Catalytic activity of Fer in combination with SnF2
To explore whether SnF2 could influence the catalytic activity of Fer, we used the 3,3′,5,5′-tetramethylbenzidine (TMB) colorimetric assay for peroxidase-like activity following a previously published protocol32, with some modifications. TMB is a chromogenic compound that yields a blue color upon oxidation with an absorption peak at 652 nm in the presence of reactive oxygen species (ROS), such as hydroxyl radical (•OH)33. As shown in Fig. 4, A and B, SnF2 alone did not produce a noticeable amount of ROS. In contrast, the catalytic activity of Fer increased significantly after combining with SnF2 as demonstrated by increased colorimetric reaction (Fig. 4, A and B), suggesting that SnF2 enhanced the catalytic activity of Fer. Photographs in the inset of Fig. 4A exhibit the color change in each condition (SnF2, Fer, and Fer + SnF2 from left to right, respectively).
Notably, we found that the enhancement of ROS production in the presence of SnF2 is dependent on pH, concentration, and incubation time. The highest catalytic activity was observed at pH 4.5 (Fig. 4C). The greater ROS production at acidic pH conditions (characteristic of pathological conditions associated with dental caries) and the minimal ROS generation close to neutral (physiological) pH suggests a selectivity toward pathogenic bacteria. Surprisingly, very small amounts of SnF2 are adequate for enhancing the catalytic activity of Fer (Fig. S5), whereby more ROS can be detected within 10 min incubation (Fig. S6A) gradually increasing to reach the highest level at 6 h (Fig. S6B), which was maintained for prolonged period.
To further confirm the enhancement of the peroxidase-like activity of the Fer in the presence of SnF2, we employed a multi-pronged approach. First, we used OPD, a colorless substrate, which yields an oxidized product with a characteristic yellow color when reacting with ROS with an absorption peak at 450 nm34. As expected, the catalytic activity of Fer increased markedly after adding SnF2 as compared to Fer alone and SnF2 alone (Fig. 4D). We also measured ROS production via photoluminescence (PL) method using DCFH-DA as a ROS tracking indicator. DCFH-DA (a nonfluorescent molecule) yields a fluorescent molecule DCF in the presence of ROS35. As depicted in Fig. 4E, the PL intensity increased to a greater extent after combining Fer with SnF2. Then, we measured the amount of hydroxyl radical (•OH) using coumarin as a photoluminescent probe molecule36, 37. As seen in Fig. 4F, Fer and SnF2 in combination generated significantly more •OH than Fer alone, further demonstrating that SnF2 enhanced the catalytic activity of Fer. In contrast, SnF2 alone did not produce a noticeable amount of •OH (Fig. S7), consistent with its lack of catalytic activity.
Next, we investigated whether the augmented catalytic activity arises from different fluoride or stannous salts. We replaced SnF2 with NaF, a commonly used fluoride salt in oral care formulations, or barium fluoride (BaF2), another fluoride salt with a divalent cation of comparable size to Sn2+. We found that neither NaF nor BaF2 increased the catalytic activity of Fer noticeably (Fig. 4, G and H), suggesting that F─ may not play a crucial role in enhancing the ROS production performance of Fer. Conversely, we used SnCl2 to evaluate whether Sn ions play a role in strengthening the ROS generation capability of Fer. We found SnCl2 enhanced the catalytic activity of Fer (Fig. 4I), indicating that Sn ions may be playing a dominant role in increasing the catalytic performance of Fer. Taken together, these findings support that SnF2 can boost the catalytic ability of Fer, indicating that Fer and SnF2 combination is an effective ROS-generating therapy that can target biofilms under pathological (acidic) conditions.
We examined whether Fer released iron ions when combined with SnF2 using inductively coupled plasma optical emission spectroscopy (ICP-OES). As depicted in Fig. S8A, the presence of SnF2 slightly increased iron ions release from Fer at acidic pH (4.5). It is noteworthy that the amount of leached irons from Fer + SnF2 formulation at circumneutral pH is negligible (Fig. S8B). Conversely, the iron leached from Fer + SnF2 at acidic pH values could provide an added benefit. Iron ions have shown cariostatic effects as they can precipitate on the surface of enamel and promote the adsorption of phosphate and calcium ions, thereby reducing enamel demineralization38, 39.
Altogether, the increased stability of SnF2 in aqueous solutions is mediated at least in part via interactions with CMD, which may be important for both fluoride bioavailability and fluoride delivery. Unexpectedly, the presence of SnF2 boosts the ROS generation capability of Fer at acidic pH, thus enhancing antibiofilm efficacy under pathological condition. This synergistic Fer and SnF2 combination provide a potent yet pH-dependent ROS-based therapy with enhanced antimicrobial fluoride stability that could prevent the onset of dental caries in vivo.
Biocompatibility of Fer+SnF2 in vitro
To examine whether this combination treatment is viable for use in vivo, the cytotoxicity of the combination of Fer and SnF2 was assessed in human gingival keratinocytes (HGK) using MTS assay. The cells were incubated with the combination of Fer (1 mg of Fe/ml) and SnF2 (250 ppm of F) for 10 min, followed by 24 h incubation with fresh cell culture media. We found that the combined treatment of Fer and SnF2 had no adverse effect on cell viability (Fig. S9).
Impact of Fer/SnF2 on caries development and on enamel surface in vivo
Topical applications of Fer and SnF2in vivo were assessed using a rodent model that mimics the characteristics of severe human caries40, including sugar-rich diet and the development of surface zones41. Rat pups were infected with S. mutans (oral bacterial pathogen) and fed a sugar-rich diet (Fig. 5A). In this model, as depicted in Fig. 5B, tooth enamel progressively develops caries lesions (analogous to those observed in humans), proceeding from initial areas of demineralization to severe lesions characterized by enamel structure damage and cavitation. The test agents were topically applied twice daily with 1 min exposure time (Fig. 5A) to mimic the clinical use of a mouthwash. After the experimental period, the incidence and severity of caries lesions were evaluated. We also included a reduced concentration of the combination of Fer (0.25 mg of Fe/ml) and SnF2 (62.5 ppm of F), since the lower amounts were capable of significantly killing the bacteria (p < 0.001) and reducing biomass (p < 0.001) compared to control in vitro (Fig. S10).
Quantitative caries scoring analyses revealed that the treatment of Fer in combination with SnF2 was exceptionally effective in preventing caries development with higher efficacy than either alone (p < 0.001) (Fig. 5C). It nearly abrogated caries initiation and completely blocked further caries lesions development, thus preventing the onset of cavitation altogether (Fig. 5, D and E). The efficacy of the lower dosage of Fer and SnF2 treatment was significantly greater than the control group (p < 0.001), and as effective as Fer (1 mg of Fe/ml) or SnF2 (250 ppm of F) treatment alone. This demonstrates that the combination of Fer and SnF2 has a synergistic effect for efficient biofilm treatment in vivo.
To determine the impact of treatment on the elemental composition of the enamel surface, lamellae oriented normal to the external enamel surface (EES) of rat mandibular first molars (M1) were lifted out using a conventional focused ion beam (FIB) technique (Fig. S11). Line profiles normal to the EES were determined by scanning transmission electron microscopy (STEM) with energy dispersive spectroscopy (STEM-EDS) (Fig. 5F) and aligned to the outer surface (see Methods). Comparing M1 from Fer + SnF2 and control groups (Fig. 5F(i)), we find that the combined mole fractions of Fe, Sn, and F are substantially elevated, and the sum of the mole fractions Ca and P correspondingly reduced, in a thin film at the surface. Preliminary analyses revealed that the thickness of this film varies from ~ 50 to greater than 300 nm. Inspection of single element profiles from a 50 nm-thick film (Fig. 5F(ii to vi)) reveals that while the calcium mole fraction is reduced from ~ 25 at% to less than 5 at% in this layer, the mole fraction of oxygen remains at the same level as in the underlying enamel (Fig. 5F(iii)). Sn reaches slightly more than 10 at% (Fig. 5F(vi)), while Fe is closer to 7 at% (Fig. 5F(v)). While the profiles of the latter show broad maxima in the center of the layer, F levels appear highest at the outer surface at ~ 5 at% and decline to ~ 1 at% at the interface (Fig. 5F(iv)). The presence of a Fe/Sn/F-rich layer was confirmed on a separately prepared sample from the same, treated rat molar using STEM with electron energy loss spectroscopy (STEM-EELS) (Fig. S12). Furthermore, the presence of Fe, Sn, and F at the surface of treated teeth, and the absence of these ions on vehicle-treated controls was confirmed using X-ray photoelectron spectroscopy (XPS, Fig. S13).
In high-resolution TEM (HRTEM) images, the Fe/Sn-rich layer was apparent as a slightly darker band between the enamel and the protective layers of FIB-deposited carbon and FIB-deposited Pt/C (Fig. S14). Lattice fringes were readily apparent in enamel (Fig. S14A), and Fast Fourier transform (FFT) images and radial integrals (Fig. S14, B and E) revealed sharp features consistent with the \(\left\{002\right\}\), \(\left\{3\stackrel{-}{2}1\right\}\), and \(\left\{3\stackrel{-}{3}0\right\}\) sets of planes of crystalline hydroxylapatite. The Fe/Sn-rich layer did not display lattice fringes, and FFT images only showed diffuse scattering with a broad maximum at ~ 0.33 nm− 1 (Fig. S14, C and F), consistent with an amorphous oxide layer.
Taken together, there is strong evidence that there is a layer comprised of Fe and Sn with varying amounts of fluoride present at the surface of the teeth of animals treated with SnF2 + Fer. The presence of Ca and P in this layer may indicate co-precipitation during its formation. Gradients of Fe, Sn, and F at the interface between the film and the underlying enamel suggest that these ions diffuse into enamel, but this remains to be confirmed.
Effect of Fer/SnF2 on host microbiota and oral tissues in vivo
The effects of Fer and SnF2 on oral microbiota and surrounding soft tissues were also evaluated to assess the impact on oral microbiome diversity and oral tissue toxicity. All treatment groups showed no significant differences in alpha diversity among each group (Fig. 6, A and B, p > 0.05, Willcox test). Furthermore, weighted UniFrac distances analyzed of principal coordinate analysis (PCoA) by treatment groups revealed that Fer and SnF2 treatment group has a similar composition with the lowest dispersion (Fig. 6C, green dots), indicating no deleterious effects on the oral microbiota diversity (p > 0.05, PERMANOVA). Notably, microbiome data revealed a higher abundance of acidogenic bacterial genera such as Streptococcus and Lactobacillus in the control group, whereas they decreased in all the treatments (Fig. 6, C and D). Veillonella is known to consume acids produced by other acidogenic oral bacteria to grow and survive. Veillonella is especially reduced in the combined treatment groups, i.e. 1/4Fer + 1/4SnF2 and Fer + SnF2 (Fig. 6, C and D), indicating reduced acidogenic environment. In contrast, commensal genera related to oral health such as Haemophilus and Rothia were increased in treatment groups. Altogether, the microbiome data indicates that bacterial diversity is not affected as a community (Fig. 6D), but specific bacteria associated with pathogenic environment are reduced by the combination treatment.
Histopathological analysis of gingival tissues revealed no indication of an acute inflammatory response, cytotoxicity, necrosis, or any changes in vascularization or proliferation, suggesting biocompatibility of Fer and SnF2 treatment (Fig. 6E), consistent with in vitro data. Collectively, the data show that the combination was substantially more potent than either alone, whereas a lower concentration of agents in combination was as effective as each alone at full strength, indicating a synergistic effect between Fer and SnF2. In addition, the treatments did not disrupt the ecological balance of the oral microbiota or cause deleterious effects on the surrounding host tissues, indicating high precision for targeting cariogenic plaque-biofilms and preventing disease progression in vivo.