Silver cermets can come in two forms:

• Two bottles, one containing a powder and the other containing a liquid. The powder and liquid must be measured out individually and mixed together by hand.
• A capsule in which the cermet components have already been proportioned correctly. The capsule is shaken in an amalgamator to mix the components.

The powder contains silver and fluoroaluminosilicate glass particles; the silver and glass particles may be fused together or separate. Other components in the powder include titanium oxide which acts as a whitening agent to improve aesthetics.

The liquid is an aqueous solution of a co-polymer of either 37% acrylic or maleic acid, or both, and 9% tartaric acid.

When the liquid and powder are mixed, an acid-base reaction occurs, initiating setting of the cermet.^[1]

Fluoride release edit

Like glass ionomer cements and dental compomers, silver cermets are able to release fluoride over a sustained period of time. However, the evidence suggests the fluoride releasing abilities of cermets are poorer than glass ionomer cements.^[1]

Adhesion edit

Cermets are able to bond to tooth tissue similar to glass ionomer cements. Like glass ionomer cements, it is recommended that the tooth tissue is conditioned with polyacrylic acid (a weak acid) before application.^[1]

Wear resistance edit

There is evidence that cermets have poor wear resistance when used to restore a large surface area. Therefore, it is advisable to limit their use to small restorations, particularly Class I cavities (see Green Vardiman Black Classification section on the Wiki page for Dental Restoration).^[1]

Radiopacity edit

The added silver imparts radio-opacity to cermets which aids radiographic detection of recurrent caries at a future date.^[1]

Silver cermets have performed poorly in clinical practice despite their theorised advantages over glass ionomer cements. As such, they are no longer a popular choice of material and it is unclear whether cermets will continue to be used.^[1]