Results 291 to 300 of about 27,953 (353)
<i>In vitro</i> Comparison of Shear Bond Strength of Various Cements for Zirconia Crowns.
J Pharm Bioallied SciMurugesan S.
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Biomimetic Approaches in Prosthodontics: Toward Natural Tooth Restoration and Regeneration.
J Pharm Bioallied SciSoni M, Soni P, Soni P.
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Journal of Esthetic and Restorative Dentistry, 2007
Selection of the appropriate dental cement when delivering an indirect restoration is vital to the success of the treatment. This task has become a challenge, considering the different types of luting agents available and the increasing number of different restorative options.
Ricardo Walter, Edward J. Swift
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Selection of the appropriate dental cement when delivering an indirect restoration is vital to the success of the treatment. This task has become a challenge, considering the different types of luting agents available and the increasing number of different restorative options.
Ricardo Walter, Edward J. Swift
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Formation of Dental Silicate Cement [PDF]
Nature, 1970 THE setting of dental silicate cement, a material widely used as an anterior tooth filling1, is generally attributed to the formation of silica gel2. Its potentially high strength (< 3,000 kg/cm2) compared with known silica gel cements3 (150–270 kg/cm2) is, however, at variance with this view.
D. Clinton +5 more
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Dental Clinics of North America, 1971
The manifold uses of dental cements-as (a) luting agents, (b) cavity linings and bases, and (c) restorations for teeth—make them perhaps the most important materials in clinical dentistry. The research of the last 10 years has resulted in four main types, classified by matrix-forming species: (1) phosphate, (2) phenolate, (3) polycarboxylate, and (4 ...
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The manifold uses of dental cements-as (a) luting agents, (b) cavity linings and bases, and (c) restorations for teeth—make them perhaps the most important materials in clinical dentistry. The research of the last 10 years has resulted in four main types, classified by matrix-forming species: (1) phosphate, (2) phenolate, (3) polycarboxylate, and (4 ...
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Journal of Veterinary Dentistry, 2018
This review provides an in-depth comparison of advantages and disadvantages of different types of dental cements as they are used for cementing base metal alloy crowns in dogs.
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This review provides an in-depth comparison of advantages and disadvantages of different types of dental cements as they are used for cementing base metal alloy crowns in dogs.
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An Erosion Test for Dental Cements
Journal of Dental Research, 1985A new method for the in vitro measurement of the erosion of dental cements is described which allows repeated, gentle removal of loose surface debris and provides a direct quantitative measurement of material lost. A linear relationship for erosion against time is demonstrated for a glass polyalkenoate material under mildly acidic conditions.
J J Murray, John F. McCabe, A.W.G. Walls
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The flow properties of dental cements
Journal of Biomedical Materials Research, 1980AbstractThe flow properties of several major types of dental cements were investigated using slow compressive strength and creep techniques. Considerable differences were found in their behavior. Whereas the phosphate‐bonded and glass‐ionomer cements exhibited brittle fracture, the other cements tended to distort to a greater or lesser extent under ...
Alan D. Wilson, Brian G. Lewis
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Thermal diffusivity of dental cements*
Australian Dental Journal, 1986AbstractA transient method for measuring the thermal diffusivity of disc‐shaped specimens of dental cements is presented.
Heitor Panzeri +3 more
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