Contents
Resveratrol (3,4',5-trihydroxystilbene) belongs to a class of polyphenolic compounds called stilbenes (1). Certain plants produce resveratrol and other stilbenoids in response to stress, injury, fungal infection, or ultraviolet (UV) radiation (2). Resveratrol is a fat-soluble compound that occurs in both trans and cis molecular configurations (Figure 1). Both cis- and trans-resveratrol also occur as glucosides, i.e., bound to a glucose molecule. One major resveratrol derivative is resveratrol-3-O-β-glucoside, also called piceid (Figure 1) (3).
Since the early 1990s, when the presence of resveratrol in red wine was established (4), the scientific community has been exploring the effects of resveratrol on health. Specifically, it was postulated that resveratrol intake via moderate red wine consumption might help explain the fact that French people have a relatively low incidence of coronary heart disease (CHD) in spite of consuming foods high in saturated fat, a phenomenon dubbed the “French Paradox” (see Cardiovascular disease) (5). Since then, reports on the potential for resveratrol to prevent cancer, delay the development of cardiovascular and neurodegenerative diseases, improve glycemic control in type 2 diabetes, and extend lifespan in experimental models have continued to generate scientific interest (see Disease Prevention).
Initial studies of the pharmacokinetics of trans-resveratrol in humans found only traces of the unmetabolized resveratrol in the plasma upon oral exposure of single trans-resveratrol doses of 5 to 25 mg. Indeed, trans-resveratrol appears to be well absorbed by humans when taken orally, but its bioavailability is relatively low due to its rapid metabolism and elimination (6). Once absorbed, resveratrol is rapidly metabolized by conjugation to glucuronic acid and/or sulfate, forming resveratrol glucuronides, sulfates, and/or sulfoglucuronides. Sulfate conjugates are the major forms of resveratrol metabolites found in plasma and urine in humans (7).
Preliminary studies found that the administration of single oral doses of 25 mg of trans-resveratrol to healthy volunteers resulted in peak blood concentrations of total resveratrol (i.e., trans-resveratrol plus its metabolites) around 60 minutes later, at about 1.8-2 μmoles/liter (μM), depending on whether resveratrol was administered in wine, vegetable juice, or grape juice (8, 9). A study in 40 healthy subjects who received single ascending doses of oral trans-resveratrol (i.e., 0.5 g, 1 g, 2.5 g, and 5 g) showed that plasma concentrations of unmetabolized resveratrol peaked between 0.8 and 1.5 hours after resveratrol administration at levels ranging from 0.3 μM to 2.3 μM (10). Of note, these values were markedly below those used to elicit chemopreventive effects of resveratrol in in vitro experiments (>5 μM). In contrast, following a single oral dose of 5 g of trans-resveratrol, the peak plasma concentrations of certain resveratrol conjugates were found to be about two to eight times higher than those of unmetabolized resveratrol (10). Also, compared to a single dose administration, the repeated intake of 5 g/day of trans-resveratrol for 29 days was found to result in significantly greater peak plasma concentrations of trans-resveratrol and two resveratrol glucuronide conjugates (11). Repeated doses of 1 g/day of trans-resveratrol (a dose less likely to cause side effects; see Safety) could yield maximum plasma concentrations of about 22 μM for resveratrol-3-O-sulfate (the most abundant sulfate conjugate in humans) and about 7-8 μM for typical monoglucuronide conjugates (12).
A few studies have examined the influence of food matrix on resveratrol absorption and/or bioavailability (reviewed in 13). One study has reported that bioavailability of trans-resveratrol from red wine did not differ when the wine was consumed with a meal (low- or high-fat) versus on an empty stomach (14). Yet, in another study, the absorption of supplemental resveratrol was found to be delayed, but not reduced, by the presence of food in the stomach (15). A third study found that the bioavailability of supplemental resveratrol was reduced by the amount of fat in the diet, but not by the co-administration of quercetin (another polyphenol) or alcohol (16).
Information about the bioavailability of resveratrol in humans is important because most of the experimental research conducted to date has been ‘preclinical,’ i.e., in vitro, exposing cells to resveratrol concentrations up to 100 times greater than peak plasma concentrations observed in humans, and in animal models given very high (non dietary) doses of resveratrol (13). While cells that line the digestive tract are exposed to unmetabolized resveratrol, other tissues are likely exposed to resveratrol metabolites. At present, little is known about the biological activity of resveratrol metabolites. Yet, if some tissues are capable of converting resveratrol metabolites back to resveratrol, stable resveratrol conjugates in tissues could serve as a pool in the body from which resveratrol might be regenerated (6, 12).
The biological significance of resveratrol has been primarily investigated in test tubes and cultured cells, and to a lesser extent, in animal models. Of note, a recent publication by Tomé-Carneiro et al. (13) thoroughly reviewed the most relevant preclinical studies published in the most recent decades. It is important to keep in mind that many of the biological activities discussed below were observed in cells cultured in the presence of resveratrol at higher concentrations than those likely to be achieved in humans consuming resveratrol orally (see Metabolism and Bioavailability).
In the test tube, resveratrol effectively scavenges (neutralizes) free radicals and other oxidants (17, 18) and inhibits low-density lipoprotein (LDL) oxidation (19, 20). Resveratrol was found to induce antioxidant enzymes, including superoxide dismutase (SOD), thioredoxin, glutathione peroxidase-1, heme oxygenase-1, and catalase, and/or inhibit reactive oxygen species (ROS) production by nicotinamide adenine dinucleotide phosphate (NADPH) oxidases (NOX) (21). However, there is little evidence that resveratrol is an important antioxidant in vivo. Upon oral consumption of resveratrol, circulating and intracellular levels of resveratrol in humans are likely to be much lower than that of other important antioxidants, such as vitamin C, uric acid, vitamin E, and glutathione. Moreover, the antioxidant activity of resveratrol metabolites, which comprise most of the circulating resveratrol, may be lower than that of resveratrol (22).
Endogenous estrogens are steroid hormones synthesized by humans and other mammals; these hormones bind to estrogen receptors within cells. The estrogen-receptor complex interacts with unique sequences in DNA (estrogen response elements; EREs) to modulate the expression of estrogen-responsive genes (23). The chemical structure of resveratrol is very similar to that of the synthetic estrogen agonist, diethylstilbestrol (Figure 2), suggesting that resveratrol might also function as an estrogen agonist, i.e., might bind to estrogen receptors and elicit similar responses to endogenous estrogens. However, in cell culture experiments, resveratrol was found to act either as an estrogen agonist or as an estrogen antagonist depending on such factors as cell type, estrogen receptor isoform (ERα or ERβ), and the presence of endogenous estrogens (23). Most recently, resveratrol was shown to improve endothelial wound healing through an ERα-dependent pathway in an animal model of arterial injury (24).
Some compounds are not carcinogenic until they have been metabolized in the body by phase I biotransformation enzymes, especially cytochrome P450 enzymes (2). By inhibiting the expression and activity of certain cytochrome P450 enzymes (25, 26), resveratrol might help prevent cancer by limiting the activation of procarcinogens. In contrast, increasing the activity of phase II detoxification enzymes generally promotes the excretion of potentially toxic or carcinogenic chemicals. Resveratrol has been found to increase the expression and activity of NAD(P)H:quinone oxidoreductase-1 (NQO1) in cultured cells (27) and may be a weak inducer of other phase II enzymes (28).
Following DNA damage, the cell cycle can be transiently arrested to allow for DNA repair or activation of pathways leading to cell death (apoptosis) if the damage is irreparable (29). Defective cell cycle regulation may result in the propagation of mutations that contribute to the development of cancer. Moreover, unlike normal cells, cancer cells proliferate rapidly and are unable to respond to cell death signals that initiate apoptosis. Resveratrol has been found to induce cell cycle arrest and/or apoptosis (programmed cell death) in a number of cancer cell lines (reviewed in 13).
Cancerous cells invade normal tissue aided by enzymes called matrix metalloproteinases. Resveratrol has been found to inhibit the activity of at least one type of matrix metalloproteinase (30, 31). To fuel their rapid growth, invasive tumors must also develop new blood vessels by a process known as angiogenesis. Resveratrol has been found to inhibit angiogenesis in vitro (32-34) and in vivo (35).
Inflammation promotes cellular proliferation and angiogenesis and inhibits apoptosis (36). Resveratrol has been found to inhibit the activity of several inflammatory enzymes in vitro, including cyclooxygenases and lipoxygenases (37, 38). Resveratrol may also inhibit pro-inflammatory transcription factors, such as NFκB or AP-1 (39, 40).
Atherosclerosis is an inflammatory process in which lipids deposit in plaques (known as atheromas) within arterial walls and increase the risk of myocardial infarction (41). One of the earliest events in the development of atherosclerosis is the recruitment of inflammatory white blood cells from the blood to the arterial wall by vascular cell adhesion molecules (42). Resveratrol has been found to inhibit the expression of adhesion molecules in cultured endothelial cells (43, 44).
The proliferation of vascular smooth muscle cells (VSMCs) plays an important role in the progression of hypertension, atherosclerosis, and restenosis (when treated arteries become blocked again). Resveratrol has been found to inhibit the proliferation of VSMCs in culture (45-47), as well as in vivo (48). Resveratrol appeared to reduce VSMC proliferation via an ERα-dependent mechanism, hence preventing the narrowing of vessels in a mouse model of arterial injury (48).
Endothelial nitric oxide synthase (eNOS) is an enzyme that catalyzes the formation of nitric oxide (NO) by vascular endothelial cells. NO is needed to maintain arterial relaxation (vasodilation), and impaired NO-dependent vasodilation is associated with an increased risk of cardiovascular disease (49). Because physiological concentrations of resveratrol were found to stimulate eNOS activity in cultured endothelial cells (50-52), resveratrol might help maintain or improve endothelial function in vivo (see Cardiovascular disease).
Platelet aggregation is one of the first steps in the formation of a blood clot that can occlude a coronary or cerebral artery, resulting in myocardial infarction or stroke, respectively. Resveratrol has been found to inhibit platelet activation and aggregation in vitro (53-55).
Age-related mood alterations and memory deficits result from a decrease in the function of the hippocampus in the elderly. Resveratrol was shown to stimulate neurogenesis and blood vessel formation in the hippocampus of healthy old rats. These structural changes were associated with significant improvements in spatial learning, memory formation, and mood function (56).
One feature of Alzheimer’s disease (AD) is the accumulation of β-amyloid peptide into senile (amyloid) plaques outside neurons in the hippocampus and cortex of AD patients (57). Senile plaques are toxic to cells, resulting in progressive neuronal dysfunction and death. Resveratrol was found to facilitate the clearance of β-amyloid peptide and promote cell survival in primary neurons in culture and neuronal cell lines (58-60). Resveratrol also reduced senile plaque counts in various brain regions of a transgenic AD mouse model (61).
Abnormally activated microglia and hypertrophic astrocytes around the senile plaques in AD brains release cytotoxic molecules, such as proinflammatory mediators and ROS, which enhance the formation and deposition of β-amyloid peptides and further damage neurons (57). Resveratrol was found able to inhibit the inflammatory response triggered by β-amyloid peptide-induced microglial activation in microglial cell lines and in a mouse model of cerebral amyloid deposition (62). A decreased occurrence of microglial activation and astrocyte hypertrophy was also reported in healthy aged rats treated with resveratrol (56).
Mitochondrial dysfunction and oxidative stress are thought to be involved in the etiology and/or progression of several neurodegenerative disorders (63). Resveratrol counteracted oxidative stress and β-amyloid peptide-induced toxicity in cultured neuroblastoma (64). Resistance against oxidative stress-related damage in primary neuronal cells treated with resveratrol has been associated with the induction of heme oxygenase-1 (HO-1), an enzyme that degrades pro-oxidant heme (65). In an experimental model of stroke, resveratrol limited infarct size during ischemia-reperfusion in wild-type mice but not in mice lacking the HO-1 gene (66). Also, resveratrol was able to correct experimentally induced oxidative stress and the associated cognitive dysfunction in rats (67).
Resveratrol has been found to inhibit the proliferation of a variety of human cancer cell lines, including those from breast, prostate, stomach, colon, pancreatic, and thyroid cancers (2). In animal models, oral administration, topical application, and/or injection of resveratrol inhibited the development of chemically-induced cancer at many sites, including gastrointestinal tract, liver, skin, breast, prostate, and lung (reviewed in 68, 69). The anti-cancer effects of resveratrol in rodent models involved the reduction of cell proliferation, the induction of apoptosis, and the inhibition of angiogenesis, tumor growth, and metastasis (reviewed in 13). Yet, a few animal studies have reported a lack of an effect of oral resveratrol in inhibiting the development of lung cancer induced by carcinogens in cigarette smoke (70, 71), and the study of resveratrol administration on colon cancer has given mixed results (72-74).
At present, it is not known whether resveratrol might be beneficial in the prevention and/or the treatment of cancer in humans. The low bioavailability of resveratrol reported in human studies limits the clinical evaluation of possible systemic health effects of resveratrol in humans (see Metabolism and Bioavailability). Yet, in a pilot study, unmetabolized resveratrol and conjugates have been detected in colorectal tumor tissues from 20 cancer patients following daily oral supplementation with either 4 g or 8 g of resveratrol for 29 days. Resveratrol appeared to be well tolerated and significantly, though modestly, reduced cell proliferation compared to baseline (75). A micronized formulation of resveratrol (named SRT501), which was meant to increase resveratrol delivery to target tissues, was given for 14 days to 6 patients with colorectal cancer and liver metastasis in a small randomized, double-blind, placebo-controlled trial (76). Unmetabolized resveratrol was measurable in the liver of five out of six patients who consumed 5 g of SRT501, and SRT501 administration resulted in an increased detection of the apoptotic marker, cleaved caspase-3, in hepatic tumor tissues. Yet, in an unrandomized and unblinded trial in patients with multiple myeloma, the administration of SRT501 was associated with a number of serious adverse effects, including kidney failure, such that the trial was halted (77). Since kidney failure is a frequent complication in myeloma patients, it is unclear whether kidney failure cases should be solely attributed to the use of SRT501. Nevertheless, there is a need to find safe ways to increase resveratrol bioavailability in humans before exploring its putative benefits in clinical settings (6, 78).
Significant reductions in cardiovascular disease risk have been associated with moderate consumption of alcoholic beverages (79). The “French Paradox” — the observation that incidence of coronary heart disease was relatively low in France despite high levels of dietary saturated fat and cigarette smoking — led to the idea that regular consumption of red wine might provide additional protection from cardiovascular disease (80). Red wine contains variable and usually low concentrations of resveratrol (see Sources) and higher concentrations of flavonoids like procyanidins. These polyphenolic compounds have displayed antioxidant, anti-inflammatory, and other potentially anti-atherogenic effects in the test tube and in some animal models of atherosclerosis (81). The results of epidemiological studies addressing this question have been inconsistent. While some large prospective cohort studies found that wine drinkers were at lower risk of cardiovascular disease than beer or liquor drinkers (82-84), others found no difference (85-87). Socioeconomic and lifestyle differences between people who prefer wine and those who prefer beer or liquor may explain part of the additional benefit observed in some studies: people who prefer wine tend to have higher incomes, more education, smoke less, and eat more fruit and vegetables and less saturated fat than those who prefer other alcoholic beverages (87-92).
Although moderate alcohol consumption has been consistently associated with reductions in coronary heart disease risk, it is not yet clear whether red wine polyphenols confer any additional risk reduction. Interestingly, studies that administered alcohol-free red wine to rodents noted improvements in various parameters related to cardiovascular disease (93, 94), and a placebo-controlled human study found that heart disease patients administered red grape polyphenol extract experienced acute improvements in endothelial function (95). Whether increased consumption of polyphenols from red wine provides any additional cardiovascular benefits beyond those associated with red wine’s alcohol content needs to be further examined (see the article on Alcoholic Beverages) (96).
Endothelial dysfunction is usually associated with the presence of cardiovascular risk factors (e.g., insulin resistance, hypertension, and hypercholesterolemia) and is thought to precede the clinical manifestation of cardiovascular and metabolic disorders. Endothelial dysfunction is characterized by abnormal vasoconstriction, leukocyte adherence to vascular endothelial cells, platelet activation and aggregation, smooth muscle cell proliferation, vascular inflammation, thrombosis (clot formation), impaired coagulation, and atherosclerosis (97).
Experimental studies: Resveratrol has been found to exert a number of protective effects on the cardiovascular system in vitro, including inhibition of both platelet activation and aggregation (53, 98, 99), promotion of vasodilation by enhancing the production of nitric oxide (NO) (52), and control of the production of inflammatory lipid mediators (38, 100, 101). However, the concentrations of resveratrol required to produce these effects are often higher than those measured in human plasma after oral consumption of resveratrol (9). Some animal studies also suggested that high oral doses of resveratrol could decrease the risk of thrombosis and atherosclerosis (102, 103), although one study found increased atherosclerosis in animals fed resveratrol (104). Other protective effects of resveratrol in vivo include the reduction of cardiac hypertrophy and the lowering of blood pressure in various models, as well as the limitation of infarct size in post myocardial infarction rats (reviewed in 13).
Randomized controlled studies: In a six-month, cross-over study, 34 patients with metabolic syndrome were randomized to receive resveratrol (100 mg/day) for three months either immediately at the beginning of the study or three months later. Resveratrol supplementation resulted in improved values of flow-mediated dilation (FMD) of the brachial artery, a surrogate marker of vascular health. Yet, FMD returned to baseline values within three months after discontinuing resveratrol (105). One study limitation was that the resveratrol formulation contained additional compounds (i.e., vitamin D3, quercetin, and rice bran phytate), which may also affect endothelial function. One randomized, placebo-controlled study in healthy overweight or obese volunteers (BMI, 25-34 kg/m2) found that a single dose of trans-resveratrol (30 mg, 90 mg, or 270 mg) improved brachial FMD around 60 minutes after administration (106). In a second study, the same investigators found that FMD improvements were similar whether participants had received a single dose of resveratrol (75 mg) or a daily dose (75 mg/day of resveratrol) for six months (107).
In a few additional studies, resveratrol was shown to improve endothelial function by reducing vascular inflammation and endothelial activation. A randomized, double-blind, placebo-controlled study in 41 healthy subjects found that daily supplementation with resveratrol (400 mg), grapeseed extract (400 mg), and quercetin (100 mg), for one month significantly reduced the expression of interleukin-8 (IL-8) and cell adhesion molecules (ICAM-1 and VCAM-1) in endothelial cells, suggestive of a protective effect against endothelial dysfunction (108). The daily intake of a resveratrol-rich grape supplement was compared to resveratrol-free grape supplement in a year-long, randomized, double blind, placebo-controlled study in 75 individuals at high risk for cardiovascular disease (CVD). Administration of the resveratrol-rich supplement (resveratrol: 8 mg/day for 6 months, then 16 mg/day for another 6 months) significantly improved the profile of circulating inflammatory markers, reducing levels of C-reactive protein (CRP) and Tumor Necrosis Factor-α (TNF-α), as well as the level of thrombogenic factor, Plasminogen Activator Inhibitor-1 (PAI-1) (109). The decreased concentrations of two CVD risk markers, oxidized low-density lipoprotein (oxLDL) and apolipoprotein B (ApoB) after six months further suggested a cardioprotective effect of resveratrol (110). Supplementation of patients with stable coronary heart disease with the same regimen also improved the profile of circulating inflammatory markers and reduced the expression of proinflammatory genes in peripheral blood mononuclear cells (PBMCs) (111). The expression of microRNAs and cytokines specifically involved in atherogenic and pro-inflammatory signals were also found to be downregulated in the PBMCs of supplemented patients (112). Finally, although it is not clear whether hypertension is a cause or an effect of endothelial dysfunction, a recent meta-analysis of randomized controlled trials suggested that high doses of resveratrol (≥150 mg/for at least one month) might help lower systolic blood pressure in individuals at risk for CVD (113).
While preliminary human studies suggest that resveratrol may have beneficial effects on cardiovascular health, there is currently no convincing evidence that these effects can be achieved in the amounts present in one to two glasses of red wine (see Sources). For more information regarding resveratrol and cardiovascular disease, see (114).
Caloric restriction is known to extend the lifespan of a number of species, including yeast, worms, flies, fish, rats, and mice (115). In yeast (Saccharomyces cerevisiae), caloric restriction stimulates the activity of an enzyme known as Silent information regulator 2 protein (Sir2) or sirtuin (116). Yeast Sir2 is a nicotinamide adenine dinucleotide (NAD)-dependent deacetylase enzyme that removes the acetyl group from acetylated lysine residues in target proteins (see the article on Niacin).
Providing resveratrol to yeast increased Sir2 activity in the absence of caloric restriction and extended the replicative (but not the chronological) lifespan of yeast by 70% (117). Resveratrol feeding also extended the lifespan of worms (Caenorhabditis elegans) and fruit flies (Drosophila melanogaster) by a similar mechanism (118). Additionally, resveratrol dose-dependently increased the lifespan of a vertebrate fish (Nothobranchius furzeri) (119). Resveratrol was also found to extend the lifespan of mice on a high-calorie diet such that their lifespan was similar to that of mice fed a standard diet (120). Although resveratrol increased the activity of the Sir2 homologous human sirtuin 1 (SIRT1) in the test tube (117), there are no epidemiological data to link resveratrol, SIRT1 activation, and extended human lifespan. Moreover, the supraphysiological concentrations of resveratrol required to increase human SIRT1 activity were considerably higher than concentrations that have been measured in human plasma after oral consumption.
The results of a nine-year prospective cohort study in over 700 older adults (≥65 years) indicated that participants who were alive at the end of the study had baseline concentrations of total urinary resveratrol metabolites (used as a biomarker of resveratrol intake) similar to those who died during the study period (121). Based on a lack of correlation with baseline inflammatory markers, cardiovascular disease and cancer incidence, and all-cause mortality, the authors concluded that higher versus lower quartiles of urinary resveratrol metabolite concentrations did not predict risk of chronic disease or mortality. However, key experts identified several limitations regarding the quality of the research (122, 123). Specifically, the use of single measures of total urinary resveratrol metabolites at baseline has been highlighted as being unlikely to reflect lifetime consumption of wine or exposure to dietary resveratrol (122).
In a mouse model of Alzheimer’s disease (AD), caloric restriction has been shown to limit the production and deposition of neurotoxic β-amyloid peptide in the brain (124). Similar to the effect of caloric restriction, resveratrol was found to improve obesity and diabetes-related metabolic deregulations via the activation of metabolic sensors, including SIRT and the AMP-activated protein kinase (AMPK) (125), as well as to promote the AMPK-dependent clearance of β-amyloid peptide in the brain of an AD mouse model (60). Resveratrol has also exhibited additional neuroprotective properties in cultured cells and animal models (see Biological Activities).
Although resveratrol bioavailability to the brain is uncertain (78), a randomized, double-blind, placebo-controlled study has reported an increase in cerebral blood flow in the prefrontal cortex of healthy young subjects (ages, 18-29 years) following a single oral dose of 500 mg of resveratrol. However, resveratrol intake did not improve performance in cognitively demanding tasks undertaken during the post-administration period (126). More recently, the co-administration of resveratrol (200 mg/day) and quercetin (320 mg/day) for 26 weeks in a double-blind, placebo-controlled study significantly improved measures of memory function and enhanced blood glucose control in 46 healthy, overweight older adults (ages, 50-80 years; BMI, 25-30 kg/m2) (127). Additional evidence of the potential of resveratrol to mimic the metabolic benefits of caloric restriction on cognitive health may come from ongoing clinical trials in both healthy older individuals and AD patients (128).
More than one out of three American adults has impaired glucose tolerance (also known as prediabetes), which places them at increased risk of developing type 2 diabetes (129). Impaired glucose tolerance is associated with insulin resistance in skeletal muscle — the major peripheral tissue for insulin-mediated glucose uptake — as well as defective insulin secretion by pancreatic β-cells. Muscle insulin resistance, which is thought to be the earliest stage in the development of type 2 diabetes, is characterized by excess lipid exposure, impaired insulin receptor signaling, impaired glucose uptake, mitochondrial dysfunction, reduced fatty acid oxidation, and increased expression of pro-inflammatory cytokines.
In animal studies, resveratrol has been shown to improve insulin sensitivity, glucose tolerance, and lipid profiles in obese and/or metabolically abnormal animals (reviewed in 130).
In humans, short-term supplementation with resveratrol has been associated with beneficial effects on glucose and lipid metabolism in individuals with type 2 diabetes. In a randomized, double-blind, placebo-controlled study, the effect of oral resveratrol supplementation (1,000 mg/day for 45 days) on the control of glucose metabolism was assessed in 70 subjects with type 2 diabetes (131). Comparison of changes between baseline and end-of-study measures between placebo and intervention groups showed that resveratrol significantly lowered both fasting glucose and fasting insulin concentrations and improved measures of glycemic control (HbA1c level) and insulin sensitivity (HOMA-IR). In addition, the level of HDL-cholesterol was increased while the level of LDL-cholesterol and systolic blood pressure were significantly reduced. No changes were found in measures of diastolic blood pressure, total cholesterol, triglycerides, and markers of liver function (131). Additionally, in a randomized, open-label, and controlled study, the effect of oral resveratrol (250 mg/day) on glycemic control and lipid metabolism was assessed in 62 type 2 diabetics (132). During the three-month study period, changes in biochemical and clinical parameters, including fasting glucose concentration, HbA1c level, systolic and diastolic blood pressure, total cholesterol, and LDL-cholesterol, were significantly improved with resveratrol compared to control (i.e., no resveratrol). Doses as low as 10 mg/day of resveratrol also resulted in lower insulin resistance in a four-week, randomized, placebo-controlled study in 19 male subjects with type 2 diabetes (133).
Obesity (defined as a body mass index [BMI] ≥ 30 kg/m2) is a well-known risk factor for the development of type 2 diabetes. A few clinical studies have evaluated the effects of resveratrol on key metabolic variables in overweight or obese subjects with no overt metabolic dysfunction and found little or no metabolic benefits following resveratrol treatment (134-136). Yet, at present, there is no available evidence to suggest whether overweight or obese individuals with impaired glucose tolerance could benefit from resveratrol supplements and reduce their risk of developing type 2 diabetes (137).
Current data suggest that resveratrol could improve specific metabolic variables in individuals with type 2 diabetes (138, 139), but more research is needed to assess its effect in individuals at risk for diabetes, including obese subjects with impaired glucose tolerance.
Resveratrol is found in grapes, wine, grape juice, peanuts, cocoa, and berries of Vaccinium species, including blueberries, bilberries, and cranberries (140-143). In grapes, resveratrol is found only in the skins (144). The amount of resveratrol in grape skins varies with the grape cultivar, its geographic origin, and exposure to fungal infection (145). The amount of fermentation time a wine spends in contact with grape skins is also an important determinant of its resveratrol content. Because grape skins are removed early during the production process of white and rosé wines, these wines generally contain less resveratrol than red wines (4). Therefore, because of variations between types of wine, vintages, and regions, it is very difficult to provide accurate estimates of resveratrol content in the thousands of wines from worldwide wineries. Yet, it appears that resveratrol content in wine is usually low, highly variable and unpredictable, and resveratrol is only a minor compound in the complete set of grape and wine polyphenols (13).
The predominant form of resveratrol in grapes and grape juice is trans-resveratrol-3-O-β-glucoside (trans-piceid), and wines contain significant amounts of resveratrol aglycones, thought to be the result of sugar cleavage during fermentation (3, 140). Many wines also contain significant amounts of cis-resveratrol (see Figure 1 above), which may be produced during fermentation or released from viniferins (resveratrol polymers) (146). Red wine is a relatively rich source of resveratrol, but other polyphenols are present in red wine at considerably higher concentrations than resveratrol (see the article on Flavonoids) (147). Estimates of resveratrol content of some beverages and foods are listed in Table 1 and Table 2. These values should be considered approximate since the resveratrol content of foods and beverages can vary considerably.
Variety | Lowest (mg/L) | Highest (mg/L) | Mean (mg/L) | 5-oz Glass (mg) |
---|---|---|---|---|
Pinot Noir | 0.2 | 11.9 | 3.6 ± 2.9 | 0.5 |
Merlot | 0.3 | 14.3 | 2.8 ± 2.6 | 0.4 |
Zweigelt | 0.6 | 4.7 | 1.9 ± 1.2 | 0.3 |
Shiraz | 0.2 | 3.2 | 1.8 ± 0.9 | 0.3 |
Cabernet Sauvignon | - | 9.3 | 1.7 ± 1.7 | 0.2 |
Red wines (global) | - | 14.3 | 1.9 ± 1.7 | 0.3 |
Food | Serving | Total Resveratrol (mg) |
---|---|---|
Peanuts (raw) | 1 cup (146 g) | 0.01-0.26 |
Peanuts (boiled) | 1 cup (180 g) | 0.32-1.28 |
Peanut butter | 1 cup (258 g) | 0.04-0.13 |
Red grapes | 1 cup (160 g) | 0.24-1.25 |
Most resveratrol supplements available in the US contain extracts of the root of Polygonum cuspidatum, also known as Fallopia japonica, Japanese knotweed, or Hu Zhang (150). Red wine extracts and grape extracts (from Vitis vinifera) containing resveratrol and other polyphenols are also available as dietary supplements. Resveratrol supplements may contain anywhere from less than 1 milligram (mg) to 500 mg of resveratrol per tablet or capsule, but it is not known whether there is a safe and effective dosage for chronic disease prevention in humans (also see the section on Safety).
In rats, daily oral administration of trans-resveratrol at doses up to 700 mg/kg of body weight for 90 days resulted in no apparent adverse effects (151). Other toxicity studies conducted in animal models estimated that the no-observed-adverse-effect-level (NOAEL) for resveratrol was 200 mg/kg/days and 600 mg/kg/day in rats and dogs, respectively (152). Resveratrol is not known to be toxic or cause significant adverse effects in humans, but there have been only a few controlled clinical trials to date (reviewed in 153). A trial evaluating the safety of oral trans-resveratrol in 10 subjects found that a single dose of 5,000 mg resulted in no serious adverse effects (10). In a follow-up study, mild-to-moderate gastrointestinal side effects, including nausea, abdominal pain, flatulence, and diarrhea, have been reported in participants who consume more than 1,000 mg/day of resveratrol for up to 29 consecutive days (11). Mild diarrhea was also reported in six out of eight individuals who consumed 2,000 mg of resveratrol twice daily for two periods of eight days in an open-label and within subject-control study (16).
The safety of resveratrol-containing supplements during pregnancy and lactation has not been established (150). Because there is no known safe amount of alcohol consumption at any stage of pregnancy (154), pregnant women should avoid consuming wine as a source of resveratrol.
Until more is known about the estrogenic activity of resveratrol in humans, women with a history of estrogen-sensitive cancers, such as breast, ovarian, and uterine cancers, should avoid resveratrol supplements (see Estrogenic and anti-estrogenic activities) (150).
Resveratrol has been found to inhibit human platelet aggregation in vitro (53, 155). Theoretically, high intakes of resveratrol (i.e., from supplements) could increase the risk of bruising and bleeding when taken with anticoagulant drugs, such as warfarin (Coumadin) and heparin; antiplatelet drugs, such as clopidogrel (Plavix) and dipyridamole (Persantine); and non-steroidal anti-inflammatory drugs (NSAIDs), including aspirin, ibuprofen, diclofenac, naproxen, and others.
Cytochrome P450 (CYP) enzymes are phase I biotransformation enzymes involved in the metabolism of a broad range of compounds, from endogenous molecules to therapeutic agents. The most abundant CYP isoform in the human liver and intestines is cytochrome P450 3A4 (CYP3A4), which catalyzes the metabolism of about half of all marketed drugs in the US (156). Resveratrol has been reported to inhibit CYP3A4 activity in vitro (157, 158) and in healthy volunteers (28). Therefore, high intakes of resveratrol (i.e., from supplements) could potentially reduce the metabolic clearance of drugs that undergo extensive first-pass metabolism by CYP3A4, hence increasing the bioavailability and risk of toxicity of these drugs. Some of the many drugs metabolized by CYP3A4 include HMG-CoA reductase inhibitors (statins), calcium channel antagonists (felodipine, nicardipine, nifedipine, nisoldipine, nitrendipine, nimodipine, and verapamil), anti-arrhythmic agents (amiodarone), HIV protease inhibitors (saquinavir), immunosuppressants (cyclosporine and tacrolimus), antihistamines (terfenadine), benzodiazepines (midazolam and triazolam), and drugs used to treat erectile dysfunction (sildenafil). Of note, a recently completed clinical trial (NCT01173640) examined the potential for single and multiple doses of resveratrol (1,000 mg) to interfere with the metabolism of midazolam in healthy volunteers, and results are soon to be published (153). Other CYP enzymes (e.g., CYP2D6 and CYP2C9) may also be inhibited by resveratrol (reviewed in 159).
Finally, resveratrol was found to be a weak inducer of the expression and activity of CYP1A2, which catalyzes the metabolism of several drugs, including acetaminophen (paracetamol) and the antidepressant drugs, clomipramine and imipramine (28, 156). This suggests that resveratrol may interfere with CYP1A2-mediated drug metabolism by increasing drug clearance, possibly lowering circulating drug concentrations below therapeutic levels.
Originally written in 2005 by:
Jane Higdon, Ph.D.
Linus Pauling Institute
Oregon State University
Updated in May 2008 by:
Victoria J. Drake, Ph.D.
Linus Pauling Institute
Oregon State University
Updated in May 2015 by:
Barbara Delage, Ph.D.
Linus Pauling Institute
Oregon State University
Reviewed in May 2015 by:
Juan Carlos Espín, Ph.D.
Research Professor
Consejo Superior de Investigaciones Científicas (CSIC)
Department of Food Science & Technology
Murcia, Spain
Last updated 6/11/15 Copyright 2005-2024 Linus Pauling Institute
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