Iron oxide nanozymes stabilize stannous fluoride for targeted biofilm killing and synergistic oral disease prevention.
Yue HuangYuan LiuNil PandeyShrey ShahAurea Simon-SoroJessica C HsuZhi RenZhenting XiangDongyeop KimTatsuro ItoMin Jun OhChristine BuckleyFaizan AlawiYong LiPaul J M SmeetsSarah BoyerXingchen ZhaoDerk JoesterDomenick T ZeroDavid CormodeHyun KooPublished in: Research square (2023)
Dental caries (tooth decay) is the most prevalent human disease caused by oral biofilms, affecting nearly half of the global population despite increased use of fluoride, the mainstay anticaries (tooth-enamel protective) agent. Recently, an FDA-approved iron oxide nanozyme formulation (ferumoxytol, Fer) has been shown to disrupt caries-causing biofilms with high specificity via catalytic activation of hydrogen peroxide, but it is incapable of interfering with enamel acid demineralization. Here, we find notable synergy when Fer is combined with stannous fluoride (SnF 2 ), markedly inhibiting both biofilm accumulation and enamel damage more effectively than either alone. Unexpectedly, our data show that SnF 2 enhances the catalytic activity of Fer, significantly increasing reactive oxygen species (ROS) generation and antibiofilm activity. We discover that the stability of SnF 2 (unstable in water) is markedly enhanced when mixed with Fer in aqueous solutions without any additives. Further analyses reveal that Sn 2+ is bound by carboxylate groups in the carboxymethyl-dextran coating of Fer, thus stabilizing SnF 2 and boosting the catalytic activity. Notably, Fer in combination with SnF 2 is exceptionally effective in controlling dental caries in vivo , preventing enamel demineralization and cavitation altogether without adverse effects on the host tissues or causing changes in the oral microbiome diversity. The efficacy of SnF 2 is also enhanced when combined with Fer, showing comparable therapeutic effects at four times lower fluoride concentration. Enamel ultrastructure examination shows that fluoride, iron, and tin are detected in the outer layers of the enamel forming a polyion-rich film, indicating co-delivery onto the tooth surface. Overall, our results reveal a unique therapeutic synergism using approved agents that target complementary biological and physicochemical traits, while providing facile SnF 2 stabilization, to prevent a widespread oral disease more effectively with reduced fluoride exposure.
Keyphrases
- drinking water
- hydrogen peroxide
- iron oxide
- reactive oxygen species
- candida albicans
- pseudomonas aeruginosa
- staphylococcus aureus
- genome wide
- endothelial cells
- drug delivery
- nitric oxide
- ionic liquid
- single cell
- quantum dots
- cancer therapy
- oxidative stress
- biofilm formation
- emergency department
- cell death
- gold nanoparticles
- electronic health record
- data analysis
- cystic fibrosis
- dna methylation
- deep learning