The influence of saliva on interbacterial adherence.

The mechanism of bacterial adherence to the mat of bacteria in preformed dental plaque is not well defined. This study measured the influence of saliva on the adherence of bacteria in suspension to a continuous bacterial surface in vitro. Twenty different pairs of bacteria were tested, consisting of Streptococcus spp., Haemophilus spp. and Actinomyces spp. The species were chosen based on the parameters of coaggregation, and salivary agglutination. The results were expressed as bacteria that adhered per mm2 of bacterial surface. When both the surface bacteria and the bacteria in suspension agglutinated in saliva, interbacterial adherence was increased 2.5-fold when a salivary coating was placed on the surface. When one or both of the bacteria did not agglutinate in saliva, interbacterial adherence was increased only slightly when the surface was saliva-coated. The results suggested that salivary-mediated adherence is significant to plaque formation once the tooth surface becomes covered with bacteria. Thus bacteria that are capable of agglutinating in saliva may have a distinct advantage in colonization of the plaque surface.

Dental plaque development on defined streptococcal surfaces.

Coaggregations between bacterial species have been widely studied in vitro but not in the mouth. A new in vivo assay was used to measure the rate and composition of indigenous plaque formation onto bovine enamel chips covered with a continuous layer of bacteria. Chips were covered with Streptococcus oralis ATCC 10557, which coaggregated with many oral species, or Streptococcus gordonii S7, which did not coaggregate with these oral species, and placed in the mouth for 4 and 24 h. There were no differences in the number of most indigenous bacterial species isolated from the two streptococcal surfaces. However, the number of Actinomyces viscosus as a proportion of total Actinomyces spp. was significantly different on the two surfaces at 24 h. With the exception of Actinomyces naeslundii and A. viscosus removed from the S7 surface, all indigenous species increased significantly in number from 4 to 24 h, irrespective of the streptococcal surface. This study demonstrated that interbacterial coaggregation had only a limited effect on in vivo plaque development. Thus suggesting that environmental factors, growth or other adherence phenomena are dominant in in vivo plaque formation.

Utilization of a continuous streptococcal surface to measure interbacterial adherence in vitro and in vivo.

Cell-to-cell interactions are essential for the formation of dental plaque. A continuous layer of Streptococcus sanguis SA-1 cells fixed to a solid surface has been used to evaluate interactions among this bacterium, Haemophilus parainfluenzae, and Streptococcus sobrinus. S. sanguis cells were attached to a Falcon 3001 tissue culture plates or bovine enamel chips, coated with a biological adhesive. Scanning electron microscopy of the chips showed the streptococci as a contiguous surface. Radiolabeled bacteria were used to measure a second-species interbacterial adherence to the streptococcal-coated culture plates. Strains of H. parainfluenzae known to coaggregate (strain HP-28) and not to coaggregate (strains HP-42 and HP-80), in suspension with S. sanguis strain SA-1, were studied for adherence. Ten-fold-higher numbers of coaggregating strain HP-28 adhered in vitro to the streptococcal layer than did the non-coaggregating strains. S. sobrinus strain 6715 did not show appreciable adherence to the S. sanguis surface. Saliva did not affect the adherence of coaggregating or non-coaggregating H. parainfluenzae strains to S. sanguis strain SA-1. Bovine enamel chips, coated with streptococci, mounted on modified orthodontic appliances and placed in the mouths of three volunteers, facilitated the measurement of interbacterial adherence in vivo of streptomycin-resistant strains of H. parainfluenzae (HP-28R or HP-42R). Suspensions of bacteria were placed into the mouth, distributed throughout, and expectorated. After 15 or 120 minutes, the appliance with the chips was removed, the chips sonified, and colony-forming units (CFU) of streptomycin-resistant haemophili determined per chip.(ABSTRACT TRUNCATED AT 250 WORDS)