Abstract
Objectives
To examine the effect of Nystatin oral rinse on oral Candida species and Streptococcus mutans carriage.
Materials and methods
Twenty healthy adults with oral candidiasis participated in the single-arm clinical trial and received Nystatin oral rinse for 7 days, 4 applications/day, and 600,000 International Units/application. Demographic-socioeconomic-oral-medical conditions were obtained. Salivary and plaque Candida species and Streptococcus mutans were assessed at baseline and 1-week and 3-month follow-ups. Twenty-four salivary cytokines were assessed. Candida albicans isolates underwent Nystatin susceptibility test.
Results
Half of participants (10/20) were free of salivary C. albicans after using Nystatin rinse. Salivary S. mutans was significantly reduced at 3-month follow-up (p < 0.05). Periodontal status reflected by bleeding-on-probing was significantly improved at 1-week and 3-month follow-ups (p < 0.05). Plaque accumulation was significantly reduced at 1-week follow-up (p < 0.05). Interestingly, the responses to Nystatin oral rinse were not associated with race, gender, age, oral hygiene practice, adherence to Nystatin rinse, or sweet consumption (p > 0.05). No C. albicans isolates were resistant to Nystatin. Furthermore, salivary cytokine eotaxin and fractalkine were significantly reduced at 3-month follow-up among participants who responded to Nystatin rinse (p < 0.05).
Conclusions
The study results indicate that oral antifungal treatment had an effect on S. mutans salivary carriage. Future clinical trials are warranted to comprehensively assess the impact of antifungal treatment on the oral flora other than S. mutans and Candida.
Clinical relevance
Due to the potential cariogenic role of oral Candida species, antifungal approaches shed new light on the prevention and management of dental caries from a fungal perspective.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Oral candidiasis is the most common fungal infection, with overgrowing Candida species in the superficial epithelium of the oral mucosa [1]. Among the oral Candida species, Candida albicans is the most prevalent fungal species that can cause oral candidiasis. Other Candida species often detected less frequently in the oral cavity include C. tropicalis, C. guilliermondii, C. glabrata, C. parapsilosis, C. dubliniensis, and C krusei [2]. C. albicans and oral bacteria have well-documented symbiotic relationships in oral mucositis, periodontal diseases, implant-related infections, and oral cancer [3]. Polymicrobial interactions between C. albicans and oral microbes affect the biofilm’s cellular and biochemical composition, which influences clinically relevant outcomes of biofilm-related oral diseases such as pathogenesis, virulence, and drug resistance [3, 4]. The interactions between C. albicans and coexisting oral bacteria occur through physical attachment, extracellular signals, and metabolic cross-feeding [3, 5].
Dental caries is a chronic infectious disease defined as the local destruction of dental hard tissues by acidic by-products from bacterial fermentation of dietary carbohydrates [6]. While Streptococcus mutans and Lactobacillus species have traditionally been considered the prime microbial risk markers and preventive targets for dental caries [7], recent research on the role of Candida species in caries and its synergistic interaction with S. mutans has shed new light on potential fungus-focused approaches to early prediction and subsequent prevention of dental caries.
The presence of Candida species in the oral cavity is usually found to be positively correlated with poor oral hygiene and high carbohydrate intake [8]. The following scientific evidence supports its potential cariogenic role: (a) Candida species (especially C. albicans) have often been detected at higher levels in the oral cavity of children with caries, compared to caries-free children [7, 9,10,11], and are positively correlated with caries severity [12]. A recent meta-analysis showed that children with oral C. albicans had 5-time greater odds of experiencing caries than children without this yeast strain. Similar findings have been reported among the adult population in our recent study [13]. (b) Our cross-sectional study [12] reported that the oral C. albicans carriage is also positively correlated with S. mutans carriage and a more cariogenic oral microbiota among individuals with caries. (c) Laboratory findings have added plausible biological evidence of the cariogenic traits of C. albicans. C. albicans is (a) acidogenic and aciduric [14, 15]; (b) capable of dissolving the major tooth component, hydroxyapatite, at an approximately 20-fold rate higher than S. mutans [16]; (c) capable of increasing S. mutans cells in biofilms through a unique C. albicans-S. mutans adhesive interaction [17, 18] that is mediated by extracellular polysaccharides (EPS) formation [17,18,19]; (d) enhancing the virulence of S. mutans when grown in S. mutans-C. albicans duo-species biofilm setting, with upregulated expression of genes that are related to microbial metabolism and cariogenicity, such as gtfB, gtfC, and gtfD [20]; and (e) capable of enhancing virulence and causing more severe caries when co-infected with S. mutans in a rodent model [17].
Due to the potential cariogenic role of oral Candida species and the synergistic interaction between oral Candida and cariogenic bacteria S. mutans, a hypothetic regimen to prevent and treat dental caries would be reducing the carriage of oral Candida by administering an antifungal medication and subsequently reduce the cariogenic interaction between Candida and cariogenic bacteria.
A recent study assessed the effect of fluconazole and povidone-iodine (PI) on inhibiting C. albicans and cariogenic bacteria in vitro and in an animal model [21]. This study indicated that a combination of fluconazole and PI has a moderate killing effect against S. mutans and lead to oral microbiota changes in rats [21]. In addition, the study revealed that added PI might enhance the antifungal activity of fluconazole while disrupting biofilm exopolysaccharide and S. mutans microcolony formation, reducing the bulk and density of infection in the animal model.
However, fluconazole is a systemic antifungal medication, and has not been routinely prescribed to treat oral candidiasis. Instead, Nystatin is considered the first-line medication for treating uncomplicated oral candidiasis [1]. Each 1 mL of Nystatin oral suspension contains 100,000 International Units (IU) of Nystatin and the following components: sodium carboxymethylcellulose, methyl p-hydroxybenzoate (E218), propyl p-hydroxybenzoate (E216), sodium metabisulphite (E223), sucrose, saccharin sodium, sodium citrate, permaseal aniseed flavor, and purified water [22]. The recommended dose of Nystatin ranges from 100,000 to 200,000 IU, four times/day for newborns/infants, and 200,000 to 600,000 IU, four times/day for children and adults [23].
Intriguingly, our recent study has shown that Nystatin application altered the formation and characteristics of C. albicans and S. mutans duo-species biofilms in an in vitro setting [24]. Even though Nystatin is the most commonly used antifungal medication to treat oral candidiasis, no studies have assessed the effect of Nystatin oral application on the carriage of S. mutans and other oral microorganisms in vivo. Therefore, the purpose of this clinical trial was to evaluate the effect of oral application of Nystatin suspension on oral microorganisms, including the fungal and bacterial communities, with an emphasis on cariogenic bacteria. The study results could lead to a better understanding of whether the oral antifungal treatment affects the carriage of oral cariogenic microorganisms.
Materials and methods
Study design
A single-arm non-randomized clinical trial was conducted among twenty study participants who met the inclusion and exclusion criteria at the Eastman Institute for Oral Health, University of Rochester. The study protocol was approved by the University of Rochester Research Subject Review Board (#STUDY00004638). This study is registered at the Trials.gov (#NCT04550546). This study followed the Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) reporting guideline.
Participants
Study participants were recruited from the existing pool of patients at the University of Rochester Medical Center (URMC) Eastman Institute for Oral Health (EIOH) clinics and from the larger community at Rochester NY.
The inclusion criteria include (a) 18 years and older; (b) positive oral Candida detection with sufficient oral Candida burden to meet the laboratory criteria for a diagnosis of oral candidiasis, ≥ 400 colony forming unit (CFU)/mL of salivary Candida [25]; and (c) ≥ 10,000 CFU/mL of S. mutans in the saliva.
The exclusion criteria include (a) visible signs of candidiasis on the mucosa or tongue at screening; (b) with systemic diseases, such as HIV, cancer, or diabetes; (c) history of using local (oral) or systemic antibiotics or antifungal medication within the last 3 months; and (d) women who are currently pregnant or reported that she is currently breast feeding. A pregnancy test (urine test) was conducted to exclude participants who are pregnant; (e) with more than 8 missing teeth (third molars and orthodontically extracted teeth are not included); (f) with more than 4 decayed teeth; (g) with removable dental prosthesis that are used to restore missing teeth; and (h) allergy to Nystatin.
Study procedures
Study participants who entered the trial were instructed to rinse the mouth with (6 ml of 100,000 IU/mL) Nystatin suspension, without swallowing the suspension, at the frequency of four times per day (every 6 h) for 1 week. The Investigational Drug Services dispensed the Nystatin oral suspension at the University of Rochester Medical Center. The Nystatin suspension bottle was returned to quantify the unused quantity of Nystatin and assess the adherence to measure. In addition, a treatment adherence log was filled out by the study participants.
Study flow
The study flow is demonstrated in Fig. 1. The study participants were assessed at 3 time points: (1) baseline visit (V1), (2) 1 week after the completion of Nystatin oral rinse (V2), and (3) 3 months after the completion of Nystatin oral rinse (V3).
Data collection and examination
At the baseline visit, data on demographic and socioeconomic background were collected using a questionnaire. Data on the medical background and medications were self-reported and confirmed by electronic medical records. The medical background included (1) physician-diagnosed systemic diseases (Y/N), such as hypertension, diabetes, asthma, anxiety, depression, and kidney disease; (2) medications that subjects were taking at the baseline study visit; and (3) smoking status (Y/N). The oral hygiene practice was collected using a questionnaire.
The comprehensive examination was performed at the baseline and each study visit by a dentist in a dedicated examination room at the URMC, using standard dental examination equipment, materials, and supplies. Caries was scored using DMFT (decayed, missing, and filled teeth).
Periodontal parameters
Bleeding on probing (BOP) was evaluated to assess the gingival inflammation. The periodontal tissue was assessed to the bottom of the clinical pocket or sulcus with a periodontal probe. Interproximal sites for every existing tooth, except the third molars, were scored from the buccal and the lingual sides [26]. Dental plaque accumulation was assessed using the Plaque Index (PI) described by Löe [27]. Each of the four gingival areas of the tooth was given a score of 0–3. A score of 0 indicates no plaque in the gingival area; a score of 1 indicates the presence of a film of plaque adhering to the free gingival margin; a score of 2 indicates moderate accumulation of soft deposits within the gingival pocket, on the gingival margin, and or adjacent tooth; and a score of 3 indicates an abundance of soft matter within the gingival pocket and or on the gingival margin and adjacent tooth structure.
Saliva and plaque sample collection
Methods used for saliva and plaque sample collection were detailed previously [12, 13]. Approximately 2 ml of whole non-stimulated saliva samples were collected by spitting into a sterile 50 ml centrifuge tube. Study subjects were instructed not to eat, drink, or brush their teeth 2 h before the oral sample collection prior to their study visit. Supragingival plaques from the whole dentition were collected using a sterilized periodontal scaler. The plaque samples were suspended in 1 ml of a 0.9% sodium chloride solution in a sterilized Eppendorf tube.
Identification and quantification of Candida spp. and S. mutans
The clinical samples (saliva and plaque) were stored on ice and transferred to the lab located at the Center for Oral Biology, UR, within 2 h for laboratory testing. The saliva and plaque sample were gently vortexed and sonicated to break down the aggregated plaque before plating. The sonication cycle was repeated three times, with 10-s sonication and 30-s rest on ice. BBL™ CHROMagar™ Candida (BD, Sparks, MD, USA) was used to isolate and identify C. albicans. S. mutans was isolated using Mitis Salivarius with Bacitracin selective medium and identified by colony morphology [28, 29]. Both Candida spp. and S. mutans were incubated at 37 °C, 5% CO2, for 48 h before identification. Colony PCR was used for a further identification of those Candida spp. and S. mutans that were unable to be identified by colony morphology [30]. The CFU values of Candida spp. and S. mutans on each plate were recorded.
Susceptibility of C. albicans isolated to Nystatin in vitro
Antifungal susceptibility testing was performed according to the Clinical and Laboratory Standards Institute (CLSI) M27-A3 broth microdilution method using (RPMI 1640; Gibco) growth medium (with glutamine and without bicarbonate). The medium was buffered with 3-(N-morpholino) propanesulfonic acid (MOPS: Fisher Scientific) at a pH of 7.0 and to a final concentration of 0.165 mol/l. Clinical isolated C. albicans were recovered from frozen stock using Yeast Peptone Dextrose Agar (YPD) and incubated overnight at 37 °C with 5% CO2. The antifungal agent tested was Nystatin (VWR International, Sanborn, NY, USA). A stock drug was prepared (100 times the higher concentration) and aliquots in small volumes for future use. Two-fold serial dilutions were prepared, yielding final concentrations ranging from 0.06 to 32 ug/ml. The yeast inoculums were prepared by picking up young colonies of appropriate size from the 24-h old fresh cultures and suspending them in 5 mL of RPMI 1640 medium. The resulting suspension cell density was adjusted to 0.5 McFarland standard, corresponding to a stock inoculum of 1–5 × 106 CFU/ml. Alternatively, the cells were counted using a hemocytometer. The suspension was diluted twice: first 1:20 and then 1:50 with RPMI medium to obtain a final working density of 1–5 × 103 CFU/ml. Subsequently, 100 ul of this working inoculum solution and 100 ul of antifungal solution (at a working concentration twice higher than the desired final concentration) were seeded into a sterile, disposable, flat-bottomed flat 96-well plate (Greiner Bio-One). In each well, the final inoculum concentration was 0.5–2.5 × 103 CFU/ml. The 96-well plates were incubated in ambient air without agitation at 35 °C and read spectrophotometrically at 600 nm after 24 h and 48 h using a 96-well microtiter plate reader (infinite M200 PRO, Tecan). In the case of the spectrophotometer readings, the MIC50 and MIC90 were determined. C. albicans SC 5314 was used as a reference for quality control in all the experiments.
Susceptibility to Nystatin was assessed using the MIC of each isolate. The isolates were classified as susceptible (S), susceptible dose-dependent (SDD), and resistant (R) and expressed visually as heatmaps. The interpretive criteria used were according to CLSI guidelines: Nystatin: resistant ≥ 16 ug/ml.
Salivary cytokine level
Cytokine/chemokine assessment for 24 analytes was performed in the University of Rochester Human Immunology Center Core Lab facility on saliva samples collected at 4 time points (baseline, 1 week, and 3 months after Nystatin rinse). Samples were centrifuged for 5 min at 125,000 rcf at 4 °C prior to incubation of the sample at neat concentration overnight at 4 °C in two multiplexed magnetic bead array assays; an 17-Plex Milliplex MAP high-sensitivity human cytokine panel (Cat#HSTCMAG-28SK) for GM-CSF, IFNg, IL-1B, IL-2, IL-4, IL-5, IL-6, IL-7, IL-8, IL-10, IL-12(p70), IL-17A, IL-21, IL-23, ITAC, Fractalkine, and TNFa; and a 7-Pex Milliplex MAP human cytokine/chemokine panel (Cat#HCYTOMAG-60 K) for Eotaxin, IL-1a, IL-1RA, IL-15, IP-10, MDC, and MCP-1. Both assays were performed following kit instructions and read on a Luminex 200 instrument. Results were reported in pg/mL based on standard curve values.
Statistical analysis
We grouped the study participant into two groups (responded and did not respond to Nystatin oral rinse) based on their salivary C. albicans status at the 1-week follow-up visit. The characteristics of the study participants from these two groups were compared using t-test for normal distributed continuous data (age, DFMT, and DMFS), Mann–Whitney U test for non-normal distributed data (weighted and non-weighted sweet/non-sweet indices), and chi-square or Fisher’s exact tests for categorical data including demographic characteristics (race, ethnicity, education level, marital status), medical background (hypertension, allergy to penicillin, long-term use of antibiotics, and smoking), oral health condition (tooth brushing frequency and use of nightguard), and detection of non-albicans Candida species. The Wilcoxon matched-pair signed-rank test was used to compare the changes of oral health conditions (BOP and PI) between the follow-up visits and baseline visit. Pair-wise t-test was used to compare the carriage of S. mutans (converted to natural log value), C. albicans (converted to natural log value), and salivary cytokines (converted to natural log value) between the follow-up visits and baseline visit. A multivariate logistic regression was used to analyze the factors (race, gender, ethnicity, age, educational level, hypertension, smoking, tooth brushing frequency, night guard usage, adherence to Nystatin rinse, weighted sweet index, and non-sweet index) associated with the response to Nystatin oral rinse. Response to oral rinse is defined as no detection of C. albicans in saliva at the 1-week follow-up visit. All statistical tests were two-sided with a significant level of 5%. SPSS IBM was used for statistical analyses.
Results
The demographic-socioeconomic-medical-oral conditions information are shown in Table 1. A total of one hundred participants were screened, and twenty participants who met the inclusion and exclusion criteria advanced to the clinical trial. All study participants completed the baseline visits. Nineteen participants completed the 1-week and 3-month follow-up visits. One participant withdrew due to reported side effect of using Nystatin oral rinse and did not complete the 7-day rinse and the 1-week and 3-month follow-up visits. Based on whether C. albicans was detected at 1-week follow-up visit, we grouped the participants into did not respond group (C. albicans + at V2) and responded group (C. albicans– at V2). No statistical differences were seen between participants in these two groups, regarding age, gender, race, ethnicity, education level, employment status, marital status, medical conditions, smoking status, and oral health status (p > 0.05).
Adherence to Nystatin rinse
Participants were instructed to rinse with 6 mm of 100,000 IU/ml Nystatin oral suspension, four times per day for 7 days, with a total of 28 applications. The mean number of medication usage among participants was 24.4 ± 4.8 doses, where 8 participants completed all doses as instructed, 5 missed less than 10% of the doses, 5 missed 11–20%, and 3 participants missed 40–60% of the doses. Only one participant complained of mild side effects that cleared up shortly (nausea and sore throat) after taking the third dose on the third day. The participant was instructed to stop taking the medication, and a follow-up appointment was scheduled for further evaluation.
Oral C. albicans carriage following Nystatin oral rinse
The changes of salivary and plaque C. albicans are shown in Fig. 2. The participants who responded to Nystatin oral rinse had a salivary carriage of C. albicans of 2.0 ± 3.6 × 102 CFU/ml at the baseline, a total elimination of salivary C. albicans at the 1-week follow up, and a lightly bounced back salivary C. albicans carriage to 3.4 ± 6.0 × 102 CFU/ml at 3-month follow-up. The reduction of salivary C. albicans between the baseline and follow-up visits was statistically significant (p < 0.05) (Fig. 2A). Reduction of plaque C. albicans was seen following Nystatin rinse among the same participants; however, no statistical differences were detected between the follow-up and baseline visits (p > 0.05).
The participants who did not respond to Nystatin oral rinse had a salivary carriage of C. albicans of 1.4 ± 3.2 × 103 CFU/ml at baseline visit and 6.4 ± 19 × 104 and 1.3 ± 3.7 × 102 CFU/ml at 1-week and 3-month follow-ups, respectively (Fig. 2A). Plaque C. albicans carriage was 2.0 ± 4.1 × 105 CFU/ml at baseline, decreased to 1.2 ± 2.3 × 102 CFU/ml at 1-week follow-up, and bounced back to 1.2 ± 3.6 × 105 CFU/ml at 3-month follow-up (Fig. 2B).
Interestingly, we found that the responses to Nystatin oral rinse among the study participants was not associated with any of the independent variables tested, such as race, gender, age group, oral hygiene practice, adherence to Nystatin rinse, or sweet consumption (p > 0.05).
Oral S. mutans carriage following Nystatin oral rinse
The changes of salivary and plaque S. mutans are shown in Fig. 3. We observed an overall salivary S. mutans carriage of 7.5 ± 10.1 × 105 CFU/ml at the baseline and a significantly decrease to 5.7 ± 8.0 × 105 CFU/ml at 3-month follow-up (p < 0.05) (Fig. 3A).
Among participants who responded to Nystatin rinse, a reduction in salivary S. mutans was observed in 1-week and 3-month follow-ups comparing to baseline 8.5 ± 4.7 × 105 CFU/ml, 7.5 ± 5.7 × 105 CFU/ml, and 5.7 ± 3.6 × 105 CFU/ml, respectively. However, no statistical differences were detected between the follow-up and baseline visits in both groups (p > 0.05) (Fig. 3A). Similar trend of S. mutans reduction in plaque samples was also observed among participants who responded to Nystatin rinse; however, no statistical significance was found (p > 0.05).
The participants who did not responded to Nystatin oral rinse had a carriage of 3.7 ± 4.1 × 105 CFU/ml S. mutans in plaque samples at the baseline and a slight reduction of S. mutans carriage to 1.7 ± 4.1 × 105 CFU/ml at 3-month follow-up. However, changes were not statistically significant (p > 0.05) (Fig. 3B).
Periodontal status following Nystatin oral rinse
We used BOP and PI to assess the periodontal status and plaque control of participants. The changes of BOP sites and plaque index are shown in Fig. 4. At the baseline visit, the number of BOP sites was 4.3 ± 4.2. The BOP sites were reduced to 2.4 ± 3.5 at the 1-week follow-up and to 2.4 ± 2.3 at the 3-month follow-up (p < 0.05) (Fig. 4A). The plaque accumulating measured by PI was also significantly reduced (Fig. 4B), with a statistical significance between the baseline and 1-week follow-up visit (p < 0.05).
Susceptibility of C. albicans clinical isolates to Nystatin in vitro
No isolates of C. albicans were resistant to in vitro Nystatin susceptibility tests. The value of MIC50 ranges from 0.03 to 0.06 ug/ml, and the value of MIC90 ranges from 0.06 to 0.23 ug/ml.
Changes of salivary cytokines following Nystatin oral rinse
Among 24 cytokines assessed in saliva, 13 were detected with valid value across the study participants. We found that the levels of Eotaxin and Fractalkine were significantly reduced at 3-month follow-up among participants who responded to Nystatin rinse (p < 0.05) (see Fig. 5A-1 and C-1). Worth noting, the changes were not seen among the individuals who did not respond to Nystatin rinse (Fig. 5A-2 and C-2). In contrast, salivary level of macrophage-derived chemokine (MDC) among participants who did not respond to Nystatin rinse had an elevation at 1-week follow-up compared to the baseline visit (Fig. 5B-2). No statistical differences were detected among other salivary cytokines (values of 13 cytokines; see Table S1).
Discussion
Candida carriage and diagnostic criteria
Candida species frequently present in the normal flora of the oral cavity without causing clinical symptoms of candidiasis [31]. The oral Candida carriage ranges from 20 to 75% in the general population but is typically around 45% in the neonates, 45–65% in healthy children, 30–45% in healthy adults, and 50–65% in adults wearing removable dentures [32,33,34,35,36]. Oral Candida becomes pathogenic when the oral flora change occurs under the change of specific host factors [37]. These factors include impaired salivary gland function, denture wearing, long-term use of broad-spectrum antibiotics, corticosteroids and antidepressants, patients with diabetes mellitus, renal failure, hyperthyroidism, cancer, and HIV infection [38,39,40].
Oral candidiasis is often diagnosed upon patient-reported symptoms and clinical manifestations, such as a white coating on the tongue and white or red patches on the cheek mucosa. Oral candidiasis could also be diagnosed based on the laboratory assay [41]. One of the laboratory criteria for diagnosing oral candidiasis is the presence of ≥ 400 colony forming units (CFU)/mL of salivary Candida, even without clinical symptoms [25].
Factors associated with recurrent oral Candidiasis and failed response to Nystatin rinse
Host factors
It has become evident that virulence factors are associated with the shift of C. albicans from being harmless commensal to pathogenic organism inside the oral cavity [42]. Besides, other host-related factors, such as compromised autoimmunity, tobacco consumption, hyposalivation, denture wearing, systemic disease, and medication, were found critical in developing oral candidiasis [43]. Therefore, the outcomes of clinical interventions may differ depending on these host-related factors and their severity. For example, the emergence of antifungal resistance is observed more frequently among HIV patients receiving long-term azole therapy [44]. Under the circumstance that host factors are unable to modify, such as administration of antifungal treatment among immunocompromised patients and patients with malignancies, oral candidiasis could be intervened by administering systemic antifungal agents, followed by prophylactic antifungal treatment [45].
Microbial factors
Another phenomena associated with response to antifungal treatment is the presence of non-albicans species, particularly C. glabrata and C. parapsilosis; these species could contribute to the onset of oral candidiasis and the development of resistance against antifungal medications [46]. Furthermore, the resistance of C. Krusei and C. glabrata against fluconazole has been reported [47]. As a result, a new class of antifungal agents, Echinocandin, has been designed to overcome the issue of fungal resistance [48]. Thus, determining the Candida species that are responsible for the disease via culturing and drug-susceptibility tests is critical for successful antifungal treatment.
Medication factors
In the 1950s, Nystatin and amphotericin B were first invented to treat oral candidiasis. They are supplied in different forms, including pastilles, lozenges, suspension, troches, suppositories, and coated tablets. However, utilizing the appropriate form of Nystatin and amphotericin B is essential to obtain the optimum outcomes. As these two agents cannot be absorbed from the gastrointestinal tract, it is not advised to swallow them orally as tablets [49]. Instead, sucking and dissolving these agents inside the oral cavity could effectively treat oral candidiasis. This approach allows topical application of the agent, where the agent is applied to the infected area. Doubling the application time of Nystatin or topical amphotericin B has been suggested to improve the clinical efficiency of the treatment. However, prolonging the treatment duration may not be convenient for the patient due to taste intolerance, which may compromise the patients’ compliance [50]. Therefore, the oral care provider should instruct the patient to use the treatment properly to prevent infection recurrence.
S. mutans reduction following Nystatin rinse
Our study suggested that the S. mutans carriage was reduced following Nystatin treatment. Several possible mechanisms could explain this reduction. Many studies show that the coexistence of C. albicans and S. mutans may increase biofilm (plaque) virulence and intensify the severity of the disease [17, 21, 51]. For instance, faster onset of disease, higher number, and more severe smooth-surface lesions were observed with C. albicans with S. mutans growing together in the presence of sucrose compared to infection with either organism alone in an animal model [17]. The associated pathogenicity appears to be related to the S. mutans-derived exoenzyme glucosyltransferase B (GtfB), a key exopolysaccharide (EPS) producer. GtfB can bind to the surface of C. albicans cells in an active form and produce EPS locally that provide enhanced binding sites for S. mutans, which in turn promote the formation of biofilms containing elevated EPS amounts and high numbers of S. mutans and C. albicans [17, 18, 52].
Association between Candida and periodontal disease
Several studies revealed an association between Candida species and periodontal disease, for instance, an increased number of Candida species, particularly C. albicans, in patients with chronic periodontitis patients, when comparing to patients with healthy periodontium [53]. Although the exact pathogenic mechanism by which Candida contribute to periodontal disease progression remains unclear, Candida virulence factors such as adhesion, invasion, dimorphism, and biofilm formation of Candida have been suggested involved in the pathogenesis [54]. One of the main proposed pathogenic mechanisms is that C. albicans may have a role in periodontal microbial plaque infrastructure and its adherence to the periodontal tissues [55]. Candida was typically found in the outer layers of the plaque and appeared to act as a barrier between the host immunity and the inner layers of the mixed biofilm [55]. Therefore, C. albicans could have a role in the immune evasion of the plaque in periodontal infections and in stimulating destructive inflammation in the underlying tissues. In our study, the improved periodontal parameters such as plaque index and bleeding index and reduced plaque accumulation among study participants could be due to the phenomena described above. However, since this study did not assess the periodontal pocket depth, we are not able to comprehensively assess the changes in the periodontal status of the study participants.
Salivary immune marker changes following Nystatin rinse
Interestingly, our results revealed a reduction of salivary cytokine/chemokine eotaxin among participants who responded to oral rinse and did not have C. albicans at 1-week and 3-month follow-ups. Chemokines are secretory proteins involved in several biological functions, such as direct migration of leukocytes, activation of immune responses, tumor behavior modulation through tumor-associated angiogenesis, tumor cell proliferation, and innate and adaptive host responses [56]. Human eotaxin is a 74 amino acid polypeptide, non-glycosylated protein chemokine, expressed by various cells, including endothelial cells, epithelial cells, broncho-alveolar macrophages, lung and dermal fibroblasts, smooth muscle cells, and chondrocytes [57]. Eotaxins bind to the CCR3 receptor (CC chemokine receptor 3) and selectively recruit eosinophils [58]. In addition to recruiting, it aggregates eosinophils and is also a chemoattractant for eosinophils, basophils, helper T cells, macrophages, and mast cells. Increased circulating eosinophils are pathognomonic characteristics for several allergic and inflammatory disorders and malignancies. Eotaxins can stimulate the migration of eosinophils from blood plasma to tissues through CCR3 activation [58]. As a result, they are implicated in the pathogenesis of several allergic conditions (atopic dermatitis, allergic rhinitis, and asthma), inflammatory diseases (inflammatory bowel disease, ulcerative colitis, Crohn’s disease, eosinophilic gastroenteritis, chronic sinusitis, nasal polyposis), as well as malignancies (Hodgkin’s lymphoma and leukemia) [58]. Studies have reported using salivary proteins as biomarkers that could help classify caries susceptibility in an individual. Paque and colleagues analyzed saliva samples from healthy/gingivitis, caries-affected/ gingivitis, and caries-affected/healthy patients for cytokines, chemokines, growth factors, and proteolytic enzymes as oral microbiomes. Four potential salivary biomarkers were identified (IL-4, 13, 2-ra, and chemokine eotaxin/CCl11) as discriminatory and could be used to determine the caries susceptibility of individuals. All four biomarkers for caries-affected patients were observed, including chemokine eotaxin (1.7 pg/mL ± 0.9 in a patient with deep caries) [59]. Reduced status of eotaxin among participants who were free of Candida might indicate an altered immune status and reduced risk for caries.
Study limitation
The following limitations need to be considered when interpreting our study results: (1) single-arm study with no control group, (2) limited sample size, and (3) the study was only conducted in one US city. Thus, generalization to other populations is unreliable.
Future direction and next step
Microbiome study to assess the effect on oral microbial changes.
Conclusions
Our study results indicate that oral antifungal treatment may positively affect the carriage of oral cariogenic microorganisms, dental plaque formation, and periodontal status evaluated by bleeding on probing. However, future clinical trials are warranted to comprehensively assess the impact of antifungal treatment on the oral flora other than S. mutans and Candida.
Data availability
The data presented in this study are included in the manuscript and supplement table.
References
Lyu X, Zhao C, Yan Z-M, Hua H (2016) Efficacy of nystatin for the treatment of oral candidiasis: a systematic review and meta-analysis. Drug Des Devel Ther 10:1161
Urizar JMA (2002) Candidiasis orales. Rev Iberoam Micol 19:17–21
Du Q, Ren B, Zhou X, Zhang L, Xu X (2022) Cross-kingdom interaction between Candida albicans and oral bacteria. Front Microbiol 13:911623
Shirtliff ME, Peters BM, Jabra-Rizk MA (2009) Cross-kingdom interactions: Candida albicans and bacteria. FEMS Microbiol Lett 299(1):1–8
Koo H, Andes DR, Krysan DJ (2018) Candida-streptococcal interactions in biofilm-associated oral diseases. PLoS Pathog 14(12):e1007342
Kidd EA, Fejerskov O (eds) (2003) Dental caries: The disease and its clinical management. Blackwell Munksgaard
de Carvalho FG, Silva DS, Hebling J, Spolidorio LC, Spolidorio DM (2006) Presence of mutans streptococci and Candida spp. in dental plaque/dentine of carious teeth and early childhood caries. Arch Oral Biol 51(11):1024–1028
Odds FC (1997) Mycology in oral pathology. Acta Stomatol Belg 94(2):75–80
Xiao J, Huang X, Alkhers N, Alzamil H, Alzoubi S, Wu TT, Castillo DA, Campbell F, Davis J, Herzog K (2018) Candida albicans and early childhood caries: a systematic review and meta-analysis. Caries Res 52(1–2):102–112
Qiu R, Li W, Lin Y, Yu D, Zhao W (2015) Genotypic diversity and cariogenicity of Candida albicans from children with early childhood caries and caries-free children. BMC Oral Health 15(1):144
Al-Ahmad A, Auschill TM, Dakhel R, Wittmer A, Pelz K, Heumann C, Hellwig E, Arweiler NB (2016) Prevalence of Candida albicans and Candida dubliniensis in caries-free and caries-active children in relation to the oral microbiota-a clinical study. Clin Oral Invest 20(8):1963–1971
Xiao J, Moon Y, Li L, Rustchenko E, Wakabayashi H, Zhao X, Feng C, Gill SR, McLaren S, Malmstrom H et al (2016) Candida albicans carriage in children with severe early childhood caries (S-ECC) and maternal relatedness. PLoS ONE 11(10):e0164242
Xiao J, Fogarty C, Wu TT, Alkhers N, Zeng Y, Thomas M, Youssef M, Wang L, Cowen L, Abdelsalam H et al (2019) Oral health and Candida carriage in socioeconomically disadvantaged US pregnant women. BMC Pregnancy Childbirth 19(1):480
Samaranayake LP, Hughes A, Weetman DA, MacFarlane TW (1986) Growth and acid production of Candida species in human saliva supplemented with glucose. J Oral Pathol 15(5):251–254
Klinke T, Kneist S, de Soet JJ, Kuhlisch E, Mauersberger S, Forster A, Klimm W (2009) Acid production by oral strains of Candida albicans and lactobacilli. Caries Res 43(2):83–91
Nikawa H, Yamashiro H, Makihira S, Nishimura M, Egusa H, Furukawa M, Setijanto D, Hamada T (2003) In vitro cariogenic potential of Candida albicans. Mycoses 46(11–12):471–478
Falsetta ML, Klein MI, Colonne PM, Scott-Anne K, Gregoire S, Pai CH, Gonzalez-Begne M, Watson G, Krysan DJ, Bowen WH et al (2014) Symbiotic relationship between Streptococcus mutans and Candida albicans synergizes virulence of plaque biofilms in vivo. Infect Immun 82(5):1968–1981
Gregoire S, Xiao J, Silva BB, Gonzalez I, Agidi PS, Klein MI, Ambatipudi KS, Rosalen PL, Bauserman R, Waugh RE et al (2011) Role of glucosyltransferase B in interactions of Candida albicans with Streptococcus mutans and with an experimental pellicle on hydroxyapatite surfaces. Appl Environ Microbiol 77(18):6357–6367
Koo H, Bowen WH (2014) Candida albicans and Streptococcus mutans: a potential synergistic alliance to cause virulent tooth decay in children. Future Microbiol 9(12):1295–1297
Xiao J, Zeng Y, Rustchenko E, Huang X, Wu TT, Falsetta ML (2023) Dual transcriptome of Streptococcus mutans and Candida albicans interplay in biofilms. J Oral Microbiol 15(1):2144047
Kim D, Liu Y, Benhamou RI, Sanchez H, Simon-Soro A, Li Y, Hwang G, Fridman M, Andes DR, Koo H (2018) Bacterial-derived exopolysaccharides enhance antifungal drug tolerance in a cross-kingdom oral biofilm. ISME J 12(6):1427–1442
Pemberton MN (2016) Nystatin and miconazole: pharmacological and clinical evidence regarding interactions with warfarin. Oral Dis 22(8):761–765
Sklenár Z, Scigel V, Horácková K, Slanar O (2013) Compounded preparations with Nystatin for oral and oromucosal administration. Acta Pol Pharm 70(4):759–762
Alomeir N, Zeng Y, Fadaak A, Wu TT, Malmstrom H, Xiao J (2023) Effect of Nystatin on Candida albicans - Streptococcus mutans duo-species biofilms. Arch Oral Biol 145:105582
Epstein J, Pearsall N, Truelove E (1980) Quantitative relationships between Candida albicans in saliva and the clinical status of human subjects. J Clin Microbiol 12(3):475–476
Joss A, Adler R, Lang NP (1994) Bleeding on probing A parameter for monitoring periodontal conditions in clinical practice. J Clin Periodontol 21(6):402–408
Loe H (1967) Gingival index plaque index and retention index systems. In: Journal of periodontology: 1967: Amer Acad Periodontology 737 North Michigan Avenue, Suite 800, Chicago, Il 610-&
Little W, Korts D, Thomson L, Bowen W (1977) Comparative recovery of Streptococcus mutans on ten isolation media. J Clin Microbiol 5(6):578–583
Zeng Y, Youssef M, Wang L, Alkhars N, Thomas M, Cacciato R, Qing S, Ly-Mapes O, Xiao J (2020) Identification of non-streptococcus mutans bacteria from predente infant saliva grown on mitis-salivarius-bacitracin agar. J Clin Pediatr Dent 44(1):28–34
Alkhars N, Zeng Y, Alomeir N, Al Jallad N, Wu TT, Aboelmagd S, Youssef M, Jang H, Fogarty C, Xiao J (2022) Oral Candida predicts Streptococcus mutans emergence in underserved US infants. J Dent Res 101(1):54–62
Cannon R, Holmes A, Mason A, Monk B (1995) Oral Candida: clearance, colonization, or candidiasis? J Dent Res 74(5):1152–1161
Ghannoum MA (2018) Candida adherence to epithelial cells. CRC Press
Manning D, Coughlin R, Poskitt E (1985) Candida in mouth or on dummy? Arch Dis Child 60(4):381–382
Berdicevsky I, Ben-Aryeh H, Szargel R, Gutman D (1984) Oral Candida in children. Oral Surg Oral Med Oral Pathol 57(1):37–40
Lucas VS (1993) Association of psychotropic drugs, prevalence of denture-related stomatitis and oral candidosis. Community Dent Oral Epidemiol 21(5):313–316
Arendorf T, Walker D (1980) The prevalence and intra-oral distribution of Candida albicans in man. Arch Oral Biol 25(1):1–10
Pereira-Cenci T, Del Bel Cury AA, Crielaard W, Ten Cate JM (2008) Development of Candida-associated denture stomatitis: new insights. J Appl Oral Sci 6(2):86–94
Epstein JB, Polsky B (1998) Oropharyngeal candidiasis: a review of its clinical spectrum and current therapies. Clin Ther 20(1):40–57
Coronado-Castellote L, Jiménez-Soriano Y (2013) Clinical and microbiological diagnosis of oral candidiasis. J Clin Exp Dent 5(5):e279
Samaranayake LP, Keung Leung W, Jin L (2009) Oral mucosal fungal infections. Periodontology 49(1):39–59
Fisher JM (2002) A study at the Brooklyn Chest Hospital to assess the change in the oral carriage of Candida species in patients co-infected with HIV and TB, before and after antifungal therapy. Stellenbosch University, Stellenbosch
Williams DW, Jordan RP, Wei X-Q, Alves CT, Wise MP, Wilson MJ, Lewis MA (2013) Interactions of Candida albicans with host epithelial surfaces. J Oral Microbiol 5(1):22434
Chu X (2017) Oral candidiasis: relation to systemic diseases and medications. Dentistry 3000 5(1):59–64
Johnson EM, Warnock DW, Luker J, Porter SR, Scully C (1995) Emergence of azole drug resistance in Candida species from HIV-infected patients receivingprolonged fluconazole therapy for oral candidosis. J Antimicrob Chemother 35(1):103–114
Thompson GR III, Patel PK, Kirkpatrick WR, Westbrook SD, Berg D, Erlandsen J, Redding SW, Patterson TF (2010) Oropharyngeal candidiasis in the era of antiretroviral therapy. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 109(4):488–495
Ruhnke M (2006) Epidemiology of Candida albicans infections and role of non-Candidaalbicans yeasts. Curr Drug Targets 7(4):495–504
Yang Y-L, Lo H-J (2001) Mechanisms of antifungal agent resistance. J Microbiol Immunol Infect = Wei mian yu gan ran za zhi 34(2):79–86
Bal A (2010) The echinocandins: three useful choices or three too many? Int J Antimicrob Agents 35(1):13–18
Epstein JB, Truelove EL, Hanson-Huggins K, Mancl LA, Chen A, Press OW, Petersdorf SH, Fritsche TR, Epstein JD (2004) Topical polyene antifungals in hematopoietic cell transplant patients: tolerability and efficacy. Support Care Cancer 12(7):517–525
Costerton JW, Lewandowski Z, Caldwell DE, Korber DR, Lappin-Scott HM (1995) Microbial biofilms. Annu Rev Microbiol 49(1):711–745
Kim HE, Liu Y, Dhall A, Bawazir M, Koo H, Hwang G (2021) Synergism of Streptococcus mutans and Candida albicans reinforces biofilm maturation and acidogenicity in saliva: an in vitro study. Front Cell Infect Microbiol 10:623980
Hwang G, Marsh G, Gao L, Waugh R, Koo H (2015) Binding force dynamics of Streptococcus mutans–glucosyltransferase B to Candida albicans. J Dent Res 94(9):1310–1317
Canabarro A, Valle C, Farias M, Santos F, Lazera M, Wanke B (2013) Association of subgingival colonization of Candida albicans and other yeasts with severity of chronic periodontitis. J Periodontal Res 48(4):428–432
Unniachan AS, Jayakumari NK, Sethuraman S (2020) Association between Candida species and periodontal disease: a systematic review. Curr Med Mycol 6(2):63
Järvensivu A, Hietanen J, Rautemaa R, Sorsa T, Richardson M (2004) Candida yeasts in chronic periodontitis tissues and subgingival microbial biofilms in vivo. Oral Dis 10(2):106–112
Frederick MJ, Clayman GL (2001) Chemokines in cancer. Expert Rev Mol Med 3(19):1–18
Rankin SM, Conroy DM, Williams TJ (2000) Eotaxin and eosinophil recruitment: implications for human disease. Mol Med Today 6(1):20–27
Zajkowska M, Mroczko B (2021) From Allergy to Cancer—Clinical Usefulness of Eotaxins. Cancers 13(1):128. https://doi.org/10.3390/cancers13010128
Paqué PN, Herz C, Wiedemeier DB, Mitsakakis K, Attin T, Bao K, Bostanci N (2021) Salivary biomarkers for dental caries detection and personalized monitoring. J Personalized Med 11(3):235. https://doi.org/10.3390/jpm11030235
Acknowledgements
We greatly appreciate Mrs. Rita Cacciato for her assistance in study coordination.
Funding
The study is supported by institute funding from the Eastman Institute for Oral Health at the University of Rochester Medical Center. Dr. Xiao’s research was supported by NIDCR (K23DE027412 and R01DE031025). The funding agencies had no role in the study design, data collection, analyses, decision to publish, or preparation of the manuscript.
Author information
Authors and Affiliations
Contributions
MA and JX contributed to the conception, design, data acquisition, analysis and interpretation, drafting, and critically revising of the manuscript; TTW contributed to data acquisition, analysis and interpretation, drafting, and critically revising of the manuscript; HJ, NA, YZ, NA, SV, AA, AL, SQ, and JB contributed to data acquisition, data interpretation, and critically reviewing of the manuscript. All authors have read and approved the final version of the manuscript and agree to be accountable for all aspects of the work.
Corresponding author
Ethics declarations
Ethics approval and consent to participate
The study protocol was approved by the University of Rochester Research Subject Review Board (#STUDY00004638). This study is registered at the Trials.gov (#NCT04550546). All study subjects have given their written informed consent.
Consent for publication
All authors have read and approved the final manuscript.
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Aljaffary, M., Jang, H., Alomeir, N. et al. Effects of Nystatin oral rinse on oral Candida species and Streptococcus mutans among healthy adults. Clin Oral Invest 27, 3557–3568 (2023). https://doi.org/10.1007/s00784-023-04969-5
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00784-023-04969-5