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Review

Dietary Polyphenols and Periodontitis—A Mini-Review of Literature

1
Department of Kinesiology and Nutrition Sciences, School of Allied Health Sciences, University of Nevada Las Vegas, 4505 S Maryland Parkway, Las Vegas, NV 89154, USA
2
Department of Biomedical Sciences, School of Dental Medicine, University of Nevada Las Vegas, Las Vegas, NV 89154, USA
*
Author to whom correspondence should be addressed.
Submission received: 10 June 2018 / Revised: 14 July 2018 / Accepted: 18 July 2018 / Published: 20 July 2018
(This article belongs to the Special Issue Natural Polyphenols and Health)

Abstract

:
Periodontitis, which is a chronic infection and disease of the periodontium, is a significant global health burden and is linked to other chronic health conditions such as diabetes and cardiovascular diseases. Dietary polyphenols present in a wide variety of plant-based foods, herbs, and botanicals have been shown to exert antimicrobial, anti-inflammatory, and reduced osteoclast and alveolar bone loss activities in animal models of periodontitis. Polyphenol-containing beverages and foods especially green tea and its active catechin epigallocatechin-3-gallate, cranberries, pomegranates, and fruit and vegetable extracts have reported bacteriostatic/bactericidal activity against microbial species such as P. gingivalis and shown total bacterial burden in clinical studies. These polyphenols also exhibit anti-inflammatory and antioxidant effects, which have the potential to impact various biological mechanisms for reducing the initiation and progression of periodontitis. The main objective of this mini-review is to focus on the mechanisms of action of dietary polyphenols in improving the pathophysiology underlying chronic inflammatory diseases like periodontitis based on pre-clinical and clinical models.

1. Introduction

Two of the most prevalent forms of oral conditions are dental plaque-induced gingivitis and chronic periodontitis. Based on the National Health and Nutrition Examination Survey (NHANES) (2009–2012), approximately 50% of US adults greater than 30 years old exhibit periodontitis with Hispanics, non-Hispanic Blacks, and aging individuals disproportionately affected by this condition [1]. In this previous cross-sectional study, periodontitis was defined by combining measures of clinical attachment loss (AL) and periodontal probing depth (PD) on all teeth except third molars, which is defined by the American Academy of Periodontology [2]. Based on the Global Burden of Disease 2010 study, severe periodontitis is a significant global health burden and represents the sixth most prevalent condition worldwide. It affects approximately 743 million people worldwide [3] Periodontitis is a localized inflammatory process mediating the destruction of soft and hard periodontal tissues triggered by a complex bacterial biofilm insult. Poor dental behaviors and oral hygiene have been determined to be the primary factors in disease risk and expression and are associated with many dietary and lifestyle factors as well as the concomitant presence of chronic systemic conditions such as diabetes [4]. Based upon the disruption of the oral epithelial barrier, periodontitis is also characterized by systemic inflammatory host responses that may contribute to the higher risk of cardiovascular disease (CVD) among affected patients [5]. Several reports consistently demonstrate a positive correlation between periodontitis and vascular diseases including reports about diabetes [6,7,8,9]. Microbial translocation from periodontal lesions and resulting systemic inflammation are considered common links that underlie these associated conditions with elevated systemic inflammation determined by biomarkers such as the C-reactive protein and pro-inflammatory cytokines and chemokines correlated to periodontitis [10,11]. These observational data identify the need for optimal oral health as an integral component for the prevention and management of chronic conditions such as CVD and diabetes. Dietary nutrients and specific bioactive compounds including polyphenols have emerged as influential factors in the etiology and progression of periodontitis. In recent years, observational studies show a strong correlation between the intake of fruits and vegetables and other antioxidant nutrients with oral health-related quality of life in adults [12,13]. These effects have been mainly attributed to their function in reducing oxidative stress, inflammation, and replacing less healthy dietary choices that promote increased bacterial burden and associated inflammation. Nutritional studies are now recognizing the role of food groups high in vitamin C and other compounds such as the anti-inflammatory omega-3-fatty acids and fiber in decreasing the risks of periodontitis [4,14,15]. While these reports are promising, further research deserves urgent attention given the high prevalence of periodontitis in the US and global population. Given the lack of reviews in this area of research, the primary objective of this focused narrative is to review and discuss the salient findings of reported nutritional studies in recent years. This paper outlines the role of dietary polyphenols in periodontitis.

2. Dietary Polyphenols: Link with Chronic Diseases and Periodontitis

Dietary polyphenols from commonly consumed foods and beverages as well as herbs and botanicals are well known for their anti-microbial, antioxidant, and anti-inflammatory functions. Dietary polyphenols can be broadly grouped into many different categories. These categories include tannins, flavonoids, and lignin-carbohydrate complexes (LCC), which have been associated with anti-microbial and anti-inflammatory properties in mechanistic studies [16], as well as those that are commonly consumed as dietary sources. For example, 437 polyphenol compounds were identified in raw and prepared foods in a newly established database for European countries [17]. Among these, the dietary flavonoids and their sub-classes (anthocyanidins, flavones, flavan-3-ols, flavonols, and flavanones) have been widely studied for their associations with chronic diseases including those related to inflammation [18,19,20]. Epidemiological and clinical studies over the last decade have accumulated substantial evidence about the inverse associations of dietary polyphenol intake especially the flavonoids found in fruits, tea, and olives with a risk for several chronic diseases such as diabetes [21], cardiovascular diseases [19], cancer [22], and neurodegenerative diseases [20]. Based on the emerging relationship of these conditions with periodontitis [23,24], studying a potential causal link of dietary polyphenols in lowering the risks of periodontitis is a critical research direction. Green tea, which is a rich source of flavonoids such as catechins, have been shown to exert significant antioxidant and bactericidal activities in small clinical trials when participants consumed green tea supplements [25] or slow release strips of green tea catechins mechanically applied into dental pockets [25]. A recent paper reviewed the role of dietary polyphenols in oral health and identified the anti-viral and anti-inflammatory effects of polyphenols derived from green tea and black tea. The paper also identified licorice root as topical agents that can be applied directly to the oral cavity [16]. Based on the results from various experimental models and clinical studies, designing polyphenol formulations into local delivery applications may present an emerging line of natural therapy for periodontitis and may maximize improved oral health among more populations.

3. Dietary Polyphenols and Periodontitis: Cellular Studies

Many in vitro studies have examined the effects of dietary polyphenols on inflammatory markers and pathogenicity of bacteria associated with periodontitis (Table 1). A variety of microorganisms have been detected in dental biofilms and in periodontopathic biofilms. These bacteria include Porphyromonas gingivalis, Tannerella forsythia, Treponema denticola, and A. actinomycetemcomitans [26]. However, recent microbiome studies have suggested the contribution of other periodontopathogens [23]. Dietary sources of polyphenols including curcumin, green tea, and pomegranates have been identified for their potential role in treating inflammatory responses of gingival and periodontal diseases. Using a comprehensive in vitro assay, Shahzad et al. screened 48 polyphenolic compounds for their role in inhibiting periodontal pathogens including the major categories of polyphenols such as organic acids (hydroxybenzoic acids, hydroxycinnamic acids, hydroxyphenylacetic acids), flavanols, flavanones, anthocyanins, flavones, isoflavonoids, and phenolics. When applied to bacterial strains implicated in periodontitis, it was observed that the curcumin was the most potent inhibitor of bacterial growth. This was followed by pyrogallol, pyrocatechol, and quercetin [26]. Notably, these polyphenol treatments were demonstrated to selectively target pathogenic biofilm microorganisms especially P. gingivalis while sparing normal microbiota members of the dental biofilm such as Streptococcus mitis [26]. The viability, proliferation, and biofilm-forming capacity of pathogens associated with periodontitis can be significantly affected by dietary polyphenols. Other commonly consumed dietary sources of polyphenols, such as blueberry extract and tea polyphenols (black and green tea extracts and theaflavins) have also been shown to inhibit biofilm formation and slow bacterial growth in several studies [26,27,28]. The addition of epigallocatechin-3-gallate (EGCG), which is the most abundant and bioactive green tea polyphenol, and green tea extract to a culture of human gingival epithelial cells inhibited the release of several cytokines [29].
Less commonly used herbal extracts such as common sorrel and Limonium brasiliense extracts were shown to reduce the adherence of P. gingivalis to human gingival fibroblast cells. The mechanism has been explained to be the potential interaction of polyphenols with protein complexes called gingipains [30,31]. Polyphenols have also been demonstrated to exert antioxidant properties and inhibit the release of inflammatory cytokines in vitro [29]. The use of resveratrol, which is a phenolic compound in grapes and wine, reduced nitric oxide expression in a dose-dependent and time-dependent manner in human periodontal ligament cells exposed to P. gingivalis [32]. These promising in vitro effects of the polyphenols in altering various responses that could contribute to pathological changes in periodontitis deserve extended investigations using animal models and human clinical studies.

4. Dietary Polyphenols and Periodontitis: Animal Studies

A limited number of in vivo studies using rodent models have provided mechanistic data on the role of dietary polyphenols in alleviating features of periodontitis (Table 2). Polyphenol treatment of animal disease models has shown to decrease inflammatory markers and macroscopic damage associated with periodontal disease [33,34,35,36]. Oral intake of EGCG and curcumin was observed to lower circulating levels of inflammatory cytokines known as IL-1β, TNF-α, and IL-17, which are implicated in the inflammation and disease progression of periodontitis [33,34]. Animal studies using St. John’s wort (Hypericum perforatum) and green tea extract found that these treatments reduced the extant of bacteria-induced immune cell infiltration into the periodontal tissues, which could help mitigate further inflammatory damage [35,36].
Animal studies have also specifically documented the effects of polyphenol treatment on alveolar bone loss. Alveolar bone resorption is a hallmark of periodontitis due to the deleterious effects of inflammatory cytokines on osteoclast numbers, maturation, and function. Osteoclastogenesis is excessively stimulated during the inflammatory process. The resulting dysregulation of bone formation and resorption due to the surplus of active osteoclasts dissolves the mineral matrix of the bone [37]. Oral intake of myricetin, which is a polyphenol derived from many plant foods, was observed to reduce alveolar bone loss in mice by interacting with osteoclast-related genes at doses of 10 μM and 50 μM concentrations [37]. Similar results have also been demonstrated following treatment with mangiferin, which is a polyphenol present in mangos, at 50 mg/kg. This revealed reduced bone loss in mice with decreased levels of IL-6 and IL-1β, which directly interact with the osteoclastogenic pathways and promote the maturation of osteoprogenitor cells into mature osteoclasts [38]. Resveratrol and curcumin treatment also demonstrated amelioration of bone loss in rats using antioxidants and reducing inflammatory cytokines at doses of 10 mg/kg and 100 mg/kg, respectively [34].
An important point to consider is the limited physiological relevance of the large polyphenol doses used in cell and animal studies. In most cases, dietary polyphenols have poor bioavailability in humans and undergo rapid metabolism and excretion. For example, feeding studies have shown consumption of 100 g dietary berries lead to concentrations of serum quercetin, which is a common dietary polyphenol that ranges from 15–25 µM in middle-aged adults [39]. Similarly, studies have reported non-detectable or very low levels of curcumin in clinical trials after a large dose intervention (~8 g curcumin/day) [40]. Therefore, while the pre-clinical data are intriguing, further studies are needed at habitual levels of intake in human clinical trials of periodontitis. These actions of dietary polyphenols in animal models of periodontitis provide consistent support for increasing exposure to common sources of dietary polyphenols such as curcumin, fruits like grapes and mangoes, and green tea for preventing and treating this oral disease.

5. Dietary Polyphenols and Periodontitis: Human Clinical Studies

For many years, the role of dietary nutrients in oral health has been largely studied from the perspectives of macronutrients such as sugars that can promote dental caries and the growth of microorganisms. Increased sugar and total carbohydrate intake have been associated with an increased risk for developing dental caries and experiencing gingival bleeding [41]. Sugar acts to diminish oral health through fermentative metabolism of many oral bacteria, which results in the release of acidic byproducts that dissolve the mineral content of the teeth [4]. Yet, lactose has been observed to be less cariogenic than other sugars [4]. An analysis of NHANES III (1984–1994) data of young adults demonstrated that a high frequency of consumption of added sugars was associated with a greater prevalence of periodontal disease [42]. Therefore, it is important to consider the influence of dietary sugars for the development and severity of periodontitis even in conjunction with dietary polyphenols.
Clinical studies have also been conducted to determine the potential antimicrobial, antioxidant, and anti-inflammatory properties of dietary polyphenols (Table 3). A clinical study administering freshly-squeezed pomegranate juice as a mouth rinse in subjects without periodontal disease demonstrated significant reductions in the colony-forming units (CFUs) of Lactobacillus and Streptococcus species [43]. Pomegranates are rich in polyphenols, tannins, ellagic acid, and anthocyanins, which may be implicated in the antimicrobial properties of this mouth rinse. In another clinical study of patients with chronic periodontitis, a gel containing 1% curcumin, which is the bioactive substance found in turmeric, was applied to affected areas in the periodontal pockets and resulted in significant bactericidal effects on P. gingivalis, P. intermedia, F. nucleatum, and Capnocytophaga [44]. Other clinical studies have demonstrated beneficial effects of dietary polyphenols on the clinical measurement of periodontal disease including probing depth (PD), gingival index (GI), and clinical attachment level (CAL), which are indicators of periodontitis severity. In one such study, supplementation with a capsule containing selected dehydrated fruits and vegetables was shown to significantly reduce PD compared with placebo pills [45]. In another study, sub-gingival application of a gel containing Emblica officinalis or gooseberry extract (10%) showed reductions in PD, an increase in CAL, and improvements in the modified sulcus bleeding index [46]. A similar study of intra-pocket application of a green tea extract gel was demonstrated to decrease PD, GI, and relative CAL (rCAL) in chronic periodontitis patients [47]. Lastly, dietary polyphenols have been shown to possess significant anti-inflammatory and antioxidant properties. In a study of chronic periodontitis, patients were treated with either a green tea dentifrice containing 60% to 90% epigallocatechin or a standard fluoride/triclosan dentifrice. It was found that the green tea treatment significantly increased the activity of glutathione-S-transferase, which is an endogenous antioxidant, and this treatment subsequently decreased the degree of gingival inflammation [48].
Another study using dark chocolate, which is rich in cocoa flavonoids, demonstrated that dark chocolate increases total antioxidant capacity and decreases lipid peroxidation and the modified papillary bleeding index when compared with a white chocolate treatment group [49]. While these clinical findings as presented in Table 3 look promising for the management of periodontitis, it is important to consider the lack of characterization and standardization of polyphenol content in foods and beverages that may be associated with differential outcomes in humans. Nevertheless, based on the findings of these clinical studies, increasing oral exposure to dietary polyphenols with a concomitant decrease in sugar intake may be considered a prudent dietary strategy in managing periodontitis.

6. Food vs. Purified Polyphenols in Periodontitis

The source of polyphenols must be taken into consideration when interpreting their effects on the outcomes of periodontitis. Commonly consumed dietary polyphenols derived from food and beverages such as green tea [28,48], blueberry [27] and cranberry extracts [50], and pomegranate juice [43] have been shown to inhibit the growth of bacterial biofilms and inflammation and improve clinical outcomes of periodontitis. Green tea is a rich source of several flavonoids especially the gallated catechins [51]. Blueberries are high in anthocyanidins and phenolic acids [52] and cranberries offer proanthocyanidins (PACs) that have been associated with multiple anti-microbial effects [53]. PACs are a class of phenolic compounds that take the form of oligomers or polymers of polyhydroxy flavan-3-ol units such as (+)-catechin and (−)-epicatechin [54]. Pomegranate juice, which is a rich source of tannins, ellagic acid, and anthocyanins, has been shown to exert the highest antioxidant potential among the commonly consumed beverages among US consumers [55]. It also includes observed anti-microbial effects following a mouth rinse [43]. In addition to these sources of food, individual polyphenols such as curcumin [34], epigallocatechin gallate [33], myricetin [37], and mangiferin [38], which represent predominant polyphenols in turmeric, green tea, leafy vegetables, and mangos, respectively, have been mostly shown to decrease inflammation in experimental models of periodontitis. Overall, it appears that the natural combination of polyphenols in extracts from whole foods and beverages exert multi-factorial protective effects compared to isolated polyphenol supplements in periodontitis.

7. Conclusions and Recommendations

Periodontitis is a local inflammatory disease of the oral cavity associated with an increased risk for developing CVD, diabetes, and other chronic diseases, which highlights the urgent need to identify cost-effective population-level strategies for periodontitis prevention and treatment. Current data from cell biology and animal models and human clinical studies have demonstrated that selected dietary polyphenols have important antimicrobial, antioxidant, and anti-inflammatory properties resulting in improved clinical markers in periodontitis (Table 4 and Figure 1,). Dietary polyphenols are derived from a variety of sources such as curcumin in the commonly consumed turmeric and quercetin and catechins in green tea, fruits, and vegetables. Dietary polyphenols have been shown to effectively ameliorate gingival bleeding as well as alveolar bone loss in animals and human clinical studies by suppressing osteoclastogenesis and inhibiting inflammatory cytokines. While data from molecular studies are promising, further research is needed to learn about the effects of polyphenols for prevention and treatment of periodontal disease. The oral cavity, which is the first port of entry for foods andbeverages, is susceptible to their immediate local actions including detrimental effects that contribute to periodontitis. Therefore, the selection of polyphenols at each meal or snack in combination with adequate measures of standard oral hygiene care may play an important role in the prevention of periodontitis as well as other chronic inflammatory conditions that comprise this constellation of co-morbid conditions.

Author Contributions

Conceptualization, A.B. and J.L.E.; Methodology, A.B.; Writing—Original Draft Preparation, A.B.; Writing—Review & Editing, A.B., E.M. and J.L.E.; Visualization, A.B.; Supervision, J.L.E.; Project Administration, A.B.

Funding

This research received no external funding. The APC was funded by the School of Allied Health Sciences at UNLV.

Acknowledgments

We acknowledge the support of faculty and staff at the School of Allied Health Sciences and the School of Dental Medicine at UNLV in this collaboration.

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. Overview of the role of dietary polyphenols in the management of periodontitis.
Figure 1. Overview of the role of dietary polyphenols in the management of periodontitis.
Molecules 23 01786 g001
Table 1. Polyphenols as antioxidant/anti-inflammatory/antimicrobial agents in periodontitis: experimental cellular models.
Table 1. Polyphenols as antioxidant/anti-inflammatory/antimicrobial agents in periodontitis: experimental cellular models.
Study Design and ModelPolyphenolSignificant FindingsAuthor, Year
HPLC culture stimulated with LPS of P. gingivalisResveratrol (25, 50, and 100 µM) Molecules 23 01786 i001 NO expression by P. gingivalis in a dose-dependent and time-dependent mannerRizzo et al., 2012 [32]
F. nucleatum cultures in Todd-Hewitt broth70% ethanolic blueberry extract of varying concentrations (500, 250, 125, 62.5, 31.25, 15.62, and 7.9 μg/mL) Molecules 23 01786 i002 growth of F. nucleatum and biofilm formationBen Lagha et al., 2015 [27]
Human gingival epithelial cells grown in keratinocyte mediumEGCG (1 and 5 mg/mL) & AC-PCs (25 and 50 mg/mL) Molecules 23 01786 i003 release of several inflammatory cytokinesLombardo et al., 2015 [29]
P. gingivalis culture in sheep blood agarRA1 (1–100 μg/mL) containing flavan-3-ols, flavonoids, and oligomeric proantho cyanidins Molecules 23 01786 i004 adhesion of P. gingivalis to human KB cells due to the specific activity of galloylated oligomeric proanthocyanidins, inhibited gingipain activity, and inhibited P. gingivalis-induced hem agglutinationSchmuch et al., 2015 [30]
Bacterial cultures of S. mitis, A actinomycetemcomitans, P. gingivalis, and F. nucleatum Phenols and polyphenols from different classes including hydroxyl acids, flavanols, flavanones, anthocyanins, and phenolics (0.24–2500 μg/mL, depending on the compound) Molecules 23 01786 i005 planktonic growth, mostly by curcumin which was followed by pyrogallol, pyrocatechol, and quercetinShahzad et al., 2015 [26]
Normal human fibroblasts incubated with HSA, G-HSA, or P. gingivalis LPSCranberry high molecular weight NDM (10–50 μg/mL with HSA or G-HSA alone; 50 or 100 μg/mL with HSA, G-HSA, and LPS) Molecules 23 01786 i006 production of IL-6 and MMP-3Tipton et al., 2016 [50]
P. gingivalis strain cultivated in agar medium and brothL. brasiliense extract in water/acetone solution (50–500 μg/mL) Molecules 23 01786 i007 adhesion of P. gingivalis to human KB cells and the activity of Arg-gingipainDe Oliveira et al., 2017 [31]
F. nucleatum in Todd-Hewitt brothGreen tea (20 mg), black tea (10 mg), and theaflavins (20 mg) in solution Molecules 23 01786 i008 biofilm formationBen Lagha et al., 2017 [28]
AC-PC, A-type cranberry proanthocyanidins, EGCG, epigallocatechin gallate, G-HSA, glycated human serum albumin, HSA, human serum albumin, HPLC, human periodontal ligament cell, IL-6, interleukin-6; LPS, lipopolysaccharide, MMP-3, matrix metalloproteinase-3, NDM, non-dialyzable material, NO, nitric oxide; RA1, Rumex acetosa (common sorrel) extract. Symbol: downward arrow, decrease.
Table 2. Polyphenols as antioxidant/anti-inflammatory/antimicrobial agents in periodontitis: experimental animal models.
Table 2. Polyphenols as antioxidant/anti-inflammatory/antimicrobial agents in periodontitis: experimental animal models.
Study Design and ModelPolyphenolSignificant FindingsAuthor, Year
Adult male Sprague-Dawley ratsHypericum perforatum extract (2 mg/kg/day) administered orally Molecules 23 01786 i009 gingivomucosal tissue injury, alveolar bone loss, & expression of NF-κB p65Paterniti et al., 2010 [35]
E. coli-induced periodontitis in Lewis ratsSunphenon BG blend (91.3% polyphenols) administered topically to affected periodontal areas Molecules 23 01786 i010 periodontal detachment and bone resorptionYoshinaga et al., 2014 [36]
P. gingivalis induced periodontitis in BALB/c miceEGCG (0.02%) or vehicle (distilled water) in drinking water Molecules 23 01786 i011 inflammation e.g., IL-17, IL-1β vs. vehicleCai et al., 2015 [33]
Ligation-induced periodontitis in Wistar ratsHawthorn (Crataeus orientalis M Bieber) extract (100 mg/kg) vs saline administered orogastrically Molecules 23 01786 i012 osteoclast activity and subsequently ameliorated alveolar bone loss induced by periodontitisHatipoğlu et al., 2015 [55]
C57BL/J6 ovariectomized female miceLow or high dose (2 or 5 mg/kg/day) of myricetin, which is a polyphenol derived from fruits and vegetables, administered intraperitoneally vs. placebo Molecules 23 01786 i013 alveolar bone loss by inhibiting osteoclastogenesis induced by periodontitisHuang et al., 2016 [37]
Wistar ratsCurcumin (100 mg/kg), resveratrol (10 mg/kg), curcumin + resveratrol or resveratrol alone administered orogastrically Molecules 23 01786 i014 gingival IL-1β in curcumin+resveratrolCorrêa et al., 2017 [34]
P. gingivalis induced periodontitis in male C57BL/6J wild-type miceMangiferin (50 mg/kg) oral application Molecules 23 01786 i015 TNF-α production, phosphorylation in the NF-κB and JK-1 signal pathways, and alveolar bone lossLi et al., 2017 [38]
EGCG, epigallocatechin gallate, Hypericum perforatum, St. John’s Wart; IL, interleukin, JK-1, Janus kinase-1, NF-κB, nuclear factor-κB, Sunphenon BG, green tea extract, TNF-α, tumor necrosis factor-alpha. Symbol: downward arrow, decrease.
Table 3. Polyphenols as antioxidant/anti-inflammatory/antimicrobial agents in periodontitis: clinical studies.
Table 3. Polyphenols as antioxidant/anti-inflammatory/antimicrobial agents in periodontitis: clinical studies.
Study Design and ModelPolyphenolSignificant FindingsAuthor, Year
Pre-post intervention, healthy volunteers (n = 30; age 25–30 years)Pomegranate juice (30 mL) mouth rinse for 2 min Molecules 23 01786 i016 CFUs of both Streptococci and Lactobacillus spp.Kote et al., 2011 [43]
Crossover RCT, patients with chronic periodontitis (n = 60, age 30–60 years)Daily oral intake of 6 FV capsules, 6 FVB capsules, or placebo capsules for 2 months Molecules 23 01786 i017 PPD in FV compared with placeboChapple et al., 2012 [45]
Patients with chronic periodontitis (n = 30; age 38.9–10.67 years)Sustained-release green tea extract gel (1%) containing ECGC administered once Molecules 23 01786 i018 GI, PD, and rCALChava & Vedula, 2013 [47]
Patients with chronic periodontitis (n = 25; age 21–45 years)1% curcumin gel inserted into periodontal pockets with blunt syringe at intervals of 1, 3, and 6 months following the start of the study Molecules 23 01786 i019 Bacterial counts of P. gingivalis, P. intermedia, F. nucleatum, and Capnocytophaga spp.Bhatia et al., 2014 [44]
Crossover RCT; patients with moderate chronic periodontitis (n = 40, age 30–50 years)Oral intake 3 times a day for 4 weeks of 30 g dark chocolate with 78% cacao (containing flavonoids such as catechin and procyanidins) or white chocolate placebo w/o cacao Molecules 23 01786 i020 MPBI and lipid peroxidationRoodgaryan et al., 2015 [49]
Patients treated with root planning and scaling (n = 40, age ≥ 30 years)10% E. officinalis extract gel administered subgingivally once and parameters measured 2 and 3 months post-treatment Molecules 23 01786 i021 Inflammation, mSBI and PPDGrover et al., 2016 [46]
Patients with mild to moderate periodontitis (n = 30, age 18–60 years)Green tea extract dentifrice with 60–90% EGCG or placebo dentifrice with fluoride and triclosan, brushed onto teeth for 2–5 min daily for 4 weeks Molecules 23 01786 i022 gingival inflammationHrishi et al., 2016 [48]
CAL, clinical attachment level, CFUs, colony-forming units, EGCG, epigallocatechin gallate; FV, fruit/vegetable-containing capsules, FVB, fruit/vegetable/berry-containing capsules, GI, gingival index, GST, glutathione-S-transferase, MPBI, modified papillary bleeding index, mSBI, modified sulcus bleeding index, PD, probing depth, PPD, probing pocket depth, rCAL, relative clinical attachment level, RCT, randomized clinical trial, TAC, total antioxidant capacity. Symbol: downward arrow, decrease.
Table 4. Summary of mechanisms of action of dietary polyphenols in periodontitis.
Table 4. Summary of mechanisms of action of dietary polyphenols in periodontitis.
PolyphenolMechanisms of Action
ResveratrolReduces NO expression by P. gingivalis bacteria by inhibiting inflammatory cytokines and improving viability of affected HPLCs [32]
Blueberry flavonoids, phenolic acids, and procyanidins e.g., chlorogenic acid, ellagic acid, quercetin, anthocyanins, and proanthocyanidinsReduce bacterial growth and biofilm formation via antibacterial, inhibitory effects against Gram-negative bacteria such as F. nucleatum [26,27,30]
EGCGInhibits release of inflammatory cytokines (IL-17, IL-1β) by modulating gene expression pathways (e.g., NF-κB), and decreasing inflammation/oxidation by increasing the activity of GST [33,48]
RA1Inhibit adhesion of bacteria through a specific activity of galloylated oligomeric proanthocyanidins [30]
CurcuminInhibits planktonic growth by decreasing metabolic activity of bacterial species [44]
Curcumin + ResveratrolReduces gingival IL-1β and inhibits NF-κB, which lowers proteasome activity and resulting cell damage and inflammation [34]
PyrogallolInhibits planktonic growth by reducing biomass of planktonic films [26]
PyrocatecholInhibits planktonic growth by reducing biomass of planktonic films [26]
QuercetinInhibits planktonic growth by reducing biomass of planktonic films [26]
Cranberry flavonoids and proanthocyanidinsInhibit IL-6 production and MMP-3 by suppressing the NF-κB and MAPK/AP-1 signaling pathways [50]
L. brasiliense flavan-3-ols and proanthocyanidinsReduce adhesion of P. gingivalis to human KB cells by inhibiting Arg-gingipain activity [30,31]
Tea polyphenols e.g., theaflavinsInhibit biofilm formation and adhesion of pathogens to the oral mucosa likely by binding to receptors in the bacterial cell wall [27,28]
Hypericum perforatum flavonoids and phenolic acidsInhibits inflammatory cytokine production by suppressing NF-κB p65 pathway and reducing NO expression by pathogenic bacteria through the suppression of the iNOS system [35]
MyricetinReduces alveolar bone loss by inhibiting osteoclastogenesis [37]
MangiferinSuppresses TNF-alpha production and inhibits phosphorylation of NF-κB and JK-1 pathways, which inhibits production of inflammatory cytokines and alleviates tissue injury [38]
Pomegranate phenolic compoundsReduces number of pathogenic Streptococci and Lactobacilli pathogens and inhibits the formation of colony units [43]
Cacao flavonoidsDecrease lipid peroxidation and improve gingival bleeding [49]
E. officinalis flavonoids, phenols, and tanninsMay reduce inflammation by suppressing the action of histamine, serotonin, prostaglandins, and other inflammatory mediators [46]
AP-1, activator protein-1, EGCG, epigallocatechin gallate, GST, glutathione-S-transferase, HPLC, human periodontal ligament cell, IL-1β, interleukin-1β, IL-6, interleukin-6, IL-17, interleukin-17, iNOS, inducible nitric oxide synthase, JK-1, Janus-kinase 1 pathway, MAPK, mitogen-activated protein kinases, MMP-3, matrix metalloproteinase-3, NF-κB, nuclear factor-κB, NO, nitric oxide, RA1, rumex acetosa extract (polyphenol), TNF-alpha, tumor necrosis factor-alpha.

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Basu, A.; Masek, E.; Ebersole, J.L. Dietary Polyphenols and Periodontitis—A Mini-Review of Literature. Molecules 2018, 23, 1786. https://0-doi-org.brum.beds.ac.uk/10.3390/molecules23071786

AMA Style

Basu A, Masek E, Ebersole JL. Dietary Polyphenols and Periodontitis—A Mini-Review of Literature. Molecules. 2018; 23(7):1786. https://0-doi-org.brum.beds.ac.uk/10.3390/molecules23071786

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Basu, Arpita, Emily Masek, and Jeffrey L. Ebersole. 2018. "Dietary Polyphenols and Periodontitis—A Mini-Review of Literature" Molecules 23, no. 7: 1786. https://0-doi-org.brum.beds.ac.uk/10.3390/molecules23071786

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