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Introduction

Dental caries is a multifactorial disease in which susceptible dental hard tissues are destructed by acidic by-products from bacterial fermentation of dietary carbohydrates . Though the disease process and the potential to prevent and control the disease are now much better understood, caries is still prevalent and a heavy financial burden around the world . Resin composites are popular filling materials . The chemical and physical properties, polymerization characteristics, and placement techniques of composites have been significantly improved . Nearly 200 million dental restorations are placed annually in the U.S. . However, half of all restorations fail within 10 years, with recurrent (secondary) caries as the main reason for failure . As a result, 50–70% of all restorations were replacements of failed restorations . Replacement dentistry is a major economic burden, considering that the annual cost for tooth cavity restorations in the U.S. was approximately $46 billion in 2005 alone .

With the development of new composites and bonding agents, the concept of complete removal of carious dentin during cavity preparation is no longer supported . This is partly because that the complete caries removal approach could not really yield caries-free cavities, with often residual infection and bacteria remaining in the cavities . On the other hand, minimally invasive techniques are recommended for the treatment of deep caries lesions in order to protect pulp vitality and preserve more tooth tissues . Modern minimally invasive techniques require removing the infected-dentin to achieve its objective of least-invasive surgical approach, leaving behind the affected-dentin in the cavity. Various methods were developed to help remove caries-infected tissue as selectively as possible, while being minimally invasive through maximum preservation of caries-affected tissue . With the preservation of more affected tissue, the cavity likely will contain more residual bacteria . Therefore, it would be highly beneficial to develop antibacterial adhesives to eradicate or greatly reduce the residual bacteria in the affected-dentin and eliminate the harmful effects caused by bacteria.

Adhesives bond composite restorations to tooth structures, and extensive studies have been performed to enhance the adhesive compositions, bond strength, and durability . Antibacterial adhesives containing 12-methacryloyloxydodecylpyridinium bromide (MDPB) were developed, which effectively reduced the growth of oral bacteria such as Streptococcus mutans . Other studies developed several different types of novel antibacterial dental materials . A literature search revealed only a few reports on the development of antibacterial primers: a primer containing MDPB , a primer containing chlorhexidine , and a primer containing quaternary ammonium dimethacrylate (QADM) and nanoparticles of silver (NAg) . The primer containing QADM and NAg showed potent antibacterial effects against dental biofilms with bacteria inoculated on the surface of the cured primer and adhesive resins . However, there has been no report on the effect of the QADM–NAg primer against bacteria impregnated into dentin blocks.

Therefore, the objectives of this study were to investigate the antibacterial effects of primers containing QADM and NAg against S. mutans impregnated into human dentin blocks for the first time, and to determine the effects of different primer compositions. It was hypothesized that: (1) QADM- and NAg-containing primers would be able to inhibit S. mutans inside dentin blocks; (2) combining two antibacterial agents QADM and NAg in primer would be more effective than QADM alone, and increasing the NAg mass fraction would increase the antibacterial potency against S. mutans inside dentin; and (3) incorporating QADM and NAg into primer would not compromise the dentin shear bond strength.

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Materials and methods