Applied Oral Physiology. Robin Wilding

Applied Oral Physiology - Robin Wilding


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of reactions which produce enzymes capable of inflicting damage to the cell walls of bacteria. These enzymes are also capable of damaging host cells, and this may be another reason for the inflammatory state of the lamina propria under the junctional epithelium. The enzymes found in GCF are evidence of the battle between invading bacteria and the defending neutrophils. For example, there is acid phosphatase (from cell breakdown), glucuronidase, lysozyme, hyaluronidase, and collagenases.

      Review Questions

      1. What do you understand by the term keystone organism?

      2. What features of the oral cavity make it possible to describe it as an ecosystem?

      3. What makes saliva supersaturated?

      4. How does pellicle protect the tooth?

      5. How does sIgA control the growth of oral organisms?

      6. What factors cause a decrease in saliva flow?

      7. What is meant by salivary clearance and how does it affect oral health?

      8. What factors affect the rate of flow of gingival crevicular fluid?

      9. What are the essential differences between GCF and saliva?

      4.3 The Biofilms of the Oral Environment

      The oral flora is established from birth by organisms which are passed from the mother to the child. Many bacteria in the air and in food also have access to the oral cavity but do not survive. The oral flora is therefore a specific and, in health, a fairly stable bacterial community. There are, even in healthy mouths, huge numbers of microorganisms. Saliva contains 100 million organisms per milliliter, but the gingival sulcus supports 100 billion bacteria per milliliter. This massive population of the gingival sulcus is possible because the oral organisms have adopted a communal existence. They have formed biofilms, in which a variety of species live in a densely packed mass. The oral biofilms depend on the establishment of a symbiotic relationship with their host and a symbiotic relationship between species, in order for their ecosystem to thrive.

      4.3.1 Biofilms

      Slime is an everyday description of the slippery film, which covers surfaces which are always wet. Slime collects on the inside of water pipes, the bottoms of ships, artificial heart valves, the lining of the gut, rocks, and plants in ponds, rivers, and sea. The word slime tells us that is slippery but not that is made up of living organisms, so biofilm is a more accurate description. Biofilms have a most interesting characteristic, in that the different species of bacteria show levels of interaction, cooperation, and organization not found in their free-swimming or planktonic forms. The collective behavior of organisms creates a microecosystem. Over time, a stable hierarchy and balance between the different species develop. As we have noted in other ecosystems, some organisms, the keystone species, have a disproportionate influence. These organisms may influence the structure of the biofilm, and if it is in a symbiotic relationship with a host, the keystone species determine the biofilms’ relationship with the host.

      The deeper layers of a biofilm have a lower concentration of oxygen than the surface layer. These oxygen-depleted layers provide a suitable microenvironment for anaerobic organisms which are unable to survive in the oxygen-rich (aerobic) environment of the oral cavity. The deeper layers of the biofilm would also have lower concentrations of nutrients were it not for channels which are maintained for the transport of nutrients through the mass of organisms.

      Fig. 4.7 A SEM image (magnification × 300) of calcified plaque (calculus) which was etched to remove all the organic material. The remaining calcified material reflects the structural organization of the living biofilm just as a piece of dried coral is a relic of the ecosystem of the living reef. The insert (magnification × 1000) reveals laminations and channels which the organisms have constructed to define a variety of habitats within the plaque biofilm.

      These channels may be seen in an oral biofilm which has calcified (calculus), a process which mineralizes the soft matrix and preserves its architecture (▶ Fig. 4.7). The gradients of substrate concentration, oxygen availability, and pH in the complex structure of the biofilm provide a wide variety of habitats for microorganisms. The structural organization and functional coordination of organisms in a biofilm and the specialized role of some species, which orchestrate the behavior of other species bring biofilms close to the realms of a single organism.

      The external environment has at first a decisive influence on the early colonizing species of a biofilm. As the biofilm matures, the cooperative influence of the early colonizers creates an inner structural and functional organization. The biofilm begins to create its own inner environment which supports organisms that would not otherwise survive in the external environment. This dynamic, in which organisms create a purpose-defined environment for the benefit of their own and other species, requires a review of accepted evolutionary theory. This orthodox view places the organism within an environment to which it must adapt or die. The restriction has not provided for the organism to create its own environment by cooperation with other species. Cross-talk between organisms, now known as quorum sensing, would have been ridiculed just 50 years ago. It is about 50 years ago an idea, suggested by James Lovelock, that the biosphere regulated itself was also ridiculed. The theory was unfortunately given a mystic name Gaia (earth mother), but it was supported by serious scientists. The more that is understood of the structural and organizational microenvironments created by biofilms, the more likely it becomes that the Gaia theory of biosphere self-regulation is a manifestation of an upscaled version of the self-organization found in biofilms (see Appendix D.3 Gaia Theory).

      4.3.2 Calculus

      Saliva is saturated with calcium and phosphate ions which may precipitate in an alkaline environment. If the precipitate occurs within plaque, it forms a firm, chalky deposit called calculus (Fig. 4.7). Plaque may become alkaline due to the activity of some oral bacteria which release ammonia during their metabolism of salivary urea. Calculus which is supragingival is generally white and chalky, whereas calculus which is subgingival is darker and harder. The precipitated calcium is either soft brushite (supragingival) or harder whitlockite (subgingival, perhaps from calcium in the crevicular fluid). The submandibular gland saliva has a higher concentration of calcium than other glands and has a relatively high pH. This may explain the rapid accumulation of calculus on the lingual surfaces of the lower incisors. Deposits of calculus have been implicated as a cause of gingivitis and periodontitis. Removal of calculus by prophylaxis has long been thought to help prevent periodontal disease although recent evidence challenges this assumption.

      4.3.3 Growth of a Biofilm

      Growth of a biofilm occurs in three distinct phases (▶ Fig. 4.8).

      Adherence to a substrate is the first phase. Generally, hydrophilic (water-loving) surfaces encourage bacterial attachment and hydrophobic surfaces encourage their detachment. Many species of oral organisms produce biosurfactants, which decrease the surface tension of the substrate surface, causing it to become hydrophilic. These biosurfactants are of universal benefit to all species of adhering organism, so the production of them has communal value. The attachments made by organisms onto oral surfaces are either by specific protein adherent sites (ligands) on the bacterial cell membrane or nonspecific polysaccharide attachments via fibrils. Of these two forms of attachment, the fibrillar attachments, though less specific, are stronger than the rather weak but specific


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