Abstract
The plant-based compounds rho-iso-alpha acids (RIAA) from Humulus lupulus (hops) and proanthocyanidins (PAC) from Acacia nilotica have been shown to modulate insulin signaling in vitro. We investigated their effects on triglyceride (TG) deposition in 3T3-L1 adipocytes, glucose and insulin in obese mouse models, and metabolic syndrome markers in adults with metabolic syndrome. The combination of RIAA and PAC synergistically increased TG content and adiponectin secretion in 3T3-L1 adipocytes under hyperinsulinemic conditions and reduced glucose or insulin in obese mice. In a clinical trial, tablets containing 100βmg RIAA and 500βmg PAC or placebo were administered to metabolic syndrome subjects (3 tablets/day, ; 6 tablets/day, ; or placebo, ) for 12 weeks. Compared to placebo, subjects taking 3 tablets daily showed greater reductions in TG, TGββ:ββHDL, fasting insulin, and HOMA scores. The combination of RIAAββ:ββPAC at 1ββ:ββ5 (wtββ:ββwt) favorably modulates dysregulated lipids in insulin resistance and metabolic syndrome.
1. Introduction
Metabolic syndrome, which affects almost 40% of American adults [1], is a complex metabolic mosaic of abnormal lipid, weight, and inflammatory markers. These metabolic abnormalities indicate underlying impairments in cellular insulin signaling and ultimately result in increased risk for diabetes or cardiovascular disease [2, 3]. Diet and exercise modification is recommended by American Heart Association as first-line treatment because of their ability to address one or more components. If lifestyle modification fails due to patient noncompliance, antidiabetic drugs are often prescribed. However, approximately half of patients require more than one pharmaceutical agent within three years of diagnosis, and the proportion increases to 75% within nine years [4].
The difficulty in treating metabolic syndrome and type 2 diabetes may be due to the failure to address underlying molecular mechanisms of insulin resistance, which remain not thoroughly understood. A relevant aspect of this pathology is that even before the development of fasting or postprandial hyperglycemia, insulin resistance manifests as abnormalities in triglyceride (TG) storage and lipolysis in insulin-sensitive tissues, causing disruption of insulin signaling, leading to activation of NF-B and the subsequent upregulation of proinflammatory genes [5, 6]. Targeting kinases related to insulin signaling and inflammation and/or reducing lipid overspill are potentially effective strategies to treat insulin resistance.
Whereas kinase-inhibiting drugs may effectively completely inhibit these and other pathway networks, such strong inhibition has been associated with adverse events when used for a long duration. It has been shown that some botanical compounds derived from common foods have kinase-modulating activity or have insulin-potentiating action, safely and effectively modifying these interconnecting cellular pathways that address dysfunctional glucose metabolism, particularly as they relate to lipotoxicity [7β10]. In addition, they may also assist in peripheral mechanisms related to type 2 diabetes, such as improving lipid metabolism, antioxidant status, and vasculature [11, 12].
We previously discovered that traditionally consumed foodstuffs such as hops (Humulus lupulus L.) and acacia (Acacia nilotica) have modulating activity on kinases specific to insulin function. Specifically, hops-derived rho-iso-alpha acids (RIAAs), used as bitter flavoring agents in the beer industry, dose-dependently reduce GSK-3, PI3K, and PKC activity in cell-free kinase assays [13]. Proanthocyanidin- (PAC-) rich extract from acacia bark was found to modulate the aforementioned kinases in addition to IKK in a dose-dependent manner (unpublished). Others have also shown that PAC from a variety of botanicals improved symptoms of metabolic syndrome in vivo [14, 15].
In this paper, we report on our identification of a specific ratio of these natural products that favorably modified TG formation in the 3T3-L1 adipocyte model. Beneficial results with this ratio of actives on serum glucose and insulin in two diabetic mice models led us to conduct a 12-week clinical trial in individuals with the metabolic syndrome.
2. Materials and Methods
2.1. Chemicals and Reagents
Troglitazone, methylisobutylxanthine, dexamethasone, Oil Red O, and insulin were obtained from Sigma (St. Louis, MO). Penicillin, streptomycin, Dulbeccoβs modified Eagleβs medium (DMEM) were from Mediatech (Herndon, VA) and 10% HI-FBS (heat inactivated fetal bovine serum) from Mediatech and Hyclone (Logan, UT). All standard reagents were obtained from Sigma and were of the highest purity commercially available. Hops RIAA and Acacia PAC were provided by Metagenics, Inc. (Gig Harbor, WA); their chemical structures have been previously described [16, 17]. Growth medium was made by adding 50βmL of HI-FBS and 5βmL of penicillin/streptomycin to 500βmL DMEM. This medium was stored at and warmed to in a water bath before use.
2.2. Cell Culture
The murine 3T3-L1 fibroblast cell line was purchased from American Type Culture Collection (Manassas, VA) and maintained according to instructions from the supplier. Preadipocytes were cultured in DMEM containing 10% HI-FBS, with added 50βU penicillin/mL and 50βg streptomycin/mL, and maintained in log phase prior to experimental setup. Cells were grown in a 5% CO2 humidified incubator at . 3T3-L1 cells were seeded at an initial density of 4 βcells/cm2 in 24-well plates. For 2 days, the cells were allowed to grow to reach confluence. To force cells to differentiate into adipocytes, medium consisted of 10% FBS/DMEM (high glucose), 0.5βmM methylisobutylxanthine, 0.5βM dexamethasone, and 10βg/mL insulin was added. After 3 days, the medium was changed to postdifferentiation medium consisting of 10βg/mL insulin in 10% FBS/DMEM.
2.3. Lipogenic Activity in 3T3-L1 Cells
Lipogenesis was assessed using the preadipocyte differentiation assay as described by Xu et al. [18] with the following modification: (1) murine 3T3-L1 preadipocytes were selected rather than freshly isolated, rat preadipocytes, (2) intracellular lipid was measured using Oil Red O and BODIPY, and (3) troglitazone (10βM) was used as the positive control in place of rosiglitazone. Test material was added in dimethyl sulfoxide (DMSO) at day 0 of differentiation and every 2 days throughout the maturation phase (days 6/7). Fresh test material was added together with fresh media. Intracellular lipid was assessed using Oil Red O staining according to the method of Kasturi and Joshi [19]. Results were represented relative to stained cells in the solvent controls.
2.4. Adiponectin Assay in 3T3-L1 Cells
For anti-inflammatory activity, on day 6 after differentiation, adipocytes were treated with test material 4 hours before addition of TNF- at a final concentration of 10βng/mL. Cells were incubated overnight for approximately 18 h, followed by removal of the supernatant medium and cell staining for nonpolar lipid with BODIPY. Adiponectin was quantified using the Quantikine Mouse IL-6 Immunoassay kit or the Mouse Adiponectin Quantikine Immunoassay kit (R&D Systems, Minneapolis, MN).
2.5. Lipogenic Index, Adiponectin Index, and Synergy Calculations
For lipogenesis assays, test compounds were each assayed in duplicate for a minimum of three independent times. The Lipogenic Index was computed for each sample by normalizing Oil Red O values to the solvent control within each experiment. For adipogenic assays, each experiment was performed in duplicate. The effect of the test compounds on adiponectin secretion was computed relative to the solvent control.
An estimate of the expected effects of the hops RIAA and acacia PAC combinations was made using the relationship 1/LI = /LIX + /LIY or 1/AI = /AIX + /AIY where LI = Lipogenic Index, AI = Adiponectin Index, and and were relative fractions of each component in the test mixture and = 1. Synergy was inferred if the mean of the estimated LI and AI fell below the lower 95% confidence interval of the estimate of the corresponding observed fraction. This definition of synergy was described previously [20].
2.6. In Vivo Study
The effect of test materials on nonfasting serum glucose and insulin was assessed in the KK-Ay/Ta and C57BLKS/J-m+/+ Lep (db/db) models of non-insulin-dependent diabetes mellitus (NIDDM) and obesity performed at MDS Pharma Services (Taiwan). Nine-week-old male KK-Ay/Ta mice, weighing 40ββ5βg, were provided by Clea Inc. (Tokyo, Japan); 9-week-old male db/db mice, weighing 50ββ5βg, were provided by the Institute for Animal Reproduction (Ibaraki, Japan). These animals exhibited hyperinsulinemia, hyperglycemia, and islet atrophy. The animals were housed in Individually Ventilated Cages Racks (IVC Racks, 36 Mini Isolator systems) throughout the experiment. Each APEC cage (in cm, 26.7 length 20.7 width 14.0 height) was sterilized with autoclave and housed 5 mice. The mice were maintained in a hygienic environment under controlled temperature (2β2) and humidity (60%β70%) with 12-hour light/dark cycle. The animals were fed sterilized lab chow and sterilized distilled water ad libitum. All aspects of this work, including housing, experimentation, and disposal of animals, were performed in accordance with the Guide for the Care and Use of Laboratory Animals (National Academy Press, Washington, D. C., 1996).
Test substances and vehicle (2% Tween 80, Wako, Japan) were administered orally daily for 3 consecutive days starting immediately after the pretreatment blood sampling (day 1). Each substance was tested in a group of 5 mice. Post-treatment blood samples were drawn from the orbital sinus 90 minutes after administration of the final dose on day 7. Serum glucose and insulin levels were determined by enzymatic (Mutaratase-GOD, Wako, Japan) and ELISA (mouse insulin assay kit, SPIbio, France) methods, respectively. Post-treatment serum glucose and insulin values expressed in percentage of respective pretreatment values were calculated, and paired -test was used for comparison. Differences were considered significant at level (2-sided).
2.7. Human Clinical Trial
To investigate the effect of RIAA and PAC (supplemented orally at 1ββ:ββ5 wtββ:ββwt) on serum glucose, insulin, and lipids in individuals with metabolic syndrome, a randomized, 12-week, double-blind, placebo-controlled trial was conducted at the Functional Medicine Research Center (Gig Harbor, WA). Inclusion criteria included, (i) age 18β70 years, (ii) BMI 25β42.5βkg/m2 and (iii) TGββ:ββHDL-cholesterol 3.5; (iv) fasting insulin 71.75βpmol/L (or 10βIU/mL). In addition, individuals had to meet 3 of the following 5 criteria: (i) waist circumference 88.9βcm (or 35 inches) for women and 101.6βcm (or 40 inches) for men, (ii) TG 1.7βmmol/L (or 150βmg/dL), (iii) HDL-cholesterol 1.3βmmol/L (or 50βmg/dL) for women and 1.0βmmol/L (or 40βmg/dL for men, (iv) blood pressure 130/85βmmβHg or diagnosed hypertension on medication, and (v) fasting glucose 5.55βmmol/L (or 100βmg/dL). Key exclusion criteria included involvement in a weight loss program leading to 10% or greater body weight loss over the preceding 4 weeks, use of blood glucose or cholesterol-lowering medications or supplements, corticosteroid use in the preceding 4 weeks, allergy to study materials, or a history of diabetes, cancer, renal, hepatic, or cardiovascular diseases. The study was conducted in accordance with the Declaration of Helsinki, and informed written consent was obtained from each participant prior to enrollment in the study.
Eligible participants were randomized to one of 4 arms using Microsoft Excel 2003 (Redmond, WA): Arm 1: placebo tablet, 3 times daily; Arm 2: active tablet consisting of hops 100βmg RIAA and 500βmg acacia PAC (1ββ:ββ5), 3 times daily; Arm 3: same as Arm 2 but at 2 tablets 3 times daily; Arm 4: placebo tablet, 2 tablets 3 times daily. All participants were instructed in an hour-long nutritional counseling session at the start of the study to follow the AHA Step (low-fat) diet. Caloric prescriptions were determined by analyzing bioelectrical impedance to calculate basal metabolic rate (BMR) using the Katch-McArdle formula [21] BMR = 370 + (21.6 lean mass in kg). The daily BMR was calculated by multiplying by an activity factor (1.12 for men and 1.14 for women) derived from the National Academy of Sciences low activity level (walking 2.2 miles daily) and was based on 150 minutes of aerobic activity per week. Caloric needs were estimated by subtracting 600 calories from the calculated BMR.
After the baseline visit, participants returned at 2, 4, 8, and 12 weeks for follow-up visits. Compliance to the diet and exercise treatment was monitored at each visit using 3-day diet and exercise diaries. Overnight fasting blood samples were collected at baseline, 8 weeks and 12 weeks for lipid analysis. For 2-hour postprandial insulin/glucose response, participants consumed a solution containing 75βg glucose (Trutol 100, CASCO NERL Diagnostics) after the fasting blood draw, and 2 hours after the glucose challenge, blood was drawn and assayed for glucose and insulin levels (Laboratories Northwest, Tacoma, WA).
2.8. Statistical Analysis
Data from Arm 1 and Arm 4 were combined and served as one placebo arm. For each variable, changes from baseline to 8 weeks and 12 weeks were calculated for each treatment arm. Baseline determinations were analyzed using one-way ANOVA. Changes from baseline to 8 weeks and 12 weeks were analyzed separately for each arm using a priori two-sided paired -test. Differences among treatments were determined by ANOVA with post hoc multiple comparisons between treatments. All the tests were 2-sided. The -value was significant if .05. Data were analyzed using SAS (version 9.1, Cary, NC).
3. Results
3.1. RIAA and PAC Synergy In Vitro
The murine 3T3-L1 preadipocyte is used to study the potential effects of test compounds on adipocyte differentiation and adipogenesis. Assessing TG synthesis of 3T3-L1 cells provides a validated model of the insulin-sensitizing capacity of the test agent [22]. For assessing the effects of hops RIAA and acacia PAC combination on lipogenesis and adiponectin secretion, the 1-to-5 and 1-to-10 combinations of RIAAββ:ββPAC at 50, 10, 5, and 1βg/mL were tested. With respect to increasing lipid incorporation under the condition of hyperinsulinemia, RIAAββ:ββPAC at 1ββ:ββ5 exhibited synergistic effects at all 4 concentrations, while at 1ββ:ββ10 the synergy was observed at 5 and 10βg/mL (Table 1). Regarding increasing adiponectin secretion from TNF stimulation, RIAAββ:ββPAC at 1ββ:ββ5 exhibited synergy at 1, 5, and 50βg/mL, while at 1ββ:ββ10 the synergy was observed at 1, 10, and 50βg/mL (Table 1).
3.2. RIAA and PAC Combinations on Serum Glucose and Insulin In Vivo
With the RIAAββ:ββPAC at 1ββ:ββ5 and 1ββ:ββ10 showing synergistic effect on lipogenesis in vitro, we went on to test the effect of these ingredients (/) with both combined ratios as well as single ingredients on glucose metabolism in 2 NIDDM mouse models. Rosiglitazone was used as the positive control. In KK-Ay/Ta mice, 3 days of RIAA or PAC treatment alone at 100βmg/kg did not reduce the glucose concentration, but RIAAββ:ββPAC at 1ββ:ββ5 significantly reduced glucose concentration from 31.20 1.33βmmol/L to 28.92 1.53βmmol/L (; Figure 1(a)). The combined ratio of 1ββ:ββ10 did not exhibit a significant effect (data now shown). The rosiglitazone treatment also significantly reduced glucose concentration. However, none of the treatments, including rosiglitazone, affected insulin concentrations in KK-Ay/Ta mice (Figure 1(b)). In db/db mice, only rosiglitazone treatment significantly reduced glucose concentration (; Figure 1(c)). RIAA treatment at 100βmg/kg reduced insulin concentration from 94.2 7.1βpmol/L to 78.4 5.5βpmol/L (), while PAC treatment at 100βmg/kg did not have any effect. The RIAAββ:ββPAC at 1ββ:ββ5, however, significantly reduced insulin from 104.5 5.7βpmol/L to 83.4 7.0βpmol/L (), as did the rosiglitazone control () (Figure 1(d)). The combined ratio of 1ββ:ββ10 did not significantly affect insulin and glucose concentrations (data not shown).
(a)
(b)
(c)
(d)
3.3. Human Clinical Trial
Given the observed synergistic effect of RIAAββ:ββPAC at 1ββ:ββ5 but not at 1ββ:ββ10 on glucose metabolism in 2 mouse models, we chose the 1ββ:ββ5 combination for our clinical trial. A total of 104 individuals were enrolled (35 for Arm 1 + 4, 35 for Arm 2, and 34 for Arm 3) and 91 completed the study (33 for Arm 1 + 4, 29 for Arm 2, and 29 for Arm 3). Baseline characteristics, fasting glucose and insulin and their 2-hour postprandial responses, and serum lipids did not differ by treatment arm (Table 2). As expected, participants exhibited high cholesterol, LDL, TG, and elevated blood pressure and were obese. There were no significant differences among arms at baseline in daily dietary caloric and nutrient intake except for soluble fiber (Table 2).
Over time, total energy, carbohydrate, total fat, and saturated fat intake decreased in all arms, but the changes did not differ among arms (Table 3). Compared to baseline intake, Arms 1 + 4 (receiving placebo) had an increase in vegetable, soluble fiber, and insoluble fiber intake at 8 and/or 12 weeks, Arm 2 (receiving 3 active tablets daily) had an increase in vegetable intake at 8 weeks, and Arm 3 (receiving 6 active tablets daily) had an increase in soluble fiber and insoluble fiber intake at 8 and/or 12 weeks. Over time, individuals in all arms lost weight, waist circumference, and BMI at 8 weeks and 12 weeks compared to baseline although the degree of changes did not differ among arms. Some reductions in systolic and diastolic blood pressure were observed in Arms 1 + 4 and Arm 2 (Table 4).
In terms of glucose metabolism (Table 4), Arms 1 and 4 participants showed an increase in fasting glucose at 8 weeks () and 12 weeks () compared to baseline; Arm 2 participants did not show any changes at 8 and 12 weeks; Arm 3 participants showed an increase at 8 weeks () and 12 weeks () compared to baseline. However, these values were within normal physiological ranges. The 2-hour post-prandial glucose values at 8 weeks and 12 weeks were similar to baseline in all 3 arms. Fasting insulin levels remained unchanged over time for Arm 1 + 4, but were significantly reduced at 8 weeks () and 12 weeks () for Arm 2. For Arm 3, the levels were also reduced at 8 weeks () but not at 12 weeks (). The 2-hour post-prandial insulin values exhibited large variations but generally remained unchanged except being higher for Arm 1 + 4 at 12 weeks ().
Of all the assessed lipid parameters (Table 3), serum TG exhibited the most significant differences over time. Compared to baseline, the TG level remained unchanged for Arm 1 + 4, decreased significantly at 8 weeks (by 0.55 0.14βmmol/L; ) and 12 weeks (by 0.59 0.12βmmol/L; ) for Arm 2, and decreased significantly at 8 weeks (by 0.50 0.18βmmol/L; ) but not 12 weeks (by 0.25 0.24βmmol/L; ) for Arm 3. Serum cholesterol was significantly reduced in Arm 1 + 4 at 12 weeks () and moderately reduced in Arm 3 at 8 weeks (). Serum LDL remained unchanged in all 3 arms except for a trend toward reduction in Arm 1 + 4 at 12 weeks (). Serum HDL also remained unaffected in all 3 arms except for a trend toward reduction in Arm 3 at 8 weeks (). TGββ:ββHDL reflected the findings of lowered serum TG; a significant reduction was observed in Arm 2 at 8 and 12 weeks. A reduction in the HOMA scores was observed for Arm 2 at 8 weeks ().
4. Discussion
In the 3T3-L1 preadipocyte differentiation assay, a validated model of insulin-sensitizing capacity, the 1ββ:ββ5 combination of RIAA and PAC increased lipid incorporation under the condition of hyperinsulinemia in a synergistic manner at all four concentrations tested. This combination also demonstrated the ability to improve glucose metabolism in vivo in 2 type 2 diabetes mouse models: nonfasting serum glucose significantly decreased in KK-Ay/Ta mice and non-fasting serum insulin significantly decreased in db/db mice after administration with RIAAββ:ββPAC at 1ββ:ββ5. Subjects with metabolic syndrome who took 100βmg RIAA and 500βmg PAC three times daily and followed the AHA Step low-fat diet for 12 weeks experienced significant decreases in fasting TG and insulin levels compared to individuals who took placebo and followed the same diet. Subjects in this treatment group also showed greater reductions in TGββ:ββHDL and HOMA scores. Taken together, results of these three studies demonstrate the potential of this synergistic combination of phytonutrients to favorably modulate dysregulated lipids and insulin sensitivity in insulin resistance and metabolic syndrome.
Mean TG levels in the United States have increased in recent decades, with elevated fasting TG (concentrations of 150βmg/dL or higher) now the norm in one out of three Americans [23]. Out of all the risk factors for metabolic syndrome, higher fasting TG, along with lower HDL and abdominal obesity, is the strongest predictor of metabolic syndrome development [24]. Other risk factors for metabolic syndrome, such as elevated blood pressure and altered glucose metabolism, differ more by age and sex and are not necessarily the strongest risk factors. In addition to predicting the risk of metabolic syndrome and new-onset diabetes [25], elevated fasting TG has been associated with 1.7 times increased risk for cardiovascular disease [26]. This increased risk is independent of LDL [27] and even HDL cholesterol levels [28]. Having both increased fasting TG levels and a high waist circumference are also independently associated with various other cardiometabolic risk factors, including small low-density lipoprotein particles, increased apolipoprotein B levels, increased insulin levels, reduced adiponectin concentrations [29], as well as subclinical vascular damage [30].
As research on the clinical and pathophysiological effects of elevated TG and systemic fatty acids on insulin resistance and metabolic syndrome continues, the traditional glucocentric perspective is being replaced. The processes of lipotoxicity and lipoapoptosis, in which the formation of reactive lipid particles promotes metabolically relevant cellular dysfunction and programmed cell death, are now known to be major mediators of insulin resistance, diabetes, and cardiovascular disease [31]. Unoxidized long-chain fatty acids overaccumulate, saturating the storage capacity of adipose tissue and leading to deleterious lipid spillover. The portal circulation becomes flooded with free fatty acids at metabolically inappropriate times when free fatty acids should be oxidized, thus exposing nonadipose tissues to fat excess. In the liver, muscle, heart, and pancreas, the excess lipids are driven into pathways which result in lipoapoptosis, ultimately leading to organ failure. The additional dysregulation of glucose homeostasis in combination with excess fatty acids provides an even greater synergistic effect leading to lipotoxicity and cell death. Therefore, TG and fatty acids should become a primary target for treating metabolic syndrome.
Lifestyle modification with diet, regular exercise, and weight control, remains the primary intervention for lowering TG [23] and has proven effective in large prospective studies for prevention and treatment of the metabolic syndrome [32]. It is to be expected that a majority of persons will forgo long-term compliance with lifestyle changes alone, and it is probable that those taking pharmaceuticals will fail to adequately control the myriad metabolic imbalances manifest in the syndrome. Due to the high cost of metabolic syndrome, both in terms of human lives and monetary expenditures, it seems highly desirable to have safe, effective natural agents to support treatment.
Animal and clinical studies with another hop compound, isohumulone, which is structurally similar to RIAA but less chemically stable [33], have revealed its ability to reduce levels of plasma TG, free fatty acids, plasma glucose, and HbA1c, improve glucose tolerance, and reduce insulin resistance [34, 35]. The in vitro and in vivo data from diabetic mouse models reported in the current study provides evidence for the hop compound RIAA for the insulin sensitizing capacity.
Though we observed statistically significant responses in terms of TG, TGββ:ββHDL, and fasting insulin in subjects receiving RIAA (100βmg)ββ:ββPAC (500βmg) three times daily at both 8 and 12 weeks, other variables, especially those related to glucose metabolism, did not improve in this arm and were actually less favorable in the arm receiving six tablets daily, as well as in the placebo arm. At least three explanations may account for this lack of favorable changes. First, subjects in all three arms had normal baseline glucose homeostasisβdefined as a fasting plasma glucose level of less than 100βmg/dL and a 2-hour oral glucose tolerance test result of less than 140βmg/dL after a 75βg oral glucose loadβwith no evidence of impaired fasting glucose or impaired glucose tolerance. After treatment, fasting glucose remained within normal physiological ranges for the 3-tablets-daily and placebo arms and increased only slightly above normal in the 6-tablets-daily arm despite the statistically significant increases from baseline in the placebo and 6-tablets-daily-arms. Because fasting glucose and glucose tolerance started and remained primarily within normal physiological ranges, and because changes were so slight, they may be considered clinically insignificant. Second, it has been shown that metabolic parameters such as fasting glucose are not the primary predictors of the metabolic syndrome [24] and that insulin sensitivity can already be substantially decreased within the normal range of fasting and 2-hour glucose [36]. As the roles of free fatty acids and insulin resistance in cardiometabolic risk continue to be refined, it is becoming apparent that treating elevated TG and associated lipotoxicity is important, independent of glucose metabolism. In the 3-tablets daily arm, the combination of normal glucose metabolism with significant improvements in TG and fasting insulin indicates the possibility that patients were mildly insulin sensitive but had not yet developed overt problems with glucose homeostasis. Perhaps extending RIAA/PAC treatment duration beyond 12 weeks or studying patients with more advanced glucose homeostasis dysregulation at baseline would have achieved more significant results in terms of measures of both glucose and lipid metabolism. Third, although the subjectsβ compliance with dietary and exercise recommendations was satisfactory, it is possible that the AHA Step (low-fat) diet, even when combined with these supplemental phytonutrients, was inadequate for producing greater changes in parameters related to glucose, insulin, or lipids. The AHA Step diet, primarily intended as the starting point for treating hypercholesterolemia, restricts total fat to no more than 30 percent of total calories, saturated fat to no more than 10 percent of total calories, and cholesterol to less than 300βmg/day [37]. It has been found to lower both serum total cholesterol and LDL cholesterol [38] but has also been associated with lowering serum HDL cholesterol [39] as well as with nutritional inadequacies [40] and has since been replaced by new, more comprehensive AHA dietary recommendations as part of Therapeutic Lifestyle Changes [41]. More comprehensive diets, such as those which reduce glycemic load and increase fiber, may be required in combination with supplemental phytonutrients such as RIAAββ:ββPAC in order to achieve more substantial reductions in established risk markers for cardiovascular disease and type 2 diabetes.
The favorable results for TG and fasting insulin observed in the arm receiving RIAAββ:ββPAC three times daily did not carry over to those receiving the tablets six times daily. The plateau may have simply been reached using the lower dosage method although this does not explain the fact that we did not observe even similar benefits in the higher-dose arm. Alternate explanations include the possibility of an absorption issue at this higher dose, or, more likely, could be related to the slightly higher serum TG and fasting insulin levels observed in the 3-tablets-daily arm at baseline. These mildly higher values may be more likely to respond to this phytonutrient combination, regardless of the dose. Both pharmacokinetic studies as well as larger controlled studies in patients with more advanced hypertriglyceridemia and glucose dysregulation at baseline would provide further insight into the dosage issue. The current data indicates that three tablets daily provide maximum physiological impact, and higher oral doses do not increase clinical benefit.
5. Conclusions
The continuing epidemic of metabolic syndrome, which substantially increases the risk of type II diabetes and cardiovascular disease, calls for novel, effective therapeutic approaches beyond pharmaceuticals and lifestyle modification. The addition of certain phytochemicals such as RIAA from hops and PAC from acacia to dietary and lifestyle modification has the potential to more favorably modulate insulin signaling and to decrease the deleterious effects of lipotoxicity which characterize metabolic syndrome. We showed that the specific combination of RIAAββ:ββPAC (1ββ:ββ5) synergistically increased TG content in 3T3-L1 adipocytes under conditions of hyperinsulinemia and increased adiponectin secretion in cells treated with TNF-. Serum glucose or insulin concentrations in KK-Ay/Ta and db/db mice were reduced by three-day oral treatment with such combination at 100βmg/kg body weight more than by treatments with individual compounds. Daily supplementation with 300βmg RIAA and 1500βmg PAC in addition to lifestyle modification including dietary alteration reduces serum TG, TGββ:ββHDL, and fasting insulin significantly more than diet and lifestyle modification alone in patients with features of the metabolic syndrome. This phytonutrient combination provides a potential therapy for correcting or modulating dysregulated lipids and improving insulin sensitivity in metabolic syndrome.
Acknowledgments
The authors thank Drs. Jyh-Lurn Chang and Kathleen Jade for manuscript preparation and Alex Hsi for statistical analysis. All studies were funded by Metagenics Inc. All research presented herein was funded by MetaProteomics, LLC. MetaProteomics is a subsidiary of Metagenics, Inc.