Oral Cells and Tissues. Philias R. Garant

Oral Cells and Tissues - Philias R. Garant


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and support I would not have been able to complete my professional education, nor lead a life in academia. I am also grateful to my six children for the love they have shown me.

       Early Tooth Development

      Teeth are formed from oral epithelium, in the form of a dental lamina, and neural crest ectomesenchyme of the maxillary and mandibular processes (Fig 1-1). The oral epithelium contributes the enamel component, and the ectomesenchyme contributes the dentin and cementum components of the fully formed tooth. Although the initiating events that trigger downgrowth of the oral epithelium to form a dental lamina are incompletely understood, it is known that neural crest ectomesenchyme is necessary.1,2 Early reciprocal inductive interactions between the oral epithelium and the underlying ectomesenchyme, and subsequent interactions between the enamel organ and dental papilla, coordinate the sequential events of tooth development.35

      Efforts to understand the instructional signals that originate in each of these interacting tissues have been ongoing for more than 50 years.6,7 Most investigations have been performed with dental tissues obtained from embryonic mice and rats or with the continuously growing incisor teeth of adult mice and rats. Organ culture techniques have been perfected to study the growth of dental tissues in chemically defined media, to observe the results of various epithelial-mesenchymal combinations, and to examine the effects of various growth factors on odontogenesis. Thus, nearly all current insight into the regulatory mechanisms of tooth development has come from studies of animal models, often from tooth buds grown in organ culture.

      This chapter contains a discussion of the initiation of tooth formation and the histodifferentiation of the enamel organ and dental papilla. Subsequent chapters will examine the cytodifferentiation of dentin-and enamel-forming cells and the secretion and mineralization of their respective matrices.

      Early in embryogenesis, soon after the neural tube forms by invagination of the overlying ectoderm, migratory pluripotent neuroepithelial cells, the neural crest cells, migrate from the dorsal midline region of the neural tube.8 In exiting from the neural tube, neural crest cells lose their epithelioid characteristics and assume a mesenchymal phenotype capable of directed cell migration. Cranial neural crest cells invade the developing branchial arches and, in a series of reciprocal inductive interactions with early oral epithelium, form tooth primordia (Figs 1-1 and 1-2). When the movement of dye-injected neural crest cells was traced in organ cultures of developing dental arches, it was shown that neural crest cells from the posterior midbrain, and to a lesser extent from the anterior hindbrain, form dental ectomesenchyme.9 The failure of neural crest ectomesenchymal cells to migrate normally to appropriate sites during craniofacial development leads to serious developmental defects, including the absence of teeth (anodontia) and underdeveloped jawbones (micrognathia).

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      Fig 1-1 Stages in the development of a tooth bud. (A) Oral epithelium and the underlying ectomesenchyme and mesenchyme during the development of the dental lamina (DL). (B) The enamel organ arises from a genetically determined site of the dental lamina by cell proliferation. The dental papilla develops from ectomesenchymal cells of neural crest origin.

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      Fig 1-2 Histologic section of a developing tooth at early bell stage. (DL) Dental lamina; (DP) dental papilla; (DS) dental sac; (EO) enamel organ; (M) mesenchyme; (OE) oral epithelium; (SL) successional lamina. (Hematoxylin-eosin stain. Original magnification × 220.)

      Subsets of cranial neural crest cells give rise to chondrocytes, osteoblasts, periodontal ligament fibroblasts, cementoblasts, and odontoblasts. Final phenotype differentiation is regulated by interaction of the ectomesenchymal cells with extrinsic factors, such as growth factors, and substrate adhesion molecules in the local microenvironment.10 It has been suggested that there may be separate populations of neural crest cells for each tooth type. The molecular code for each tooth type appears to reside in specific sets of homeobox genes.11,12

      The first evidence of tooth formation in humans is observed as a thickening of the oral epithelium in the mandibular, maxillary, and medial nasal processes in the 1-month-old fetus (Figs 1-3 to 1-5). It has been suggested that the zone of epithelial thickening (the dental plate or placode) contains the genetic determinants for the initiating signals that regulate the number and position of the future tooth buds. Experiments with epithelial-mesenchymal tissue recombination have shown that early-stage oral epithelium is capable of inducing tooth development in non-oral ectomesenchyme.1315 When non-oral epithelium is used in the recombination, only bone and cartilage form in the ectomesenchyme. Mouse oral epithelium has been shown to induce biochemical markers of early tooth development in chick oral ectomesenchyme, a tissue thought to have lost its ability to form teeth.16 The results of these studies suggest that the oral ectoderm contains instructional signals for tooth development and perhaps the prepattern for the entire dentition. Weiss et al17 suggested that a very early signaling system (prior to neural crest migration) involving Shh and Pax6 genes might form the basis of epithelial patterning mechanisms for tooth development.

      Formation of the dental lamina

      At a slightly later stage of development (11- to 14-mm embryos), the epithelium invaginates into the underlying mesenchyme to form the dental lamina. This process begins in the distal (molar) region and later in the midline. In 15- to 20-mm human embryos, the dental lamina shows signs of additional differential growth, reflecting the determination of incisor, canine, and molar domains (see Figs 1-4 and 1-5). Deep notches in the dental lamina are present between the incisor and canine domains, especially in the mandible. Continued site-specific enlargement of the dental lamina, along with condensation of neural crest ectomesenchyme, gives rise to the individual tooth buds.

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      Fig 1-3 Facial region of a human embryo. (LNP) Lateral nasal process; (MNP) medial nasal process; (MP) maxillary process; (MdP) mandibular process; (CRL) crown-rump length. (Adapted from Ooe74 with permission.)

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      Fig 1-4 Degree of oral epithelial thickening in various human embryos ranging from 10- to 20-mm crown-rump length (CRL). Note the undulating character of the undersurface of the epithelium. (Adapted from Ooe74 with permission.)

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      Fig 1-5 Model


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