key: cord-0963589-8yqn1n6x authors: Taherkhani, Shima; Suzuki, Katsuhiko; Ruhee, Ruheea Taskin title: A Brief Overview of Oxidative Stress in Adipose Tissue with a Therapeutic Approach to Taking Antioxidant Supplements date: 2021-04-13 journal: Antioxidants (Basel) DOI: 10.3390/antiox10040594 sha: b3c0bceb8c7aeff9dc8decef432fdba80971a5cd doc_id: 963589 cord_uid: 8yqn1n6x One of the leading causes of obesity associated with oxidative stress (OS) is excessive consumption of nutrients, especially fast-foods, and a sedentary lifestyle, characterized by the ample accumulation of lipid in adipose tissue (AT). When the body needs energy, the lipid is broken down into glycerol (G) and free fatty acids (FFA) during the lipolysis process and transferred to various tissues in the body. Materials secreted from AT, especially adipocytokines (interleukin (IL)-1β, IL-6, and tumor necrosis factor-α (TNF-α)) and reactive oxygen species (ROS), are impressive in causing inflammation and OS of AT. There are several ways to improve obesity, but researchers have highly regarded the use of antioxidant supplements due to their neutralizing properties in removing ROS. In this review, we have examined the AT response to OS to antioxidant supplements focusing on animal studies. The results are inconsistent due to differences in the study duration and diversity in animals (strain, age, and sex). Therefore, there is a need for different studies, especially in humans. Since 1998, the National Institutes of Health (NIH) has recognized obesity as a disease due to the impact of individuals' health on society and the high economic and social costs incurred [1] . There is an adjacent link between obesity and metabolic disorders, including Alzheimer's disease, respiratory problems, cardiovascular disease (CVD), type 2 diabetes (T2D), cancer, and non-alcoholic fatty liver disease (NAFLD) [2] . Body mass index (BMI) ≥ 30 has been accepted in many studies as one of the critical indicators of obesity. Still, this index is less valid than measuring the waist-to-hip ratio (WHR) due to the inability to count the lean body mass (LBM) [3] . Obesity is the result of overconsumption of nutrients and a sedentary lifestyle. As the consumption of nutrients increases, an imbalance is created between energy intake and expenditure, leading to fat accumulation in adipose tissue (AT) and obesity [4] . The World Health Organization (WHO) estimates the number of obese people globally at 650 million [2] . Several studies have shown that obesity depends on the regional distribution of excess body fat, not excess body weight. Thus, one of the most critical risk factors for obesity and related diseases is abdominal fat, which leads to the stimulation of proinflammatory and pro-oxidant states [5] , the overproduction of free radicals, and pursuant oxidative stress (OS) in AT [6] . Scientists have made several efforts to control this disease. Various treatment methods, such as medication, surgery, exercise, and diet, have been considered in this regard. However, control of the disease is still far from expected. Increasing energy expenditure and subsequent weight loss is a smart way to control and prevent obesity [7] . In this regard, although authoritative articles have approved anti-obesity drugs, such as orlistat, and the use of weight-loss surgeries, the use of these methods is associated with many side defenses against these molecules. However, in stressful situations, endogenous protection alone may not be enough to eliminate or neutralize ROS. In such cases, various exogenous factors such as diet, lifestyle, medication, and physical activity play an essential role in maintaining ROS balance [27] . One of the tissues that are severely affected by ROS imbalance is AT. Under similar conditions, adipokines secreted by AT such as leptin and adiponectin increase and decrease, respectively [16] . ROS production in AT occurs due to excessive consumption of nutrients [20, 23, 28] . It is noteworthy that the hormone adiponectin acts as an anti-inflammatory hormone in AT. Since obesity is an inflammatory disease, this hormone's concentration in obesity decreases due to increased inflammatory cytokines. By reducing this hormone's expression in obese people, its influential role in improving insulin sensitivity also diminishes. As a result, obese people face a complication named insulin resistance (IR), which predisposes them to T2D [29] . Multiple factors are responsible for the production of ROS, both endogenous and exogenous. Endogenous sources are: mitochondria, cellular oxidases (xanthine oxidase (XO), nicotinamide adenine dinucleotide phosphate (NADPH) oxidase (NOX)), nitric oxide synthase (NOS), myeloperoxidase (MPO), processes related to peroxisomes, cellular respiration, cytochrome P450 oxidases, microsomal cyclooxygenase (COX), and catalyzed metal reactions. ROS is also produced exogenously through sources such as chemical drugs, pollutants, nutrient overdose, mutagens, xenobiotics, and ionizing radiation (Figure 1) [24] . Several studies have shown that ROS-derived mitochondria and NOX are critical sources of ROS production in adipocytes [30] . The main energy production source in the body is the mitochondria, which do this by oxidative phosphorylation. Interestingly, the O2 •− radical is mainly produced by oxidative phosphorylation. O2 •− is made in the mitochondrial ETC complex due to not being metabolized by about 0.15% and 2% of oxygen consumption in complexes I and III. Hence, mitochondria are one of the main sources of ROS and oxidative stress. After producing O2 •− mitochondrial manganese SOD (MnSOD) converts it to H2O2 [16, 21] . On the other The main energy production source in the body is the mitochondria, which do this by oxidative phosphorylation. Interestingly, the O 2 •− radical is mainly produced by oxidative phosphorylation. O 2 •− is made in the mitochondrial ETC complex due to not being metabolized by about 0.15% and 2% of oxygen consumption in complexes I and III. Hence, mitochondria are one of the main sources of ROS and oxidative stress. After producing O 2 •− mitochondrial manganese SOD (MnSOD) converts it to H 2 O 2 [16, 21] . On the other hand, ROS is mainly produced by the respiratory chain and during the formation of adenosine triphosphate (ATP). O 2 is created by activating the oxygen molecule's base state by transferring electrons or energy in the form of a single O 2 [11] . Because this radical crosses the cell membrane by aquaporins (AQPS) or proxy purines it can cause effects such as proliferation and recruitment of immune cells [32] . When germs attack these cells, NOX enzymes are activated during a respiratory burst. The enhanced products then absorb NADPH and O 2 . Thus, NADPH can act as an electron donor. This action starts the NOX enzyme complex in the plasma membrane by producing O 2 •− from O 2 molecules. In general, the production of O 2 •− by NOX is related to the time when an electron is taken from NADPH in the cytoplasm and transferred to an O 2 molecule [33] . NOX consists of a total of seven isoforms of catalytic subunits, including NOX 1-5 and dual oxidase 1 (Duox1) and dual oxidase 2 (Duox2). It should be noted that the main isoform of NOX in fat cells is NOX4. In response to the excessive consumption of glucose or palmitate, this isoform concentration in AT increases [21] . On the other hand, classical cytosolic subunits are not required for NOX4 activation, and only P22 phox is needed. Furthermore, the modulation of NOX4 activity is responsible for Polymerase deltainteracting protein 2 (Poldip2), which ultimately produces O 2 •− and H 2 O 2 . NOX5 and Duoxs 1 and 2 do not require cytosolic subunits for activation. These three members of the NOX family must bind to intracellular N-terminal EF hand motifs via Ca 2+ for activation. The EF hand has a helix-loop-helix structure, which is mainly found in calcium-bound proteins. This eventually leads to the production of O 2 •− and H 2 O 2 , respectively [34] [35] [36] [37] . In short, all NOX members except NOX5 need the P22 phox subunit to form. This subunit is usually regulated by the mineralocorticoid receptor (MR). It should be noted that all NOX components look at NADPH as an electron donor for the production of O 2 •− and H 2 O 2 [16] . NOX enzyme complexes play an important role in the production of O 2 •− by transferring electrons from NADPH to O 2 . H 2 O 2 is known as a highly absorbent radical in cell membranes. Finally, H 2 O 2 is reduced to H 2 O and O 2 by the enzyme CAT [34] . Mitochondria can produce ROS in both direct and indirect forms. Mitochondria can indirectly serve as a target for ROS production by the NOX enzyme complex, indicating a cross-link between NOX and mitochondria. In addition to acting as a potential source of ROS, mitochondria can also be responsible for NOX stimulation under certain conditions. This is especially important when ROS is neutralized by target mitochondrial antioxidant enzymes. By inhibiting ROS production, these enzymes can also partially alleviate NOX activity [33] . NADH and 1,5-dihydroflavin adenine dinucleotide (FADH2) are the products of glucose metabolism as electron donors in the tricarboxylic acid (TCA) cycle. This process eventually accelerates ROS production. On the other hand, the oxidation of free fatty acids (FFA) by mitochondria increases FFA intake. In this case, NADH and FADH2 are also produced by the oxidation of FFA-derived acetyl-CoA and the beta-oxidation of fatty acids (FAs) as electron donors. On the other hand, NOX is present on plasma membranes and can convert molecular O 2 to O 2 •− . NOX may be closely related to ROS production associated with nutrient overdose [38] . Excessive FFA accumulation in adipocytes increases ROS production. On the other hand, ROS overproduction is reversed by NOX inhibitors such as diphenyleneiodonium or apocynin. This indicates NOX's role in the production of ROS due to excessive consumption of fatty acids. Activation of NADPH oxidase by excessive consumption of fatty acids stimulates the synthesis of diacylglycerol and subsequent activation of protein kinase C (PKC) by FFA, especially palmitate [39] . FFA's molecular mechanism that activates the NOX enzyme complex is closely related to the stimulation of diacylglycerol synthesis and subsequently activated PKC [21] . ROS levels' evaluation and measurement are important, practical steps to improve these reactive species' effects. By measuring these species, a more accurate view of them can be achieved, and the appropriate treatment method can be used for each of them. Of course, direct measurement of ROS has its problems and difficulties [40] . This is important because some ROS, such as O 2 •− and • OH, while having very short half-lives of 5 −10 and 9 −10 s, respectively, also have very high reactivity. Over the years, countless indicators have been discovered to measure these species, but many of them did not provide consistent and reliable results and were easily discarded. However, in the following years, valid indicators were calculated to measure the oxidation of various tissues and cells of lipids, proteins, and DNA [41] . In general, the grouping of OS indicators is very important. In one group, the biochemical nature of molecules such as proteins, lipids, carbohydrates, and DNA is considered. While in the second group, products of oxidation of cellular compounds are formed to balance cellular mechanisms (oxidation-reduction). This group itself is divided into several subgroups [42] . The first group to free radicals leads to the change of various biomolecules such as malondialdehyde (MDA) from lipid oxidation, 4-hydroxy-2-nonenal (4-HNE), and reactive carbonyls from protein oxidation and 8-hydroxy-2'-deoxyguanosine (8-OHdG) of nucleic acid oxidation have been noted. In the second group, the relationship between free radical metabolism and physiological antioxidant defense molecules such as reduced glutathione (GSH) and CAT is considered. Furthermore, in the third group, modulation of free radicals with transcription factors such as c-Myc and Nuclear factor-κB (NF-κB) is important [16] . Here are the most common and commonly used indicators of OS: When lipid molecules are exposed to OS, various products are produced in lowdensity lipoproteins (LDL) or cell membranes. One of its end products is MDA. The reactive substance, thiobarbituric acid reactive substances (TBARS), is responsible for measuring MDA levels [13] . When DNA is exposed to ROS, compounds such as 8-hydroxy guanine, 8-OHdG, and MDA-DNA are formed to break the DNA strands. 8-OHdG is composed of guanine oxidation, which plays an important role in mutagenic DNA damage and is used as a suitable indicator of oxidative damage to DNA [42] . In addition to producing 8-OHdG, guanine nitration also makes 8-NO 2 -Gua. These DNA metabolites are used to measure OS to DNA. In fact, in inflamed epithelial cells, 8-NO 2 -Gua levels increase. The amino acid polypeptides are separated by the reaction of amino acid side groups with ROS, and proteins are oxidized. With the oxidation of proteins, reactive carbonyl groups (aldehydes and ketones) are formed, and their tracing is known as an indicator of oxidative damage in protein molecules. It should also be noted that carbonyl groups are formed due to ROS reactions with proteins, carbohydrates, and lipids [43] . Among the products produced by the oxidation of carbohydrates are advanced glycation end products (AGEs), which are formed due to non-enzymatic glycosylation of proteins. The highest presence of AGEs is in plasma and tissues, leading to diabetes, kidney failure, and aging [44] . One of the most sensitive indicators of oxidative damage is the redox ratio GSH: GSSG. Influence on regulating gene expression, signaling conduction, NO metabolism, apoptosis, and impact on free radical scavenging are among the effective roles of GSH. On the other hand, the removal of ONOOis highly dependent on the formation of oxidized glutathione (GS-SG) by GSH, which is eventually converted to GSH through NADPH-dependent glutathione reductase [45] . Various signaling pathways such as C-Jun N-terminal kinase, protein kinase B, mitogen-activated protein kinase, apoptosis signal-regulated kinase 1, NF-κB, and protein phosphatase 1 and 2A are affected due to changes in the GSH/GSSG ratio [46] . The definition given to AT today is very different from what it used to be. It was previously thought that this tissue was just a tissue with the property of storing energy in the form of lipids. Today, a new perspective has emerged on it as an endocrine tissue [21, [47] [48] [49] . Of course, the feature of this tissue's storage source has helped many living things throughout history. When there is a lack or excessive consumption of nutrients, it has always been AT that has been able to help maintain the body's energy homeostasis with hyperplasia or hypertrophy in different conditions [50] [51] [52] [53] . On the other hand, the new look at this tissue owes much to discovering the hormone leptin in 1994 as a food controller. Even earlier, in 1987, it was found that sex steroids were metabolized in this tissue, followed by the production of adipsin [54, 55] . Adipsin was one of the first adipokines to be identified in cultured adipocytes based on differentiationdependent expression of its mRNA. Adipsin is an endocrine factor secreted by 3T3 fat cells [56] [57] [58] . Other important roles of adipose tissue in the body include effects on lipid and glucose metabolism, maintaining energy balance, appetite control, glucose homeostasis, insulin sensitivity, energy expenditure, inflammation, and repair of AT [59, 60] . Various factors such as FFA supply, FFA esterification to triglycerides (TG), and TG degradation through the lipolysis process determine fat stores in AT. In general, the two enzymes of hormone-sensitive lipase (HSL) and adipose triglyceride lipase (ATGL) play an important role in the lipolysis process, which indicates the formation of FFA and glycerol as a result of the separation of the TG ester bond [61] . In general, AT contains high levels of stromal vascular cells, immunity, stem, endothelial, lymphocytes, adipocytes, preadipocytes, connective tissue matrix, and nerve tissue [55, 62, 63] . This tissue is also divided into brown adipose tissue (BAT) and white adipose tissue (WAT). There are apparent differences between BAT and WAT, morphologically. One of these differences is related to the size of the fat storage drops. White adipose cells are placed in a large fat drop (unilocular), and brown fat cells are placed in several small fat cytoplasm drops (multilocular) [64] . Another apparent difference between these two types of tissue is the number of mitochondria in them. The number of mitochondria in BAT is much higher than in WAT but the number of mitochondria in the WAT is limited. Because WAT plays an important role in lipid metabolism processes, including beta-oxidation and the TCA cycle, maturation, and differentiation of adipocytes, the importance of mitochondrial function is highlighted [16] . In this way, the BAT can maintain body temperature, especially when it is cold. BAT owes this feature to the high number of mitochondria within it. Of course, this tissue also plays a very important role in lipid oxidation [65] . The mitochondria's inner membrane hosts a protein called uncoupling protein 1 (UCP1) that can generate heat by transferring protons to the mitochondrial matrix and separating oxidative phosphorylation and the electron transfer chain from ATP synthesis [60, 66, 67] . In fact, by consuming too many nutrients and being exposed to cold temperatures, UCP1 is expressed to protect the body's organisms against obesity and the cold. Sympathetic neurons stimulate UCP1 inside the BAT to lead to exotherm and energy loss. Thus, in both humans and rodents, the association between obesity and UCP1 expression is inverse [68] . Sesterins are among the vital proteins associated with obesity due to oxidative stress, which play an important role in regulating metabolic homeostasis, suppressing ROS accumulation, and regulating the AMP-activated protein kinase (AMPK)-mammalian target of rapamycin complex 1 (mTORC1) signaling pathway. However, reducing these proteins in the body is associated with obesity and other metabolic disorders [69] . In general, three different isoforms have been discovered for sestrin (sestrin 1-3), of which sestrin 2 is more expressed in liver and adipose tissue. It has been estimated that sestrin 2 can reduce fat accumulation in AT and improve metabolic homeostasis by suppressing ROS and mTORC1 [70] . The most important site for cold-induced exotherm in rodents is BAT. This tissue is also involved in the exotherm of fat tissue. The distribution of BAT in humans and rodents varies according to their age. In humans, there is a large amount of BAT in the body only in early infancy, and with age, the distribution of BAT in the body decreases. However, in the case of rodents, the opposite is true. Because BAT expands as rodents live longer, on the other hand, different types of BAT have been deposited in the body in a scattered manner; interscapular BAT (IBAT) is the most important and vital type [71] . The point here is that the calorific value of IBAT is consistent with the body's OS. The hypothalamus is responsible for controlling IBAT activity and is controlled primarily by the sympathetic nerves and body temperature control centers. Oxidation of FFA in IBAT provides the fuel needed for noradrenaline to activate lipolysis and heat production. However, since IBAT uses a lot of O 2 to generate heat, part of the oxygen molecules are converted to free radicals, especially O 2 •− by mitochondrial assemblies I and III [72] . However, WAT works more to maintain the balance of energy homeostasis and the source of fat storage and release. WAT content includes subcutaneous WAT (scWAT), visceral WAT (vWAT), and peripheral arteries, each containing fat such as the omental, gonadal, retroperitoneum, epicardial, mesenteric, and perineal. However, it should be noted that all of these reserves are responsible for regulating total energy homeostasis [16] . Most importantly, the endocrine properties of AT are embedded in WAT [66] . This means that there are many hormonal mediators, including cytokines (IL-1β, IL-6, and TNFα), adipokines (adiponectin, resistin, and leptin), and chemokines (macrophage inflammatory protein 1 (MIP1), monocyte chemoattractant protein-1 (MCP-1)), ROS and FFA from WAT [73] . However, various studies have shown that pro-inflammatory cytokines are much less expressed in scWAT than in vWAT [29] . On the other hand, different hormones affect the storage and release of WAT fat. For example, after a meal, TG storage is highly dependent on insulin action. While in fasting and when different body organs (skeletal muscle and liver) need energy, the TG stored in WAT is broken down by catecholamines into FFA and G [65] . Furthermore, beige or brown (brown-in-white) fat cells are a new type of exothermic fat cell within WAT. However, these cells have both white and brown fat cells at the same time. They are more similar to fat white cells in terms of growth and more similar to BAT in terms of function and morphology [64, 74] . One of the practical and important factors in maintaining animals' and humans' body weight is maintaining fat homeostasis in WAT. This depends a lot on the proper and adequate performance of the WAT-derived materials [75, 76] . Excess fat due to the long-term balance of positive energy contributes to OS in adipocytes, obesity, and subsequent obesityrelated metabolic disorders such as hyperglycemia, insulin resistance and cardiovascular disease. [55, 65] . Thus, systemic OS is closely related to obesity. During obesity, the concentration of OS indicators such as high-sensitivity C-reactive protein (CRP) and oxidized LDL increases [33] . Obesity results from increasing the size and volume of body fat cells and has adverse effects on the health of living organisms [76, 77] . On the other hand, the mismatch between height and body weight due to excessive fat accumulation is named obesity [78] . Today, the people of developed countries are facing obesity-related health problems, but the people of developing countries are grappling with this global dilemma [79] . It is estimated that by 2030, half of all retirees in the United States will suffer from chronic obesity and related diseases, especially cardiovascular disease. This has numerous negative effects on the global health system due to the costly and time-consuming treatment of obesity [80] . Countless BMI studies have accepted more than 30 as obesity, but several studies have shown that BMI is not a good indicator of obesity. These studies cited the inability of this criterion to measure lean mass. These studies have shown that the measure of waist-to-pelvis or waist circumference may be a more accurate and accurate indicator of BMI in calculating fat distribution [16, 81] . According to statistics published by the WHO, the prevalence of this disease is likely to reach more than one billion people in the world by 2030, which is a worrying statistic [79, 82] . On the other hand, there is a direct and positive relationship between BMI and indicators of oxidative damage to proteins (advanced oxidation protein products (AOPP), lipids (MDA or 8-iso-PGF2α), and DNA (8-OHdG) during obesity) [30] . Oxidative DNA damage due to prolonged exposure to OS impairs mitochondrial function and leads to excessive fat accumulation and subsequent insulin resistance [16] . In recent years, obesity has become widespread due to lifestyle changes such as increased consumption of nutrients, especially fast foods, and decreased physical activity (environmental factors). Of course, the role of genetics is also felt to some extent in the development of this disease, but its effect is not as tangible as environmental factors [83] . There should be a strong emphasis on body weight control as a practical way to prevent obesity-related diseases. This usually happens with lifestyle modifications and focuses on eating healthy and adequate nutrients and engaging in regular exercise [84] . Various studies have shown that obesity is associated with increased OS, decreased antioxidant activity, and insulin resistance in AT [85] . Numerous studies have shown that fat accumulation in obesity is closely related to an increase in ROS and subsequent OS. Therefore, obesity-induced OS plays an important role in disrupting adipokines regulation and amplifying inflammatory signals and even leads to changes in cellular composition and premature aging [84] . It is estimated that with excessive consumption of nutrients, WAT expands (size increases) by 10% per year, which is known as fatty remodeling and the penetration of immune cells into AT [21] . AT remodeling leads to the rapid spread of obesity, which is usually accompanied by changes in the size (hypertrophy) and number (hyperplasia) of fat cells [16, 51] . Obesity is the cause of various other diseases such as T2D, dyslipidemia, cardiovascular disease, atherosclerosis, and hypertension [53] . Clinical studies have also shown that BMI is directly related to OS by-products such as protein carbonylation products or lipid peroxidation. By causing OS in AT, adipocytokines' secretion (IL-1β, IL-6, and TNFα) is disrupted and eventually leads to obesity and associated diseases [85] . Of course, the function of other cells and tissues in the body, including beta pancreatic cells, vascular endothelial cells, and myocytes, is affected by obesity due to adipose tissue [21] . As mentioned earlier in this article, oxidative damage can be defined as an imbalance between ROS production and antioxidant defense, leading to overproduction of ROS. The result of this imbalance is a change in cellular redox status. In vivo, antioxidant defense systems play an important role in restoring cellular redox status, especially under normal and stress-free conditions [86] . To combat OS, the body uses enzymatic antioxidant systems (SOD, CAT, peroxidase (POD), peroxiredoxin (Prxs), and glutathione peroxidases (GPX)) and non-enzymatic (carotenoids, tocopherol, and ascorbic acid) [85] . When the body is under pressure using various stressors, especially fat accumulation in AT, these antioxidant defenses alone may not be sufficient and require the use of antioxidant supplements [87] [88] [89] [90] [91] . McCord and Fridovich, by discovering SOD, showed that this enzyme could defend cells exposed to O 2 as a defense mechanism [86] . To counteract O 2 •− , SOD is the first enzyme to convert this free radical to H 2 O 2 [92] [93] [94] . Based on specific cofactors and cell locations, there are three different isoforms of SOD. These isoforms include cytosolic (SOD1 or Cu/ZnSOD), mitochondrial SOD (SOD2 or MnSOD), and extracellular SOD (SOD3 or ecSOD) [16] . SOD1 consists of both copper and zinc ions, which are responsible for maintaining enzymatically active sites. SOD1 does this by working with the remaining imidazolate ligands of the histidine SOD1. On the other hand, zinc ions are responsible for stabilizing enzymes in different cells of the body. It has also been estimated that the nuclear part of mammalian cells, cytoplasm, peroxisomes, lysosomes, chloroplasts, and cytosols host SOD1. However, the highest SOD1 activity has been reported in the human liver [91] . The second cofactor of SOD is MnSOD, which has the most increased activity in the renal cortex, and mainly peroxisomes and mitochondrial matrix are the enzyme sites [95] . The third cofactor (EC-SOD) is also present in human lymphocytes and plasma. Zinc and copper are found in this enzyme and effectively remove O 2 •− from tissues [96] . GPx is usually in the mitochondria and cytosol of various cells and is mainly a glycoprotein containing selenocysteine residues. This antioxidant enzyme is skilled in converting H 2 O 2 to water. This enzyme also participates in the catalysis cycle to reduce hydroperoxides to alcohol and ultimately involves the oxidation of GSSG induced by GSH [97] . There is a positive relationship between increased GPX concentration and anti-inflammatory activity of the cardiovascular system. On the other hand, lipid hydroperoxides such as cholesterol, free fatty acids, cholesterol esters, and phospholipids are rapidly neutralized by phospholipases and GPX. It is also noteworthy that the detoxification of lipid hydroperoxides is performed by the enzymes PRx, glutathione S-transferase (GST), and GPX [92] . To date, approximately five different isoforms of GPX have been identified. These isoforms include cytosolic or classical GPX (cGPX or GPx1), gastrointestinal GPX (GIGPX or GPX2), plasma GPX (PGPX or GPX3), phospholipid GPX (PHGPX or GPX4), and sperm nuclear GPx or GPx (Sn) [97] . The peroxisome part of many cells contains the enzyme CAT, which effectively reduces hydrogen peroxide to water. As mentioned earlier, both CAT and GPX are sensitive to H 2 O 2 . These two enzymes are exposed to high and low H 2 O 2 concentrations, respectively. For this reason, the concentration of free radicals determines the importance of the two enzymes GPX and CAT [98] . Another way to measure ROS is to observe changes in the antioxidant defense system. Tools such as Total Antioxidant Status (TAS), Trolex Equivalent Antioxidant Capacity (TEAC), Total Radical Trapping Antioxidant Parameter (TRAP), Plasma Iron Reduction Capacity (FRAP), and Radical Oxygen Absorption Capacity (ORAC) can measure antioxidant capacity [41] . Because obesity is more associated with physical inactivity and overeating, genetics play a very limited role in causing the disease. Therefore, for the treatment of obesity, special attention should be paid to the lifestyle because this disease can be prevented and even treated by lifestyle modification [73, 99, 100] . As mentioned, one of the most important treatment strategies and, of course, prevention of various diseases, especially obesity, is exercise. Multiple studies have shown that AT reserves are reduced by regulating exerciseinduced lipase regulation, which ultimately leads to weight loss and obesity treatment. Another important role of exercise is to create antioxidant profiles, which can be a key solution to further reduce body fat due to OS [61] . The results of various studies show the depletion of both enzymatic and non-enzymatic antioxidant systems. However, the type of tissue and the degree of obesity is among the factors that play an important role in the rate of discharge of these systems [30] . These enzymes protect the body's cells by catalyzing free radicals into water. Various studies have shown that Prxs expression in humans and obese animals is closely related to OS induced by AT. The activity of this enzyme decreases with obesity. On the other hand, PRDXS in adipocytes can increase and decrease lipolytic and lipogenic gene expression, respectively [101] . Scientists have studied the effects of antioxidant supplements on the improvement of obesity caused by OS in various studies. These studies' results are contradictory, and further studies in this field are still required to reach a correct and logical conclusion. For example, vitamin E is one of the supplements for which the usefulness or harmfulness in treating obesity or other metabolic disorders remains unclear [30] . Simán et al. (1996) examined the effect of consuming an antioxidant diet containing butylated hydroxytoluene (BHT 0.5% and 1%) with or without vitamin E acetate (4%) for four weeks in 30 female Sprague Dawley rats. They concluded no change in the alphatocopherol concentration of abdominal AT with BHT supplementation [102] . In another study, Rodrigues et al. (2020) examined the effect of consuming an antioxidant fruit called chestnut at a dose of 1.1% in 18 FVB/Nn male 7-month-old mice. They concluded that this supplement reduced adipose tissue, serum cholesterol, and adipose tissue deposition [103] . Furthermore, Candiracci et al. (2014) investigated the effect of consuming an antioxidant source of rice bran enzymatic extract for 20 weeks in obese and lean Zucker rats. This study's results included the reduction of overproduction of IL-6, TNF-α, IL-1β, and NOS in abdominal and epidermal visceral AT. In addition, reducing the adipocyte size of abdominal and epidural visceral AT was another effect of this supplement on AT [29] . In a study, Valls et al. (2003) investigated the impact of eating a diet rich in corn oil with or without antioxidant supplementation of vitamin E (30 mg per day) on the antioxidant status and oxidative damage of AT in male Wistar rats. This study showed that the activity of the antioxidant enzymes CAT and SOD was reduced by taking a hyperlipidemia supplement along with vitamin E in AT [104] . In one study, Arias et al. (2014) examined the effect of quercetin (30 mg/kg body weight) in 28 male Wistar rats. This study shows that this supplement has no impact on reducing AT size and body weight. The activity of lipoprotein lipase and lipogenic enzymes remained unchanged with the use of this supplement [105] . Chen et al. (2020) investigated the effect of antioxidant supplementation of protease A-digested crude-chalaza hydrolysates (CCH-As) on Syrian male Golden Hamsters. They showed that adiposeperinatal/hepatic tissue size decreased as a result of consuming this antioxidant composition. Increased lipolysis (unpaired carnitine palmitoyltransferase 1, hormone-sensitive lipase, and protein 2) was also observed in these hamsters' AT [106] . Because mice, unlike humans, can endogenously synthesize vitamin C (ascorbate and ascorbic acid) and meet their daily needs, it is hypothesized that consuming extra amounts of vitamin C will counteract the anti-inflammatory effects. Therefore, in a study, researchers examined the effect of 4 weeks of vitamin C supplementation (low and high doses of 0.75 and 25 mg of ascorbic acid per kg of body weight, respectively) on male Wistar rats. Excessive consumption of this antioxidant supplement was able to strengthen antioxidant defenses (MnSOD, CuZnSOD, and CAT in AT [107] . Sung et al. (2012) investigated the effect of antioxidant supplementation of Polygonum aviculare L. (knotgrass) (PAE) in male C57BL/6J mice. They were given a high-fat diet or a high-fat diet with PAE antioxidant supplementation at a dose of 400 mg/kg body weight per day. In this article, the researchers found that adipose tissue weight, serum TG concentration, body weight, MDA and leptin concentrations, and fat cell area decreased as a result of taking this supplement [108] . Furthermore, Alcalá et al. (2015) examined the effect of taking antioxidant vitamin E supplementation (150 mg twice daily) in C57BL/6J mice. This study's results included a reduction in collagen deposition and OS in rat visceral AT. Consumption of this vitamin also led to increased storage capacity and fat cells' proliferation [30] (Table 1) . Simán et al. [102] Sprague Dawley rats BHT (0.5% and 1%) with or without vitamin E acetate (4%) for four weeks. No change in the alpha-tocopherol concentration of abdominal AT with BHT supplementation. Rodrigues et al. [103] FVB/n male 7-month-old mice Chestnut at a dose of 1.1%. The reduction of serum cholesterol and AT deposition. Candiracci et al. [29] Obese and lean Zucker rats Rice bran enzymatic extract (RBEE) for 20 weeks. The reduction of overproduction of IL-6, TNF-α, IL-1β, and NOS in abdominal and epidermal visceral AT. Reducing the adipocyte size of abdominal and epidural visceral AT. Valls et al. [104] Male Wistar rats Diet rich in corn oil with or without antioxidant supplementation of vitamin E (30 mg per day). The reduction of activity of the antioxidant enzymes CAT and SOD. Arias et al. [105] Male Wistar rats Quercetin (30 mg/kg body weight). No impact on reducing AT size and body weight. No change in the activity of lipoprotein lipase and lipogenic enzymes. Chen et al. [106] Syrian male Golden Hamsters Protease A-digested crude-chalaza hydrolysates (CCH-As). The reduction adipose-perinatal/hepatic tissue size. The increase of lipolysis (unpaired carnitine palmitoyltransferase 1, hormone-sensitive lipase, and protein 2). Djurasevic et al. [107] Male Wistar rats Vitamin C supplementation (low and high doses of 0.75 and 25 mg of ascorbic acid per kg of body weight, respectively) for 4 weeks. Excessive consumption of this antioxidant supplement was able to strengthen antioxidant defenses (MnSOD, CuZnSOD, and CAT in AT Sung et al. [108] Male C57BL/6J mice High-fat diet or a high-fat diet with PAE at a dose of 400 mg/kg body weight per day. The reduction of AT weight, serum TG concentration, body weight, MDA and leptin concentrations, and fat cell area. Alcalá et al. [30] C57BL/6J mice Vitamin E supplementation (150 mg twice daily). The reduction in collagen deposition and OS in rat visceral AT. The increase of storage capacity and fat cells' proliferation. AT is one of the essential tissues that modulate innate and adaptive immune responses in the body. This tissue modulates these responses by secreting adipokines such as leptin and adiponectin. However, during obesity, the function of this tissue is impaired. This means that the secretion of leptin and adiponectin increases and decreases, respectively, and eventually, the immune system's role is impaired [109] . In such cases, the chest wall is also affected by fat accumulation and impairs the lungs' proper functioning [110] . One of the consequences of an impaired immune system is the induction of inflammatory cytokines and the development of viral infections such as COVID-19 due to reduced natural killer (NK) cell activity. This infectious disease is caused by SARS-COV-2 (Severe Acute Respiratory Syndrome Coronavirus 2) (Figure 2 ) [111] [112] [113] . Antioxidants 2021, 10, x FOR PEER REVIEW 13 of 22 Figure 2 . During obesity, adipose tissue (ATs) function is impaired, and secretion of leptin and adiponectin increases and decreases, respectively. Moreover, the immune system's function is impaired. One of the consequences of an impaired immune system is the induction of viral infections such as COVID-19 due to reduced natural killer (NK) cell activity. COVID-19 requires binding to the Angiotensin-Converting Enzyme 2 (ACE2) receptor and porphyrins on the cell surface to enter and then infect fat cells. Eventually, heme oxygenase-1 (HO-1) and ROS levels decrease and increase, respectively [109] [110] [111] [112] [113] . Various factors such as central obesity, IR, T2D, over nutrition, lack of exercise, and other metabolic syndrome parameters predispose multiple diseases such as non-alcoholic fatty liver disease (NAFLD) [126, 127] . NAFLD is usually characterized by fat accumulation in the liver tissue, and oxidative stress plays a crucial role in its formation and development. It covers a wide range of liver-related diseases such as steatosis, steatohepatitis, liver fibrosis, liver cirrhosis, and even hepatocellular carcinoma [128, 129] . For NAFLD, there are non-progressive forms (non-alcoholic fatty liver disease (NAFLD) or simple steatosis) and progressive and aggressive forms (non-alcoholic steatohepatitis (NASH)). Hepatocellular carcinoma (HCC) and cirrhosis are considered as consequences of NASH [130] [131] [132] . Macrophages and Kupffer cells can stimulate pro-inflammatory mechanisms and then satellite cell activity at the liver surface by secreting inflammatory cytokines such Figure 2 . During obesity, adipose tissue (ATs) function is impaired, and secretion of leptin and adiponectin increases and decreases, respectively. Moreover, the immune system's function is impaired. One of the consequences of an impaired immune system is the induction of viral infections such as COVID-19 due to reduced natural killer (NK) cell activity. COVID-19 requires binding to the Angiotensin-Converting Enzyme 2 (ACE2) receptor and porphyrins on the cell surface to enter and then infect fat cells. Eventually, heme oxygenase-1 (HO-1) and ROS levels decrease and increase, respectively [109] [110] [111] [112] [113] . COVID-19 was first seen in December 2019 in Wuhan Province, China. Then, in January 2020, the disease's first cases were reported outside China (one in Japan and two in Thailand). Since then, the disease has spread rapidly to all countries of the world [114, 115] . The condition was declared a pandemic on 11 March 2020, by WHO on 11 March 2020, and to date (22 February 2021), the total number of infected patients has reached 112,045,556, of which 2,479,625 people lost their lives (https://www.worldometers.info/coronavirus/, accessed on 20 February 2021). The virus requires binding to the Angiotensin-Converting Enzyme 2 (ACE2) receptor and porphyrins on the cell surface to enter and then infect fat cells. Eventually, heme oxygenase-1 enzymes (HO-1) and ROS levels decrease and increase, respectively [116] [117] [118] . Fatigue, headache, fever, and loss of taste and smell are symptoms associated with this disease, and most of these infected people recover without hospitalization. Various studies examining healthy people and people with underlying conditions have shown that people with cardiovascular disease, kidney damage, diabetes, and severe obesity (BMI ≥ 30 kg/m 2 ) are more susceptible to the virus [119] . The risk of developing COVID-19 does not depend on age, and the severity of the disease follows a different pattern at each age. According to Public Health England (PHE), the risk of COVID-19 death in people with a BMI between 35 and 40 kg/m 2 increases by 40%. However, this increase of risk in people with a BMI ≥ 40 kg reaches 90% [120] . As mentioned, obesity is directly related to COVID-19 disease and leads to increased inflammation, mitochondrial dysfunction, and increased ACE2 receptors. Numerous studies have shown that high BMI (≥30 kg/m 2 ) and excess visceral fat (VF) are effective methods in diagnosing the severity of COVID-19, especially in obese patients [115, 119, 121] . For more than a year, the COVID-19 disease has affected human society in all aspects of life. The medical community has been able to develop effective vaccines against the disease. Furthermore, scientists in authoritative articles have suggested various drugs and nutrients reduce inflammation in the immune system, indirectly helping cure the disease. Among the various nutrients, antioxidants (vitamins C, D, and E, iron, and selenium) have always been at the forefront of strengthening the immune system and reducing inflammation in various body tissues, especially AT [122] . The recommended dose of vitamins C, D, and E in healthy individuals is 200 mg/day, 2000 IU/day (50 µg/day), and 15 mg/day, respectively. However, in patients who have inflammation in their immune system, it is better to increase the daily intake of vitamin C to 1-2 gr. It has also been suggested that the daily dose of vitamin D in these patients be increased to 10,000 IU in the first few weeks and then continued at a dose of 5000 IU. Also, the daily intake of vitamin E in these patients should be increased to 200 IU [123, 124] . Consumption levels of another nutrient, iron, are usually about 8 mg daily in men, approximately 18 mg in women between the ages of 19 and 50, and around 8 mg in women over 51 years of age. However, if the person has inflammation in the immune system, 60 mg Fe should be consumed daily in both men and women and all age groups [114] . The daily intake of selenium in healthy men and women is 50 µg, respectively, but in inflammatory conditions, this amount increases to 200 µg per day [125] . Various factors such as central obesity, IR, T2D, over nutrition, lack of exercise, and other metabolic syndrome parameters predispose multiple diseases such as non-alcoholic fatty liver disease (NAFLD) [126, 127] . NAFLD is usually characterized by fat accumulation in the liver tissue, and oxidative stress plays a crucial role in its formation and development. It covers a wide range of liver-related diseases such as steatosis, steatohepatitis, liver fibrosis, liver cirrhosis, and even hepatocellular carcinoma [128, 129] . For NAFLD, there are non-progressive forms (non-alcoholic fatty liver disease (NAFLD) or simple steatosis) and progressive and aggressive forms (non-alcoholic steatohepatitis (NASH)). Hepatocellular carcinoma (HCC) and cirrhosis are considered as consequences of NASH [130] [131] [132] . Macrophages and Kupffer cells can stimulate pro-inflammatory mechanisms and then satellite cell activity at the liver surface by secreting inflammatory cytokines such as IL-6, TNF-α, and IL-β. In such inflammatory conditions, conditions are provided for increasing the deterioration of insulin resistance and the development of liver fibrosis (Figure 3 ) [133] . In general, in patients with NAFLD, lipids' storage capacity in the liver tissue is so high that it leads to hepatocyte dysfunction and even death [134] . . Various factors such as central obesity, insulin resistance (IR), type 2 diabetes (T2D), overnutrition, lack of exercise, and other metabolic syndrome parameters predispose multiple diseases such as NAFLD. Macrophages and Kupffer cells can stimulate pro-inflammatory mechanisms and then satellite cell activity at the liver surface by secreting inflammatory cytokines such as IL-6, TNF-α, and IL-β. In such inflammatory environments, conditions are provided for increasing the deterioration of IR and the development of liver fibrosis. It should be noted that the increased flow of FAs to the liver through the bloodstream, the synthesis of de novo hepatocytes, and impaired clearance through β-oxidation lead to the accumulation of TAG droplets in hepatocytes. Various proteins such as FATP, transmembrane proteins, FABP, caveolins, and FAT/CD36 can accelerate the absorption of FA by increasing the proliferation of FFA in blood vessels. It is noteworthy that these proteins' expression can improve by an HFHSD. On the other hand, in fasting conditions, FFAs are mainly produced during the lipolysis process by beta-adrenergic receptor agonists [126] [127] [128] [129] [130] [131] [132] [133] . Nutraceuticals are not recognized traditionally as a nutrient but have physiologi health benefits in the human body. Plant-derived nutraceuticals are well-known for th direct or indirect antioxidant activities, which relates to scavenging or eliminating fr radicals during cellular metabolism. They can interact with the oxidized species at bo cellular and molecular levels by regulating gene expression, epigenetic controls, and p tein and DNA repair. Previously it was reported that nutraceuticals have potential pro erties in immunity modulation, gene expression, and various signaling process regulati [153] [154] [155] [156] [157] [158] . The nutraceuticals can be prepared from the foods available in the local mark for example, ginger, garlic, avocado, and onion, in the form of polyphenols, carotenoi sulforaphane and other isothiocyanates, glucosinolate, phytosterol, etc. [159] . They c increase the level of heme oxygenase (HO) 1, total glutathione, and other phase 2 enzym by activating the transcription Nrf2. Moreover, treatment for a certain period w nutraceuticals may also improve the lipid profile and can reverse the harmful effects obesity on blood lipids [160] . For example, curcumin is a potential nutraceutical, reduc macrophage infiltration in WAT, increase adiponectin in AT, decreases NF-κB activi therefore reduces the expression of inflammatory markers and OS [161] . To date, the u Figure 3 . Various factors such as central obesity, insulin resistance (IR), type 2 diabetes (T2D), overnutrition, lack of exercise, and other metabolic syndrome parameters predispose multiple diseases such as NAFLD. Macrophages and Kupffer cells can stimulate pro-inflammatory mechanisms and then satellite cell activity at the liver surface by secreting inflammatory cytokines such as IL-6, TNF-α, and IL-β. In such inflammatory environments, conditions are provided for increasing the deterioration of IR and the development of liver fibrosis. It should be noted that the increased flow of FAs to the liver through the bloodstream, the synthesis of de novo hepatocytes, and impaired clearance through β-oxidation lead to the accumulation of TAG droplets in hepatocytes. Various proteins such as FATP, transmembrane proteins, FABP, caveolins, and FAT/CD36 can accelerate the absorption of FA by increasing the proliferation of FFA in blood vessels. It is noteworthy that these proteins' expression can improve by an HFHSD. On the other hand, in fasting conditions, FFAs are mainly produced during the lipolysis process by beta-adrenergic receptor agonists [126] [127] [128] [129] [130] [131] [132] [133] . Numerous studies have shown that the mechanisms associated with the pathogenesis of obesity and NAFLD are the same [135] . A two-hit theory can usually explain the pathogenesis of NAFLD. The first theory is explained when triacylglycerol (TAG) droplets accumulate in hepatocytes and lead to simple hepatic steatosis development. In the second theory, NAFLD's pathogenesis is attributed to increased oxidative stress, IR, lipid peroxidation, and endoplasmic reticulum inflammation [136, 137] . It should be noted that the increased flow of FAs to the liver through the bloodstream, the synthesis of de novo hepatocytes, and impaired clearance through β-oxidation lead to the accumulation of TAG droplets in hepatocytes. TG synthesis in the liver is mainly due to the lipids produced by de novo lipogenesis (DNL), dietary lipids, and carbohydrates. TG synthesis is dependent on the uptake of FFAs from the plasma by the liver [138] . DNL is the process by which exogenous energy sources or endogenous carbohydrates can synthesize lipids. Three steps are defined for this process. First, FAs can be synthesized through acetyl-CoA subunits produced during glycolysis and carbohydrate metabolism. Then, to form long-chain unsaturated FAs, FA elongation and desaturation must occur. Finally, the FAs formed from the previous step are assembled to convert to TG and very-low-density lipoproteins (VLDLs). When the balance between TG synthesis and degradation is lost, the conditions for NAFLD are created [130] . Various proteins such as fatty acid (FA) transporter protein (FATP), transmembrane proteins, FA binding protein (FABP), caveolins, FA translocase (FAT)/CD36 can accelerate the absorption of FA by increasing the proliferation of FFA in blood vessels. It is noteworthy that these proteins' expression can improve by a high-fat, high-sugar diet (HFHSD). On the other hand, in fasting conditions, FFAs are mainly produced during the lipolysis process by beta-adrenergic receptor agonists [139] . AT is severely affected by NAFLD because it is a source of FAs storage, and the secretion of adipokines is impaired. AT acts like a double-edged sword. This means that some hormones secreted by AT, such as adiponectin and visfatin, have protective effects against NAFLD; however, the hormones resistin and leptin contribute to hepatic development of steatosis and IR [140, 141] . ROS production in hepatic mitochondria results from excessive oxidation of fatty acids, which ultimately causes OS in liver tissue. Proteins, DNA, and lipids are susceptible to OS and are easily damaged by activating pro-inflammatory cells such as Kupffer cells and stimulating the release of inflammatory cytokines. Furthermore, the expression and activity of antioxidant enzymes are usually inhibited by ROS overload, and thus, the liver's antioxidant capacity undergoes a declining trend. Finally, NAFLD occurs as a result of OS and chronic inflammation. Researchers should try to reduce OS to improve NAFLD disease [142] . Approximately 25% of adults worldwide are affected by this disease. This trend is increasing, and the number of these patients increases every year. According to a metaanalysis study, the global prevalence of NAFLD has risen to 25.2% in the last 20 years and has caused concern among the public [143] . On the other hand, no effective treatment for this disease has been achieved despite significant medical advances. Currently, the only treatment approach is lifestyle changes (diet and exercise) and bariatric surgery [144] . Because there are substantial differences between different communities in terms of lifestyle and diet, various studies have shown that the prevalence of NAFLD in Eastern societies is lower than in Western societies [145] . At the systemic level, there is impaired control of food intake resulting in hyperalimentation, intestinal dysbiosis leading to gastrointestinal hormone secretion, IR, gut dysfunction, abnormal adipokine, and activation of pro-inflammatory factors [146] . One of the effective strategies in the prevention and treatment of NAFLD is nuclear factor erythroid-derived 2-like 2 (Nrf2), which as a transcription factor consists of a highly protected basic region-leucine zipper (bZIP) structure and is mainly a member of the Cap "n" Collar (CNC) family. Activation of cellular antioxidant enzymes, regulation of lipid metabolism, and insulin sensitivity improvement are the essential cytoprotective effects of Nrf2. Hence, many researchers have tried to identify Nrf2 activators to improve NAFLD [147] . The Kelch-like-ECH-associated protein 1 (Keap1)-Nrf2-antioxidative response element (ARE) signaling pathway has been considered an essential antioxidant mechanism due to its effect on improving the oxidative stress response [148] . The Nrf2 gene includes six highly protected epichlorohydrin (EHC) domains (Nrf2-EHC homology, Neh) called Neh1-6. The C-terminus Neh1 subtends a protected bZIP DNA region that binds to musculoaponeurotic fibrosarcoma protein (Maf) to create a heterodimer. This heterodimer eventually binds to DNA and can detect ARE. On the other hand, Neh2 is composed of two vital regions, ETGE and DLG, which, by binding to KEAP1, can contribute to the strong binding of Nrf2 to the cytoplasm [129] . C-terminus is the site of another Nrf2 domain, Neh3, which participates in the transcriptional activity of ARE after binding with chromo-ATPase/helicase DNA-binding protein (CHD6). The other two Nrf2 domains, Neh4 and Neh5, initiate the transcription process when interacting with the cyclic adenosine monophosphate response element (CREB)-binding protein (CBP) [149] . Finally, the last Nrf2 domain, Neh6, and being rich in serine are used to Nrf2 decompose independent of KEAP1 [150] . The expression of Nrf2 in homeostatic conditions and combination with KEAP1 in the cytoplasm is considered a mediator for the degradation and ubiquitinoylation of Nrf2. However, when exposed to oxidative or electrophilic stress, KEAP1 modulates cysteine residues and ultimately releases Nrf2. On the other hand, the Nrf2 protein isolated from KEAP1 returns to the cell nucleus and is dimerized to bind to AREs, along with bZIP proteins such as Maf [151] , and then promotes the expression of ARE-mediated downstream target genes containing antioxidant enzymes. The most critical antioxidant proteins targeting Nrf2 are HO-1, GSH, and NAD(P)H quinone oxidoreductase 1 (NQO1). It should also be noted that Nrf2 plays a pivotal role in suppressing the progression of NAFLD, maintaining cellular homeostasis, and protecting against oxidative or electrophilic stresses [152] . Nutraceuticals are not recognized traditionally as a nutrient but have physiological health benefits in the human body. Plant-derived nutraceuticals are well-known for their direct or indirect antioxidant activities, which relates to scavenging or eliminating free radicals during cellular metabolism. They can interact with the oxidized species at both cellular and molecular levels by regulating gene expression, epigenetic controls, and protein and DNA repair. Previously it was reported that nutraceuticals have potential properties in immunity modulation, gene expression, and various signaling process regulation [153] [154] [155] [156] [157] [158] . The nutraceuticals can be prepared from the foods available in the local market, for example, ginger, garlic, avocado, and onion, in the form of polyphenols, carotenoids, sulforaphane and other isothiocyanates, glucosinolate, phytosterol, etc. [159] . They can increase the level of heme oxygenase (HO) 1, total glutathione, and other phase 2 enzymes by activating the transcription Nrf2. Moreover, treatment for a certain period with nutraceuticals may also improve the lipid profile and can reverse the harmful effects of obesity on blood lipids [160] . For example, curcumin is a potential nutraceutical, reduces macrophage infiltration in WAT, increase adiponectin in AT, decreases NF-κB activity, therefore reduces the expression of inflammatory markers and OS [161] . To date, the use of nutraceuticals, bioactive compounds or exercise could be an additional strategy in reducing obesity and related diseases [162, 163] . OS affects various tissues, such as adipose tissue, skeletal muscle, and heart, in the body. In this study, we specifically examined adipose tissue response to OS. As mentioned in the text, this tissue is disrupted by various factors such as overconsumption of nutrients and sedentary lifestyle. This disorder eventually leads to lipid accumulation in adipose tissue and reduced energy expenditure. Of course, various treatments have been introduced for this disorder. However, most of them face limitations that are fully explained in the text. On the other hand, numerous studies have proven the effectiveness of diet, especially the use of antioxidant supplements, on the improvement of obesity caused by OS. The results of this treatment are inconsistent but have fewer side effects than other treatments such as medication and surgery. Further studies are needed because the results of the studies are contradictory. In future studies, researchers will investigate the effect of taking antioxidant supplements on heart and skeletal muscle tissues. Author Contributions: S.T. conceived the review and drafted the manuscript. K.S. and R.T.R. made some additions to the text, revised the manuscript and approved the final version. All authors have read and agreed to the published version of the manuscript. The publication was supported by the Scientific Research (A) (20H00574) from the Ministry of Education, Culture, Sports, Science, and Technology of Japan. Best practices in the management of overweight and obesity Metabolic inflammation in obesity-At the crossroads between fatty acid and cholesterol metabolism The metabolic phenotype in obesity: Fat mass, body fat distribution, and adipose tissue function Brown adipose tissue transplantation as a novel alternative to obesity treatment: A systematic review Inflammation, oxidative stress, and obesity Obesity, oxidative stress, adipose tissue dysfunction, and the associated health risks: Causes and therapeutic strategies Properties and functions of adipose tissue macrophages in obesity Relations between antioxidant vitamins in adipose tissue, plasma, and diet Anti-obesity effects of polyphenol intake: Current status and future possibilities Reactive oxygen species-Sources, functions, oxidative damage Oxidative Stress Mechanisms and Their Modulation Chemical and molecular mechanisms of antioxidants: Experimental approaches and model systems Anaerobic exercise and oxidative stress: A review Antioxidant and antiobesity activities of seed extract from campbell early grape as a functional ingredient Procyanidins from grape pomace are suitable inhibitors of human endothelial NADPH oxidase Mitochondrial oxidative stress in obesity: Role of the mineralocorticoid receptor The two faces of reactive oxygen species (ROS) in adipocyte function and dysfunction The role of oxidative stress in physiopathology and pharmacological treatment with pro-and antioxidant properties in chronic diseases A short overview of changes in inflammatory cytokines and oxidative stress in response to physical activity and antioxidant supplementation Formulation and evaluation on human skin of a water-in-oil emulsion containing Muscat hamburg black grape seed extract Oxidative stress and metabolic pathologies: From an adipocentric point of view Grape seed proanthocyanidin extract improves the hepatic glutathione metabolism in obese Zucker rats A review of the mechanisms and effectiveness of dietary polyphenols in reducing oxidative stress and thrombotic risk Proanthocyanidin-rich grape seed extract reduces leg swelling in healthy women during prolonged sitting Grape seed extract Vitis vinifera protects against radiation-induced oxidative damage and metabolic disorders in rats Free radicals and antioxidants in normal physiological functions and human disease Effects of exercise on markers of oxidative stress: An ancillary analysis of the Alberta physical activity and breast cancer prevention trial Blockade of Angiotensin II type-1 receptor reduces oxidative stress in adipose tissue and ameliorates adipocytokine dysregulation Rice bran enzymatic extract-supplemented diets modulate adipose tissue inflammation markers in Zucker rats Vitamin E reduces adipose tissue fibrosis, inflammation, and oxidative stress and improves metabolic profile in obesity Oxidative stress Regulation of metabolic processes by hydrogen peroxide generated by NADPH oxidases Exercise training attenuates the dysregulated expression of adipokines and oxidative stress in white adipose tissue The role of NADPH oxidases in the etiology of obesity and metabolic syndrome: Contribution of individual isoforms and cell biology Poldip2 takes a central role in metabolic reprograming Assays of RGS3 activation and modulation Relating form and function of EF-hand calcium binding proteins The pathobiology of diabetic complications: A unifying mechanism Increased oxidative stress in obesity: Implications for metabolic syndrome, diabetes, hypertension, dyslipidemia, atherosclerosis, and cancer Effects of exercise, vitamin E, and ozone on pulmonary function and lipid peroxidation Acute exercise and oxidative stress: A 30 year history Measuring reactive species and oxidative damage in vivo and in cell culture: How should you do it and what do the results mean? 8-nitroguanine, a product of nitrative DNA damage caused by reactive nitrogen species: Formation, occurrence, and implications in inflammation and carcinogenesis Increased serum levels of advanced glycation endproducts predict total, cardiovascular and coronary mortality in women with type 2 diabetes: A population-based 18 year follow-up study Free radicals, antioxidants, and nutrition. Nutrition Redox potential of GSH/GSSG couple: Assay and biological significance Control of adipocyte differentiation Imaging of adipose tissue Adipose tissue extracellular matrix: Newly organized by adipocytes during differentiation Adipose tissue-specific PPARgamma deficiency increases resistance to oxidative stress Adipose tissue remodeling and obesity Physiological role of adipose tissue: White adipose tissue as an endocrine and secretory organ Adipose tissue remodeling: Its role in energy metabolism and metabolic disorders Adipose tissue as a source of hormones Adipose tissue as an endocrine organ Adipsin: A circulating serine protease homolog secreted by adipose tissue and sciatic nerve Regulation of adipsin expression by endoplasmic reticulum stress in adipocytes Adipsin is an adipokine that improves β cell function in diabetes Changes in integrin expression during adipocyte differentiation The endocrine function of adipose tissues in health and cardiometabolic disease Effect of physical training on the adipose tissue of diet-induced obesity mice: Interaction between reactive oxygen species and lipolysis Adipose tissue: Cell heterogeneity and functional diversity Adipose tissue remodeling in pathophysiology of obesity Brown and beige adipose tissue and aging Adipose tissue: Between the extremes The developmental origins of adipose tissue Anatomy and Physiology of Adipose Tissue Sestrin2 inhibits uncoupling protein 1 expression through suppressing reactive oxygen species Maintenance of metabolic homeostasis by Sestrin2 and Sestrin3 Sestrins activate Nrf2 by promoting p62-dependent autophagic degradation of Keap1 and prevent oxidative liver damage A role for brown adipose tissue in diet-induced thermogenesis Superoxide production by the mitochondrial respiratory chain Immune and inflammatory signaling pathways in exercise and obesity Browning of white fat: Agents and implications for beige adipose tissue to type 2 diabetes Release of interleukins and other inflammatory cytokines by human adipose tissue is enhanced in obesity and primarily due to the nonfat cells Relationship between adipocyte size and adipokine expression and secretion Leptin level and oxidative stress contribute to obesity-induced low testosterone in murine testicular tissue Influence of the periprostatic adipose tissue in obesity-associated mouse urethral dysfunction and oxidative stress: Effect of resveratrol treatment Dietary fiber and its effect on obesity: A review article Aging exacerbates obesity-induced oxidative stress and inflammation in perivascular adipose tissue in mice: A paracrine mechanism contributing to vascular redox dysregulation and inflammation How effective are antioxidant supplements in obesity and diabetes? Role of oxidative stress and antioxidants in daily nutrition and human health Extracellular matrix remodeling of adipose tissue in obesity and metabolic diseases Prevention of high-fat diet-induced muscular lipid accumulation in rats by alpha lipoic acid is not mediated by AMPK activation Inflammation and oxidative stress in adipose tissue: Nutritional regulation Biomarkers for Antioxidant Defense and Oxidative Damage: Principles and Practical Applications Double-blind, placebocontrolled, randomised phase II trial of IH636 grape seed proanthocyanidin extract (GSPE) in patients with radiation-induced breast induration Antioxidants 2021 Antioxidant enzymes and their role in phoxim and carbaryl stress in Caenorhabditis elegans Effects of palm vitamin e supplementation on exercise-induced oxidative stress and endurance performance in the heat Acute pre-/post-treatment with 8th day SOD-like supreme (a free radical scavenging health product) protects against oxidant-induced injury in cultured cardiomyocytes and hepatocytes in vitro as well as in mouse myocardium and liver in vivo Overexpressing the sedum alfredii Cu/Zn superoxide dismutase increased resistance to oxidative stress in transgenic arabidopsis Enzymatic mechanisms involved in evasion of fungi to the oxidative stress: Focus on scedosporium apiospermum Variability in superoxide dismutase isoforms in tall and dwarf cultivars of coconut Mass spectrometric quantification of F2-isoprostanes in biological fluids and tissues as measure of oxidant stress Superoxide dismutase 2 gene and cancer risk: Evidence from an updated meta-analysis Glutathione peroxidase family-An evolutionary overview The mechanism of catalase action. I. Steady-state analysis Mechanisms linking obesity to insulin resistance and type 2 diabetes Chronic inflammation as an immunological abnormality and effectiveness of exercise The impact of oxidative stress on adipose tissue energy balance Effect of butylated hydroxytoluene on alpha-tocopherol content in liver and adipose tissue of rats Dietary supplementation with chestnut (Castanea sativa) reduces abdominal adiposity in FVB/n mice: A preliminary study Effect of corn oil and vitamin E on the oxidative status of adipose tissues and liver in rat Quercetin can reduce insulin resistance without decreasing adipose tissue and skeletal muscle fat accumulation Antiobesity and hypolipidemic effects of protease A-digested crude-chalaza hydrolysates in a high-fat diet The influence of vitamin C supplementation on the oxidative status of rat interscapular brown adipose tissue The antiobesity effect of polygonum aviculare L. ethanol extract in high-fat diet-induced obese mice Leptin functions in infectious diseases Effect of increased BMI and obesity on the outcome of COVID-19 adult patients: A systematic review and meta-analysis Dysregulation of natural killer cells in obesity COVID-19 and obesity Physical activity and nutrition guidelines to help with the fight against COVID-19 Key aspects in nutritional management of COVID-19 patients Obesity and COVID-19: What makes obese host so vulnerable? Genetic polymorphisms complicate COVID-19 therapy: Pivotal role of HO-1 in cytokine storm Visceral fat is associated to the severity of COVID-19 Angiotensin-Converting enzyme 2: SARS-CoV-2 receptor and regulator of the Renin-Angiotensin System: Celebrating the 20th anniversary of the discovery of ACE2 The pivotal role of adipocyte-Na K peptide in reversing systemic inflammation in obesity and COVID-19 in the development of heart failure Metabolic healthy obesity, vitamin D status, and risk of COVID-19 Do body mass index (BMI) and history of nutritional supplementation play a role in the severity of COVID-19? A retrospective study Immune function and micronutrient requirements change over the life course Optimal nutritional status for a well-functioning immune system is an important factor to protect against viral infections Evidence that vitamin D supplementation could reduce risk of influenza and COVID-19 infections and deaths Association between regional selenium status and reported outcome of COVID-19 cases in China Mitochondrial oxidative injury: A key player in nonalcoholic fatty liver disease Role of MicroRNAs in the development of hepatocellular carcinoma in nonalcoholic fatty liver disease Role of oxidative stress in the pathogenesis of nonalcoholic steatohepatitis Chemical activators of the Nrf2 signaling pathway in nonalcoholic fatty liver disease Mutual interaction between endoplasmic reticulum and mitochondria in nonalcoholic fatty liver disease Exercise training suppresses scavenger receptor CD36 expression in kupffer cells of nonalcoholic steatohepatitis model mice Exercise training attenuates hepatic inflammation, fibrosis and macrophage infiltration during diet induced-obesity in mice Fat and sugar-A dangerous duet. A comparative review on metabolic remodeling in rodent models of nonalcoholic fatty liver disease Oxidative stress-related parameters in the liver of non-alcoholic fatty liver disease patients Non-alcoholic fatty liver disease as a cause and a consequence of metabolic syndrome The multiple-hit pathogenesis of non-alcoholic fatty liver disease (NAFLD) Nonalcoholic fatty liver disease: A challenge from mechanisms to therapy Dietary carbohydrates and fatty liver disease: De novo lipogenesis Konstantynowicz-Nowicka, K. Does the enterolactone (ENL) affect fatty acid transporters and lipid metabolism in liver? Plasma adiponectin is decreased in nonalcoholic fatty liver disease Adiponectin: Structure, physiological functions, role in diseases, and effects of nutrition Antioxidant mechanisms in nonalcoholic fatty liver disease From the metabolic syndrome to NAFLD or vice versa? Dig. Liver Dis Current and future therapeutic regimens for nonalcoholic fatty liver disease and nonalcoholic steatohepatitis Nonalcoholic fatty liver disease The role of tissue macrophage-mediated inflammation on NAFLD pathogenesis and its clinical implications The rise of antioxidant signaling-The evolution and hormetic actions of Nrf2 Molecular mechanisms activating the Nrf2-Keap1 pathway of antioxidant gene regulation Liver regeneration Redox-regulated turnover of Nrf2 is determined by at least two separate protein domains, the redox-sensitive Neh2 degron and the redox-insensitive Neh6 degron Physiological significance of reactive cysteine residues of Keap1 in determining Nrf2 activity Experimental nonalcoholic steatohepatitis and liver fibrosis are ameliorated by pharmacologic activation of Nrf2 (NF-E2 p45-related factor 2) Cancer chemoprevention with dietary phytochemicals Curcumin and its analogues: Potential anticancer agents Taheebo polyphenols attenuate free fatty acid-induced inflammation in murine and human macrophage cell lines as inhibitor of cyclooxygenase-2. Front Single dose administration of taheebo polyphenol enhances endurance capacity in mice Sulforaphane protects cells against lipopolysaccharide-stimulated inflammation in murine macrophages Protective effects of sulforaphane on exercise-induced organ damage via inducing antioxidant defense responses Nutraceuticals: Facts and fiction Ginger and avocado as nutraceuticals for obesity and its comorbidities Nutraceuticals in pathogenic obesity; striking the right balance between energy imbalance and inflammation Characterization and Modulation of Systemic Inflammatory Response to Exhaustive Exercise in Relation to Oxidative Stress We gratefully appreciate our colleagues and laboratory team for research progress and discussion. The authors declare no conflict of interest.Antioxidants 2021, 10, 594