Biofilm Degradation by Seashell-Derived Calcium Hydroxide and Hydrogen Peroxide

Hata, Yoshiya; Bouda, Yuta; Hiruma, Sumiyo; Miyazaki, Hiromi; Nakamura, Shingo

doi:10.3390/nano12203681

Cited by 4 publications

(5 citation statements)

References 38 publications

(44 reference statements)

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“…35 The release of Ca 2+ ions from calcium peroxide has also been reported to elicit an antibacterial effect. 36 The generation of ROS which has been found to improve biofilm degradation appeared to be similar between the CP and ZP, 37 but the antibacterial effectiveness of ZP was lower than CP and MP. Consequently, ROS appeared to be not a key factor rather the combination of pH and hydrogen peroxide.…”

Section: Discussionmentioning

confidence: 98%

Comparison of antimicrobial properties of inorganic peroxide polymer composites

Job,

Matta,

Dang

et al. 2024

MedComm – Biomaterials and Applications

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Wound healing and prevention of bacterial infections are critical aspects of modern medical care. In this work, antibacterial films were produced by creating composites of polycaprolactone with inorganic peroxides. Calcium, magnesium, and zinc peroxide were incorporated in a biocompatible polymeric film. Iron oxide, sodium bicarbonate, and calcium phosphate were added to reduce hydrogen peroxide and to maintain pH in a less alkaline range, allowing for optimization of the material's antibacterial efficacy while minimizing cytotoxicity toward human fibroblasts. Experiments with common wound pathogens, Staphylococcus aureus and Pseudomonas aerugonisa, confirmed significant and prolonged antibacterial effects of peroxide‐doped films. Findings showed that the addition of CaO2 and MgO2 within the film increased cytotoxicity toward human fibroblasts after 48 h (30%–40% decrease compared to control), whereas ZnO2‐based films exhibited a minimal cytotoxicity consistently maintaining over 70% cell viability throughout the course of the experiment. We examined the materials’ sustained release of reactive oxygen species and oxygen, and pH variation correlated with antibacterial activity. Given the unique combination of antibacterial efficacy and mammalian biocompatibility, these peroxides have value as components to sustain hydrogen peroxide release when appropriately compounded to reduce pH variation and avoid excessive hydrogen peroxide levels.

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Section: Discussionmentioning

confidence: 98%

Comparison of antimicrobial properties of inorganic peroxide polymer composites

Job,

Matta,

Dang

et al. 2024

MedComm – Biomaterials and Applications

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“…The secondary mechanism of antimicrobial activity is by the dissociation of CaO in the slurry phase and generation of the high content of Ca2+ and ROS (Reactive Oxygen Species), a cationic environment that bonds with the cardiolipin (negative surface charge) the main lipid in the cell membrane of the pathogen. The binding of Ca2+ and cardiolipin results in changing the cell metabolism, starvation and cell wall rupture of the fungal cell (29,30).…”

Section: Surface Roughness Measurementmentioning

confidence: 99%

Impact of apigenin and seashell nano-additives on the antifungal and roughness behavior of a soft denture liner

Nadia Tawfiq Jaffer,

Rizgar Mohammed-Ameen Hasan,

Ghada Abd Alrhman Taqa

2023

Cell Mol Biol (Noisy-le-grand)

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“…In this context, seashell-derived CaO, which is prepared via heat treatments of seashells composed mainly of calcium carbonate (CaCO 3 ), has been used as a food additive for pH control, nutrient supplement, dough conditioning, and other purposes. , Moreover, studies have investigated its application as a disinfectant with excellent microbicidal and virucidal activities. , The microbicidal and virucidal activities originate mainly from the alkalinity of calcium hydroxide (Ca(OH) 2 ) produced from CaO via hydration, while reactive oxygen species generated by CaO particles may also contribute. ,, Seashell-derived CaO has been shown to exhibit a broad spectrum of microbicidal and virucidal activities against various pathogenic bacteria, viruses, bacterial spores, , fungi, and biofilms, − and its aqueous solutions and suspensions have been investigated for the disinfection of food, such as vegetables, , meats, , and fish . Moreover, we have recently explored the medical use of these water-based disinfectants from seashell-derived CaO. ,− Given that it is a common food additive, seashell-derived CaO is a promising disinfectant for producing safe and pure water that is usable for drinking and even medical purposes; however, the potential of seashell-derived CaO for use in water treatments has rarely been investigated so far.…”

Section: Introductionmentioning

confidence: 99%

“… 27 Moreover, we have recently explored the medical use of these water-based disinfectants from seashell-derived CaO. 11 , 28 − 32 Given that it is a common food additive, seashell-derived CaO is a promising disinfectant for producing safe and pure water that is usable for drinking and even medical purposes; however, the potential of seashell-derived CaO for use in water treatments has rarely been investigated so far.…”

Section: Introductionmentioning

confidence: 99%

Sequential Approach for Water Purification Using Seashell-Derived Calcium Oxide through Disinfection and Flocculation with Polyphosphate for Chemical Pollutant Removal

Hata,

Hiruma,

Miyazaki

et al. 2024

ACS Omega

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Safe water supply is usually inadequate in areas without water treatment plants and even in a city under emergency conditions due to a disaster, even though safe water is essential for drinking and other various purposes. The purification of surface water from a river, lake, or pond requires disinfection and removal of chemical pollutants. In this study, we report a water purification strategy using seashell-derived calcium oxide (CaO) via disinfection and subsequent flocculation with polyphosphate for chemical pollutant removal. Seashell-derived CaO at a concentration (2 g L −1 ) higher than its saturation concentration caused the >99.999% inactivation of bacteria, mainly due to the alkalinity of calcium hydroxide (Ca(OH) 2 ) produced by hydration. After the disinfection, the addition of sodium polyphosphate at 2 g L −1 allowed for the flocculation of CaO/Ca(OH) 2 particles with adsorbing chemical pollutants, such as Congo red, dichlorodiphenyltrichloroethane, di(2-ethylhexyl)phthalate, and polychlorinated biphenyls, for removing these pollutants; purified water was obtained through filtration. Although this purified water was initially highly alkaline (pH ∼ 12.5), its pH decreased into a weak alkaline region (pH ∼ 9) during exposure to ambient air by absorbing carbon dioxide from the air with the precipitating calcium carbonate. The advantages of this water purification strategy include the fact that the saturation of CaO/Ca(OH) 2 potentially serves as a visual indicator of disinfection, that the flocculation by polyphosphate removes excessive CaO/Ca(OH) 2 as well as chemical pollutants, and that the high pH and Ca 2+ concentrations in the resulting purified water are readily decreased. Our findings suggest the usability of seashellderived material−polymer assemblies for water purification, especially under emergency conditions due to disasters.

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Biofilm Degradation by Seashell-Derived Calcium Hydroxide and Hydrogen Peroxide

Cited by 4 publications

References 38 publications

Comparison of antimicrobial properties of inorganic peroxide polymer composites

Comparison of antimicrobial properties of inorganic peroxide polymer composites

Impact of apigenin and seashell nano-additives on the antifungal and roughness behavior of a soft denture liner

Sequential Approach for Water Purification Using Seashell-Derived Calcium Oxide through Disinfection and Flocculation with Polyphosphate for Chemical Pollutant Removal

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