Caries Management - Science and Clinical Practice. Группа авторов
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Название: Caries Management - Science and Clinical Practice

Автор: Группа авторов

Издательство: Ingram

Жанр: Медицина

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isbn: 9783131693815

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СКАЧАТЬ dentin. Usually, the demineralized areas within a well-developed dentin caries lesion precede the bacterially infected areas. Among the histological techniques used to investigate enamel and dentin caries lesions, light microscopy can be used to reveal different zones within enamel and dentin caries that correspond to different pore volumes and size distribution of such porosities. Microradiographic techniques are able to analyze exactly the mineral content as a function of lesion depth. Scanning electron microscopy shows changes at the enamel surface at early lesion states and within a lesion at the enamel prism level, while transmission electron microscopy provides insight into changes at the crystal level. Even when a caries lesion progresses, demineralization is interrupted by phases of remineralization. Net remineralization can be achieved only when the biological and chemical conditions at the surface of such a lesion change toward a less cariogenic environment. Clinically, this means successful regular plaque removal and administration of fluoride. Under these conditions, the caries process can come to halt and remineralization of the outer layers of enamel or exposed dentin is possible. However, the result of lesion remineralization can be considered to be a “scar,” because complete remineralization in the sense of a “restitutio ad integrum” does not occur. Remineralization of deeper lesions most likely leaves behind a less mineralized area. Both caries and erosion cause loss of mineral from a tooth, but the etiology and the histology are considerably different. Erosion is not caused by bacteria, but by the direct dissolution of enamel and dentin due to acids that originate from the nutrition, the stomach, or other environmental sources. Erosion leads to immediate irreversible loss of calcium and phosphate from the enamel or dentin surface and creates only a shallow softening of the surface. This softened surface is prone to abrasive loss, but may be remineralized when left mechanically undisturbed for some time.

      Acknowledgments. The author would like to thank Prof. Dr. Hans Ulrich Luder, University of Zurich, Center for Dentistry, Institute for Oral Biology for kindly providing Figs. 3.9, 3.10, 3.13, 3.16, 3.17, and 3.18 and for numerous valuable discussions. I also would like to thank Dr. Hao Yu for preparation and imaging of Figs. 3.3, 3.4, and 3.14 and PD Dr. Áine M. Lennon for providing Fig. 3.21.

      REFERENCES

      1. Thylstrup A, Bruun C, Holmen L. In vivo caries models—mechanisms for caries initiation and arrestment. Adv Dent Res 1994; 8(2):144–157

      2. Ekstrand KR, Kuzmina I, Bjørndal L, Thylstrup A. Relationship between external and histologic features of progressive stages of caries in the occlusal fossa. Caries Res 1995;29(4):243–250

      3. Ekstrand KR, Martignon S, Ricketts DJ, Qvist V. Detection and activity assessment of primary coronal caries lesions: a methodologic study. Oper Dent 2007;32(3):225–235

      4. Ekstrand KR, Ricketts DN, Kidd EAM, Qvist V, Schou S. Detection, diagnosing, monitoring and logical treatment of occlusal caries in relation to lesion activity and severity: an in vivo examination with histological validation. Caries Res 1998;32(4):247–254

      5. Carvalho JC, Ekstrand KR, Thylstrup A. Dental plaque and caries on occlusal surfaces of first permanent molars in relation to stage of eruption. J Dent Res 1989;68(5):773–779

      6. Carvalho JC, Ekstrand KR, Thylstrup A. Results after 1 year of non-operative occlusal caries treatment of erupting permanent first molars. Community Dent Oral Epidemiol 1991;19(1):23–28

      7. Carvalho JC, Thylstrup A, Ekstrand KR. Results after 3 years of non-operative occlusal caries treatment of erupting permanent first molars. Community Dent Oral Epidemiol 1992;20(4): 187–192

      8. Nyvad B, Machiulskiene V, Baelum V. Reliability of a new caries diagnostic system differentiating between active and inactive caries lesions. Caries Res 1999;33(4):252–260

      9. Hecht E. Optics. 3rd ed. Reading: Addison-Wesley; 1998

      10. Silverstone L. Structure of carious enamel, including the early lesion. Oral Sci Rev 1973;3:100–160

      11. Silverstone LM, Johnson NW, Hardie JM, Williams RAD. Enamel caries. In: Silverstone LM, Johnson NW, Hardie JM, Williams RAD, eds. Dental Caries: Aetiology, Pathology and Prevention. London: Macmillan; 1981:133–161

      12. Darling A. Studies of the early lesion of enamel caries. Br Dent J 1958;105:119–135

      13. Silverstone LM. Remineralization and enamel caries: significance of fluoride and effect on crystal diameter. In: Leach SA, Edgar WM, eds. Demineralization and Remineralization of Teeth. Oxford: IRL Press: 1983:185–205

      14. Shellis RP, Hallsworth AS, Kirkham J, Robinson C. Organic material and the optical properties of the dark zone in caries lesions of enamel. Eur J Oral Sci 2002;110(5):392–395

      15. Schroeder HE. Karies und Erosion. Pathobio Oral Struktur 1997; 3:95

      16. Meyer-Lueckel H, Paris S, Kielbassa AM. Surface layer erosion of natural caries lesions with phosphoric and hydrochloric acid gels in preparation for resin infiltration. Caries Res 2007;41(3): 223–230

      17. Buchalla W, Attin T, Schulte-Mönting J, Hellwig E. Fluoride uptake, retention, and remineralization efficacy of a highly concentrated fluoride solution on enamel lesions in situ. J Dent Res 2002;81(5):329–333

      18. Angmar B, Carlström D, Glas JE. Studies on the ultrastructure of dental enamel. IV. The mineralization of normal human enamel. J Ultrastruct Res 1963;8:12–23

      19. de Josselin de Jong E, ten Bosch JJ, Noordmans J. Optimised microcomputer-guided quantitative microradiography on dental mineralised tissue slices. Phys Med Biol 1987;32(7):887–899

      20. Arends J, Christoffersen J. The nature of early caries lesions in enamel. J Dent Res 1986;65(1):2–11

      21. Magalhães AC, Moron BM, Comar LP, Wiegand A, Buchalla W, Buzalaf MA. Comparison of cross-sectional hardness and transverse microradiography of artificial carious enamel lesions induced by different demineralising solutions and gels. Caries Res 2009;43(6):474–483

      22. Weatherell JA, Robinson C, Hallsworth AS. Microanalytical studies on single sections of enamel. In: Stack MV, Fearnhead RW, eds. Tooth Enamel II: Its Composition, Properties, and Fundamental Structure. Report of the Proceedings of a Second International Symposium on the Composition, Properties, and Fundamental Structure of Tooth Enamel, held at the London Hospital Medical College, 16/17 June 1969. Bristol: Wright and Sons; 1971:31–38

      23. Boyde A. The structure of developing mammalian dental enamel. In: Stack MV, Fearnhead RW, eds. Tooth Enamel: Its Composition, Properties, and Fundamental Structure: Bristol: Wright and Sons; 1965:163–167

      24. Meckel AH, Griebstein WJ, Neal RJ. Structure of mature human dental enamel as observed by electron microscopy. Arch Oral Biol 1965;10(5):775–783

      25. Johansen E. The nature of СКАЧАТЬ