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Brain Structure and Function
Published in: Brain Structure and Function 4/2005

01-04-2005 | Original Article

Deposition of cellular cementum onto hypoplastic enamel of fluorotic teeth in wild boars (Sus scrofa L.)

Authors: H. Kierdorf, U. Kierdorf, C. Witzel

Published in: Brain Structure and Function | Issue 4/2005

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Abstract

The nature of deposits present in hypoplastic defects of fluorotic enamel of wild boar teeth was studied by light microscopy and scanning electron microscopy. The fluorotic enamel showed different developmental abnormalities, denoting a severe disturbance of ameloblast function during the secretory stage of amelogenesis. These abnormalities included the occurrence of grossly accentuated incremental lines with associated zones of aprismatic enamel and the presence of different forms of hypoplastic defects. Two types of deposits were present on the hypoplastic enamel: cellular cementum and posteruptively acquired, presumably partially mineralized dental plaque. Coronal cementum is not normally formed in pig teeth. Presence of this tissue in fluorotic teeth of wild boars is seen as indicative of a premature disintegration of the enamel epithelium prior to the completion of amelogenesis. This was supposed to have resulted in a contact of mesenchymal cells of the dental follicle with the surface of the immature enamel and, in consequence, in a differentiation of these cells into cementoblasts. To our knowledge, this is the first study reporting the formation of coronal cementum as part of the spectrum of pathological changes in fluorotic teeth in a species whose tooth crowns are normally free of cementum.
Literature
Arwill T (1974) A qualitative microradiographic study of the enamel and the dentine in ground sections of impacted human permanent teeth. Acta Odont Scand 32:1–13
Briedermann L (1990) Schwarzwild, 2nd edn. DLV, Berlin, pp 106–126
Diekwisch TGH (2001) The developmental biology of cementum. Int J Dev Biol 45:695–706PubMed
Freeman E (1985) Periodontium. In: Ten Cate ER (ed) Oral histology: development, structure, and function. Mosby, St. Louis, pp 234–263
Goodman AH, Rose JC (1990) Assessment of systemic physiological perturbations from dental enamel hypoplasias and associated histological changes. Yrbk Phys Anthropol 33:59–110
Hammarström L (1997) Enamel matrix, cementum development and regeneration. J Clin Periodontol 24:658–668PubMed
Handa K, Saito M, Yamauchi M, Kiyono T, Sato S, Terenaka T, Narayanan AS (2002) Cementum matrix formation in vivo by cultured dental follicle cells. Bone 31:606–611
Heritier M (1982) Experimental induction of cementogenesis on the enamel of transplanted mouse tooth germs. Arch Oral Biol 27:87–97
Ismail OS, Weber DF (1988) Light and scanning electron microscopic observations of the canalicular system of human cellular cementum. Anat Rec 222:121–127
Jones SJ, Boyde A (1974) Coronal cementogenesis in the horse. Arch Oral Biol 19:605–614
Kagayama M, Sasano Y, Mizoguchi I, Takahashi I (1997) Confocal microscopy of cementocytes and their lacunae and canaliculi in rat molars. Anat Embryol 195:491–496
Kierdorf H, Kierdorf U (1992) Zur Frage der Kronenzementbildung an den Backenzähnen des Rehes (Capreolus capreolus L.). Z Jagdwiss 38:160–164
Kierdorf H, Kierdorf U, Richards A, Sedlacek F (2000) Disturbed enamel formation in wild boars (Sus scrofa L.) from fluoride polluted areas in Central Europe. Anat Rec 259:12–24
Kierdorf H, Kierdorf U, Richards A, Josephsen K (2004) Fluoride-induced alterations of enamel structure: an experimental study in the miniature pig. Anat Embryol 207:463–474.
Kilic S, Dixon PM, Kempson SA (1997) A light microscopic and ultrastructural examination of calcified dental tissues of horses: 4. Cement and the amelocemental junction. Equine Vet J 29:213–219
Kodaka T, Debari K (2002) Scanning electron microscopy and energy-dispersive X-ray microanalysis studies of afibrillar cementum and cementicle-like structures in human teeth. J Electron Microsc 51:327–335
Kotányi E (1924) Histologische Befunde an retinierten Zähnen. Z Stomatol 22:747–790
Listgarten MA (1967) A mineralized cuticular structure with connective tissue characteristics on the crowns of human unerupted teeth in amelogenesis imperfecta. Arch Oral Biol 12:877–889
Listgarten MA (1968) A light and electron microscopic study of coronal cementogenesis. Arch Oral Biol 13:93–114
Listgarten MA, Kamin A (1969) The development of a cementum layer over the enamel surface of rabbit molars—a light and electron microscopic study. Arch Oral Biol 14:961–985
Mills PB, Irving JT (1967) Coronal cementogenesis in cattle. Arch Oral Biol 12:929–931
Mitchell SR, Kempson SA, Dixon PM (2003) Structure of peripheral cementum of normal equine cheek teeth. J Vet Dent 20:199–208
Shearer TR, Kolstad DL, Suttie JW (1978) Bovine dental fluorosis: histologic and physical characteristics. Am J Vet Res 39:597–602
Silness J, Gustavsen F, Fejerskov O, Karring T, Löe H (1976) Cellular, afibrillar coronal cementum in human teeth. J Periodontal Res 11:331–338
Schroeder HE (1991) Pathobiologie oraler Strukturen, 2nd edn. Karger, Basel, pp 56–57
Schroeder HE (1992) Orale Strukturbiologie, 4th edn. Thieme, Stuttgart, pp 144–169
Spahr A, Hammarström L (1999) Response of dental follicular cells to the exposure of denuded enamel matrix in rat molars. Eur J Oral Sci 107:360–367
Suckling G, Elliot DC, Thurley DC (1986) The macroscopic appearance and associated histological changes in the enamel organ of hypoplastic lesions of sheep incisor teeth resulting from induced parasitism. Arch Oral Biol 31:427–439
Tonge CH, McCance RA (1965) Severe undernutrition in growing and adult animals. 15. The mouth, jaws and teeth of pigs. Br J Nutr 19:361–372
Weinmann JP, Svoboda JF, Woods PW (1945) Hereditary disturbances of enamel formation and calcification. J Am Dent Assoc 32:397–418
Weinreb MM, Sharav Y (1964) Tooth development in sheep. Am J Vet Res 25:891–908
Yamamoto, T, Domon T, Takahashi S, Islam N, Suzuki R (2000) Twisted plywood structure of an alternating lamellar pattern in cellular cementum of human teeth. Anat Embryol 202:25–30
Zietschmann O, Ackerknecht E, Grau H (1943) Ellenberger-Baum, Handbuch der vergleichenden Anatomie der Haustiere, 18th edn. Springer, Berlin Heidelberg New York, pp 348–394
Metadata
Title
Deposition of cellular cementum onto hypoplastic enamel of fluorotic teeth in wild boars (Sus scrofa L.)
Authors
H. Kierdorf
U. Kierdorf
C. Witzel
Publication date
01-04-2005
Publisher
Springer-Verlag
Published in
Brain Structure and Function / Issue 4/2005
Print ISSN: 1863-2653
Electronic ISSN: 1863-2661
DOI
https://doi.org/10.1007/s00429-004-0442-x

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