Rapidly-Dissolving Silver-Containing Bioactive Glasses for Cariostatic Applications

Rodriguez, Omar; Alhalawani, Adel M.F.; Arshad, Saad

doi:10.3390/jfb9020028

Cited by 15 publications

(10 citation statements)

References 58 publications

(70 reference statements)

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“…The alkali-free (especially Na-free) BAG with the composition of 70% diopside, 10% fluorapatite, and 20% tricalcium phosphate is commercially known as FastOs ® BG. Network modifiers such as CaO, Na 2 O, and P 2 O 5 can be incorporated into the elemental Na 2 O-CaO-SiO 2 composition to make the surface and silica network more reactive [14].…”

Section: Compositions Of Bioactive Glassmentioning

confidence: 99%

Bioactive Glass Applications in Dentistry

Skallevold

Rokaya

Khurshid

et al. 2019

IJMS

178

113

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At present, researchers in the field of biomaterials are focusing on the oral hard and soft tissue engineering with bioactive ingredients by activating body immune cells or different proteins of the body. By doing this natural ground substance, tissue component and long-lasting tissues grow. One of the current biomaterials is known as bioactive glass (BAG). The bioactive properties make BAG applicable to several clinical applications involving the regeneration of hard tissues in medicine and dentistry. In dentistry, its uses include dental restorative materials, mineralizing agents, as a coating material for dental implants, pulp capping, root canal treatment, and air-abrasion, and in medicine it has its applications from orthopedics to soft-tissue restoration. This review aims to provide an overview of promising and current uses of bioactive glasses in dentistry.

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Section: Compositions Of Bioactive Glassmentioning

confidence: 99%

Bioactive Glass Applications in Dentistry

Skallevold

Rokaya

Khurshid

et al. 2019

IJMS

178

113

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“…A helpful property of silicate‐based materials is the capacity to be created into diverse mass shapes and structures through high temperature sintering without trading off the biomineralization of the nano‐ceramics. The capability of utilizing silicate‐based materials for bone recovery has been affirmed by various examinations, which reflects the capacity of the material to accomplish direct bonding (biomineralization) with local bone, bringing about positive in vitro and in vivo recovery results 5,21‐24 …”

Section: Resultsmentioning

confidence: 99%

Radiological evaluations of low cost wollastonite nano‐ceramics graft doped with iron oxide in the treatment of induced defects in canine mandible

et al. 2020

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Wollastonite with/without maghemite [(Fe2O3), 0, 3 and 10 wt%] was prepared by facile wet precipitation method. Effect of Fe2O3 presence in the obtained nano‐ceramics on physical structure, morphology, size and the mechanical features was evaluated using X‐ray diffraction, transmission electron microscope, and universal testing machine. Moreover, the in vitro biomineralization was examined using simulated body fluid (SBF) by means of scanning electron microscope/energy dispersive X‐ray, Fourier transform infrared, and inductively coupled plasma. An in vivo study was conducted on 24 adult male mongrel dogs to test the biosafety of fabricated samples in the reconstruction of experimentally induced mandibular bone defects. Bone density was measured through cone beam computed tomography analysis conducted at 1 and 3 months following surgery. Wollastonite was the main phase in all the prepared samples however little maghemite was developed in Fe‐containing samples. No remarkable changes were recognized for physical structure of obtained microcrystalline structures, however, a decrease in particle size was noted in the existence of Fe2O3 (10‐15 nm) when compared to the pure wollastonite (30–50 nm). Mechanical features were dependent on the included Fe2O3 concentration within the wollastonite ceramic matrix. The degree of biomineralization of the samples immersed in SBF was elevated with the increase in Fe2O3 percentage. Clinically, the reconstruction of bone defects was uneventful without any adverse toxic effect. Bone density was significantly increased at 1 and 3 months (p < .001) in grafted defects compared to control ones. Increasing the doping concentrations of iron oxide was associated with significant increase (p < .001) of bone density in all induced defects. Due to the impressive healing effect of current fabricated nano‐ceramics, they are recommended to be utilized as low cost bone graft alternatives.

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“…Besides above content, it may also contain some of biocompatible and bioactive minerals like: Network modifiers, namely CaO, Na 2 O, and P 2 O 5 , are generally used. 5 However, both CaO and Na 2 O may be replaced with magnesium oxide and potassium oxide, which promote apatite crystal formation. To alter the surface reactions and melting properties, aluminum oxide and barium oxide may be added.…”

Section: Compositionmentioning

confidence: 99%

Bioglass: A New Era in Modern Dentistry

Singh

Patil

Mali

et al. 2022

European Journal of General Dentistry

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The function of biomaterials has been to replace infected or injured tissues. The first used biomaterials were bioinert, thus minimizing formation of scar tissue at the interface with host tissues. Bioglass was discovered in 1969. Larry Hench developed Bioglass 45S5, which was the earliest synthetic substance that was bonded chemically with bone. In recent researches it has appeared that Bioglass bonds with bone more readily than other bioceramics; it also indicated that the osteogenic properties are due to stimulation of osteoprogenitor cells by the dissolution products formed from Bioglass. Bioglass is chemically calcium sodium phosphosilicate, which is capable of forming an active chemical bond with the tissues. Bioglass is particularly biocompatible which, when placed in body cavity or on reacting with body stimulating factors, induces hydroxyapatite formation. This paper reviews Bioglass as a material of modern dentistry and its various applications in modern dentistry. It also discusses its composition, methods of preparation, and mechanism of action, along with its advantages and disadvantages.

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Rapidly-Dissolving Silver-Containing Bioactive Glasses for Cariostatic Applications

Cited by 15 publications

References 58 publications

Bioactive Glass Applications in Dentistry

Bioactive Glass Applications in Dentistry

Radiological evaluations of low cost wollastonite nano‐ceramics graft doped with iron oxide in the treatment of induced defects in canine mandible

Bioglass: A New Era in Modern Dentistry

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