Problems associated with maintenance of oral health are faced by many people throughout the world, irrespective of their age and gender. The most common oral problems amongst all are dental caries, bleeding gums (periodontal diseases) and oral cancers ¹ . Over few decades, the severity and prevalence of dental caries, and oral cancer, which can be a fatal condition, have increased ^{2, 3} .

In the US, caries were estimated to be five times as common as asthma and seven times as common as allergic rhinitis ³ . According to the World Health Organization (WHO), dental caries are caused due to high sugar consumption, which is also linked with being overweight and obesity ⁴ . The incidence of periodontal diseases is estimated to be about 20–50% of the global population ⁵ . There are two approaches for the management of caries: extraction and preventions. The primary treatment modality for these caries, though very painful, is extraction of carious teeth ^{2, 3} . The routine prevention measures for dental caries are to maintain oral hygiene, involving the use of fluoride toothpaste and/or xylitol ^{6, 7} . Looking at the currently prevailing painful treatment, there is a need for new products to be developed for the prevention of oral cavities. The pathological organisms responsible for these caries/ periodontal diseases are Streptococcus mutans, Streptococcus sanguis and Streptococcus salivarius.

Since mouth washes and different tinctures have been found to be ineffective against dental biofilm formation ⁸ , finding novel products effective against cariogenic microbes like S. mutans is important. While Listerine ^®, has some antimicrobial activity, toothpastes such as Toss-K and Senquel-AD have no activity against four important dental caries pathogens ⁹ . Thus, the search continues for more effective agent(s) ¹⁰ . A novel product that is effective against biofilm formation would be an important contribution to chewing sticks, toothpastes or other dental products.

S. mutans has the ability to adhere the enamel surface, produce acid metabolites, build glycogen reserves and to synthesize extracellular polysaccharides. Mutans streptococci create acidic environment creating a risk for formation of cavity. During the formation of dental plaque, S. mutans adhere to primary colonizers by cell to cell interaction which forms biofilm on the teeth which induces bacterial growth ¹¹ .

Streptococcus sanguis is normally found in the human oral cavity. Due to low cariogenicity, it forms a colony on tooth surface which gets aggregated by other oral bacteria and leads to maturation of dental plaque ¹² . Another organism, Streptococcus salivarius belonging to the salivarius subspecies is found in oral cavity in humans a few hours after birth and remain there as the predominant inhabitant. All these organisms enhance caries formation and thus the progression of periodontal disease. The aforementioned treatment modalities are unsuccessful in controlling or killing these bacteria and hence in prevention of caries.

Silver has been used since ancient times as antibacterial agent for various pathological elements. During the last century, the antimicrobial action of silver has been investigated ¹³ . Colloidal silver is observed to be less toxic than ionic silver and has good compatibility with human cells. Silver was found to be effective in dentine desensitizer and is used as root canal disinfectant ¹⁴ . Silver nanoparticles are also used in dental material depending on the type of material being used. For example, titanium samples are mainly soaked in AgNO ₃ solution for dental implants to avoid bacterial contamination ¹⁵ . The mechanism of action of silver compounds on carious tooth is to inhibit demineralization process and anti-bacterial effect by interfering with bacterial cell membrane, cytoplasmic enzyme and inhibition of DNA replication of bacteria ¹⁴ .

Oral health being a global concern, it is essential to develop strategies to prevent dental caries and plaque formation. This study aimed at investigating the efficacy of a colloidal silver gel in inhibiting biofilm formation in vitro by the principal oral bacteria, Streptococcus mutans, Streptococcus sanguis and Streptococcus salivarius.

There are over 700 different species that contribute to the formation of dental biofilm (plaque) ^{9– 11} . Among these species, Streptococcus mutans, Streptococcus salavarius, and Streptococcus sanguinis are the main members of this plaque ^{20– 22} . These bacteria are also considered to be the primary etiologic agents of human dental caries ^{23– 26} . It is the interaction of S. mutans with other streptococci that is thought to be important in dental plaque formation. ²⁷ . S. mutans can cause cariogenicigty by the production of glucosyltransferase enzymes that allows glucose from sucrose to be used for the synthesis of glucan, and have also been implicated in heart problems ^{28, 29} . S. sanguinis is an another common organism in dental plaque, which can colonize dental cavities. An additional problem is that this organism is also often found in the bloodstream. This allows it to attach to heart valves, causing bacterial endocarditis ²² . Thus, S. sanguinis is a key agent in infective endocarditis ²¹ .

Since S. salivarius is also part of the normal human flora, it can contaminate sterile body fluid. Thus, therapeutic interventions that disrupt the cells protecting the blood vessels can allow it to enter the blood stream and cause problems in areas such as the meninges and the cerebrospinal fluid. ^{30– 33} . This results in a variety of infections such as meningitis and bacteraemia along with many other bacterial problems. ^{27, 30, 34– 39} . Thus, these three bacterial species can not only work together to form plaque on teeth, but can play a major role in other medical problems in the body.

The objective of the current study was to evaluate the test Ag-gel for its efficacy to either control or annihilate the growth of these 3 organisms. The results present quantitative data of the antimicrobial effect on S. salivarius, S. sanguis, or S. mutans bacteria, of Ag-gel, layered on a cellulose disc which was inoculated with these bacteria or a combination of all three bacterial strains. The CFU assay results of in vitro studies using Ag-gel treated dressings showed over 6 log of killing (100%) for S. salivarius, S. sanguis, or S. mutans as compared with a control gel dressing containing no Ag-gel. Since biofilms adhere strongly to surfaces, the experiments were also studied by SEM. These SEM studies confirmed the CFU results with S. salivarius, S. sanguis, or S. mutans biofilms, in the presence of Ag-gel or placebo gel. As seen in Figure 2, mature biofilms formed in the presence of the placebo gel, but none in the presence of the Ag-gel.

The mixture of these three bacteria was also studied, since it is proposed that the combination of bacteria is more resistant to growth inhibition than the individual bacteria. Similar results to the individual bacteria, (>6-log kill rate, 100%) were obtained with the combination of the three bacteria by both the CFU assay and by SEM studies.

An Ag-gel was found to be capable of over 6 log (100%) inhibition of S. salivarius, S. sanguis, or S. mutans bacteria, or a mixture of all three bacteria forming biofilms on cellulose discs by CFU studies. These results were confirmed by SEM studies of biofilm formation by S. salivarius, S. sanguis, or S. mutans or a mixture of all three bacteria, where the Ag-gel dressing showed total inhibition of biofilm formation on cellulose discs. These results indicate that use of a colloidal silver gel is an effective way to inhibit the formation of biofilms by the most common bacteria implicated in oral plaque formation, and this gel stands good potential to be developed into an effective commercial dentifrice product.

Raw data for this study are available on OSF. DOI: https://doi.org/10.17605/OSF.IO/AJNYU ¹⁹ .

Data are available under the terms of the Creative Commons Zero "No rights reserved" data waiver (CC0 1.0 Public domain dedication).