The nature of early caries lesions in enamel.

Since 1935, various mechanisms have been suggested for the formation of subsurface lesions and, in particular, the surface layer covering enamel lesions. The relatively intact mineral-rich and porous surface layer is most likely caused by kinetic events. The suggested mineral-rich outer layer in sound enamel, the organic matrix, the pellicle, or a non-uniform ion distribution have all been shown to be non-essential for surface layer formation; they may, however, influence the rate of surface layer formation. Models based on outer surface protection by adsorbed agents, the dissolution-precipitation mechanism, and combinations of these two models, as well as models based on porosity or solubility gradients, are discussed in this paper together with their advantages and disadvantages. Most models have not explained some important recent experimental observations on initial in vivo caries lesion formation: e.g., initial enamel lesions formed in vivo do not have a surface layer initially but develop this mineral-rich layer later on; and the fact that the F- level in the solid sound enamel is not determining the subsurface lesion formation. Furthermore, the observations that in vitro fluoride ions in the liquid at very low levels (approximately equal to 0.02 ppm) determine surface layer formation are difficult to explain. A new kinetic model for subsurface lesion formation is described, in which inhibitors such as F- or proteins play an important role. The model predicts that if lesions depth and demineralization period are denoted by df and t, lesion progress can be described by: dfp = alpha t + c, where alpha and c are constants with 1 less than or equal to p less than or equal to 3, depending on the lesion formation conditions. If lesion progress is entirely diffusion-controlled, p = 3, corresponding to low inhibitor concentrations; if the inhibitor content is so high that the progress is controlled by processes at the crystallite surface, p = 1. A kinetic mechanism for surface layer formation in vivo is proposed, based on the assumption that F- is a main inhibitor in the plaque-covered acidic in vivo situation. The inhibiting fluoride, adsorbed onto the crystallite surfaces at OH- vacancies, originates from the so-called fluoride in the liquid phase (FL) between the enamel crystallites. Under acidic conditions (plaque), we have, due to an influx of fluoride from the saliva or plaque as FL, an aqueous phase in the enamel supersaturated with respect to the mineral for a small distance (x*) only.(ABSTRACT TRUNCATED AT 400 WORDS)

[1]  F.C. Besic Carieslike Enamel Changes by Chemical Means , 1953, Journal of dental research.

[2]  F. Driessens,et al.  The surface layer during artificial carious lesion formation. , 1984, Caries research.

[3]  B. J. Murphy,et al.  Development of carious-like lesions in partially saturated lactate buffers. , 1985, Caries research.

[4]  F. Brudevold,et al.  Effects of daily rinsing and ingestion of fluoride solutions upon dental caries and enamel fluoride. , 1972, Archives of oral biology.

[5]  J. Arends,et al.  Progress of artificial carious lesions in enamel. , 1982, Caries research.

[6]  A. E. Nielsen Electrolyte crystal growth mechanisms , 1984 .

[7]  M. Jacobs,et al.  A microscopic comparison of clinically and artificially produced changes in enamel. , 1955, Oral surgery, oral medicine, and oral pathology.

[8]  J M ten Cate,et al.  Comparison of artificial caries-like lesions by quantitative microradiography and microhardness profiles. , 1983, Caries research.

[9]  J. Featherstone,et al.  Relative rates of progress of artificial carious lesions in bovine, ovine and human enamel. , 1981, Caries research.

[10]  J. Christoffersen,et al.  Kinetics of dissolution of calcium hydroxyapatite: IV. The effect of some biologically important inhibitors , 1981 .

[11]  J. Featherstone,et al.  Diffusion Phenomena During Artificial Carious Lesion Formation , 1977, Journal of dental research.

[12]  J Arends,et al.  In vivo remineralization of plaque-induced initial enamel lesions--a microradiographic investigation. , 1986, Caries research.

[13]  H. Margolis,et al.  Kinetic and thermodynamic aspects of enamel demineralization. , 1985, Caries research.

[14]  E. Moreno,et al.  Effect of Salivary Pellicle on Enamel Subsurface Demineralization In Vitro , 1976, Journal of dental research.

[15]  J. Featherstone,et al.  A mechanism for dental caries based on chemical processes and diffusion phenomena during in-vitro caries simulation on human tooth enamel. , 1979, Archives of oral biology.

[16]  J. Arends,et al.  Lesion formation and lesion remineralization in enamel under constant composition conditions. A new technique with applications. , 1985, Caries research.

[17]  F. Feagin,et al.  REMINERALIZATION OF DENTAL ENAMEL BY SALIVA IN VITRO * , 1965, Annals of the New York Academy of Sciences.

[18]  J Arends,et al.  INFLUENCE OF PH AND DEMINERALIZATION TIME ON MINERAL CONTENT, THICKNESS OF SURFACE-LAYER AND DEPTH OF ARTIFICIAL CARIES LESIONS , 1975 .

[19]  ten Cate Jm,et al.  Influence of fluoride in solution on tooth demineralization. I. Chemical data. , 1983 .

[20]  B. Clarkson,et al.  Redistribution of enamel fluoride during white spot lesion formation: an in vitro study on human dental enamel. , 1981, Caries research.

[21]  J. Arends,et al.  KINETICS OF DISSOLUTION OF CALCIUM HYDROXYAPATITE .7. THE EFFECT OF FLUORIDE IONS , 1984 .

[22]  C. Robinson,et al.  The effect of tooth wear on the distribution of fluoride in the enamel surface of human teeth. , 1973, Archives of oral biology.

[23]  J. Arends,et al.  Effect of Various Fluorides on Enamel Structure and Chemistry , 1984 .

[24]  J. Christoffersen,et al.  Kinetics of dissolution of calcium hydroxyapatite: V. The acidity constant for the hydrogen phosphate surface complex , 1982 .

[25]  J. Voegel,et al.  Scanning electron microscopy of the human enamel surface layer of incipient carious lesions. , 1983, Caries research.

[26]  P. Gaengler,et al.  In vivo Remineralization of Human Enamel and Dental Calculus Formation , 1984, Journal of dental research.

[27]  A. E. Nielsen,et al.  Electrolyte crystal growth kinetics , 1984 .

[28]  J. Arends,et al.  Microradiography of in vivo remineralized lesions in human enamel. II. , 1984, Journal de biologie buccale.

[29]  H. Odelius,et al.  Ion Probe Study of Fluorine Gradients in Outermost Layers of Human Enamel , 1976, Journal of dental research.

[30]  J. Arends,et al.  Influence of fluoride concentration on the progress of demineralization in bovine enamel at pH 4.5. , 1983, Caries research.

[31]  J. Arends Mechanism of Dental Caries , 1982 .

[32]  Enamel biopsy results of children receiving fluoride tablets. , 1977, Journal of the American Dental Association.

[33]  S. O. Zimmerman A mathematical theory of enamel solubility and the onset of dental caries: 3. Development and computer simulation of a model of caries formation. , 1966, The Bulletin of mathematical biophysics.

[34]  J. Arends,et al.  MICRORADIOGRAPHY OF INVIVO REMINERALIZED LESIONS IN HUMAN-ENAMEL .2. , 1984 .

[35]  G. H. Nancollas,et al.  Kinetics of dissolution of calcium hydroxyapatite: VI. The effects of adsorption of methylene diphosphonate, stannous ions and partly-peptized collagen , 1983 .

[36]  C. L. Davidson Ontharding van glazuur , 1973 .

[37]  E. Moreno,et al.  Chemistry of Enamel Subsurface Demineralization In Vitro , 1974, Journal of dental research.

[38]  M. Hubbard Correlated Light and Scanning Electron Microscopy of Artificial Carious Lesions , 1982, Journal of dental research.

[39]  J. J. Pollock,et al.  Factors Involved in Artificial Caries Induction by Oral Streptococci in Extracted Human Teeth , 1984, Journal of dental research.

[40]  J. Elliott,et al.  Microradiographic observation of acidic subsurface decalcification in synthetic apatite aggregates. , 1980, Caries research.

[41]  J. Arends,et al.  Enamel lesion formation with and without 0.12 ppm F in solution. , 1985, Caries research.

[42]  J. Ekstrand,et al.  Action of fluoride on initiation of early enamel caries in vivo. A microradiographical investigation. , 1986, Caries research.

[43]  J. M. Cate,et al.  TOOTH ENAMEL REMINERALIZATION , 1981 .

[44]  F. Driessens,et al.  Chemical and mathematical simulation of caries. , 1979, Caries research.

[45]  F. V. Bartheld Membrane phenomena in carious dissolution of the teeth , 1961 .

[46]  Silverstone Lm The surface zone in caries and in caries-like lesions produced in vitro. , 1968 .

[47]  J. Christoffersen,et al.  Kinetics of dissolution of calcium hydroxyapatite: II. Dissolution in non-stoichiometric solutions at constant pH , 1979 .

[48]  J. Arends,et al.  Lesion depth and microhardness indentations on artificial white spot lesions. , 1980, Caries research.

[49]  J. M. ten Cate,et al.  Influence of fluoride in solution on tooth demineralization. I. Chemical data. , 1983, Caries research.

[50]  E. Moreno,et al.  In Vitro Enamel Demineralization by Streptococcus mutans in the Presence of Salivary Pellicles , 1977, Journal of dental research.

[51]  A. H. Meckel The nature and importance of organic deposits on dental enamel. , 1968, Caries research.

[52]  M. Larsen Chemically induced in vitro lesions in dental enamel. , 1974, Scandinavian journal of dental research.

[53]  E. Applebaum The Radiopaque Surface Layer of Enamel and Caries , 1940 .

[54]  J. Arends,et al.  In vivo remineralization of artificial subsurface lesions in human enamel. I. , 1984, Journal de biologie buccale.