AI Article Synopsis
- Dental caries, caused by bacteria and yeasts forming acid-producing biofilms, remains a preventable but challenging disease, with current prevention methods failing to effectively manage these biofilms.
- Recent research shows that natural compounds like trans-cinnamaldehyde (TC) can inhibit biofilm formation, but delivering these compounds is difficult due to their hydrophobic nature.
- To tackle this issue, a novel delivery system using porous silicon (pSi) microparticles was created, which successfully carried TC, demonstrating a controlled release and significant inhibition of biofilm development and acid production related to dental caries in children.
Article Abstract
Dental caries, a preventable disease, is caused by highly-adherent, acid-producing biofilms composed of bacteria and yeasts. Current caries-preventive approaches are ineffective in controlling biofilm development. Recent studies demonstrate definite advantages in using natural compounds such as trans-cinnamaldehyde in thwarting biofilm assembly, and yet, the remarkable difficulty in delivering such hydrophobic bioactive molecules prevents further development. To address this critical challenge, we have developed an innovative platform composed of components with a proven track record of safety. We fabricated and thoroughly characterised porous silicon (pSi) microparticles to carry and deliver the natural phenyl propanoid trans-cinnamaldehyde (TC). We investigated its effects on preventing the development of cross-kingdom biofilms ( and ), typical of dental caries found in children. The prepared pSi microparticles were roughly cubic in structure with 70-75% porosity, to which the TC (pSi-TC) was loaded with about 45% efficiency. The pSi-TC particles exhibited a controlled release of the cargo over a 14-day period. Notably, pSi-TC significantly inhibited biofilms, specifically downregulating the glucan synthesis pathways, leading to reduced adhesion to the substrate. Acid production, a vital virulent trait for caries development, was also hindered by pSi-TC. This pioneering study highlights the potential to develop the novel pSi-TC as a dental caries-preventive material.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9322055 | PMC |
| http://dx.doi.org/10.3390/pharmaceutics14071428 | DOI Listing |
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