ROS emission mediated mitochondrial fission. At the same time, others indicated that fission was the cause of ROS. Intriguingly, in the past few years, normalization of ROS emission using conventional antioxidants have been reported to mitigate diabetes-related modulating mitochondrial regulatory factors Drp1/Mfn2. Additionally, under oxidative stress, mitochondrial-generated ROS contributes to mtDNA damage in patients with DM characterized by decreased functioning and glucose-stimulated insulin secretion of β cells.

Overall, oxidative stress has been implicated in the development of various diseases, highlighting the importance of improving our understanding of oxidative stress-related mechanisms contributing to the crosstalk between redox imbalance, ROS and mitochondrial dysfunction and their role in vascular diseases in diabetes.

2.2. Mediators of Oxidative Stress and Their Role in the Development of Diabetic Complications

Under conditions of cellular homeostasis, ROS has been shown to play an essential role in numerous physiological processes via participating in various signaling networks [67]. However, increased production of ROS has been implicated in the mechanisms of diabetes-induced pathological complications including inflammation, autophagy, fibrosis, necrosis, and apoptosis, impairing the biological function of different organs [9]. Typically, in T2D, a metabolic shift leads to impaired glucose tolerance and lipid metabolism. These may result in hyperlipidemia and consequent accumulation of ectopic lipid metabolites, including diacylglycerol (DAG), long-chain acyl-CoAs (LCACoA), and ceramide [68]. This results in increased free radical production and interferes with insulin signaling in adipocytes and non-adipose tissues like liver and skeletal muscle [69]. For instance, accumulation of DAG in the liver was associated with the activation of protein kinase Cε(PKCε), subsequently reducing the phosphorylation of insulin-stimulated receptor substrate-2(IRS-2) via inhibition of insulin receptor kinase activity, which leads to hepatic insulin resistance [70,71]. Similarly, LCACoA, through stimulation of PKC isoenzymes, disrupts muscle glucose utilization promoting insulin resistance. Additionally, ceramide attenuates insulin signaling and promotes insulin resistance by blocking the transmission via phosphatidylinositol-3kinase (PI3K) and inhibiting the activation of Akt kinase/Protein B(PKB) [72].

The progression of diabetes-related complications is also determined by the intracellular and extracellular production and accumulation of AGEs. Glucose at high concentrations tends to react with free amino groups in the proteins, forming a Schiff base, which fosters the production of AGEs. AGEs impart diverse effects in cells via receptor-dependent- and independent mechanisms thereby contributing to the complications of diabetes by raising intracellular oxidative stress and chronic inflammation [73,74]. For instance, AGE interaction with advance glycation end product-specific receptor (RAGE) on the endothelial cell surface can stimulate NADPH oxidase-mediated ROS production [75]. Additional mechanisms such as AGE-induced ROS generation and the subsequent increased activation of monocyte chemoattractant protein 1 (MCP1), and intracellular adhesion molecule-1 (ICAM-1) accelerated inflammation and were associated with severity of diabetic complications [76,77,78]. Evidence of AGE/RAGE mechanisms exacerbating micro vasculopathy in vivo has also been demonstrated. Diabetic leptin receptor (Lepr^dbdb) deficient mice displayed increased expression and production of tumor necrosis factor (TNF-α) and ROS, subsequently increasing the transcription factor nuclear factor-κB (NF-κB) [79]. Further, diabetic apolipoprotein (ApoE) deficient mice devoid of RAGE displayed reduced atherosclerosis [80].

Intracellular signal transduction of ectopic lipid metabolites and AGEs increases intracellular ROS. Numerous studies have demonstrated that ROS induced substantial damage to macromolecules, including nucleic acids, lipids, and proteins [61]. For instance, clinical studies have shown elevated levels of oxidized DNA products such as 8-hydroxy-2′-deoxyguanosine (8-OHdG) and 8-oxo-7,8-dihydro-2′-deoxyguanosine(8-oxodG), the products of ROS-induced DNA damage, in the blood and urine specimens of diabetic patients compared to their respective controls [81,82,83,84,85]. Similarly, lipid oxidation products like malondialdehyde (MDA), 4-hydroxynonenal (4HNE), and thiobarbituric acid-reactive substances (TBARS) have been quantified in biological fluids to assess oxidative stress in diabetic patients [86,87,88,89,90]. It should be noted, however, that photometric analyses of TBARS need to be further validated by identification of the products formed before the results can be interpreted as indicative of increased lipid peroxidation. Interestingly, hyperglycemia often alters the activity of critical proteins involved in antioxidant defense, such as superoxide dismutases (SOD), glutathione peroxidases (GPX), and catalase (CAT) which are found to corelate with clinical parameters such as glycated hemoglobin (Hb1Ac) and oxidative stress biomarkers 8-OHdG in diabetic patients [91,92,93,94].

Despite their methodological limitations, both DNA oxidation biomarkers and markers of lipid peroxidation provide experimental support for the involvement of oxidative stress in diabetes and diabetic complications. However, from mechanistic, diagnostic, and therapeutic standpoints, improved assays and oxidative stress biomarkers need to be established and validated for both qualitative and quantitative characterization of the oxidative stress component, with rigorous identification of the products of oxidative modification of biomolecules in collected biological fluids.

2.3. Circulating lncRNAs: Emerging Biomarkers of Oxidative Stress in Diabetes Complication

Long non-coding RNAs (lncRNAs) depict the most diverse class of non-coding RNA transcripts, including linear and circular RNAs (circRNAs) > 200 nt in length, with no significant role in translation [95,96]. Current transcriptome profiling and RNA sequencing data from various studies highlight the presence and stability of these lncRNAs in biological fluids, including blood, serum, plasma, and urine, raising the possibility that they might have clinical significance [97,98,99,100]. High-throughput RNA sequencing and profiling data from past studies, including ours, have elucidated the association of aberrant signatures of circulating lncRNA with diabetic complications, establishing their potential value as biomarkers for early prediction of diabetes development and for developing a strategy for its management [101,102]. In this section, we specifically emphasize the circulating lncRNAs implicated with oxidative stress and those which have clinical significance in diabetes-related CVDs (Figure 1).

Recently, several studies investigated changes in the signature of circulating lncRNA and their association with oxidative stress in diabetes-associated complications. For example, patients with diabetic nephropathy (DN) had a significantly higher expression level of circulating lncRNA Metastasis-associated lung adenocarcinoma transcript 1 (MALAT1), also known as NEAT2, which was accompanied by decreased levels of SOD [103]. Also, the expression of lncRNA CASC2 was significantly reduced in the serum of DN patients and human mesangial cells (HMCs) cultured under high glucose (HG) in vitro. Restoration, of the CASC2 expression was found to mitigate HG-induced oxidative stress in vitro via modulating the miR-133b/FOXP1 axis [104]. In addition to DN, impaired circulating lncRNA expression indicates the redox status of diabetes retinopathy (DR) patients. Atef et al. [105] found that the expression of lncRNA HIF1A-AS2 was increased in the serum of proliferative DR patients, and its expression level was found to positively correlate (p < 0.05) with predictors of oxidative stress [105]. Recently, Antisense RNA to INK4 locus (ANRIL), also known as CDKN2B-AS1, has been reported to play a significant role in the pathogenesis and development of diabetes-induced complications [106]. Silencing ANRIL expression restored HG-induced oxidative stress in podocytes via upregulating membrane metal endopeptidase (MME) in DKDs [107]. Similarly, lncRNA Brown Fat lncRNA 1(Blnc1) was upregulated in the serum of DN patients compared to matched controls (n = 30) and in streptozotocin-induced diabetic mice models and high glucose-induced HK2 cells. Suppression of Blnc1using siRNA in vitro was found to mitigate oxidative stress and inflammation via modulation of NRF2/HO-1 and NF-κB pathways in HK2 cells [108].

Besides the lncRNAs mentioned above, other investigators also found dysregulation in lncRNA expression in diabetic patients with cardiovascular complications. For example, Zhu et al. [109] reported elevated expression of ANRIL in circulating PBMCs of patients with DKDs which showed positive correlation with disease progression [109]. On the other hand, in patients with diabetic lung disease, the serum expression level of smoke and cancer-associated lncRNA 1 (SCAL1) was significantly downregulated. Intriguingly, the expression level of SCAL1 and that of iNOS and NO production depicted an inverse correlation when investigated in HG (30 mM) cultured normal lung cells, which could be attenuated by overexpression of SCAL1 [110]. Furthermore, the level of another lncRNA NEAT1 was found to be high in the plasma of diabetic ischemic stroke patients (DISP) [111]. Again, in T2DM patients, the circulating lncRNAs NKILA, NEAT1, MALAT, and MIAT were highly correlated with the clinical parameters [112].

Altogether, the studies mentioned above indicate that changes in the expression of human lncRNAs can be correlated to oxidative stress and may serve as a diagnostic and prognostic biomarker. However, the inadequacies of the present studies such as (a) insufficient sample size; (b) ambiguity regarding the function of several lncRNAs and the way they modulate oxidative stress, (c) changed expression signature being precisely due to oxidative stress, as opposed to a consequence of diabetes and (d) lncRNA stability in subjects requiring more extended period for sample collection raise few challenges that need to be addressed. Future studies should focus on modifying oxidative stress to quantify lncRNA levels and derive a direct link between them. Furthermore, future studies can be focused on prospectively tracking the changes of these circulating lncRNAs with disease progression, which can then be used to develop a therapeutic intervention to mitigate disease development and progression. (Table 1) summarizes emerging lncRNAs as oxidative-stress biomarkers.

2.4. LncRNA as Regulators of Oxidative Stress and Mitochondrial Function in Diabetic Complications

Mitochondria can utilize a dynamic range of substrates for generating ATP through OXPHOS to maintain energy homeostasis [113]. The coding and regulation of the functional proteome machinery of the mitochondria are complicated as its components are derived from both mitochondrial and nuclear genomes [114,115]. The advancement of OMIC and NGS technologies has provided a greater insight into the context of the subcellular localization and transportation of lncRNA transcripts between organelles [116]. Over the past decade, lncRNAs have emerged as a critical regulator of essential cellular processes, including metabolism [117]. Additionally, an emerging line of evidence indicates that mitochondria-associated lncRNA (mtlncRNA) transcripts, including the RNAs derived from mtDNA and nuclear-encoded DNA, work in concert with transcription factors and other epigenetic regulators to modulate oxidative stress and mitochondrial functions [118,119]. Moreover, numerous lncRNA have been cataloged to translocate to the mitochondria and impact its structure, function, and genomic integrity [120]. However, the exact mechanisms via which lncRNA can modulate redox homeostasis and mitochondrial function in diabetes-associated complications remain poorly understood. This section explicitly discusses the pathophysiological relevance of dysregulated lncRNAs in the HG environment and their role in modulating oxidative stress and mitochondrial function (Figure 2).

In recent years several studies showed that dysregulated lncRNAs were involved in regulating redox homeostasis in diabetic complications. For instance, lncRNA Lethe expression was found to be downregulated in RAW264.7 macrophages cultured under high glucose conditions (25 mM) for 24 h. with concomitant increase in ROS production and NOX2 expression. A similar expression of lncRNA Lethe was observed in a mouse model of diabetic wound healing. The overexpression of Lethe in the RAW264.7 cell was found to mitigate hyperglycemia-induced oxidative stress via binding to the p65 subunit of NF-κB and blocking its binding to DNA attenuating NOX2 expression [121]. In another study, Xie and colleagues [122] identified lncRNA Gas5 expression to be downregulated in the HG-stimulated HK2 cells. They also revealed HG upregulated ROS, TNF-α, IL-6, MCP1, and miR-452-5p and decreased the expression levels of SOD in HK2 cells. Meanwhile, Gas5 overexpression in HG-stimulated HK-2 cells transfected with pcDNA-GAS5 was found to revert oxidative stress and pyroptosis, downregulating the expression of miR-452-5p [122]. MALAT-1 is among the most well-studied lncRNA in the nervous system and has numerous neurological functions such as synapse formation and dendrite growth. The impact of MALAT-1 on neurological function was validated in a rat model of diabetes and after gain-and-loss of function studies in HG-cultured brain microvascular endothelial cells (BMEC), demonstrating that inhibiting lncRNA MALAT1 by siRNA lessens apoptosis of microvascular endothelial cells cultured in high glucose via activating the miR-7641/TPR axis [123]. Additionally, LINC01619 lncRNA was downregulated explicitly in podocyte cells, inducing oxidative and ER stress via modulating miR-27a/FOXO1 and subsequently impairing renal function in DN patients [124].

Mechanistic and functional studies on the implication of individual lncRNAs that influence mitochondrial function in diabetic complications are also emerging. Our group was one of the first to show dysregulation of thousands of lncRNA alongside mRNA and its association with DCM development both in diabetic mice and human induced pluripotent stem cell-based disease modeling [125,126]. Interestingly, several dysregulated lncRNAs from our studies were associated with crucial signaling pathways, including TNF-α- and p38 MAPK- that modulate mitochondrial function in DCM [102]. More recently, Zhang et al. [127] described the role of lncRNA LncDACH1 modulating mitochondrial oxidative stress by interacting with sirtuin3 in the DCM heart and HG-stimulated cardiomyocytes. The expression of lncDACH1 was found to be decreased under hyperglycemic conditions, exacerbating mitochondria-derived reactive oxygen species (mtROS) levels, apoptosis and decreasing the activity of manganese superoxide dismutase (Mn-SOD). Meanwhile, the silencing of lncDACH1 attenuated ROS production, mitochondrial dysfunction, cell apoptosis, and increased the activity of Mn-SOD in cardiomyocytes treated with HG [127]. Following the studies above, nuclear encoded lncMALAT1 and lncNEAT1 were reported to translocate to the mitochondria of HG cultured human retinal endothelial cells (HRECs), affecting mitochondrial structure and function and leading to oxidative stress. Modulating the expression of lncMALAT1 and lncNEAT1 by their respective siRNA restored mitochondrial homeostasis by mitigating oxidative stress [128].

In summary, deciphering the epigenetic modulations and mechanism of action of lncRNAs implicated in oxidative stress-induced mitochondrial dysfunction might pave the path for lncRNA-based therapeutics to prevent diabetic complications. Different dysregulated lncRNAs and their role in modulating mechanisms associated with oxidative stress and mitochondrial function are summarized in (Table 2).

2.5. Conventional Antioxidants and Their Application in Diabetic Complications: Success and Limitations

Cells have complex antioxidant systems consisting of both enzymatic and nonenzymatic processes that work harmoniously to protect the organism against damage caused by free radicals. Unfortunately, these antioxidant defenses may be downregulated in people with diabetes, as suggested by the reports of reduced plasma/serum status of total antioxidants, scavenging activity of free radicals, certain antioxidant enzymes and levels of specific antioxidants, including vitamin E and ascorbic acid [129]. The resultant augmentation of oxidative stress, combined with the association between diabetes susceptibility risk and antioxidant intake or serum levels, would suggest that mitigating oxidative stress via treatment with antioxidants may be an effective strategy for preventing or managing diabetic complications. Indeed, many animal studies involving treatment with various antioxidants have demonstrated reversals in diabetes-induced changes of oxidative stress indicators. However, a cautionary note in interpreting the results of these studies would be to consider the extensive assortment of the experimental model of diabetes, duration of the studies, and type of antioxidant used in addition to the markers that were evaluated for oxidative stress. Moreover, the results of many studies may need to adequately reflect the actual serum antioxidant status as they are focused on only a limited number of individual antioxidants [130]. There are also different categories of antioxidants: those that prevent the initiation of radical chain reaction and those that interrupt the oxidative process altogether by interacting with chain-propagating radicals to form stable products [131]. Further complicating matters is that their respective activities or impact can be measured regarding their binding capacities or serum concentrations. Accordingly, caution may be warranted when interpreting results depending on the type of antioxidant studied and the assay performed. While studies with experimental models have shown favorable effects of antioxidants reducing diabetic complications, evidence for using classic antioxidant regimes from clinical trials has demonstrated variable and conflicting results. For example, in a prospective cohort study, intake of vitamin C was found to be associated with reduced development of diabetes [132] and potentially being effective against complications faced by diabetics [133]. However, these findings are discounted by the reports of unsuccessful clinical trials, even trials with observed increases in plasma vitamin C [134,135,136]. N-acetylcysteine (NAC) is an L-cysteine prodrug whose antioxidant properties are due to its ability to replenish levels of intracellular glutathione (GSH). It’s the only antioxidant drug to have clinical utility in improving a renal condition whose pathologic mechanism may involve oxidative stress. A pilot study demonstrated that NAC could not reduce serum biomarkers of oxidant stress in patients with diabetic proteinuria [134] even though preclinical studies have shown cardiovascular benefits or reduced progression of diabetes attributed to NAC-mediated inhibition of ROS production [137,138,139]. Intake of the fat-soluble vitamin E, known to be deficient in diabetes, was reported to be significantly associated with reduced risk of type 2 diabetes [140]. While clinical trials demonstrated favorable effects of its supplementation on biomarkers of oxidative stress [141,142] other studies have failed to show beneficial effects on diabetic complications and clinical events [143,144,145]. A constant among these conventional antioxidants is that they work by directly scavenging the already present oxidants in a stoichiometric manner. The relative quantities or ratio of antioxidants to oxidants highlights a fundamental shortcoming of antioxidant therapy. Additionally, introduction of an antioxidant into the already highly oxidative environment of a diabetic patient may inadvertently promote the pro-oxidant characteristic of the antioxidant [146].

Diabetic patients have been reported to display abnormally high ROS production and experience reduced expression of antioxidant enzymes [9]. Another approach to ameliorating oxidative stress would involve the induction of the cell’s own endogenous antioxidant response system. The Nrf2/Keap1/ARE pathway is a fundamental protective response pathway to oxidative stress. Induction of this pathway results in the promoted expression of several cytoprotective and antioxidant response genes which function to counter reactive molecules [147]. Activation of this pathway and resultant increased expression of many antioxidant response enzymes would presumably afford more promising results than supplementation of antioxidants that only scavenge ROS in a stoichiometric manner. Indeed, preclinical studies and clinical trials have suggested that activation of this pathway can reverse or delay the oxidative stress-induced diabetic dysfunction. Clinical trials with Nrf2 activators having shown initial promise were not, however, without their shortcomings. A phase III trial (BEACON) with a potent Nrf2 activator, bardoxolone methyl, in TIIDM patients with stage IV CKD had to be terminated early due to severe adverse events including death. While potential off-target effects of bardoxolone methyl should not be disregarded, another consideration is that the cell’s own endogenous antioxidant response system may not be sufficient to protect the cell against reactive molecules. Moreover, it has been suggested that Nrf2 activation be done in a timely and highly specific manner with consideration for cell types that would be affected and induction of target genes [148]. A cautionary note is that while generally resulting in cytoprotective effects, the temporal expression of the many different Nrf2-regulated genes may confer differential responses that may or may not benefit the cell. Additionally, antioxidant enzymes and proteins generally rely on an optimal amount of cellular reducing equivalents (i.e., NADH, NADPH, low molecular weight thiols including GSH) for their ability to function effectively. The supply of reducing equivalents defines the ultimate antioxidant capacity of a tissue [149]. Such reducing equivalents may be mostly consumed during oxidative stress, thus compromising the cell’s capacity for antioxidant activities. Perhaps a more comprehensive approach would involve ensuring an adequate supply of reducing equivalents to guarantee an effective antioxidant response and prevent the system from shifting too far into the oxidative stress side of the redox spectrum. That is to say that maintaining an appropriate amount of the components necessary for an efficacious antioxidant enzyme activity may provide the cell a better capacity to prevent oxidative stress. Most of the reactive molecules would be scavenged and Nrf2 activation would not be warranted. In this context, the lack of Nrf2 activation would be a consequence of having an optimal cellular redox status as opposed to the interpretation that the lack is harmful.

3. Mitochondrial-Targeted Antioxidants for Diabetic Complications

Mitochondria are recognized as critical sites of localized injury in several chronic pathologies, leading to the development of organelle-directed therapeutics. Many pharmacological strategies have been developed over the past two decades to mitigate mtROS [150,151]. One of the approaches employed is to specifically target a range of active compounds, including antioxidants, to the mitochondria, via their conjugation with a delocalized lipophilic cation (DLC) such as triphenylphosphonium (TPP) (Figure 3).

Intriguingly, the DLC is hydrophobic and can freely pass through the phospholipid bilayer of the plasma membrane and other organelles without the requirement for a specific uptake mechanism. Additionally, the transmembrane potential (ΔΨm) across the plasma membrane (−30 to −60 mV) and the mitochondrial inner membrane (−150 to −170 mV) drives the movement of lipophilic TPP conjugated with compounds from the extracellular space into the cytoplasmic compartment and then specifically to the mitochondrial matrix [152,153]. This has led to the development of a wide range of bioactive molecules and probes that can be delivered to mitochondria in vivo following oral, intravenous, intraperitoneal, and subcutaneous administration [154]. Studies showed low antioxidant activity and increased free radicals in patients with diabetes even before diagnosis. Therefore, mitochondrial-targeted antioxidants (MTAs) have been intensively investigated using animal models, cell culture-based studies, and clinical trials to restore redox homeostasis in diabetic complications. Representative studies on the TPP-linked MTAs (Figure 4) observed to play a role in protection against different complication induced by diabetes are summarized in (Table 3).

3.1. MitoQ

Mitoquinone (MitoQ) is among the most substantially utilized antioxidant molecules targeted to the mitochondria. It is the structural analog of the endogenous antioxidant Coenzyme Q10 (CoQ10), also known as ubiquinone, attached to TPP by a hydrophobic 10-carbon alkyl chain [155]. These properties enable MitoQ to cross the plasma membrane and accumulate in the mitochondrial matrix [156]. It also allows the ubiquinone component to access the active site of complex II where it is converted to the active antioxidant, ubiquinol, to reduce mtROS. Preclinical findings from recent studies have demonstrated that targeted mitochondrial therapy using the antioxidant MitoQ has proven to be beneficial for treating diabetes-related cardiovascular complications. The therapeutic efficacy of MitoQ has been investigated in mice models of diabetic kidney diseases (DKDs), where intraperitoneal administration of MitoQ reverted tubular injury by ameliorating mtROS and mitochondrial fragmentation via enhancing mitophagy mediated by Nrf2 and PTEN induced kinase 1 PINK1 [157]. Ward et al. [158] also suggested that MitoQ can mitigate mitochondrial dysfunction, conferring equivalent renoprotection in DKDs as conventional first-line therapies like ramipril [158]. Another interesting proof of action that treatment with MitoQ can be protective in diabetes was documented by assessing its effect on pancreatic β cells cultured under normoglycemic (NG, 11.1 mM glucose), hyperglycemic (HG, 25 mM glucose) and lipidic (palmitic acid (PA), 0.5 mM) conditions. MitoQ was found to prevent augmentation of ROS production, O₂ consumption, protein levels of ER stress markers (GRP78 and P-eIF2α), and the proinflammatory nuclear transcription factor NFκB-p65 under HG condition via modulating mitochondrial function, which in turn facilitates endoplasmic reticulum stress improving β cell function [159]. In the neuroprotective assessment of MitoQ in vivo, Fink et al. [160] reported dietary supplementation of MitoQ (0.93 g/kg diet) for 12 weeks improved peripheral neuropathy in in vivo models of diet-induced obesity and T2D [160]. Yang et al. [161] also reported that MitoQ treatment exerts a protective effect by reducing HG-induced ROS, cytoskeletal damage, and apoptosis in brain microvascular endothelial cells (BMECs) via activating the Nrf2/HO-1 pathway [161]. Additionally, Ji et al. [162] documented that MitoQ was able to ameliorate post-myocardial-ischemia reperfusion (MIR) injury in T2D by mitophagy upregulation via PINK1/Parkin pathway in rat models of T2D [162]. Moreover, the antioxidant and anti-inflammatory action of MitoQ was recently reported in leukocytes whereby its administration reduced ROS production, leukocyte-endothelium interactions, and TNFα through the action of NFκB, preventing CVDs in T2D patients [163].

3.2. SKQ1

10-(6′-plastoquinone)decyltriphenylphosphonium (SKQ1s) is another efficient antioxidant, structurally similar to MitoQ but, with replacement of ubiquinone with plastoquinone that has been successfully targeted to the mitochondria. SkQ1 is one of the most prevalent utilized SKQs, having a TPP moiety covalently conjugated with plastoquinone [164]. In previous studies, Voronkova et al. [165,166] evaluated the ability of SkQ1 to restore hyperglycemia-induced oxidative stress in diabetic rat models via attenuating mtROS, and decreasing the burden on the antioxidant machinery such as catalase, superoxide dismutase, glutathione, and NAPDH-generating enzymes [165,166]. In support of this finding, Agarkov et al. [167] also demonstrated that free radical fluctuation was significantly alleviated in the heart and blood serum of rats with streptozotocin-induced hyperglycemia upon administration of SkQ1 [167]. Recently, studies have reported the beneficial effects of antioxidant pre-therapy using SkQ1 in diabetes-related complications. For example, Demyanenko et al. [168] observed that diabetic C57BL/KsJ-db⁻/db⁻ mice orally supplemented with SkQ1 (250 nmol/kg of body weight) for eight months showed increased wound healing via suppressing lipid peroxidation and immune cells (neutrophils and macrophages) infiltration [168]. In addition, SkQ1 was also effective in improving the blood glucose level in diabetic rats via genetic/epigenetic modifications in the expression of mRNA/microRNA associated with oxidative stress and metabolisms [169].

3.3. Mito-Tempo

Mito-Tempo is another cell-permeable antioxidant with a robust radical scavenging property targeted explicitly to mitochondria, via piperidine nitroxide (TEMPO) conjugation with the TPP moiety. Mito-Tempo is a mitochondria targeted SOD mimetic that can catalytically convert O₂^•− to O₂ and H₂O₂ and has been shown to alleviate mitochondrial induced-oxidative stress in diabetes-associated cardiovascular complications [170]. Regarding cardiomyopathy, treatment with Mito-Tempo, diminished high glucose-induced oxidative stress and apoptosis, which abrogated myocardial dysfunction in diabetic mice via modulating the ERK1/2 pathway [171]. In a T1D rat model associated with vascular dysfunction, a reduction in vascular tone, hypertension, and ROS production were prevented by treatment with Mito-Tempo via modulation of the GLP-1/CREB/adiponectin axis [172]. Mito-Tempo also significantly improved endothelial function by reducing mitochondrial ROS in the arterioles of T2D patients [173]. Additionally, Mito-Tempo administration restored insulin resistance-induced impairment of mitochondrial complex II activity in the visceral adipose tissue of patients with severe obesity [174]. Table 3

Mitochondrial targeted antioxidants in different diabetic complications.

Abbreviation: T2D:Type 2 diabetes; MTA: Mitochondrial targeted antioxidants; PINK1: PTEN induced kinase 1; NOX2: NADPH oxidase 2; ERK1/2: Extracellular signal-regulated protein kinase 1/2; GLP-1: Glucagon-like peptide 1; CREB: cAMP response element binding protein; GRP78: Glucose related protein 78; NFκB: Nuclear factor kappa B; Nrf2: Nuclear factor erythroid 2–related factor 2; PTEN: Phosphatase and tensin homolog; HO-1: Heme oxygenase 1; TNFα: Tumor necrotic factor α; GPx: Glutathione peroxidases; GSTs: Glutathione S transferase; GSRs: Glutathione disulfide reductase; GLP-1: Glucagon-like peptide 1; CREB: Cyclic AMP response element binding protein.

3.4. Mito-PBN

Mito-PBN has emerged as a promising MTA preventing oxidative stress by scavenging mitochondria-generated free radicals. Recently, Wu et al. generated and intraperitoneally administered liposome encapsulated nano-Mito-PBN particles to assess its therapeutic effect in restoring redox balance in the liver of animal models of diabetes. The results of the present study indicated that liposomal encapsulated Mito-PBN resulted in a relatively higher accumulation in hepatocytes, efficiently scavenging mitochondrial O₂^•− and H₂O_2, resulting in a decreased ratio of NADH: NAD+, improved mitochondrial oxidative energy coupling, and ATP synthesis, which alleviated ROS-induced mitochondrial dysfunction [175].

3.5. Szeto-Schiller (SS) Peptides

SS-peptides are another class of cell-permeable MTAs that have been shown to play a protective role against mitochondrial-generated ROS in several pathological conditions, including diabetes. Administration of mitochondria targeted SS-31 peptides in vitro and in vivo has been found to restore mitochondrial function in numerous diabetic complications, which has been reviewed in the past [176] and subsequently lies outside the scope of this review article. However, future studies in animal models of diabetes are warranted to better assess treatment efficacy before designing clinical trials.

In conclusion, based on the data generated from numerous preclinical studies, MTAs can be considered a class of compounds with the potential to alleviate oxidative stress and prevent diabetes-related cardiovascular complications. However, clinical studies are warranted to assess the reproducibility of the preclinical findings to choose the most suitable MTAs to alleviate mitochondria-related oxidative stress in diabetic patients.

4. Challenges and Prospects of Mitochondrial Targets Antioxidants

Extensive evidence from the past have linked oxidative stress-induced mitochondrial dysfunction to the progression of various cardiovascular complication in diabetic patients [177,178]. Therefore, developing an efficient therapeutic strategy to alleviate mitochondrial oxidative stress is imperative. Antioxidants such as vitamin C, vitamin E (α-tocopherol) and NAC have been utilized in studies with the aim of ameliorating mitochondrial ROS, and while they have been observed to decrease O₂^•− reaction-products, these antioxidants were plagued with shortcomings such as low bioavailability and subpar ROS reduction. To overcome these challenges, researchers sought to target ROS at its main source, the mitochondria, with the implementation of targeted antioxidants (MTAs) able to accumulate within the mitochondria at 10–100-fold higher capacities compared to non-targeted antioxidants. Modern strategies targeting antioxidants specifically to mitochondria have offered an excellent alternative to mitigate oxidative stress and restore redox balance, improving mitochondrial function in different diseases, including diabetes. Additionally, high selectivity, fewer side effects, ease of production, efficient pharmacokinetics, and absorption make them an ideal tool to be tested in clinical settings. This targeted approach has aided common pharmacological criteria desired for drug development including targeted action, increased potency and clinically relevant drug doses. However, despite extensive preliminary data, substantial challenges like variation in the mitochondrial membrane potential which may vary in different diabetic complications and is confounded by non-specific or lower mitochondrial accumulation, clinically relevant dosage, and nonspecific interaction of TPP cations with mitochondriotropic agents, needs to be taken into consideration before assessing their effects in clinical trials. Additionally, it has been a point of discussion that the ability of the MTAs to restore the redox balance is due to its effects as a radical scavenger or because of its ability to modulate the enzyme activity of other antioxidants. Therefore, we hypothesize that modification of the structure of MTAs to modulate their radical scavenging activity while retaining similar pharmacokinetic properties may help decipher their underlying therapeutic mechanisms to mitigate oxidative stress.

5. Conclusions and Perspectives

Oxidative stress is now widely recognized as a crucial factor contributing to the development and progression of diabetes-related complications. Therefore, it is relevant to identify oxidative stress biomarkers and the methods to measure them to develop a comprehensive understanding of the link between oxidative stress biomarkers and disease development and progression in diabetic patients. In recent years, the expression level of lncRNA has shown a strong correlation with oxidative stress indicating that they might modulate redox status in diabetic complications. Furthermore, there is emerging scientific evidence depicting that MTAs can mitigate mitochondrial oxidative stress caused by hyperglycemia in diabetes, providing promising oxidative stress-targeting therapeutic strategies. However, most studies to date investigating the effect of MTAs on oxidative stress have been conducted using animal models or cell cultures rather than diabetic patients.

In the future, it is imperative that further research focuses on designing clinical studies assessing the safe use of MTAs and their beneficial effects in diabetic patients. Furthermore, combining MTAs in conjunction with lncRNA-targeting strategies shows promise as a potential therapeutic strategy for diabetes and diabetic cardio- and vascular complications.

Footnotes

Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Enlarge this image.

Figure 1. Roles and functions of the listed lncRNAs in the regulation of oxidative stress in diabetic complications. Arrows indicate the direction of changes in the expression or function. DN: Diabetic nephropathy; DR: Diabetic retinopathy; CVDs: Cardiovascular diseases; DLD: Diabetes lung disease; T2DM: Type 2 diabetes mellitus; lncRNA: Long non-coding RNA; MALAT1: Metastasis-associated lung adenocarcinoma transcript 1; ANRIL: Antisense non-coding RNA in the INK4 locus; Blnc1:Brown Fat lncRNA 1; CASC2: Cancer susceptibility candidate 2; HF1A-AS2: Hypoxia inducible factor 1 alpha-antisense RNA 2; NEAT1: Nuclear paraspeckle assembly transcript 1; LUCAT1: Lung cancer associated transcript 1; NKILA: NF-κB-interacting long noncoding RNA; MIAT: Myocardial infarction-associated transcript.

Enlarge this image.

Figure 2. Dysregulated lncRNA and their role in regulating oxidative stress and mitochondrial function in diabetic complications. Arrows indicate the direction of changes in the expression or function. lncRNA: Long non-coding RNA; Gas5: Growth arrest specific transcript 5; DACH1: Dachshund homolog 1; NEAT1: Nuclear paraspeckle assembly transcript 1; NOX2: NAPDH Oxidase 2; NF-κB: Nuclear factor-kappa B; TNFα: Tumor necrotic factor alpha; IL1-β: Interleukin-1 beta; IL6: Interleukin 6; BAX: Bcl-2-associated X protein; MnSOD: Manganese superoxide dismutase; ND: NADH dehydrogenase; COX1: Cytochrome c oxidase 1 rRNA: Ribosomal RNA.

Enlarge this image.

Figure 3. Chemical structures of TPP-linked mitochondrial-targeted antioxidants MitoQ, SkQ1, Mito-TEMO, MITO-TEMPOL and Mito-PBN.

Enlarge this image.

Figure 4. Potential application of mitochondrial targeted antioxidants in diabetic complications. Arrows indicate the direction of changes in the expression or function. MTA: Mitochondrial targeted antioxidants; PINK1: PTEN induced kinase 1; NOX2: NADPH oxidase 2; ERK1/2: Extracellular signal-regulated protein kinase 1/2; GRP78: Glucose related protein 78; NFκB: Nuclear factor kappa B; Nrf2: Nuclear factor erythroid 2–related factor 2; PTEN: Phosphatase and tensin homolog; HO-1: Heme oxygenase 1; TNFα: Tumor necrotic factor α; GPx: Glutathione peroxidases; GSTs: Glutathione S transferase; GSRs: Glutathione disulfide reductase; GLP-1: Glucagon-like peptide 1; CREB: Cyclic AMP response element binding protein.

References

1. Unnikrishnan, R.; Pradeepa, R.; Joshi, S.R.; Mohan, V. Type 2 Diabetes: Demystifying the Global Epidemic. Diabetes; 2017; 66, pp. 1432-1442. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28533294][DOI: https://dx.doi.org/10.2337/db16-0766]

2. ElSayed, N.A.; Aleppo, G.; Aroda, V.R.; Bannuru, R.R.; Brown, F.M.; Bruemmer, D.; Collins, B.S.; Hilliard, M.E.; Isaacs, D.; Johnson, E.L. et al. 2. Classification and Diagnosis of Diabetes: Standards of Care in Diabetes—2023. Diabetes Care; 2023; 46, (Suppl. 1), pp. S19-S40. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36507649][DOI: https://dx.doi.org/10.2337/dc23-S002]

3. Saeedi, P.; Petersohn, I.; Salpea, P.; Malanda, B.; Karuranga, S.; Unwin, N.; Colagiuri, S.; Guariguata, L.; Motala, A.A.; Ogurtsova, K. et al. Global and regional diabetes prevalence estimates for 2019 and projections for 2030 and 2045: Results from the International Diabetes Federation Diabetes Atlas, 9(th) edition. Diabetes Res. Clin. Pract.; 2019; 157, 107843. [DOI: https://dx.doi.org/10.1016/j.diabres.2019.107843] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31518657]

4. Benjamin, E.J.; Muntner, P.; Alonso, A.; Bittencourt, M.S.; Callaway, C.W.; Carson, A.P.; Chamberlain, A.M.; Chang, A.R.; Cheng, S.; Das, S.R. et al. Heart Disease and Stroke Statistics-2019 Update: A Report From the American Heart Association. Circulation; 2019; 139, pp. e56-e528. [DOI: https://dx.doi.org/10.1161/CIR.0000000000000659]

5. Einarson, T.R.; Acs, A.; Ludwig, C.; Panton, U.H. Prevalence of cardiovascular disease in type 2 diabetes: A systematic literature review of scientific evidence from across the world in 2007–2017. Cardiovasc. Diabetol.; 2018; 17, 83. [DOI: https://dx.doi.org/10.1186/s12933-018-0728-6] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/29884191]

6. Alicic, R.Z.; Rooney, M.T.; Tuttle, K.R. Diabetic Kidney Disease: Challenges, Progress, and Possibilities. Clin. J. Am. Soc. Nephrol.; 2017; 12, pp. 2032-2045. [DOI: https://dx.doi.org/10.2215/CJN.11491116] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28522654]

7. Sivitz, W.I.; Yorek, M.A. Mitochondrial dysfunction in diabetes: From molecular mechanisms to functional significance and therapeutic opportunities. Antioxid. Redox Signal.; 2010; 12, pp. 537-577. [DOI: https://dx.doi.org/10.1089/ars.2009.2531]

8. Sergi, D.; Naumovski, N.; Heilbronn, L.K.; Abeywardena, M.; O’Callaghan, N.; Lionetti, L.; Luscombe-Marsh, N. Mitochondrial (Dys)function and Insulin Resistance: From Pathophysiological Molecular Mechanisms to the Impact of Diet. Front. Physiol.; 2019; 10, 532. [DOI: https://dx.doi.org/10.3389/fphys.2019.00532] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31130874]

9. Giacco, F.; Brownlee, M. Oxidative stress and diabetic complications. Circ. Res.; 2010; 107, pp. 1058-1070. [DOI: https://dx.doi.org/10.1161/CIRCRESAHA.110.223545] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/21030723]

10. DeFronzo, R.A.; Ferrannini, E.; Groop, L.; Henry, R.R.; Herman, W.H.; Holst, J.J.; Hu, F.B.; Kahn, C.R.; Raz, I.; Shulman, G.I. et al. Type 2 diabetes mellitus. Nat. Rev. Dis. Prim.; 2015; 1, 15019. [DOI: https://dx.doi.org/10.1038/nrdp.2015.19]

11. Nowotny, K.; Jung, T.; Hohn, A.; Weber, D.; Grune, T. Advanced glycation end products and oxidative stress in type 2 diabetes mellitus. Biomolecules; 2015; 5, pp. 194-222. [DOI: https://dx.doi.org/10.3390/biom5010194] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/25786107]

12. Kolluru, G.K.; Bir, S.C.; Kevil, C.G. Endothelial dysfunction and diabetes: Effects on angiogenesis, vascular remodeling, and wound healing. Int. J. Vasc. Med.; 2012; 2012, 918267. [DOI: https://dx.doi.org/10.1155/2012/918267] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/22611498]

13. Shi, Y.; Vanhoutte, P.M. Macro- and microvascular endothelial dysfunction in diabetes. J. Diabetes; 2017; 9, pp. 434-449. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28044409][DOI: https://dx.doi.org/10.1111/1753-0407.12521]

14. Fucho, R.; Casals, N.; Serra, D.; Herrero, L. Ceramides and mitochondrial fatty acid oxidation in obesity. FASEB J.; 2017; 31, pp. 1263-1272. [DOI: https://dx.doi.org/10.1096/fj.201601156R]

15. Di Paola, M.; Cocco, T.; Lorusso, M. Ceramide interaction with the respiratory chain of heart mitochondria. Biochemistry; 2000; 39, pp. 6660-6668. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/10828984][DOI: https://dx.doi.org/10.1021/bi9924415]

16. Ueda, N. Ceramide-induced apoptosis in renal tubular cells: A role of mitochondria and sphingosine-1-phoshate. Int. J. Mol. Sci.; 2015; 16, pp. 5076-5124. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/25751724][DOI: https://dx.doi.org/10.3390/ijms16035076]

17. Gao, C.L.; Zhu, C.; Zhao, Y.P.; Chen, X.H.; Ji, C.B.; Zhang, C.M.; Zhu, J.G.; Xia, Z.K.; Tong, M.L.; Guo, X.R. Mitochondrial dysfunction is induced by high levels of glucose and free fatty acids in 3T3-L1 adipocytes. Mol. Cell. Endocrinol.; 2010; 320, pp. 25-33. [DOI: https://dx.doi.org/10.1016/j.mce.2010.01.039] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/20144685]

18. Anderson, E.J.; Kypson, A.P.; Rodriguez, E.; Anderson, C.A.; Lehr, E.J.; Neufer, P.D. Substrate-specific derangements in mitochondrial metabolism and redox balance in the atrium of the type 2 diabetic human heart. J. Am. Coll. Cardiol.; 2009; 54, pp. 1891-1898. [DOI: https://dx.doi.org/10.1016/j.jacc.2009.07.031]

19. Anderson, E.J.; Rodriguez, E.; Anderson, C.A.; Thayne, K.; Chitwood, W.R.; Kypson, A.P. Increased propensity for cell death in diabetic human heart is mediated by mitochondrial-dependent pathways. Am. J. Physiol. Heart Circ. Physiol.; 2011; 300, pp. H118-H124. [DOI: https://dx.doi.org/10.1152/ajpheart.00932.2010]

20. Mariappan, N.; Elks, C.M.; Sriramula, S.; Guggilam, A.; Liu, Z.; Borkhsenious, O.; Francis, J. NF-kappaB-induced oxidative stress contributes to mitochondrial and cardiac dysfunction in type II diabetes. Cardiovasc. Res.; 2010; 85, pp. 473-483. [DOI: https://dx.doi.org/10.1093/cvr/cvp305]

21. Field, B.C.; Gordillo, R.; Scherer, P.E. The Role of Ceramides in Diabetes and Cardiovascular Disease Regulation of Ceramides by Adipokines. Front. Endocrinol.; 2020; 11, 569250. [DOI: https://dx.doi.org/10.3389/fendo.2020.569250] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33133017]

22. Beaudoin, M.S.; Perry, C.G.; Arkell, A.M.; Chabowski, A.; Simpson, J.A.; Wright, D.C.; Holloway, G.P. Impairments in mitochondrial palmitoyl-CoA respiratory kinetics that precede development of diabetic cardiomyopathy are prevented by resveratrol in ZDF rats. J. Physiol.; 2014; 592, pp. 2519-2533. [DOI: https://dx.doi.org/10.1113/jphysiol.2013.270538] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/24639481]

23. Steinberg, S.F. Oxidative stress and sarcomeric proteins. Circ. Res.; 2013; 112, pp. 393-405. [DOI: https://dx.doi.org/10.1161/CIRCRESAHA.111.300496] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/23329794]

24. Lee, T.I.; Kao, Y.H.; Chen, Y.C.; Pan, N.H.; Chen, Y.J. Oxidative stress and inflammation modulate peroxisome proliferator-activated receptors with regional discrepancy in diabetic heart. Eur. J. Clin. Investig.; 2010; 40, pp. 692-699. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/20561028][DOI: https://dx.doi.org/10.1111/j.1365-2362.2010.02318.x]

25. Lee, T.I.; Kao, Y.H.; Chen, Y.C.; Huang, J.H.; Hsiao, F.C.; Chen, Y.J. Peroxisome proliferator-activated receptors modulate cardiac dysfunction in diabetic cardiomyopathy. Diabetes Res. Clin. Pract.; 2013; 100, pp. 330-339. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/23369225][DOI: https://dx.doi.org/10.1016/j.diabres.2013.01.008]

26. Burkart, E.M.; Sambandam, N.; Han, X.; Gross, R.W.; Courtois, M.; Gierasch, C.M.; Shoghi, K.; Welch, M.J.; Kelly, D.P. Nuclear receptors PPARbeta/delta and PPARalpha direct distinct metabolic regulatory programs in the mouse heart. J. Clin. Investig.; 2007; 117, pp. 3930-3939. [DOI: https://dx.doi.org/10.1172/JCI32578]

27. Finck, B.N.; Lehman, J.J.; Leone, T.C.; Welch, M.J.; Bennett, M.J.; Kovacs, A.; Han, X.; Gross, R.W.; Kozak, R.; Lopaschuk, G.D. et al. The cardiac phenotype induced by PPARalpha overexpression mimics that caused by diabetes mellitus. J. Clin. Investig.; 2002; 109, pp. 121-130. [DOI: https://dx.doi.org/10.1172/JCI0214080]

28. Okere, I.C.; Chandler, M.P.; McElfresh, T.A.; Rennison, J.H.; Sharov, V.; Sabbah, H.N.; Tserng, K.Y.; Hoit, B.D.; Ernsberger, P.; Young, M.E. et al. Differential effects of saturated and unsaturated fatty acid diets on cardiomyocyte apoptosis, adipose distribution, and serum leptin. Am. J. Physiol. Heart Circ. Physiol.; 2006; 291, pp. H38-H44. [DOI: https://dx.doi.org/10.1152/ajpheart.01295.2005]

29. Yu, M.; Shan, X.; Liu, Y.; Zhu, J.; Cao, Q.; Yang, F.; Liu, Y.; Wang, G.; Zhao, X. RNA-Seq analysis and functional characterization revealed lncRNA NONRATT007560.2 regulated cardiomyocytes oxidative stress and apoptosis induced by high glucose. J. Cell. Biochem.; 2019; 120, pp. 18278-18287. [DOI: https://dx.doi.org/10.1002/jcb.29134]

30. Zuo, Y.; Chen, L.; He, X.; Ye, Z.; Li, L.; Liu, Z.; Zhou, S. Atorvastatin Regulates MALAT1/miR-200c/NRF2 Activity to Protect Against Podocyte Pyroptosis Induced by High Glucose. Diabetes Metab. Syndr. Obes.; 2021; 14, pp. 1631-1645. [DOI: https://dx.doi.org/10.2147/DMSO.S298950]

31. Durackova, Z. Some current insights into oxidative stress. Physiol. Res.; 2010; 59, pp. 459-469. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/19929132][DOI: https://dx.doi.org/10.33549/physiolres.931844]

32. Pizzino, G.; Irrera, N.; Cucinotta, M.; Pallio, G.; Mannino, F.; Arcoraci, V.; Squadrito, F.; Altavilla, D.; Bitto, A. Oxidative Stress: Harms and Benefits for Human Health. Oxid. Med. Cell. Longev.; 2017; 2017, 8416763. [DOI: https://dx.doi.org/10.1155/2017/8416763] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28819546]

33. Sies, H. Oxidative eustress: On constant alert for redox homeostasis. Redox Biol.; 2021; 41, 101867. [DOI: https://dx.doi.org/10.1016/j.redox.2021.101867]

34. Phaniendra, A.; Jestadi, D.B.; Periyasamy, L. Free radicals: Properties, sources, targets, and their implication in various diseases. Indian J. Clin. Biochem.; 2015; 30, pp. 11-26. [DOI: https://dx.doi.org/10.1007/s12291-014-0446-0] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/25646037]

35. Collin, F. Chemical Basis of Reactive Oxygen Species Reactivity and Involvement in Neurodegenerative Diseases. Int. J. Mol. Sci.; 2019; 20, 2407. [DOI: https://dx.doi.org/10.3390/ijms20102407] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31096608]

36. Snezhkina, A.V.; Kudryavtseva, A.V.; Kardymon, O.L.; Savvateeva, M.V.; Melnikova, N.V.; Krasnov, G.S.; Dmitriev, A.A. ROS Generation and Antioxidant Defense Systems in Normal and Malignant Cells. Oxid. Med. Cell. Longev.; 2019; 2019, 6175804. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31467634][DOI: https://dx.doi.org/10.1155/2019/6175804]

37. Brand, M.D. The sites and topology of mitochondrial superoxide production. Exp. Gerontol.; 2010; 45, pp. 466-472. [DOI: https://dx.doi.org/10.1016/j.exger.2010.01.003]

38. Mailloux, R.J. An Update on Mitochondrial Reactive Oxygen Species Production. Antioxidants; 2020; 9, 472. [DOI: https://dx.doi.org/10.3390/antiox9060472]

39. Murphy, M.P. How mitochondria produce reactive oxygen species. Biochem. J.; 2009; 417, pp. 1-13. [DOI: https://dx.doi.org/10.1042/BJ20081386]

40. Chen, Q.; Vazquez, E.J.; Moghaddas, S.; Hoppel, C.L.; Lesnefsky, E.J. Production of reactive oxygen species by mitochondria: Central role of complex III. J. Biol. Chem.; 2003; 278, pp. 36027-36031. [DOI: https://dx.doi.org/10.1074/jbc.M304854200]

41. Hirst, J.; King, M.S.; Pryde, K.R. The production of reactive oxygen species by complex I. Biochem. Soc. Trans.; 2008; 36, pp. 976-980. [DOI: https://dx.doi.org/10.1042/BST0360976] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/18793173]

42. Pizzinat, N.; Copin, N.; Vindis, C.; Parini, A.; Cambon, C. Reactive oxygen species production by monoamine oxidases in intact cells. Naunyn-Schmiedebergs Arch. Pharmacol.; 1999; 359, pp. 428-431. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/10498294][DOI: https://dx.doi.org/10.1007/PL00005371]

43. Baudry, N.; Laemmel, E.; Vicaut, E. In vivo reactive oxygen species production induced by ischemia in muscle arterioles of mice: Involvement of xanthine oxidase and mitochondria. Am. J. Physiol. Heart Circ. Physiol.; 2008; 294, pp. H821-H828. [DOI: https://dx.doi.org/10.1152/ajpheart.00378.2007]

44. Starkov, A.A.; Fiskum, G.; Chinopoulos, C.; Lorenzo, B.J.; Browne, S.E.; Patel, M.S.; Beal, M.F. Mitochondrial alpha-ketoglutarate dehydrogenase complex generates reactive oxygen species. J. Neurosci.; 2004; 24, pp. 7779-7788. [DOI: https://dx.doi.org/10.1523/JNEUROSCI.1899-04.2004] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/15356189]

45. Pena-Silva, R.A.; Miller, J.D.; Chu, Y.; Heistad, D.D. Serotonin produces monoamine oxidase-dependent oxidative stress in human heart valves. Am. J. Physiol. Heart Circ. Physiol.; 2009; 297, pp. H1354-H1360. [DOI: https://dx.doi.org/10.1152/ajpheart.00570.2009] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/19666839]

46. Lambeth, J.D. NOX enzymes and the biology of reactive oxygen. Nat. Rev. Immunol.; 2004; 4, pp. 181-189. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/15039755][DOI: https://dx.doi.org/10.1038/nri1312]

47. Bedard, K.; Krause, K.H. The NOX family of ROS-generating NADPH oxidases: Physiology and pathophysiology. Physiol. Rev.; 2007; 87, pp. 245-313. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/17237347][DOI: https://dx.doi.org/10.1152/physrev.00044.2005]

48. Zeeshan, H.M.; Lee, G.H.; Kim, H.R.; Chae, H.J. Endoplasmic Reticulum Stress and Associated ROS. Int. J. Mol. Sci.; 2016; 17, 327. [DOI: https://dx.doi.org/10.3390/ijms17030327]

49. Haynes, C.M.; Titus, E.A.; Cooper, A.A. Degradation of misfolded proteins prevents ER-derived oxidative stress and cell death. Mol. Cell; 2004; 15, pp. 767-776. [DOI: https://dx.doi.org/10.1016/j.molcel.2004.08.025]

50. Wu, R.F.; Ma, Z.; Liu, Z.; Terada, L.S. Nox4-derived H₂O₂ mediates endoplasmic reticulum signaling through local Ras activation. Mol. Cell. Biol.; 2010; 30, pp. 3553-3568. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/20622528][DOI: https://dx.doi.org/10.1128/MCB.01445-09]

51. Abdal Dayem, A.; Hossain, M.K.; Lee, S.B.; Kim, K.; Saha, S.K.; Yang, G.M.; Choi, H.Y.; Cho, S.G. The Role of Reactive Oxygen Species (ROS) in the Biological Activities of Metallic Nanoparticles. Int. J. Mol. Sci.; 2017; 18, 120. [DOI: https://dx.doi.org/10.3390/ijms18010120] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28075405]

52. Azzam, E.I.; Jay-Gerin, J.P.; Pain, D. Ionizing radiation-induced metabolic oxidative stress and prolonged cell injury. Cancer Lett.; 2012; 327, pp. 48-60. [DOI: https://dx.doi.org/10.1016/j.canlet.2011.12.012] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/22182453]

53. Rajagopalan, S.; Politi, P.M.; Sinha, B.K.; Myers, C.E. Adriamycin-induced free radical formation in the perfused rat heart: Implications for cardiotoxicity. Cancer Res.; 1988; 48, pp. 4766-4769. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/2842038]

54. Tirichen, H.; Yaigoub, H.; Xu, W.; Wu, C.; Li, R.; Li, Y. Mitochondrial Reactive Oxygen Species and Their Contribution in Chronic Kidney Disease Progression Through Oxidative Stress. Front. Physiol.; 2021; 12, 627837. [DOI: https://dx.doi.org/10.3389/fphys.2021.627837] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33967820]

55. Oldford, C.; Kuksal, N.; Gill, R.; Young, A.; Mailloux, R.J. Estimation of the hydrogen peroxide producing capacities of liver and cardiac mitochondria isolated from C57BL/6N and C57BL/6J mice. Free Radic. Biol. Med.; 2019; 135, pp. 15-27. [DOI: https://dx.doi.org/10.1016/j.freeradbiomed.2019.02.012]

56. Aon, M.A.; Stanley, B.A.; Sivakumaran, V.; Kembro, J.M.; O’Rourke, B.; Paolocci, N.; Cortassa, S. Glutathione/thioredoxin systems modulate mitochondrial H2O2 emission: An experimental-computational study. J. Gen. Physiol.; 2012; 139, pp. 479-491. [DOI: https://dx.doi.org/10.1085/jgp.201210772]

57. Zorov, D.B.; Juhaszova, M.; Sollott, S.J. Mitochondrial reactive oxygen species (ROS) and ROS-induced ROS release. Physiol. Rev.; 2014; 94, pp. 909-950. [DOI: https://dx.doi.org/10.1152/physrev.00026.2013]

58. Guo, C.; Sun, L.; Chen, X.; Zhang, D. Oxidative stress, mitochondrial damage and neurodegenerative diseases. Neural Regen. Res.; 2013; 8, pp. 2003-2014. [DOI: https://dx.doi.org/10.3969/j.issn.1673-5374.2013.21.009]

59. Ayala, A.; Munoz, M.F.; Arguelles, S. Lipid peroxidation: Production, metabolism, and signaling mechanisms of malondialdehyde and 4-hydroxy-2-nonenal. Oxid. Med. Cell. Longev.; 2014; 2014, 360438. [DOI: https://dx.doi.org/10.1155/2014/360438]

60. Schutt, F.; Bergmann, M.; Holz, F.G.; Kopitz, J. Proteins modified by malondialdehyde, 4-hydroxynonenal, or advanced glycation end products in lipofuscin of human retinal pigment epithelium. Investig. Ophthalmol. Vis. Sci.; 2003; 44, pp. 3663-3668. [DOI: https://dx.doi.org/10.1167/iovs.03-0172]

61. Maynard, S.; Schurman, S.H.; Harboe, C.; de Souza-Pinto, N.C.; Bohr, V.A. Base excision repair of oxidative DNA damage and association with cancer and aging. Carcinogenesis; 2009; 30, pp. 2-10. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/18978338][DOI: https://dx.doi.org/10.1093/carcin/bgn250]

62. Rovira-Llopis, S.; Banuls, C.; Diaz-Morales, N.; Hernandez-Mijares, A.; Rocha, M.; Victor, V.M. Mitochondrial dynamics in type 2 diabetes: Pathophysiological implications. Redox Biol.; 2017; 11, pp. 637-645. [DOI: https://dx.doi.org/10.1016/j.redox.2017.01.013] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28131082]

63. Loson, O.C.; Song, Z.; Chen, H.; Chan, D.C. Fis1, Mff, MiD49, and MiD51 mediate Drp1 recruitment in mitochondrial fission. Mol. Biol. Cell.; 2013; 24, pp. 659-667. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/23283981][DOI: https://dx.doi.org/10.1091/mbc.e12-10-0721]

64. Nan, J.; Hu, H.; Sun, Y.; Zhu, L.; Wang, Y.; Zhong, Z.; Zhao, J.; Zhang, N.; Wang, Y.; Wang, Y. et al. TNFR2 Stimulation Promotes Mitochondrial Fusion via Stat3- and NF-kB-Dependent Activation of OPA1 Expression. Circ. Res.; 2017; 121, pp. 392-410. [DOI: https://dx.doi.org/10.1161/CIRCRESAHA.117.311143] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28637784]

65. Shenouda, S.M.; Widlansky, M.E.; Chen, K.; Xu, G.; Holbrook, M.; Tabit, C.E.; Hamburg, N.M.; Frame, A.A.; Caiano, T.L.; Kluge, M.A. et al. Altered mitochondrial dynamics contributes to endothelial dysfunction in diabetes mellitus. Circulation; 2011; 124, pp. 444-453. [DOI: https://dx.doi.org/10.1161/CIRCULATIONAHA.110.014506] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/21747057]

66. Yu, T.; Robotham, J.L.; Yoon, Y. Increased production of reactive oxygen species in hyperglycemic conditions requires dynamic change of mitochondrial morphology. Proc. Natl. Acad. Sci. USA; 2006; 103, pp. 2653-2658. [DOI: https://dx.doi.org/10.1073/pnas.0511154103] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/16477035]

67. Schieber, M.; Chandel, N.S. ROS function in redox signaling and oxidative stress. Curr. Biol.; 2014; 24, pp. R453-R462. [DOI: https://dx.doi.org/10.1016/j.cub.2014.03.034]

68. Perseghin, G.; Scifo, P.; De Cobelli, F.; Pagliato, E.; Battezzati, A.; Arcelloni, C.; Vanzulli, A.; Testolin, G.; Pozza, G.; Del Maschio, A. et al. Intramyocellular triglyceride content is a determinant of in vivo insulin resistance in humans: A 1H-13C nuclear magnetic resonance spectroscopy assessment in offspring of type 2 diabetic parents. Diabetes; 1999; 48, pp. 1600-1606. [DOI: https://dx.doi.org/10.2337/diabetes.48.8.1600]

69. Summers, S.A. Ceramides in insulin resistance and lipotoxicity. Prog. Lipid Res.; 2006; 45, pp. 42-72. [DOI: https://dx.doi.org/10.1016/j.plipres.2005.11.002]

70. Samuel, V.T.; Liu, Z.X.; Wang, A.; Beddow, S.A.; Geisler, J.G.; Kahn, M.; Zhang, X.M.; Monia, B.P.; Bhanot, S.; Shulman, G.I. Inhibition of protein kinase Cepsilon prevents hepatic insulin resistance in nonalcoholic fatty liver disease. J. Clin. Investig.; 2007; 117, pp. 739-745. [DOI: https://dx.doi.org/10.1172/JCI30400]

71. Jornayvaz, F.R.; Birkenfeld, A.L.; Jurczak, M.J.; Kanda, S.; Guigni, B.A.; Jiang, D.C.; Zhang, D.; Lee, H.Y.; Samuel, V.T.; Shulman, G.I. Hepatic insulin resistance in mice with hepatic overexpression of diacylglycerol acyltransferase 2. Proc. Natl. Acad. Sci. USA; 2011; 108, pp. 5748-5752. [DOI: https://dx.doi.org/10.1073/pnas.1103451108] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/21436037]

72. Sokolowska, E.; Blachnio-Zabielska, A. The Role of Ceramides in Insulin Resistance. Front. Endocrinol.; 2019; 10, 577. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31496996][DOI: https://dx.doi.org/10.3389/fendo.2019.00577]

73. Tobon-Velasco, J.C.; Cuevas, E.; Torres-Ramos, M.A. Receptor for AGEs (RAGE) as mediator of NF-kB pathway activation in neuroinflammation and oxidative stress. CNS Neurol. Disord. Drug Targets; 2014; 13, pp. 1615-1626. [DOI: https://dx.doi.org/10.2174/1871527313666140806144831] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/25106630]

74. El-Mesallamy, H.O.; Hamdy, N.M.; Ezzat, O.A.; Reda, A.M. Levels of soluble advanced glycation end product-receptors and other soluble serum markers as indicators of diabetic neuropathy in the foot. J. Investig. Med.; 2011; 59, pp. 1233-1238. [DOI: https://dx.doi.org/10.2310/JIM.0b013e318231db64]

75. Gao, X.; Zhang, H.; Schmidt, A.M.; Zhang, C. AGE/RAGE produces endothelial dysfunction in coronary arterioles in type 2 diabetic mice. Am. J. Physiol. Heart Circ. Physiol.; 2008; 295, pp. H491-H498. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/18539754][DOI: https://dx.doi.org/10.1152/ajpheart.00464.2008]

76. Oguntibeju, O.O. Type 2 diabetes mellitus, oxidative stress and inflammation: Examining the links. Int. J. Physiol. Pathophysiol. Pharmacol.; 2019; 11, pp. 45-63.

77. Inagaki, Y.; Yamagishi, S.; Okamoto, T.; Takeuchi, M.; Amano, S. Pigment epithelium-derived factor prevents advanced glycation end products-induced monocyte chemoattractant protein-1 production in microvascular endothelial cells by suppressing intracellular reactive oxygen species generation. Diabetologia; 2003; 46, pp. 284-287. [DOI: https://dx.doi.org/10.1007/s00125-002-1013-4] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/12627328]

78. Yamagishi, S.; Matsui, T.; Nakamura, K.; Inoue, H.; Takeuchi, M.; Ueda, S.; Okuda, S.; Imaizumi, T. Olmesartan blocks inflammatory reactions in endothelial cells evoked by advanced glycation end products by suppressing generation of reactive oxygen species. Ophthalmic Res.; 2008; 40, pp. 10-15. [DOI: https://dx.doi.org/10.1159/000111152]

79. Gao, X.; Belmadani, S.; Picchi, A.; Xu, X.; Potter, B.J.; Tewari-Singh, N.; Capobianco, S.; Chilian, W.M.; Zhang, C. Tumor necrosis factor-alpha induces endothelial dysfunction in Lepr(db) mice. Circulation; 2007; 115, pp. 245-254. [DOI: https://dx.doi.org/10.1161/CIRCULATIONAHA.106.650671]

80. Harja, E.; Bu, D.X.; Hudson, B.I.; Chang, J.S.; Shen, X.; Hallam, K.; Kalea, A.Z.; Lu, Y.; Rosario, R.H.; Oruganti, S. et al. Vascular and inflammatory stresses mediate atherosclerosis via RAGE and its ligands in apoE-/- mice. J. Clin. Investig.; 2008; 118, pp. 183-194. [DOI: https://dx.doi.org/10.1172/JCI32703]

81. Al-Aubaidy, H.A.; Jelinek, H.F. 8-Hydroxy-2-deoxy-guanosine identifies oxidative DNA damage in a rural prediabetes cohort. Redox Rep.; 2010; 15, pp. 155-160. [DOI: https://dx.doi.org/10.1179/174329210X12650506623681]

82. Xu, G.W.; Yao, Q.H.; Weng, Q.F.; Su, B.L.; Zhang, X.; Xiong, J.H. Study of urinary 8-hydroxydeoxyguanosine as a biomarker of oxidative DNA damage in diabetic nephropathy patients. J. Pharm. Biomed. Anal.; 2004; 36, pp. 101-104. [DOI: https://dx.doi.org/10.1016/j.jpba.2004.04.016] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/15351053]

83. Ye, X.; Jiang, R.; Zhang, Q.; Wang, R.; Yang, C.; Ma, J.; Du, H. Increased 8-hydroxy-2′-deoxyguanosine in leukocyte DNA from patients with type 2 diabetes and microangiopathy. J. Int. Med. Res.; 2016; 44, pp. 472-482. [DOI: https://dx.doi.org/10.1177/0300060515621530] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/27009027]

84. Wang, X.B.; Cui, N.H.; Liu, X.; Liu, X. Mitochondrial 8-hydroxy-2′-deoxyguanosine and coronary artery disease in patients with type 2 diabetes mellitus. Cardiovasc. Diabetol.; 2020; 19, 22. [DOI: https://dx.doi.org/10.1186/s12933-020-00998-6] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32075646]

85. Leinonen, J.; Lehtimaki, T.; Toyokuni, S.; Okada, K.; Tanaka, T.; Hiai, H.; Ochi, H.; Laippala, P.; Rantalaiho, V.; Wirta, O. et al. New biomarker evidence of oxidative DNA damage in patients with non-insulin-dependent diabetes mellitus. FEBS Lett.; 1997; 417, pp. 150-152. [DOI: https://dx.doi.org/10.1016/S0014-5793(97)01273-8]

86. Kaefer, M.; De Carvalho, J.A.; Piva, S.J.; da Silva, D.B.; Becker, A.M.; Sangoi, M.B.; Almeida, T.C.; Hermes, C.L.; Coelho, A.C.; Tonello, R. et al. Plasma malondialdehyde levels and risk factors for the development of chronic complications in type 2 diabetic patients on insulin therapy. Clin. Lab.; 2012; 58, pp. 973-978.

87. Mahreen, R.; Mohsin, M.; Nasreen, Z.; Siraj, M.; Ishaq, M. Significantly increased levels of serum malonaldehyde in type 2 diabetics with myocardial infarction. Int. J. Diabetes Dev. Ctries; 2010; 30, pp. 49-51. [DOI: https://dx.doi.org/10.4103/0973-3930.60006] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/20431807]

88. Pillon, N.J.; Croze, M.L.; Vella, R.E.; Soulere, L.; Lagarde, M.; Soulage, C.O. The lipid peroxidation by-product 4-hydroxy-2-nonenal (4-HNE) induces insulin resistance in skeletal muscle through both carbonyl and oxidative stress. Endocrinology; 2012; 153, pp. 2099-2111. [DOI: https://dx.doi.org/10.1210/en.2011-1957]

89. Laaksonen, D.E.; Atalay, M.; Niskanen, L.; Uusitupa, M.; Hanninen, O.; Sen, C.K. Increased resting and exercise-induced oxidative stress in young IDDM men. Diabetes Care; 1996; 19, pp. 569-574. [DOI: https://dx.doi.org/10.2337/diacare.19.6.569]

90. Griesmacher, A.; Kindhauser, M.; Andert, S.E.; Schreiner, W.; Toma, C.; Knoebl, P.; Pietschmann, P.; Prager, R.; Schnack, C.; Schernthaner, G. et al. Enhanced serum levels of thiobarbituric-acid-reactive substances in diabetes mellitus. Am. J. Med.; 1995; 98, pp. 469-475. [DOI: https://dx.doi.org/10.1016/S0002-9343(99)80347-7]

91. Tavares, A.M.; Silva, J.H.; Bensusan, C.O.; Ferreira, A.C.F.; Matos, L.P.L.; KLA, E.S.; Cardoso-Weide, L.C.; Taboada, G.F. Altered superoxide dismutase-1 activity and intercellular adhesion molecule 1 (ICAM-1) levels in patients with type 2 diabetes mellitus. PLoS ONE; 2019; 14, e0216256. [DOI: https://dx.doi.org/10.1371/journal.pone.0216256] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31042755]

92. Fujita, H.; Sakamoto, T.; Komatsu, K.; Fujishima, H.; Morii, T.; Narita, T.; Takahashi, T.; Yamada, Y. Reduction of circulating superoxide dismutase activity in type 2 diabetic patients with microalbuminuria and its modulation by telmisartan therapy. Hypertens. Res.; 2011; 34, pp. 1302-1308. [DOI: https://dx.doi.org/10.1038/hr.2011.127] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/21814206]

93. Gawlik, K.; Naskalski, J.W.; Fedak, D.; Pawlica-Gosiewska, D.; Grudzien, U.; Dumnicka, P.; Malecki, M.T.; Solnica, B. Markers of Antioxidant Defense in Patients with Type 2 Diabetes. Oxid. Med. Cell. Longev.; 2016; 2016, 2352361. [DOI: https://dx.doi.org/10.1155/2016/2352361]

94. Takemoto, K.; Tanaka, M.; Iwata, H.; Nishihara, R.; Ishihara, K.; Wang, D.H.; Ogino, K.; Taniuchi, K.; Masuoka, N. Low catalase activity in blood is associated with the diabetes caused by alloxan. Clin. Chim. Acta; 2009; 407, pp. 43-46. [DOI: https://dx.doi.org/10.1016/j.cca.2009.06.028] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/19563792]

95. Kopp, F.; Mendell, J.T. Functional Classification and Experimental Dissection of Long Noncoding RNAs. Cell; 2018; 172, pp. 393-407. [DOI: https://dx.doi.org/10.1016/j.cell.2018.01.011] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/29373828]

96. Consortium, E.P.; Birney, E.; Stamatoyannopoulos, J.A.; Dutta, A.; Guigo, R.; Gingeras, T.R.; Margulies, E.H.; Weng, Z.; Snyder, M.; Dermitzakis, E.T. et al. Identification and analysis of functional elements in 1% of the human genome by the ENCODE pilot project. Nature; 2007; 447, pp. 799-816. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/17571346][DOI: https://dx.doi.org/10.1038/nature05874]

97. Viereck, J.; Thum, T. Circulating Noncoding RNAs as Biomarkers of Cardiovascular Disease and Injury. Circ. Res.; 2017; 120, pp. 381-399. [DOI: https://dx.doi.org/10.1161/CIRCRESAHA.116.308434]

98. Pant, T.; Juric, M.; Bosnjak, Z.J.; Dhanasekaran, A. Recent Insight on the Non-coding RNAs in Mesenchymal Stem Cell-Derived Exosomes: Regulatory and Therapeutic Role in Regenerative Medicine and Tissue Engineering. Front. Cardiovasc. Med.; 2021; 8, 737512. [DOI: https://dx.doi.org/10.3389/fcvm.2021.737512]

99. Pant, T.; Dhanasekaran, A.; Fang, J.; Bai, X.; Bosnjak, Z.J.; Liang, M.; Ge, Z.D. Current status and strategies of long noncoding RNA research for diabetic cardiomyopathy. BMC Cardiovasc. Disord.; 2018; 18, 197. [DOI: https://dx.doi.org/10.1186/s12872-018-0939-5]

100. Pant, T.; DiStefano, J.K.; Logan, S.; Bosnjak, Z.J. Emerging Role of Long Noncoding RNAs in Perioperative Neurocognitive Disorders and Anesthetic-Induced Developmental Neurotoxicity. Anesth. Analg.; 2021; 132, pp. 1614-1625. [DOI: https://dx.doi.org/10.1213/ANE.0000000000005317]

101. de Gonzalo-Calvo, D.; Kenneweg, F.; Bang, C.; Toro, R.; van der Meer, R.W.; Rijzewijk, L.J.; Smit, J.W.; Lamb, H.J.; Llorente-Cortes, V.; Thum, T. Circulating long-non coding RNAs as biomarkers of left ventricular diastolic function and remodelling in patients with well-controlled type 2 diabetes. Sci. Rep.; 2016; 6, 37354. [DOI: https://dx.doi.org/10.1038/srep37354] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/27874027]

102. Pant, T.; Dhanasekaran, A.; Zhao, M.; Thorp, E.B.; Forbess, J.M.; Bosnjak, Z.J.; Benjamin, I.J.; Ge, Z.D. Identification and analysis of circulating long non-coding RNAs with high significance in diabetic cardiomyopathy. Sci. Rep.; 2021; 11, 2571. [DOI: https://dx.doi.org/10.1038/s41598-021-82345-7] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33510471]

103. Zhou, L.J.; Yang, D.W.; Ou, L.N.; Guo, X.R.; Wu, B.L. Circulating Expression Level of LncRNA Malat1 in Diabetic Kidney Disease Patients and Its Clinical Significance. J. Diabetes Res.; 2020; 2020, 4729019. [DOI: https://dx.doi.org/10.1155/2020/4729019]

104. Zhang, X.L.; Zhu, H.Q.; Zhang, Y.; Zhang, C.Y.; Jiao, J.S.; Xing, X.Y. LncRNA CASC2 regulates high glucose-induced proliferation, extracellular matrix accumulation and oxidative stress of human mesangial cells via miR-133b/FOXP1 axis. Eur. Rev. Med. Pharmacol. Sci.; 2020; 24, pp. 802-812. [DOI: https://dx.doi.org/10.26355/eurrev_202001_20063] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32016985]

105. Atef, M.M.; Shafik, N.M.; Hafez, Y.M.; Watany, M.M.; Selim, A.; Shafik, H.M.; Safwat El-Deeb, O. The evolving role of long noncoding RNA HIF1A-AS2 in diabetic retinopathy: A cross-link axis between hypoxia, oxidative stress and angiogenesis via MAPK/VEGF-dependent pathway. Redox Rep.; 2022; 27, pp. 70-78. [DOI: https://dx.doi.org/10.1080/13510002.2022.2050086] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35285425]

106. Broadbent, H.M.; Peden, J.F.; Lorkowski, S.; Goel, A.; Ongen, H.; Green, F.; Clarke, R.; Collins, R.; Franzosi, M.G.; Tognoni, G. et al. Susceptibility to coronary artery disease and diabetes is encoded by distinct, tightly linked SNPs in the ANRIL locus on chromosome 9p. Hum. Mol. Genet.; 2008; 17, pp. 806-814. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/18048406][DOI: https://dx.doi.org/10.1093/hmg/ddm352]

107. Cai, R.; Jiang, J. LncRNA ANRIL Silencing Alleviates High Glucose-Induced Inflammation, Oxidative Stress, and Apoptosis via Upregulation of MME in Podocytes. Inflammation; 2020; 43, pp. 2147-2155. [DOI: https://dx.doi.org/10.1007/s10753-020-01282-1]

108. Feng, X.; Zhao, J.; Ding, J.; Shen, X.; Zhou, J.; Xu, Z. LncRNA Blnc1 expression and its effect on renal fibrosis in diabetic nephropathy. Am. J. Transl. Res.; 2019; 11, pp. 5664-5672.

109. Zhu, Y.; Dai, L.; Yu, X.; Chen, X.; Li, Z.; Sun, Y.; Liang, Y.; Wu, B.; Wang, Q.; Wang, X. Circulating expression and clinical significance of LncRNA ANRIL in diabetic kidney disease. Mol. Biol. Rep.; 2022; 49, pp. 10521-10529. [DOI: https://dx.doi.org/10.1007/s11033-022-07843-x]

110. Li, P.; Zhang, N.; Ping, F.; Gao, Y.; Cao, L. lncRNA SCAL1 inhibits inducible nitric oxide synthase in lung cells under high-glucose conditions. Exp. Ther. Med.; 2019; 18, pp. 1831-1836. [DOI: https://dx.doi.org/10.3892/etm.2019.7729]

111. Karam, R.A.; Amer, M.M.; Zidan, H.E. Long Noncoding RNA NEAT1 Expression and Its Target miR-124 in Diabetic Ischemic Stroke Patients. Genet. Test. Mol. Biomark.; 2022; 26, pp. 398-407. [DOI: https://dx.doi.org/10.1089/gtmb.2021.0301] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36027040]

112. Alfaifi, M.; Ali Beg, M.M.; Alshahrani, M.Y.; Ahmad, I.; Alkhathami, A.G.; Joshi, P.C.; Alshehri, O.M.; Alamri, A.M.; Verma, A.K. Circulating long non-coding RNAs NKILA, NEAT1, MALAT1, and MIAT expression and their association in type 2 diabetes mellitus. BMJ Open Diabetes Res. Care; 2021; 9, e001821. [DOI: https://dx.doi.org/10.1136/bmjdrc-2020-001821] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33436407]

113. Spinelli, J.B.; Haigis, M.C. The multifaceted contributions of mitochondria to cellular metabolism. Nat. Cell Biol.; 2018; 20, pp. 745-754. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/29950572][DOI: https://dx.doi.org/10.1038/s41556-018-0124-1]

114. Kurland, C.G.; Andersson, S.G. Origin and evolution of the mitochondrial proteome. Microbiol. Mol. Biol. Rev.; 2000; 64, pp. 786-820. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/11104819][DOI: https://dx.doi.org/10.1128/MMBR.64.4.786-820.2000]

115. Gray, M.W. Mosaic nature of the mitochondrial proteome: Implications for the origin and evolution of mitochondria. Proc. Natl. Acad. Sci. USA; 2015; 112, pp. 10133-10138. [DOI: https://dx.doi.org/10.1073/pnas.1421379112]

116. Bridges, M.C.; Daulagala, A.C.; Kourtidis, A. LNCcation: lncRNA localization and function. J. Cell. Biol.; 2021; 220, e202009045. [DOI: https://dx.doi.org/10.1083/jcb.202009045]

117. Lin, Y.H. Crosstalk of lncRNA and Cellular Metabolism and Their Regulatory Mechanism in Cancer. Int. J. Mol. Sci.; 2020; 21, 2947. [DOI: https://dx.doi.org/10.3390/ijms21082947] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32331347]

118. Rackham, O.; Shearwood, A.M.; Mercer, T.R.; Davies, S.M.; Mattick, J.S.; Filipovska, A. Long noncoding RNAs are generated from the mitochondrial genome and regulated by nuclear-encoded proteins. RNA; 2011; 17, pp. 2085-2093. [DOI: https://dx.doi.org/10.1261/rna.029405.111]

119. Dong, Y.; Yoshitomi, T.; Hu, J.F.; Cui, J. Long noncoding RNAs coordinate functions between mitochondria and the nucleus. Epigenetics Chromatin; 2017; 10, 41. [DOI: https://dx.doi.org/10.1186/s13072-017-0149-x]

120. Li, Y.; Li, W.; Hoffman, A.R.; Cui, J.; Hu, J.F. The Nucleus/Mitochondria-Shuttling LncRNAs Function as New Epigenetic Regulators of Mitophagy in Cancer. Front. Cell Dev. Biol.; 2021; 9, 699621. [DOI: https://dx.doi.org/10.3389/fcell.2021.699621]

121. Zgheib, C.; Hodges, M.M.; Hu, J.; Liechty, K.W.; Xu, J. Long non-coding RNA Lethe regulates hyperglycemia-induced reactive oxygen species production in macrophages. PLoS ONE; 2017; 12, e0177453. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28494015][DOI: https://dx.doi.org/10.1371/journal.pone.0177453]

122. Xie, C.; Wu, W.; Tang, A.; Luo, N.; Tan, Y. lncRNA GAS5/miR-452-5p Reduces Oxidative Stress and Pyroptosis of High-Glucose-Stimulated Renal Tubular Cells. Diabetes Metab. Syndr. Obes.; 2019; 12, pp. 2609-2617. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31849505][DOI: https://dx.doi.org/10.2147/DMSO.S228654]

123. Che, F.; Han, Y.; Fu, J.; Wang, N.; Jia, Y.; Wang, K.; Ge, J. LncRNA MALAT1 induced by hyperglycemia promotes microvascular endothelial cell apoptosis through activation of the miR-7641/TPR axis to exacerbate neurologic damage caused by cerebral small vessel disease. Ann. Transl. Med.; 2021; 9, 1762. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35071456][DOI: https://dx.doi.org/10.21037/atm-21-5997]

124. Bai, X.; Geng, J.; Li, X.; Wan, J.; Liu, J.; Zhou, Z.; Liu, X. Long Noncoding RNA LINC01619 Regulates MicroRNA-27a/Forkhead Box Protein O1 and Endoplasmic Reticulum Stress-Mediated Podocyte Injury in Diabetic Nephropathy. Antioxid. Redox Signal.; 2018; 29, pp. 355-376. [DOI: https://dx.doi.org/10.1089/ars.2017.7278] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/29334763]

125. Pant, T.; Dhanasekaran, A.; Bai, X.; Zhao, M.; Thorp, E.B.; Forbess, J.M.; Bosnjak, Z.J.; Ge, Z.D. Genome-wide differential expression profiling of lncRNAs and mRNAs associated with early diabetic cardiomyopathy. Sci. Rep.; 2019; 9, 15345. [DOI: https://dx.doi.org/10.1038/s41598-019-51872-9]

126. Pant, T.; Mishra, M.K.; Bai, X.; Ge, Z.D.; Bosnjak, Z.J.; Dhanasekaran, A. Microarray analysis of long non-coding RNA and mRNA expression profiles in diabetic cardiomyopathy using human induced pluripotent stem cell-derived cardiomyocytes. Diabetes Vasc. Dis. Res.; 2019; 16, pp. 57-68. [DOI: https://dx.doi.org/10.1177/1479164118813888] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/30482051]

127. Zhang, Q.; Li, D.; Dong, X.; Zhang, X.; Liu, J.; Peng, L.; Meng, B.; Hua, Q.; Pei, X.; Zhao, L. et al. LncDACH1 promotes mitochondrial oxidative stress of cardiomyocytes by interacting with sirtuin3 and aggravates diabetic cardiomyopathy. Sci. China Life Sci.; 2022; 65, pp. 1198-1212. [DOI: https://dx.doi.org/10.1007/s11427-021-1982-8]

128. Mohammad, G.; Kowluru, R.A. Nuclear Genome-Encoded Long Noncoding RNAs and Mitochondrial Damage in Diabetic Retinopathy. Cells; 2021; 10, 3271. [DOI: https://dx.doi.org/10.3390/cells10123271] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/34943778]

129. Bajaj, S.; Khan, A. Antioxidants and diabetes. Indian J. Endocrinol. Metab.; 2012; 16, pp. S267-S271. [DOI: https://dx.doi.org/10.4103/2230-8210.104057]

130. Giugliano, D.; Ceriello, A.; Paolisso, G. Oxidative stress and diabetic vascular complications. Diabetes Care; 1996; 19, pp. 257-267. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/8742574][DOI: https://dx.doi.org/10.2337/diacare.19.3.257]

131. Halliwell, B.; Gutteridge, J.M. The antioxidants of human extracellular fluids. Arch. Biochem. Biophys.; 1990; 280, pp. 1-8. [DOI: https://dx.doi.org/10.1016/0003-9861(90)90510-6] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/2191627]

132. Feskens, E.J.; Virtanen, S.M.; Rasanen, L.; Tuomilehto, J.; Stengard, J.; Pekkanen, J.; Nissinen, A.; Kromhout, D. Dietary factors determining diabetes and impaired glucose tolerance. A 20-year follow-up of the Finnish and Dutch cohorts of the Seven Countries Study. Diabetes Care; 1995; 18, pp. 1104-1112. [DOI: https://dx.doi.org/10.2337/diacare.18.8.1104]

133. Mason, S.A.; Keske, M.A.; Wadley, G.D. Effects of Vitamin C Supplementation on Glycemic Control and Cardiovascular Risk Factors in People with Type 2 Diabetes: A GRADE-Assessed Systematic Review and Meta-analysis of Randomized Controlled Trials. Diabetes Care; 2021; 44, pp. 618-630. [DOI: https://dx.doi.org/10.2337/dc20-1893] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33472962]

134. Saklayen, M.G.; Yap, J.; Vallyathan, V. Effect of month-long treatment with oral N-acetylcysteine on the oxidative stress and proteinuria in patients with diabetic nephropathy: A pilot study. J. Investig. Med.; 2010; 58, pp. 28-31. [DOI: https://dx.doi.org/10.2310/JIM.0b013e3181c5e9e9] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/20051769]

135. Darko, D.; Dornhorst, A.; Kelly, F.J.; Ritter, J.M.; Chowienczyk, P.J. Lack of effect of oral vitamin C on blood pressure, oxidative stress and endothelial function in Type II diabetes. Clin. Sci.; 2002; 103, pp. 339-344. [DOI: https://dx.doi.org/10.1042/cs1030339]

136. Chen, H.; Karne, R.J.; Hall, G.; Campia, U.; Panza, J.A.; Cannon, R.O., 3rd; Wang, Y.; Katz, A.; Levine, M.; Quon, M.J. High-dose oral vitamin C partially replenishes vitamin C levels in patients with Type 2 diabetes and low vitamin C levels but does not improve endothelial dysfunction or insulin resistance. Am. J. Physiol. Heart Circ. Physiol.; 2006; 290, pp. H137-H145. [DOI: https://dx.doi.org/10.1152/ajpheart.00768.2005]

137. Liu, C.; Lu, X.Z.; Shen, M.Z.; Xing, C.Y.; Ma, J.; Duan, Y.Y.; Yuan, L.J. N-Acetyl Cysteine improves the diabetic cardiac function: Possible role of fibrosis inhibition. BMC Cardiovasc. Disord.; 2015; 15, 84. [DOI: https://dx.doi.org/10.1186/s12872-015-0076-3]

138. Argaev Frenkel, L.; Rozenfeld, H.; Rozenberg, K.; Sampson, S.R.; Rosenzweig, T. N-Acetyl-l-Cysteine Supplement in Early Life or Adulthood Reduces Progression of Diabetes in Nonobese Diabetic Mice. Curr. Dev. Nutr.; 2019; 3, nzy097. [DOI: https://dx.doi.org/10.1093/cdn/nzy097]

139. Dludla, P.V.; Orlando, P.; Silvestri, S.; Mazibuko-Mbeje, S.E.; Johnson, R.; Marcheggiani, F.; Cirilli, I.; Muller, C.J.F.; Louw, J.; Obonye, N. et al. N-Acetyl cysteine ameliorates hyperglycemia-induced cardiomyocyte toxicity by improving mitochondrial energetics and enhancing endogenous Coenzyme Q(9/10) levels. Toxicol. Rep.; 2019; 6, pp. 1240-1245. [DOI: https://dx.doi.org/10.1016/j.toxrep.2019.11.004]

140. Montonen, J.; Knekt, P.; Jarvinen, R.; Reunanen, A. Dietary antioxidant intake and risk of type 2 diabetes. Diabetes Care; 2004; 27, pp. 362-366. [DOI: https://dx.doi.org/10.2337/diacare.27.2.362]

141. Khatami, P.G.; Soleimani, A.; Sharifi, N.; Aghadavod, E.; Asemi, Z. The effects of high-dose vitamin E supplementation on biomarkers of kidney injury, inflammation, and oxidative stress in patients with diabetic nephropathy: A randomized, double-blind, placebo-controlled trial. J. Clin. Lipidol.; 2016; 10, pp. 922-929. [DOI: https://dx.doi.org/10.1016/j.jacl.2016.02.021] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/27578124]

142. Devaraj, S.; Leonard, S.; Traber, M.G.; Jialal, I. Gamma-tocopherol supplementation alone and in combination with alpha-tocopherol alters biomarkers of oxidative stress and inflammation in subjects with metabolic syndrome. Free Radic. Biol. Med.; 2008; 44, pp. 1203-1208. [DOI: https://dx.doi.org/10.1016/j.freeradbiomed.2007.12.018] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/18191645]

143. Ceriello, A. New insights on oxidative stress and diabetic complications may lead to a “causal” antioxidant therapy. Diabetes Care; 2003; 26, pp. 1589-1596. [DOI: https://dx.doi.org/10.2337/diacare.26.5.1589] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/12716823]

144. Marchioli, R.; Schweiger, C.; Levantesi, G.; Tavazzi, L.; Valagussa, F. Antioxidant vitamins and prevention of cardiovascular disease: Epidemiological and clinical trial data. Lipids; 2001; 36, pp. S53-S63. [DOI: https://dx.doi.org/10.1007/s11745-001-0683-y]

145. Lonn, E.; Yusuf, S.; Hoogwerf, B.; Pogue, J.; Yi, Q.; Zinman, B.; Bosch, J.; Dagenais, G.; Mann, J.F.; Gerstein, H.C. et al. Effects of vitamin E on cardiovascular and microvascular outcomes in high-risk patients with diabetes: Results of the HOPE study and MICRO-HOPE substudy. Diabetes Care; 2002; 25, pp. 1919-1927. [DOI: https://dx.doi.org/10.2337/diacare.25.11.1919]

146. Sotler, R.; Poljsak, B.; Dahmane, R.; Jukic, T.; Pavan Jukic, D.; Rotim, C.; Trebse, P.; Starc, A. Prooxidant Activities of Antioxidants and Their Impact on Health. Acta Clin. Croat.; 2019; 58, pp. 726-736. [DOI: https://dx.doi.org/10.20471/acc.2019.58.04.20]

147. Baird, L.; Yamamoto, M. The Molecular Mechanisms Regulating the KEAP1-NRF2 Pathway. Mol. Cell. Biol.; 2020; 40, e00099-20. [DOI: https://dx.doi.org/10.1128/MCB.00099-20]

148. Matzinger, M.; Fischhuber, K.; Heiss, E.H. Activation of Nrf2 signaling by natural products-can it alleviate diabetes?. Biotechnol. Adv.; 2018; 36, pp. 1738-1767. [DOI: https://dx.doi.org/10.1016/j.biotechadv.2017.12.015]

149. Kehrer, J.P.; Lund, L.G. Cellular reducing equivalents and oxidative stress. Free Radic. Biol. Med.; 1994; 17, pp. 65-75. [DOI: https://dx.doi.org/10.1016/0891-5849(94)90008-6]

150. Reily, C.; Mitchell, T.; Chacko, B.K.; Benavides, G.; Murphy, M.P.; Darley-Usmar, V. Mitochondrially targeted compounds and their impact on cellular bioenergetics. Redox Biol.; 2013; 1, pp. 86-93. [DOI: https://dx.doi.org/10.1016/j.redox.2012.11.009]

151. Armstrong, J.S. Mitochondrial medicine: Pharmacological targeting of mitochondria in disease. Br. J. Pharmacol.; 2007; 151, pp. 1154-1165. [DOI: https://dx.doi.org/10.1038/sj.bjp.0707288] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/17519949]

152. Smith, R.A.; Porteous, C.M.; Coulter, C.V.; Murphy, M.P. Selective targeting of an antioxidant to mitochondria. Eur. J. Biochem.; 1999; 263, pp. 709-716. [DOI: https://dx.doi.org/10.1046/j.1432-1327.1999.00543.x] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/10469134]

153. Smith, R.A.; Porteous, C.M.; Gane, A.M.; Murphy, M.P. Delivery of bioactive molecules to mitochondria in vivo. Proc. Natl. Acad. Sci. USA; 2003; 100, pp. 5407-5412. [DOI: https://dx.doi.org/10.1073/pnas.0931245100] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/12697897]

154. Zielonka, J.; Joseph, J.; Sikora, A.; Hardy, M.; Ouari, O.; Vasquez-Vivar, J.; Cheng, G.; Lopez, M.; Kalyanaraman, B. Mitochondria-Targeted Triphenylphosphonium-Based Compounds: Syntheses, Mechanisms of Action, and Therapeutic and Diagnostic Applications. Chem. Rev.; 2017; 117, pp. 10043-10120. [DOI: https://dx.doi.org/10.1021/acs.chemrev.7b00042]

155. Murphy, M.P.; Smith, R.A. Targeting antioxidants to mitochondria by conjugation to lipophilic cations. Annu. Rev. Pharmacol. Toxicol.; 2007; 47, pp. 629-656. [DOI: https://dx.doi.org/10.1146/annurev.pharmtox.47.120505.105110]

156. Smith, R.A.; Murphy, M.P. Animal and human studies with the mitochondria-targeted antioxidant MitoQ. Ann. N. Y. Acad. Sci.; 2010; 1201, pp. 96-103. [DOI: https://dx.doi.org/10.1111/j.1749-6632.2010.05627.x]

157. Xiao, L.; Xu, X.; Zhang, F.; Wang, M.; Xu, Y.; Tang, D.; Wang, J.; Qin, Y.; Liu, Y.; Tang, C. et al. The mitochondria-targeted antioxidant MitoQ ameliorated tubular injury mediated by mitophagy in diabetic kidney disease via Nrf2/PINK1. Redox Biol.; 2017; 11, pp. 297-311. [DOI: https://dx.doi.org/10.1016/j.redox.2016.12.022]

158. Ward, M.S.; Flemming, N.B.; Gallo, L.A.; Fotheringham, A.K.; McCarthy, D.A.; Zhuang, A.; Tang, P.H.; Borg, D.J.; Shaw, H.; Harvie, B. et al. Targeted mitochondrial therapy using MitoQ shows equivalent renoprotection to angiotensin converting enzyme inhibition but no combined synergy in diabetes. Sci. Rep.; 2017; 7, 15190. [DOI: https://dx.doi.org/10.1038/s41598-017-15589-x]

159. Escribano-Lopez, I.; Banuls, C.; Diaz-Morales, N.; Iannantuoni, F.; Rovira-Llopis, S.; Gomis, R.; Rocha, M.; Hernandez-Mijares, A.; Murphy, M.P.; Victor, V.M. The Mitochondria-Targeted Antioxidant MitoQ Modulates Mitochondrial Function and Endoplasmic Reticulum Stress in Pancreatic beta Cells Exposed to Hyperglycaemia. Cell. Physiol. Biochem.; 2019; 52, pp. 186-197. [DOI: https://dx.doi.org/10.33594/000000013]

160. Fink, B.; Coppey, L.; Davidson, E.; Shevalye, H.; Obrosov, A.; Chheda, P.R.; Kerns, R.; Sivitz, W.; Yorek, M. Effect of mitoquinone (Mito-Q) on neuropathic endpoints in an obese and type 2 diabetic rat model. Free Radic. Res.; 2020; 54, pp. 311-318. [DOI: https://dx.doi.org/10.1080/10715762.2020.1754409]

161. Yang, M.Y.; Fan, Z.; Zhang, Z.; Fan, J. MitoQ protects against high glucose-induced brain microvascular endothelial cells injury via the Nrf2/HO-1 pathway. J. Pharmacol. Sci.; 2021; 145, pp. 105-114. [DOI: https://dx.doi.org/10.1016/j.jphs.2020.10.007] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33357768]

162. Ji, Y.; Leng, Y.; Lei, S.; Qiu, Z.; Ming, H.; Zhang, Y.; Zhang, A.; Wu, Y.; Xia, Z. The mitochondria-targeted antioxidant MitoQ ameliorates myocardial ischemia-reperfusion injury by enhancing PINK1/Parkin-mediated mitophagy in type 2 diabetic rats. Cell Stress Chaperones; 2022; 27, pp. 353-367. [DOI: https://dx.doi.org/10.1007/s12192-022-01273-1] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35426609]

163. Escribano-Lopez, I.; Diaz-Morales, N.; Rovira-Llopis, S.; de Maranon, A.M.; Orden, S.; Alvarez, A.; Banuls, C.; Rocha, M.; Murphy, M.P.; Hernandez-Mijares, A. et al. The mitochondria-targeted antioxidant MitoQ modulates oxidative stress, inflammation and leukocyte-endothelium interactions in leukocytes isolated from type 2 diabetic patients. Redox Biol.; 2016; 10, pp. 200-205. [DOI: https://dx.doi.org/10.1016/j.redox.2016.10.017] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/27810734]

164. Izyumov, D.S.; Domnina, L.V.; Nepryakhina, O.K.; Avetisyan, A.V.; Golyshev, S.A.; Ivanova, O.Y.; Korotetskaya, M.V.; Lyamzaev, K.G.; Pletjushkina, O.Y.; Popova, E.N. et al. Mitochondria as source of reactive oxygen species under oxidative stress. Study with novel mitochondria-targeted antioxidants--the “Skulachev-ion” derivatives. Biochemistry; 2010; 75, pp. 123-129. [DOI: https://dx.doi.org/10.1134/S000629791002001X] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/20367598]

165. Voronkova, Y.G.; Popova, T.N.; Agarkov, A.A.; Skulachev, M.V. Influence of 10-(6′-Plastoquinonyl)decyltriphenylphosphonium (SkQ1) on Oxidative Status in Rats with Protamine Sulfate-Induced Hyperglycemia. Biochemistry; 2015; 80, pp. 1606-1613. [DOI: https://dx.doi.org/10.1134/S0006297915120093]

166. Voronkova, Y.G.; Popova, T.N.; Agarkov, A.A.; Zinovkin, R.A. Effect of SkQ1 on Activity of the Glutathione System and NADPH-Generating Enzymes in an Experimental Model of Hyperglycemia. Biochemistry; 2015; 80, pp. 1614-1621. [DOI: https://dx.doi.org/10.1134/S000629791512010X]

167. Agarkov, A.A.; Popova, T.N.; Boltysheva, Y.G. Influence of 10-(6-plastoquinonyl) decyltriphenylphosphonium on free-radical homeostasis in the heart and blood serum of rats with streptozotocin-induced hyperglycemia. World J. Diabetes; 2019; 10, pp. 546-559. [DOI: https://dx.doi.org/10.4239/wjd.v10.i12.546]

168. Demyanenko, I.A.; Zakharova, V.V.; Ilyinskaya, O.P.; Vasilieva, T.V.; Fedorov, A.V.; Manskikh, V.N.; Zinovkin, R.A.; Pletjushkina, O.Y.; Chernyak, B.V.; Skulachev, V.P. et al. Mitochondria-Targeted Antioxidant SkQ1 Improves Dermal Wound Healing in Genetically Diabetic Mice. Oxid. Med. Cell. Longev.; 2017; 2017, 6408278. [DOI: https://dx.doi.org/10.1155/2017/6408278]

169. Dvoretskaya, Y.; Glanz, V.; Gryaznova, M.; Syromyatnikov, M.; Popov, V. Mitochondrial Antioxidant SkQ1 Has a Beneficial Effect in Experimental Diabetes as Based on the Analysis of Expression of microRNAs and mRNAs for the Oxidative Metabolism Regulators. Antioxidants; 2021; 10, 1749. [DOI: https://dx.doi.org/10.3390/antiox10111749]

170. Dikalova, A.E.; Bikineyeva, A.T.; Budzyn, K.; Nazarewicz, R.R.; McCann, L.; Lewis, W.; Harrison, D.G.; Dikalov, S.I. Therapeutic targeting of mitochondrial superoxide in hypertension. Circ. Res.; 2010; 107, pp. 106-116. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/20448215][DOI: https://dx.doi.org/10.1161/CIRCRESAHA.109.214601]

171. Ni, R.; Cao, T.; Xiong, S.; Ma, J.; Fan, G.C.; Lacefield, J.C.; Lu, Y.; Le Tissier, S.; Peng, T. Therapeutic inhibition of mitochondrial reactive oxygen species with mito-TEMPO reduces diabetic cardiomyopathy. Free Radic. Biol. Med.; 2016; 90, pp. 12-23. [DOI: https://dx.doi.org/10.1016/j.freeradbiomed.2015.11.013] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/26577173]

172. Xiong, X.; Lu, W.; Qin, X.; Luo, Q.; Zhou, W. Downregulation of the GLP-1/CREB/adiponectin pathway is partially responsible for diabetes-induced dysregulated vascular tone and VSMC dysfunction. Biomed. Pharmacother.; 2020; 127, 110218. [DOI: https://dx.doi.org/10.1016/j.biopha.2020.110218]

173. Kizhakekuttu, T.J.; Wang, J.; Dharmashankar, K.; Ying, R.; Gutterman, D.D.; Vita, J.A.; Widlansky, M.E. Adverse alterations in mitochondrial function contribute to type 2 diabetes mellitus-related endothelial dysfunction in humans. Arterioscler. Thromb. Vasc. Biol.; 2012; 32, pp. 2531-2539. [DOI: https://dx.doi.org/10.1161/ATVBAHA.112.256024] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/22879582]

174. Ngo, D.T.M.; Sverdlov, A.L.; Karki, S.; Macartney-Coxson, D.; Stubbs, R.S.; Farb, M.G.; Carmine, B.; Hess, D.T.; Colucci, W.S.; Gokce, N. Oxidative modifications of mitochondrial complex II are associated with insulin resistance of visceral fat in obesity. Am. J. Physiol. Endocrinol. Metab.; 2019; 316, pp. E168-E177. [DOI: https://dx.doi.org/10.1152/ajpendo.00227.2018] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/30576243]

175. Wu, M.; Liao, L.; Jiang, L.; Zhang, C.; Gao, H.; Qiao, L.; Liu, S.; Shi, D. Liver-targeted Nano-MitoPBN normalizes glucose metabolism by improving mitochondrial redox balance. Biomaterials; 2019; 222, 119457. [DOI: https://dx.doi.org/10.1016/j.biomaterials.2019.119457] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31476661]

176. Ding, X.W.; Robinson, M.; Li, R.; Aldhowayan, H.; Geetha, T.; Babu, J.R. Mitochondrial dysfunction and beneficial effects of mitochondria-targeted small peptide SS-31 in Diabetes Mellitus and Alzheimer’s disease. Pharmacol. Res.; 2021; 171, 105783. [DOI: https://dx.doi.org/10.1016/j.phrs.2021.105783] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/34302976]

177. Teodoro, J.S.; Nunes, S.; Rolo, A.P.; Reis, F.; Palmeira, C.M. Therapeutic Options Targeting Oxidative Stress, Mitochondrial Dysfunction and Inflammation to Hinder the Progression of Vascular Complications of Diabetes. Front. Physiol.; 2018; 9, 1857. [DOI: https://dx.doi.org/10.3389/fphys.2018.01857]

178. Kaludercic, N.; Di Lisa, F. Mitochondrial ROS Formation in the Pathogenesis of Diabetic Cardiomyopathy. Front. Cardiovasc. Med.; 2020; 7, 12. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32133373][DOI: https://dx.doi.org/10.3389/fcvm.2020.00012]