Background
Conventional brackets are often used during orthodontic therapy of patients with malocclusion. The complex construction of such brackets greatly inhibits oral hygiene, which predisposes to increased carriage of bacteria and yeasts [
1,
2]. An increased amount of fungi in the oral cavity can, with predisposing factors, lead to the development of oral mycosis. A count of yeast colonies (colony-forming unit, CFU) can be used to estimate the number of fungi, calculated from the volume of washings collected from the patient’s mouth. This method allows both the number composition (quantitative assessment) and species composition (qualitative assessment) of isolated colonies to be determined, unlike swabs, which are less reliable for technical reasons (they require sampling from a specific surface area (e.g., 1 cm
2) or the same location (such as the palate; they also involve a high risk of contamination through touching other anatomical structures, and are prone to errors related to adherence and recovery of colonies from a swab) [
3]. The state of oral hygiene can also be expressed numerically, as with the periodontological indices. One of the most popular dental indicators is the approximal plaque index (API), which expresses the amount of uncleaned interdental space as a percentage. API values of 25–39% indicate good hygiene, and < 25% point to optimal hygiene. A permanent lack of good oral hygiene causes inflammation of the gums, the first symptom of which is bleeding. The gingival bleeding index (GBI) is used to assess gum inflammation. GBI values of below 10% indicate clinically healthy periodontium.
One element of conventional orthodontic brackets are elastomeric rings, which are used to connect the bracket with the orthodontic wires. The irregularity and roughness of the surface of these rings are favorable to colonization and biofilm formation by microorganisms [
4,
5]. Biofilms are usually multispecies assemblages of microorganisms encased in a matrix a mode of life common to most microorganisms in natural and medical systems (as well as components of orthodontic appliances), which allows survival in hostile environments. A biofilm can become a reservoir of pathogens and, with predisposing factors, can contribute to thrush and other forms of oropharyngeal candidosis. One factor in Candida’s virulence is the ability of yeasts to form biofilms, and it would seem that strains isolated from patients colonized and using orthodontic appliances will form a biofilm well [
6,
7].
Even though
Candida is a part of the normal oral microbiota, being found in 17–75% human population, it can often be the cause of oral mycoses, especially in immunodeficient patients [
8,
9]. The most common etiological factor of oral candidosis is
Candida albicans. However,
C. tropicalis, C. glabrata, C. parapsilosis, C. krusei sometimes occur with high prevalence, especially in susceptible patients such as diabetics [
10‐
12]. All these species have a great ability to form biofilms, especially with oral gram positive bacteria [
8‐
11].
Very few studies have compared
Candida prevalence and
Candida growth in orthodontic patients before, during, and after treatment [
1,
12]. The small number of papers related to this topic and the correlation between orthodontic elastomeric rings and oral
Candida growth led to this study.
The purpose of this study was to investigate the occurrence of Candida species and the role of oral hygiene, as measured by periodontal parameters during fixed appliance therapy. A further aim was to characterize the isolated Candida species by their ability to form biofilms, which are a virulence factor in the development of candidosis related to orthodontic therapy.
Methods
Patients and samples
Seventeen patients (eleven females and six males, aged 11–30 years old, average age 17 ± 7 years, median 14 years) at the Department of Orthodontics, University Dental Clinic, Kraków, Poland, were randomly selected. Due to occlusion defects, all subjects required orthodontic treatment using conventional brackets and gave their written consent to participate in the study. The inclusion criteria were healthy individuals, both sexes, aged ≤30 years old. The exclusion criteria were oral mucosa disease; smoking; use of antibiotics, corticosteroids, or any hormone medication in the 3 months prior to the study; pregnancy, or breastfeeding. All patients were informed that the use of antimicrobial mouthwashes was prohibited during the study.
The research project included a schedule of four visits: T0: before bonding brackets; T1, T2, and T3: approximately 2, 6, and 12 weeks after bonding brackets, respectively.
During the study, patients used the same type elastic rings (color Glow Blue, catalogue index OCLGB, Orthodontic Design and Production, USA), metal brackets Cannon Ultra System (Orthodontic Design and Production, USA), and NiTi wires (Fairfield Orthodontics, USA).
All participants were thoroughly instructed by one of the authors on how to properly take care of oral hygiene during orthodontic treatment. Patients reported for all appointments properly prepared (in accordance with written recommendations): in the morning, on an empty stomach (minimum 6 h after eating), before morning toothbrushing and other oral hygiene procedures. Patients were also asked to limit exercise and follow a mixed diet on the day preceding the study.
During visit T0, before brackets were bonding, oral hygiene was assessed using the approximal plaque index (API), following Lange, and the gingival bleeding index (GBI), following Ainamo and Bay. Oral rinses were collected.
To measure API, a periodontal probe was gently guided through the approximal spaces of the first and third quadrants from the oral aspect, and of the second and fourth quadrants from the buccal aspect. The presence of plaque deposits was recorded as a positive result. The percentage of sites with positive results was counted.
The GBI was taken by gently probing the orifice of the gingival crevice. If bleeding occurred within 10 s, a positive finding was recorded. The number of positive sites was recorded and then expressed as a percentage of the number of sites examined.
Collection of mycological material was performed using oral rinses. Patients under the supervision of the orthodontist rinsed their mouth for 60 s with 10 ml isotonic saline (0.9% NaCl) at room temperature, and spat out the rinses into a sterile container, which was immediately delivered to the mycological laboratory.
During visits T1, T2, and T3, the API and GBI indices were re-evaluated, and oral rinses and elastomeric rings were collected. Orthodontic ligatures were placed into Eppendorf tubes filled with saline solution. Elastomers were collected using a sterile dental kit in aseptic conditions to prevent material contamination.
Microbiological analysis
Total candida and mean candida carriage
The mouth washing samples were vigorously shaken for 90 s with a Vortex shaker, and then quantitatively plated on Sabouraud’s chloramphenicol agar (Biocorp) and incubated at 35 ± 2 °C for 72 h. The collected elastomeric ligatures were inoculated directly onto the medium. The grown colonies were identified based on classical mycological methods, such as colony morphology, the Dalmau plate technique, and an API 20C AUX commercial assimilation test (Biomerieux).
Strains were collected and frozen for further biofilm formation studies.
In vivo biofilm scanning electron microscopy (SEM)
Several randomly selected ligatures, present in the oral cavity for about 4 weeks, with known Candida growth were subjected to a scanning electron microscope analysis to assess the biofilm produced in vivo. The topography of an unused elastic ligature was also examined as a control. Analysis of the prepared samples was performed using a JEOL JSM-35CF scanning microscope (JSM-35CF; JEOL Vacuum Evaporator) at the Laboratory of the Otolaryngology Clinic, University Hospital, Kraków.
The biofilm formation assay was performed as follows: the overnight culture of investigated strains was transferred to sterile saline, and the fungal suspension was adjusted to 1 on McFarland scale with a densitometer (DEN1 Biosan, Lithuania). One hundred μL of standardized suspensions (eight wells per strain) were added to each well of sterile 96-well flat-bottom polystyrene plates filled previously (100 μL per well) with double concentrated Roswell Park Memorial Institute (RPMI) 1640 medium with L-glutamine without bicarbonate (Sigma Aldrich), supplemented with 2% glucose (Avantor Performance Materials, Gliwice, Poland) and buffered with 3-morpholinopropane-1-sulfonic acid (MOPS, Sigma Aldrich). The plates were incubated for 1.5 h at 37 °C for the adherence phase, before being washed twice with sterile phosphate buffered saline (PBS) to remove nonadherent cells. Each well was then filled with new RPMI medium and incubated without shaking for 72 h at 37 °C. After that time, the plates were washed with PBS, dried in air for 45 min, and stained with 125 μL per well of 0.1% crystal violet solution (Avantor Performance Materials, Gliwice, Poland) for 45 min at room temperature. The microtiter dish was then washed and then dried. A 150 μL volume of 95% ethanol (Avantor Performance Materials, Gliwice, Poland) was added to each well, and then plates were covered and incubated for 45 min at room temperature. A 100 μL sample of the resulting ethanol-crystal violet solution was then transferred from each well to a new microtiter plate, and the optical density (OD) was determined at a wavelength of 570 nm (Infinite 200 Pro Tecan Männedorf, Switzerland). The experiment was repeated, with each strain being analyzed in sixteen replicates.
The study included 27 isolates from ten patients and one reference strain of C. albicans (ATCC 90028).
Statistical analysis
To detect differences in GBI, API, and number of
Candida colony-forming unit (CFU) across multiple tests, we used one-way repeated measures analysis of variance by ranks (Friedman test and Skillings–Mack test). Differences in biofilm formation among
Candida strains were evaluated using the Kruskal–Wallis test with Dunn’s post hoc analysis. All statistical analysis was carried out using R software [
13,
14], and a
p-value below 0.05 was considered significant.
Discussion
In the current study, the percentage of
Candida-carriers before orthodontic treatment was relatively high, at 47% of patients. It increased during orthodontic treatment to almost 59% (nearly 12% of subjects became carriers). This would not be expected given the occurrence of
Candida in the Polish population, affecting an average of 30.6% of healthy individuals [
15]. However, the study citied used oral swabs (
N = 654; 7–45 years old) and the lower result may be the effect of the different collecting method. Tooyama et al. [
3] showed that the test result depends significantly on the sampling method. In his study of Japanese patients (
N = 200, average age 47.2 years old), when measured using oral swabs,
Candida affected 33.5% of patients, whereas 52% of the same group of patients were found to be colonized with
Candida sp. when concentrated rinse was used as the collecting method, comparable with our results and methodology. This shows that the method of sampling has a great impact on the results, and that not all studies can be directly compared.
Zheng et al. [
16] determined that oral
Candida sp
. was present in only 14% of young Chinese adults (
N = 50, average age 13.6 years old) before the application of fixed orthodontic appliance. This lower result may be the effect of toothbrushing prior to sampling. Arslan et al. [
17] tested a Turkish population (
N = 72, average age 19.6 years old) using saliva samples and oral swabs, finding high
Candida-carriage rate of 58.5%. This may suggest the occurrence of large population variables, both within age and ethnic groups, as carriage of fungi depends on many factors, such as diet and lifestyle.
In our investigation, two patients (nearly 12%) became
Candida-carriers over the course of the experimental phase of the study (after bracket placement). This is coherent with other publications that have suggested that treatment with orthodontic appliances promotes
Candida yeast colonization. Hägg et al. [
18] demonstrated using the imprint technique that overall
Candida prevalence increases after bonding brackets (
N = 27, mean age 15 years old).
Lee et al. [
19] described that 15% of subjects became
Candida-carriers in their study using oral concentrated rinse analysis of Chinese patients (
N = 112, average age 17.7 years old), amount to an increase in
Candida-carriers from an initial 32% (T0: before bracket bonding) to a maximum of 50% (T5: around 5 months after bonding). They reported that 11% of subjects were consistent carriers of
Candida species, 64% were inconsistent carriers, and only 25% were consistent non
-carriers (i.e., never carried
Candida species throughout the experimental period of 12 months)
. We were also able to distinguish a group of consistent (35%) and inconsistent (23.5%)
Candida-carriers. This may indicate that the initially tested noncarrier group at the study baseline contained some false negative results. It needs to be considered that the introduction of orthodontic appliance is only one variable factor influencing the prevalence of
Candida yeast in the oral cavity (others being diet, oral hygiene, lifestyle, immune system, etc.). In future studies, longer observation of the study group with multiple tests is recommended to isolate the group of consistent and inconsistent carriers before the start of the experimental phase of the study.
In our study, a quantitative analysis of
Candida colonies in carriers group was carried out, as the number of yeast colonies indicates development of oral yeast infection during orthodontic treatment. Tooyama et al. [
3] determined the reference ranges of
Candida colonies for healthy commensal carriages at 0–5 CFU/swab and 0–670 CFU/ml with the concentrated rinse method. In our study, five patients had an average colony count higher than 670 CFU/ml, but clinically did not show any symptoms suggesting that
Candida grew on the abiotic surface of dental appliances, rather than on the mucosa. Analysis of the quantitative data shows that the number of colonies differs by time and by patient. However, in our research, we found no statistically significant differences in the number of
Candida sp. during the 12 weeks of study. Despite this, our results suggest a positive correlation between the average number of colonies and the duration of study. The amount of oral
Candida may fluctuate, and the lack of statistical significance may be due to the hygiene habits of patients, the food they consume, yeast biology, the small research sample, or high initial number of oral
Candida-carriers.
Our findings regarding the upward trend of yeast growth during orthodontic treatment are consistent with the data presented in the literature [
16‐
19]. The study of Zheng et al. [
16] showed that the CFU/ml increases in users of fixed orthodontic appliances after 2 months of treatment. Lee et al. [
19], in their long-term research (involving almost 12 months of observation), showed that the amount of
Candida albicans increases after bracket bonding and peaks in the fifth month of treatment, before slightly decreasing and approaching the maximum again at the end of the first year of treatment. Arslan et al. [
17], on the basis of 1 year of observation of a group of orthodontic patients, stated that a statistically significant increase in the
Candida population occurs in the first month of orthodontic treatment. A decrease in the amount of
Candida DNA in wash mouth samples was only found in Bergamo et al. [
20] (
N = 15, mean age 17.53 ± 8.0 years), who employed 90 days of observation after bracket application; this study group was heterogenous, consisting of 14 women and a single male. Unfortunately, the authors of none of these studies described patient preparation procedures, such as toothbrushing. Only Zheng et al. [
16] stated that patients had had breakfast and had undergone their regular morning oral hygiene routine. Our recommendations were typical of laboratory tests: patients reported on an empty stomach, without having brushed their teeth. This is one of the methodological variable factors that may greatly affect results of the study.
The species profile obtained in our study is similar to that of Hägg and al [
18]. and of Lee at al [
19].:
Candida albicans dominates and
C. guilliermondii and
C. tropicalis were isolated in small percentage
. This may serve as a guideline for choosing antibiotic therapy for patients affected by oral mycosis. An interesting phenomenon, not noted by other authors, was the change in colonizing species seen in two patients over the course of the study (in K.J.,
C. albicans was replaced by
C. tropicalis; and in D.M., strains of
C. guilliermondii led to high biofilm formation; see Fig.
4). Further research may be needed to better understand the intraspecies relationships of
Candida yeast.
Conventional orthodontic brackets have many retention areas that impede proper oral hygiene, thus leading to greater plaque build-up. In our study, the mean number of
Candida CFUs had a tendency to grow. However, the API and GBI did not show significant changes. Interestingly, statistically significant fungal growth was seen in patients whose API decreased (indicating that oral hygiene improved) during subsequent visits, whereas patients with increasing GBI (periodontal inflammation) had lower yeast carriage. This leads to the conclusion that
Candida sp. proliferated less in patients with an altered periodontium i.e., these were probably more colonized by bacteria. Similarly, no differences in plaque index (PI), gingival index (GI), or gingival bleeding index (GBI) during the use of fixed orthodontic appliances were observed by Bergamo et al. [
20]. However, Hägg et al. [
18] found a statistically significant increase in PI during the second and third visits after beginning orthodontic treatment with brackets.
One of the factors in
Candida virulence is the ability of these yeasts to form biofilm on abiotic surfaces, including components of orthodontic appliances. The formation of a biofilm protects the cells forming it against the adverse effects of the environment, including antimicrobial drugs. Few studies have taken up the topic of the multiplication of microorganisms on orthodontic elastomers [
5,
21]. Casaccica et al. [
4] showed that the elastomers used in orthodontics are manufactured with due care and do not pose a biological threat. SEM images of the topography of uninfected elastic ligatures presented in this publication also confirm the absence of microorganisms. The surface of elastic ligatures however enables the formation of architecturally complex and species-rich biofilms, and is rapidly colonized during orthodontic treatment.
It would seem that strains isolated from patients colonized while using orthodontic appliances will form a biofilm well. For our patients, the level of colonization before treatment was high, and during the course of treatment, the ability to create biofilm did not change, except in sporadic cases. This indicates that, while the number of yeasts including those derived from biofilms produced in the oral cavity increased, the biofilm-forming potential (virulence) of the isolated strains did not change. It can thus be concluded that, while oral appliances promote colonization by yeasts, they do not increase their virulence. Appropriate antifungal prophylaxis should thus permit control of the development of oral mycosis during long-term orthodontic therapy. However, in vivo biofilm formation may not coincide with in vitro biofilm formation capacity. The model does not take into account all factors (especially the presence of bacteria). The Candida pathogenicity (biofilm formation) described in the literature thus does not coincide with the pathogenicity of strains in vivo.
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