Tooth development

Tooth development or odontogenesis is the complex process by which teeth form from embryonic cells, grow, and erupt into the mouth. Although many diverse species have teeth, non-human tooth development is largely the same as in humans. For human teeth to have a healthy oral environment, enamel, dentin, cementum, and the periodontium must all develop during appropriate stages of fetal development. Primary (baby) teeth start to form between the sixth and eighth weeks, and permanent teeth begin to form in the twentieth week.[1] If teeth do not start to develop at or near these times, they will not develop at all.

A significant amount of research has focused on determining the processes that initiate tooth development. It is widely accepted that there is a factor within the tissues of the first branchial arch that is necessary for the development of teeth.[1]

In vertebrates several specializations of epithelial tissue ('phanères') generate after thickening specific structures: keratinized structure (hair, nails) or exoskeletons structure (scales, teeth). Placoids scales and teeth of sharks are considered homologous organs.[2]

Contents

Overview

The tooth bud (sometimes called the tooth germ) is an aggregation of cells that eventually forms a tooth.[3] These cells are derived from the ectoderm of the first branchial arch and the ectomesenchyme of the neural crest.[1][4][5] The tooth bud is organized into three parts: the enamel organ, the dental papilla and the dental follicle.

The enamel organ is composed of the outer enamel epithelium, inner enamel epithelium, stellate reticulum and stratum intermedium.[3] These cells give rise to ameloblasts, which produce enamel and the reduced enamel epithelium. The location where the outer enamel epithelium and inner enamel epithelium join is called the cervical loop.[1] The growth of cervical loop cells into the deeper tissues forms Hertwig's Epithelial Root Sheath, which determines the root shape of the tooth. [6]

The dental papilla contains cells that develop into odontoblasts, which are dentin-forming cells.[3] Additionally, the junction between the dental papilla and inner enamel epithelium determines the crown shape of a tooth.[1] Mesenchymal cells within the dental papilla are responsible for formation of tooth pulp.

The dental follicle gives rise to three important entities: cementoblasts, osteoblasts, and fibroblasts. Cementoblasts form the cementum of a tooth. Osteoblasts give rise to the alveolar bone around the roots of teeth. Fibroblasts develop the periodontal ligaments which connect teeth to the alveolar bone through cementum.[7]

Human tooth development timeline

The following tables present the development timeline of human teeth.[8] Times for the initial calcification of primary teeth are for weeks in utero. Abbreviations: wk = weeks; mo = months; yr = years.

Maxillary (upper) teeth
Primary teeth Central
incisor
Lateral
incisor

Canine
First
molar
Second
molar
Initial calcification 14 wk I.U. 16 wk I.U. 17 wk I.U. 15.5 wk I.U. 19 wk I.U.
Crown completed 1.5 mo 2.5 mo 9 mo 6 mo 11 mo
Root completed 1.5 yr 2 yr 3.25 yr 2.5 yr 3 yr
 Mandibular (lower) teeth 
Initial calcification 14 wk I.U. 16 wk I.U. 17 wk I.U. 15.5 wk I.U. 18 wk I.U.
Crown completed 2.5 mo 3 mo 9 mo 5.5 mo 10 mo
Root completed 1.5 yr 1.5 yr 3.25 yr 2.5 yr 3 yr
Maxillary (upper) teeth
Permanent teeth Central
incisor
Lateral
incisor

Canine
First
premolar
Second
premolar
First
molar
Second
molar
Third
molar
Initial calcification 3–4 mo 10–12 mo 4–5 mo 1.5–1.75 yr 2–2.25 yr at birth 2.5–3 yr 7–9 yr
Crown completed 4–5 yr 4–5 yr 6–7 yr 5–6 yr 6–7 yr 2.5–3 yr 7–8 yr 12–16 yr
Root completed 10 yr 11 yr 13–15 yr 12–13 yr 12–14 yr 9–10 yr 14–16 yr 18–25 yr
 Mandibular (lower) teeth 
Initial calcification 3–4 mo 3–4 mo 4–5 mo 1.5–2 yr 2.25–2.5 yr at birth 2.5–3 yr 8–10 yr
Crown completed 4–5 yr 4–5 yr 6–7 yr 5–6 yr 6–7 yr 2.5–3 yr 7–8 yr 12–16 yr
Root completed 9 yr 10 yr 12–14 yr 12–13 yr 13–14 yr 9–10 yr 14–15 yr 18–25 yr

The developing tooth bud

One of the earliest steps in the formation of a tooth that can be seen microscopically is the distinction between the vestibular lamina and the dental lamina. The dental lamina connects the developing tooth bud to the epithelial layer of the mouth for a significant time.[9]

Tooth development is commonly divided into the following stages: the bud stage, the cap, the bell, and finally maturation. The staging of tooth development is an attempt to categorize changes that take place along a continuum; frequently it is difficult to decide what stage should be assigned to a particular developing tooth.[1] This determination is further complicated by the varying appearance of different histologic sections of the same developing tooth, which can appear to be different stages.

Bud stage

The bud stage is characterized by the appearance of a tooth bud without a clear arrangement of cells. The stage technically begins once epithelial cells proliferate into the ectomesenchyme of the jaw.[1] Typically, this occurs when the fetus is around 6 weeks old.[10] The tooth bud itself is the group of cells at the end of the dental lamina.

Along with the formation of the dental lamina, 10 round epithelial structures, each referred to as a bud, develop at the distal aspect of the dental lamina of each arch. These correspond to the 10 deciduous teeth of each dental arch, and they signify the bud stage of tooth development. Each bud is separated from the ectomesenchyme by a basement membrane. Ectomesenchymal cells congregate deep to the bud, forming a cluster of cells, which is the initiation of the condensation of the ectomesenchyme. The remaining ectomesenchymal cells are arranged in a more or less haphazardly uniform fashion.

Cap stage

The first signs of an arrangement of cells in the tooth bud occur in the cap stage. A small group of ectomesenchymal cells stops producing extracellular substances, which results in an aggregation of these cells called the dental papilla. At this point, the tooth bud grows around the ectomesenchymal aggregation, taking on the appearance of a cap, and becomes the enamel (or dental) organ. A condensation of ectomesenchymal cells called the dental follicle surrounds the enamel organ and limits the dental papilla. Eventually, the enamel organ will produce enamel, the dental papilla will produce dentin and pulp, and the dental follicle will produce all the supporting structures of a tooth.[1]

Bell stage

The bell stage is known for the histodifferentiation and morphodifferentiation that takes place. The dental organ is bell-shaped during this stage, and the majority of its cells are called stellate reticulum because of their star-shaped appearance.THE BELL STAGE IS DIVIDED INTO EARLY BELL STAGE & LATE BELL STAGES. &[1] Cells on the periphery of the enamel organ separate into three important layers. Cuboidal cells on the periphery of the dental organ are known as outer enamel epithelium.[3] The columnar cells of the enamel organ adjacent to the dental papilla are known as inner enamel epithelium. The cells between the inner enamel epithelium and the stellate reticulum form a layer known as the stratum intermedium. The rim of the dental organ where the outer and inner enamel epithelium join is called the cervical loop.[11] In summary, the layers in order of innermost to outermost consist of dentine, enamel (formed by inner enamel epithelium, or 'ameloblasts', as they move outwards/upwards), inner enamel epithelium and stratum intermedium (specialised stratified cells that support the synthetic activity of the Inner Enamel Epithelium) What follows is part of the initial 'enamel organ', the middle of which is made up of stellate reticulum cells. This is all encased by the outer enamel epithelium layer.

Other events occur during the bell stage. The dental lamina disintegrates, leaving the developing teeth completely separated from the epithelium of the oral cavity; the two will not join again until the final eruption of the tooth into the mouth.[1]

The crown of the tooth, which is influenced by the shape of the internal enamel epithelium, also takes shape during this stage. Throughout the mouth, all teeth undergo this same process; it is still uncertain why teeth form various crown shapes—for instance, incisors versus canines. There are two dominant hypotheses. The "field model" proposes there are components for each type of tooth shape found in the ectomesenchyme during tooth development. The components for particular types of teeth, such as incisors, are localized in one area and dissipate rapidly in different parts of the mouth. Thus, for example, the "incisor field" has factors that develop teeth into incisor shape, and this field is concentrated in the central incisor area, but decreases rapidly in the canine area. The other dominant hypothesis, the "clone model", proposes that the epithelium programs a group of ectomesenchymal cells to generate teeth of particular shapes. This group of cells, called a clone, coaxes the dental lamina into tooth development, causing a tooth bud to form. Growth of the dental lamina continues in an area called the "progress zone". Once the progress zone travels a certain distance from the first tooth bud, a second tooth bud will start to develop. These two models are not necessarily mutually exclusive, nor does widely accepted dental science consider them to be so: it is postulated that both models influence tooth development at different times.[1]

Other structures that may appear in a developing tooth in this stage are enamel knots, enamel cords, and enamel niche.[1]

Crown stage

Hard tissues, including enamel and dentin, develop during the next stage of tooth development. This stage is called the crown, or maturation, stage by some researchers. Important cellular changes occur at this time. In prior stages, all of the inner enamel epithelium cells were dividing to increase the overall size of the tooth bud, but rapid dividing, called mitosis, stops during the crown stage at the location where the cusps of the teeth form. The first mineralized hard tissues form at this location. At the same time, the inner enamel epithelial cells change in shape from cuboidal to columnar. The nuclei of these cells move closer to the stratum intermedium and away from the dental papilla.[1]

The adjacent layer of cells in the dental papilla suddenly increases in size and differentiates into odontoblasts, which are the cells that form dentin.[12] Researchers believe that the odontoblasts would not form if it were not for the changes occurring in the inner enamel epithelium. As the changes to the inner enamel epithelium and the formation of odontoblasts continue from the tips of the cusps, the odontoblasts secrete a substance, an organic matrix, into their immediate surrounding. The organic matrix contains the material needed for dentin formation. As odontoblasts deposit organic matrix, they migrate toward the center of the dental papilla. Thus, unlike enamel, dentin starts forming in the surface closest to the outside of the tooth and proceeds inward. Cytoplasmic extensions are left behind as the odontoblasts move inward. The unique, tubular microscopic appearance of dentin is a result of the formation of dentin around these extensions.[1]

After dentin formation begins, the cells of the inner enamel epithelium secrete an organic matrix against the dentin. This matrix immediately mineralizes and becomes the tooth's enamel. Outside the dentin are ameloblasts, which are cells that continue the process of enamel formation; therefore, enamel formation moves outwards, adding new material to the outer surface of the developing tooth.

Hard tissue formation

Enamel

Enamel formation is called amelogenesis and occurs in the crown stage of tooth development. "Reciprocal induction" governs the relationship between the formation of dentin and enamel; dentin formation must always occur before enamel formation. Generally, enamel formation occurs in two stages: the secretory and maturation stages.[13] Proteins and an organic matrix form a partially mineralized enamel in the secretory stage; the maturation stage completes enamel mineralization.

In the secretory stage, ameloblasts release enamel proteins that contribute to the enamel matrix, which is then partially mineralized by the enzyme alkaline phosphatase.[14] The appearance of this mineralized tissue, which occurs usually around the third or fourth month of pregnancy, marks the first appearance of enamel in the body. Ameloblasts deposit enamel at the location of what become cusps of teeth alongside dentin. Enamel formation then continues outward, away from the center of the tooth.

In the maturation stage, the ameloblasts transport some of the substances used in enamel formation out of the enamel. Thus, the function of ameloblasts changes from enamel production, as occurs in the secretory stage, to transportation of substances. Most of the materials transported by ameloblasts in this stage are proteins used to complete mineralization. The important proteins involved are amelogenins, ameloblastins, enamelins, and tuftelins.[15] By the end of this stage, the enamel has completed its mineralization.

Dentin

Dentin formation, known as dentinogenesis, is the first identifiable feature in the crown stage of tooth development. The formation of dentin must always occur before the formation of enamel. The different stages of dentin formation result in different types of dentin: mantle dentin, primary dentin, secondary dentin, and tertiary dentin.

Odontoblasts, the dentin-forming cells, differentiate from cells of the dental papilla. They begin secreting an organic matrix around the area directly adjacent to the inner enamel epithelium, closest to the area of the future cusp of a tooth. The organic matrix contains collagen fibers with large diameters (0.1–0.2 μm in diameter).[16] The odontoblasts begin to move toward the center of the tooth, forming an extension called the odontoblast process.[1] Thus, dentin formation proceeds toward the inside of the tooth. The odontoblast process causes the secretion of hydroxyapatite crystals and mineralization of the matrix. This area of mineralization is known as mantle dentin and is a layer usually about 150 μm thick.[16]

Whereas mantle dentin forms from the preexisting ground substance of the dental papilla, primary dentin forms through a different process. Odontoblasts increase in size, eliminating the availability of any extracellular resources to contribute to an organic matrix for mineralization. Additionally, the larger odontoblasts cause collagen to be secreted in smaller amounts, which results in more tightly arranged, heterogeneous nucleation that is used for mineralization. Other materials (such as lipids, phosphoproteins, and phospholipids) are also secreted.[16]

Secondary dentin is formed after root formation is finished and occurs at a much slower rate. It is not formed at a uniform rate along the tooth, but instead forms faster along sections closer to the crown of a tooth.[17] This development continues throughout life and accounts for the smaller areas of pulp found in older individuals.[16] Tertiary dentin, also known as reparative dentin, forms in reaction to stimuli, such as attrition or dental caries.[18]

Cementum

Cementum formation is called cementogenesis and occurs late in the development of teeth. Cementoblasts are the cells responsible for cementogenesis. Two types of cementum form: cellular and acellular.[19]

Acellular cementum forms first. The cementoblasts differentiate from follicular cells, which can only reach the surface of the tooth's root once Hertwig's Epithelial Root Sheath (HERS) has begun to deteriorate. The cementoblasts secrete fine collagen fibrils along the root surface at right angles before migrating away from the tooth. As the cementoblasts move, more collagen is deposited to lengthen and thicken the bundles of fibers. Noncollagenous proteins, such as bone sialoprotein and osteocalcin, are also secreted.[20] Acellular cementum contains a secreted matrix of proteins and fibers. As mineralization takes place, the cementoblasts move away from the cementum, and the fibers left along the surface eventually join the forming periodontal ligaments.

Cellular cementum develops after most of the tooth formation is complete and after the tooth occludes (in contact) with a tooth in the opposite arch.[20] This type of cementum forms around the fiber bundles of the periodontal ligaments. The cementoblasts forming cellular cementum become trapped in the cementum they produce.

The origin of the formative cementoblasts is believed to be different for cellular cementum and acellular cementum. One of the major current hypotheses is that cells producing cellular cementum migrate from the adjacent area of bone, while cells producing acellular cementum arise from the dental follicle.[20] Nonetheless, it is known that cellular cementum is usually not found in teeth with one root.[20] In premolars and molars, cellular cementum is found only in the part of the root closest to the apex and in interradicular areas between multiple roots.

Formation of the periodontium

The periodontium, which is the supporting structure of a tooth, consists of the cementum, periodontal ligaments, gingiva, and alveolar bone. Cementum is the only one of these that is a part of a tooth. Alveolar bone surrounds the roots of teeth to provide support and creates what is commonly called a "socket". Periodontal ligaments connect the alveolar bone to the cementum, and the gingiva is the surrounding tissue visible in the mouth.[21]

Periodontal ligament

Cells from the dental follicle give rise to the periodontal ligament (PDL). Specific events leading to the formation of the periodontal ligament vary between deciduous (baby) and permanent teeth and among various species of animals.[20] Nonetheless, formation of the periodontal ligament begins with ligament fibroblasts from the dental follicle. These fibroblasts secrete collagen, which interacts with fibers on the surfaces of adjacent bone and cementum.[22] This interaction leads to an attachment that develops as the tooth erupts into the mouth. The occlusion, which is the arrangement of teeth and how teeth in opposite arches come in contact with one another, continually affects the formation of periodontal ligament. This perpetual creation of periodontal ligament leads to the formation of groups of fibers in different orientations, such as horizontal and oblique fibers.[20]

Alveolar bone

As root and cementum formation begin, bone is created in the adjacent area. Throughout the body, cells that form bone are called osteoblasts. In the case of alveolar bone, these osteoblast cells form from the dental follicle.[20] Similar to the formation of primary cementum, collagen fibers are created on the surface nearest the tooth, and they remain there until attaching to periodontal ligaments.

Like any other bone in the human body, alveolar bone is modified throughout life. Osteoblasts create bone and osteoclasts destroy it, especially if force is placed on a tooth.[23] As is the case when movement of teeth is attempted through orthodontics, an area of bone under compressive force from a tooth moving toward it has a high osteoclast level, resulting in bone resorption. An area of bone receiving tension from periodontal ligaments attached to a tooth moving away from it has a high number of osteoblasts, resulting in bone formation.

Gingiva

The connection between the gingiva and the tooth is called the dentogingival junction. This junction has three epithelial types: gingival, sulcular, and junctional epithelium. These three types form from a mass of epithelial cells known as the epithelial cuff between the tooth and the mouth.[20]

Much about gingival formation is not fully understood, but it is known that hemidesmosomes form between the gingival epithelium and the tooth and are responsible for the primary epithelial attachment.[20] Hemidesmosomes provide anchorage between cells through small filament-like structures provided by the remnants of ameloblasts. Once this occurs, junctional epithelium forms from reduced enamel epithelium, one of the products of the enamel organ, and divides rapidly. This results in the perpetually increasing size of the junctional epithelial layer and the isolation of the remnants of ameloblasts from any source of nutrition. As the ameloblasts degenerate, a gingival sulcus is created.

Nerve and vascular formation

Frequently, nerves and blood vessels run parallel to each other in the body, and the formation of both usually takes place simultaneously and in a similar fashion. However, this is not the case for nerves and blood vessels around the tooth, because of different rates of development.[1]

Nerve formation

Nerve fibers start to near the tooth during the cap stage of tooth development and grow toward the dental follicle. Once there, the nerves develop around the tooth bud and enter the dental papilla when dentin formation has begun. Nerves never proliferate into the enamel organ.<[1]

Vascular formation

Blood vessels grow in the dental follicle and enter the dental papilla in the cap stage.[1] Groups of blood vessels form at the entrance of the dental papilla. The number of blood vessels reaches a maximum at the beginning of the crown stage, and the dental papilla eventually forms in the pulp of a tooth. Throughout life, the amount of pulpal tissue in a tooth decreases, which means that the blood supply to the tooth decreases with age.[23] The enamel organ is devoid of blood vessels because of its epithelial origin, and the mineralized tissues of enamel and dentin do not need nutrients from the blood.

Tooth eruption

Tooth eruption occurs when the teeth enter the mouth and become visible. Although researchers agree that tooth eruption is a complex process, there is little agreement on the identity of the mechanism that controls eruption.[24] Some commonly held theories that have been disproven over time include: (1) the tooth is pushed upward into the mouth by the growth of the tooth's root, (2) the tooth is pushed upward by the growth of the bone around the tooth, (3) the tooth is pushed upward by vascular pressure, and (4) the tooth is pushed upward by the cushioned hammock.[25] The cushioned hammock theory, first proposed by Harry Sicher, was taught widely from the 1930s to the 1950s. This theory postulated that a ligament below a tooth, which Sicher observed under a microscope on a histologic slide, was responsible for eruption. Later, the "ligament" Sicher observed was determined to be merely an artifact created in the process of preparing the slide.[26]

The most widely held current theory is that while several forces might be involved in eruption, the periodontal ligaments provide the main impetus for the process. Theorists hypothesize that the periodontal ligaments promote eruption through the shrinking and cross-linking of their collagen fibers and the contraction of their fibroblasts.[27]

Although tooth eruption occurs at different times for different people, a general eruption timeline exists. Typically, humans have 20 primary (baby) teeth and 32 permanent teeth.[28] Tooth eruption has three stages. The first, known as deciduous dentition stage, occurs when only primary teeth are visible. Once the first permanent tooth erupts into the mouth, the teeth are in the mixed (or transitional) dentition. After the last primary tooth falls out of the mouth—a process known as exfoliation—the teeth are in the permanent dentition.

Primary dentition starts on the arrival of the mandibular central incisors, usually at eight months, and lasts until the first permanent molars appear in the mouth, usually at six years.[29] The primary teeth typically erupt in the following order: (1) central incisor, (2) lateral incisor, (3) first molar, (4) canine, and (5) second molar.[30] As a general rule, four teeth erupt for every six months of life, mandibular teeth erupt before maxillary teeth, and teeth erupt sooner in females than males.[31] During primary dentition, the tooth buds of permanent teeth develop below the primary teeth, close to the palate or tongue.

Mixed dentition starts when the first permanent molar appears in the mouth, usually at six years, and lasts until the last primary tooth is lost, usually at eleven or twelve years.[32] Permanent teeth in the maxilla erupt in a different order from permanent teeth on the mandible. Maxillary teeth erupt in the following order: (1) first molar (2) central incisor, (3) lateral incisor, (4) first premolar, (5) second premolar, (6) canine, (7) second molar, and (8) third molar. Mandibular teeth erupt in the following order: (1) first molar (2) central incisor, (3) lateral incisor, (4) canine, (5) first premolar, (6) second premolar, (7) second molar, and (8) third molar. Since there are no premolars in the primary dentition, the primary molars are replaced by permanent premolars.[33] If any primary teeth are lost before permanent teeth are ready to replace them, some posterior teeth may drift forward and cause space to be lost in the mouth.[34] This may cause crowding and/or misplacement once the permanent teeth erupt, which is usually referred to as malocclusion. Orthodontics may be required in such circumstances for an individual to achieve a straight set of teeth.

The permanent dentition begins when the last primary tooth is lost, usually at 11 to 12 years, and lasts for the rest of a person's life or until all of the teeth are lost (edentulism). During this stage, third molars (also called "wisdom teeth") are frequently extracted because of decay, pain or impactions. The main reasons for tooth loss are decay and periodontal disease.[35]

Eruption times for primary and permanent teeth [36]
Primary teeth
Central
incisor
Lateral
incisor

Canine
First
premolar
Second
premolar
First
molar
Second
molar
Third
molar
Maxillary teeth 10 mo 11 mo 19 mo 16 mo 29 mo
Mandibular teeth 8 mo 13 mo 20 mo 16 mo 27 mo
Permanent teeth
Central
incisor
Lateral
incisor

Canine
First
premolar
Second
premolar
First
molar
Second
molar
Third
molar
Maxillary teeth 7–8 yr 8–9 yr 11–12 yr 10–11 yr 10–12 yr 6–7 yr 12–13 yr 17–21 yr
Mandibular teeth 6–7 yr 7–8 yr 9–10 yr 10–12 yr 11–12 yr 6–7 yr 11–13  yr 17–21 yr

Immediately after the eruption enamel is covered by a specific film: Nasmyth's membrane or 'enamel cuticle', structure of embryological origin is composed of keratin which gives rise to the enamel organ.[37][38]

Nutrition and tooth development

As in other aspects of human growth and development, nutrition has an effect on the developing tooth. Essential nutrients for a healthy tooth include calcium, phosphorus, and vitamins A, C, and D.[39] Calcium and phosphorus are needed to properly form the hydroxyapatite crystals, and their levels in the blood are maintained by Vitamin D. Vitamin A is necessary for the formation of keratin, as Vitamin C is for collagen. Fluoride is incorporated into the hydroxyapatite crystal of a developing tooth and makes it more resistant to demineralization and subsequent decay.[22]

Deficiencies of these nutrients can have a wide range of effects on tooth development.[40] In situations where calcium, phosphorus, and vitamin D are deficient, the hard structures of a tooth may be less mineralized. A lack of vitamin A can cause a reduction in the amount of enamel formation. Fluoride deficiency causes increased demineralization when the tooth is exposed to an acidic environment, and also delays remineralization. Furthermore, an excess of fluoride while a tooth is in development can lead to a condition known as fluorosis.

Abnormalities

There are a number of tooth abnormalities relating to development.

Anodontia is a complete lack of tooth development, and hypodontia is a lack of some tooth development. Anodontia is rare, most often occurring in a condition called Hypohidrotic ectodermal dysplasia, while hypodontia is one of the most common developmental abnormalities, affecting 3.5–8.0% of the population (not including third molars). The absence of third molars is very common, occurring in 20–23% of the population, followed in prevalence by the second premolar and lateral incisor. Hypodontia is often associated with the absence of a dental lamina, which is vulnerable to environmental forces, such as infection and chemotherapy medications, and is also associated with many syndromes, such as Down syndrome and Crouzon syndrome.[41]

Hyperdontia is the development of extraneous teeth. It occurs in 1–3% of Caucasians and is more frequent in Asians.[42] About 86% of these cases involve a single extra tooth in the mouth, most commonly found in the maxilla, where the incisors are located.[43] Hyperdontia is believed to be associated with an excess of dental lamina.

Dilaceration is an abnormal bend found on a tooth, and is nearly always associated with trauma that moves the developing tooth bud. As a tooth is forming, a force can move the tooth from its original position, leaving the rest of the tooth to form at an abnormal angle. Cysts or tumors adjacent to a tooth bud are forces known to cause dilaceration, as are primary (baby) teeth pushed upward by trauma into the gingiva where it moves the tooth bud of the permanent tooth.[44]

Regional odontodysplasia is rare, but is most likely to occur in the maxilla and anterior teeth. The cause is unknown; a number of causes have been postulated, including a disturbance in the neural crest cells, infection, radiation therapy, and a decrease in vascular supply (the most widely held hypothesis).[45] Teeth affected by regional odontodysplasia never erupt into the mouth, have small crowns, are yellow-brown, and have irregular shapes. The appearance of these teeth in radiographs is translucent and "wispy," resulting in the nickname "ghost teeth".[46]

Molecular biology

In fish hox gene expression regulate mechanisms for teeth initiation.[47][48]

In mouse WNT signals are required for the initiation of teeth development.[49][50]

NGF-R was present in the condensing ecto-mesenchymal cells of the dental papilla in the early cap stage tooth germ [51] and play multiple roles during morphogenetic and cytodifferentiation events in the tooth.[52][53][54] There is a relationship between tooth agenesis and absence of the peripheral trigeminal nerve (see Hypodontia).

All stages (bud, cap, bell, crown), growth and morphogenesis of the teeth are regulated by a protein: sonic hedgehog.[49][55][56][57]

During tooth development there are strong similarities between keratinization and amelogenesis.[58][59] Keratin is also present in epithelial cells of tooth germ [60] and a thin film of keratin is present on the tooth erupted recently (Nasmyth's membrane or enamel cuticle).[61]

Enamel knots as a signaling center in the tooth morphogenesis and odontoblast differentiation.[62][63][64][65]

Various phenotypic inputs modulate the size of the teeth.[66]

The shape of the teeth in prehistoric man was different from that of modern man.[66][67]

In some dermoid teratomas (particularly ovarian, lung, pancreas, testes) develop complete teeth.[68][69][70][71]

For the tooth eruption is necessary parathyroid hormone.[72]

Tooth development in animals

The organism with genome simplest with teeth is probably the worm genus Ancylostoma (Ancylostoma duodenale, Necator americanus).[73]

Teeth is atavic structure and their development is similar in many vertebrates.[56][74][75][76][77][78]

Fish have many specialized bony structures,[79] it exist with (Archosargus probatocephalus order Perciformes, family Sparidae) and without teeth (Caristiidae order Perciformes, family Caristiidae, teeth in traces present in juveniles).[80]

Unlike most animals, sharks continuously produce new teeth throughout life[81][82][83] via a drastically different mechanism. Because shark teeth have no roots, sharks easily lose teeth when they feed (zoologists estimate that a single shark can lose up to 2,400 teeth in one year[84])—they must therefore be continually replaced. Shark teeth form from modified scales near the tongue and move outward on the jaw in rows until they fully develop, are used, and are eventually dislodged.[85]

Snakes generally have teeth, with some exception (African Egg-eating Snake).

Today, birds do not have teeth, though it is speculated that prehistoric birds, such as archaeopteryx, did.[86]

In order Tubulidentata (Class Mammalia) teeth are without enamel, they lack incisors and canines and the molars molars are growing continuously from the root.[87]

Generally, tooth development in non-human mammals is similar to human tooth development. The variations lie in the morphology, number, development timeline, and types of teeth, not usually in the actual development of the teeth.

Enamel formation in non-human mammals is almost identical to that in humans. The ameloblasts and enamel organ, including the dental papilla, function similarly.[88] Nonetheless, while ameloblasts die in humans and most other animals—making further enamel formation impossible—rodents continually produce enamel, forcing them to wear down their teeth by gnawing on various materials.[89] If rodents are prevented from gnawing, their teeth eventually puncture the roofs of their mouths. In addition, rodent incisors consist of two halves, known as the crown and root analogues. The labial half is covered with enamel and resembles a crown, while the lingual half is covered with dentin and resembles a root. Both root and crown develop simultaneously in the rodent incisor and continue to grow for the life of the rodent.

The mineral distribution in rodent enamel is different from that of monkeys, dogs, pigs, and humans.[90] In horse teeth, the enamel and dentin layers are intertwined, which increases the strength and decreases the wear rate of the teeth.[91][92]

Supporting structures that create a "socket" are found exclusively in Mammalia and Crocodylia.[20] In manatees, mandibular molars develop separately from the jaw, and are encased in a bony shell separated by soft tissue. This also occurs in elephants' successional teeth, which erupt to replace lost teeth.

Notes

  1. ^ a b c d e f g h i j k l m n o p q r Ten Cate, A. R. (1998). Oral histology: development, structure, and function. St. Louis: Mosby. pp. 81–102. ISBN 0-8151-2952-1. 
  2. ^ Luan, X.; Ito Y., & Diekwisch T.G. H. (2005). "Evolution and development of Hertwig's epithelial root sheath.". Developmental Dynamics 235: 1167-1180. 
  3. ^ a b c d University of Texas Medical Branch.
  4. ^ Thesleff I, Vaahtokari A, Partanen AM (February 1995). "Regulation of organogenesis. Common molecular mechanisms regulating the development of teeth and other organs". The International Journal of Developmental Biology 39 (1): 35–50. PMID 7626420. http://www.intjdevbiol.com/paper.php?doi=7626420. 
  5. ^ Thesleff I, Vaahtokari A, Kettunen P, Aberg T (1995). "Epithelial-mesenchymal signaling during tooth development". Connective Tissue Research 32 (1–4): 9–15. doi:10.3109/03008209509013700. PMID 7554939. 
  6. ^ Luan, X.; Ito Y., & Diekwisch T.G. H. (2005). "Evolution and development of Hertwig's epithelial root sheath.". Developmental Dynamics 235: 1167-1180. 
  7. ^ Ross, Michael H.; Kaye, Gordon I.; Pawlina, Wojciech (2003). Histology: a text and atlas: with cell and molecular biology (4th ed.). Hagerstwon, MD: Lippincott Williams & Wilkins. p. 453. ISBN 978-0-683-30242-4. 
  8. ^ Ash, Major M.; Nelson, Stanley J. (2003). Wheeler's dental anatomy, physiology, and occlusion. Philadelphia: W.B. Saunders. pp. 32, 45, and 53. ISBN 978-0-7216-9382-8. 
  9. ^ University of Southern California School of Dentistry, The Bell Stage: Image 26 found here [1].
  10. ^ Barbara Young, Paul R. Wheater (2006). Wheaters Functional Histology. Elsevier Health Sciences. p. 255. ISBN 9780443068508. http://books.google.com/?id=88tla60sHAUC&pg=PA255&lpg=PA255. 
  11. ^ University of Southern California School of Dentistry, The Bell Stage: Image 30 found here [2].
  12. ^ Ross, Kaye, and Pawlina, Histology: a text and atlas, p. 444.
  13. ^ Cate, Oral Histology, p. 197.
  14. ^ Ross, Kaye, and Pawlina, Histology: Text and Atlas, p. 445.
  15. ^ Ross, Kaye, and Pawlina, Histology: Text and Atlas, p. 447.
  16. ^ a b c d Cate, Oral Histology, p. 128-139.
  17. ^ Summitt, Fundamentals of Operative Dentistry, p. 13.
  18. ^ Summitt, Fundamentals of Operative Dentistry, p. 183.
  19. ^ Johnson, Biology of the Human Dentition, p. 183.
  20. ^ a b c d e f g h i j Cate, Oral Histology, p. 236-248.
  21. ^ Luan X, Ito Y, Diekwisch TG (May 2006). "Evolution and Development of Hertwig's Epithelial Root Sheath". Developmental Dynamics 235 (5): 1167–80. doi:10.1002/dvdy.20674. PMC 2734338. PMID 16450392. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2734338. 
  22. ^ a b Ross, Kaye, and Pawlina, Histology: Text and Atlas, p. 453.
  23. ^ a b Ross, Kaye, and Pawlina, Histology: Text and Atlas, p. 452.
  24. ^ Riolo and Avery, Essentials for Orthodontic Practice, p. 142.
  25. ^ Harris, Craniofacial Growth and Development, pp. 1–3.
  26. ^ Harris, Craniofacial Growth and Development, p. 3.
  27. ^ Harris, Craniofacial Growth and Development, p. 5.
  28. ^ The American Dental Association, Tooth Eruption Charts found here [3].
  29. ^ Ash, Major M.; Nelson, Stanley J. (2003). Wheeler's dental anatomy, physiology, and occlusion. Philadelphia: W.B. Saunders. pp. 38 and 41. ISBN 978-0-7216-9382-8. 
  30. ^ Ash, Major M.; Nelson, Stanley J. (2003). Wheeler's dental anatomy, physiology, and occlusion. Philadelphia: W.B. Saunders. p. 38. ISBN 978-0-7216-9382-8. 
  31. ^ WebMd, Dental Health: Your Child's Teeth found here [4].
  32. ^ Ash, Major M.; Nelson, Stanley J. (2003). Wheeler's dental anatomy, physiology, and occlusion. Philadelphia: W.B. Saunders. p. 41. ISBN 978-0-7216-9382-8. 
  33. ^ Monthly Microscopy Explorations, Exploration of the Month: January 1998 .
  34. ^ Health Hawaii, Primary Teeth: Importance and Care found here [5].
  35. ^ American Academy of Periodontology, Oral Health Information for the Public found here [6].
  36. ^ Ash, Major M.; Nelson, Stanley J. (2003). Wheeler's dental anatomy, physiology, and occlusion. Philadelphia: W.B. Saunders. p. 53. ISBN 978-0-7216-9382-8. 
  37. ^ Armstrong WG (September 1968). "Origin and nature of the acquired pellicle". Proceedings of the Royal Society of Medicine 61 (9): 923–30. PMC 1902619. PMID 5679017. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=1902619. 
  38. ^ Darling AI (July 1943). "The Distribution of the Enamel Cuticle and Its Significance". Proceedings of the Royal Society of Medicine 36 (9): 499–502. PMC 1998608. PMID 19992694. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=1998608. 
  39. ^ The American Dental Hygiene Association, Nutritional Factors in Tooth Development found here [7].
  40. ^ The American Dental Hygiene Association, Table II. Effects of nutrient deficiencies on tooth development found here [8].
  41. ^ Millett, Declan T.; Richard Welbury (2000). Orthodontics and Paediatric Dentistry. Elsevier Health Sciences. ISBN 0443062870. 
  42. ^ Neville, Damm, Allen, and Bouquot, Oral & Maxillofacial Pathology, p. 70.
  43. ^ Kahn, Basic Oral & Maxillofacial Pathology, p. 49.
  44. ^ Neville, Damm, Allen, and Bouquot, Oral & Maxillofacial Pathology, p. 86.
  45. ^ Neville, Damm, Allen, and Bouquot, Oral & Maxillofacial Pathology, p. 99.
  46. ^ Kahn, Basic Oral & Maxillofacial Pathology, p. 58.
  47. ^ Fraser GJ, Hulsey CD, Bloomquist RF, Uyesugi K, Manley NR, Streelman JT (February 2009). Jernvall, Jukka. ed. "An Ancient Gene Network Is Co-opted for Teeth on Old and New Jaws". PloS Biology 7 (2): e31. doi:10.1371/journal.pbio.1000031. PMC 2637924. PMID 19215146. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2637924. 
  48. ^ Fraser GJ, Bloomquist RF, Streelman JT (2008). "A periodic pattern generator for dental diversity". BMC Biology 6: 32. doi:10.1186/1741-7007-6-32. PMC 2496899. PMID 18625062. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2496899. 
  49. ^ a b Dassule HR, Lewis P, Bei M, Maas R, McMahon AP (November 2000). "Sonic hedgehog regulates growth and morphogenesis of the tooth". Development 127 (22): 4775–85. PMID 11044393. http://dev.biologists.org/cgi/pmidlookup?view=long&pmid=11044393. 
  50. ^ Järvinen E, Salazar-Ciudad I, Birchmeier W, Taketo MM, Jernvall J, Thesleff I (December 2006). "Continuous tooth generation in mouse is induced by activated epithelial Wnt/β-catenin signaling". Proceedings of the National Academy of Sciences of the United States of America 103 (49): 18627–32. doi:10.1073/pnas.0607289103. PMC 1693713. PMID 17121988. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=1693713. 
  51. ^ Christensen L R, Møllgård K, Kjær I, Janas M S. (1993). "Immunocytochemical demonstration of nerve growth factor receptor (NGF.-R) in developing human fetal teeth". Anat Embryol 188 (3): 247–55. doi:10.1007/BF00188216. PMID 8250280. http://www.springerlink.com/content/um52t22r725k0v07/. 
  52. ^ Mitsiadis TA, Dicou E, Joffre A, Magloire H. (1992). "Immunohistochemical localization of nerve growth factor (NGF) and NGF receptor (NGF-R) in the developing first molar tooth of the rat". Differentiation 49 (1): 47–61. doi:10.1111/j.1432-0436.1992.tb00768.x. PMID 1320577. http://www.ncbi.nlm.nih.gov/pubmed/1320577. 
  53. ^ Mitsiadis TA, Dicou E, Joffre A, Magloire H. (2001). "NGF Signals Supporting the Tooth Development are Mediated through p75. (Japanese)". Journal of the Kyushu Dental Society 55 (6): 347–355. doi:10.2504/kds.55.347. http://sciencelinks.jp/j-east/article/200207/000020020702A0095496.php. 
  54. ^ Amano O, Bringas P, Takahashi I, Takahashi K, Yamane A, Chai Y, Nuckolls GH, Shum L, Slavkin HC. (1999). "Nerve growth factor (NGF) supports tooth morphogenesis in mouse first branchial arch explants". Dev Dyn 216 (3): 299–310. doi:10.1002/(SICI)1097-0177(199911) (inactive 2010-07-26). PMID 10590481. http://www3.interscience.wiley.com/journal/66501488/abstract?CRETRY=1&SRETRY=0. 
  55. ^ Cobourne MT, Hardcastle Z, Sharpe PT (November 2001). "Sonic hedgehog regulates epithelial proliferation and cell survival in the developing tooth germ". Journal of Dental Research 80 (11): 1974–9. doi:10.1177/00220345010800110501. PMID 11759005. 
  56. ^ a b Nakatomi M, Morita I, Eto K, Ota MS (May 2006). "Sonic hedgehog signaling is important in tooth root development". Journal of Dental Research 85 (5): 427–31. doi:10.1177/154405910608500506. PMID 16632755. 
  57. ^ "Expression of Sonic hedgehog in mouse tooth". Gene expression in tooth by Pekka Nieminen. http://bite-it.helsinki.fi/SHH.HTM. Retrieved 2009-10-17. 
  58. ^ Toto PD, O'Malley JJ, Grandel ER (1967). "Similarities of keratinization and amelogenesis". Journal of Dental Research 46 (3): 602–7. doi:10.1177/00220345670460032401. PMID 4165207. http://jdr.sagepub.com/cgi/pmidlookup?view=long&pmid=4165207. 
  59. ^ Gustafson G, Sundström B (June 1975). "Enamel: morphological considerations". Journal of Dental Research 54 Spec No B (2 suppl): B114–20. doi:10.1177/00220345750540020301. PMID 1094042. http://jdr.sagepub.com/cgi/pmidlookup?view=long&pmid=1094042. 
  60. ^ Domingues MG, Jaeger MM, Araújo VC, Araújo NS (February 2000). "Expression of cytokeratins in human enamel organ". European Journal of Oral Sciences 108 (1): 43–7. doi:10.1034/j.1600-0722.2000.00717.x. PMID 10706476. http://www3.interscience.wiley.com/resolve/openurl?genre=article&sid=nlm:pubmed&issn=0909-8836&date=2000&volume=108&issue=1&spage=43. 
  61. ^ Rosebury, Theodor (1934). "Presence of Iron in Enamel Keratin". Journal of Dental Research 14 (4): 269–72. doi:10.1177/00220345340140040301. http://jdr.sagepub.com/cgi/reprint/14/4/269. 
  62. ^ Vaahtokari A, Aberg T, Jernvall J, Keränen S, Thesleff I (January 1996). "The enamel knot as a signaling center in the developing mouse tooth". Mechanisms of Development 54 (1): 39–43. doi:10.1016/0925-4773(95)00459-9. PMID 8808404. 
  63. ^ Tucker AS, Headon DJ, Schneider P, et al. (November 2000). "Edar/Eda interactions regulate enamel knot formation in tooth morphogenesis". Development 127 (21): 4691–700. PMID 11023871. http://dev.biologists.org/cgi/pmidlookup?view=long&pmid=11023871. 
  64. ^ Thesleff I, Keränen S, Jernvall J (August 2001). "Enamel knots as signaling centers linking tooth morphogenesis and odontoblast differentiation". Advances in Dental Research 15: 14–8. doi:10.1177/08959374010150010401. PMID 12640732. 
  65. ^ Lesot H, Lisi S, Peterkova R, Peterka M, Mitolo V, Ruch JV (August 2001). "Epigenetic signals during odontoblast differentiation". Advances in Dental Research 15: 8–13. doi:10.1177/08959374010150012001. PMID 12640731. 
  66. ^ a b Townsend G, Richards L, Hughes T (May 2003). "Molar intercuspal dimensions: genetic input to phenotypic variation". Journal of Dental Research 82 (5): 350–5. doi:10.1177/154405910308200505. PMID 12709500. 
  67. ^ Keith A (1913). "Problems relating to the Teeth of the Earlier Forms of Prehistoric Man". Proceedings of the Royal Society of Medicine 6 (Odontol Sect): 103–124. PMC 2005996. PMID 19977113. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2005996. 
  68. ^ "Ovarian teratoma (dermoid) with teeth". Doctor T's BrokenDown Palace. http://home.earthlink.net/~radiologist/tf/040802.htm. Retrieved 2009-11-07. 
  69. ^ Lee R (1860). "On the Nature of Ovarian Cysts which contain Teeth, Hair, and Fatty Matter". Medico-Chirurgical Transactions 43 (2): 93–114. PMC 2147752. PMID 20896161. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2147752. 
  70. ^ Eccles WM, Hopewell-Smith A (1912). ""Dermoid Teeth," or Teeth developed in Teratomata". Proceedings of the Royal Society of Medicine 5 (Odontol Sect): 123–139. PMC 2005364. PMID 19976169. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2005364. 
  71. ^ Smith CJ (November 1967). "A teratoma of the lung containing teeth". Annals of the Royal College of Surgeons of England 41 (5): 413–22. PMC 2312017. PMID 6061946. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2312017. 
  72. ^ Philbrick WM, Dreyer BE, Nakchbandi IA, Karaplis AC (September 1998). "Parathyroid hormone-related protein is required for tooth eruption". Proceedings of the National Academy of Sciences of the United States of America 95 (20): 11846–51. doi:10.1073/pnas.95.20.11846. PMC 21728. PMID 9751753. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=21728. 
  73. ^ "Ancylostoma duodenale". Nematode.net Genome Sequencing Center. Archived from the original on 2008-05-16. http://web.archive.org/web/20080516010133/http://www.nematode.net/Species.Summaries/Ancylostoma.duodenale/index.php. Retrieved 2009-10-27. 
  74. ^ James WW, Wellings AW (November 1943). "The Dental Epithelium and its Significance in Tooth Development". Proceedings of the Royal Society of Medicine 37 (1): 1–6.12. PMC 2180846. PMID 19992735. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2180846. 
  75. ^ Koussoulakou DS, Margaritis LH, Koussoulakos SL (2009). "A Curriculum Vitae of Teeth: Evolution, Generation, Regeneration". International Journal of Biological Sciences 5 (3): 226–43. PMC 2651620. PMID 19266065. http://www.biolsci.org/v05p0226.htm. 
  76. ^ Salazar-Ciudad I, Jernvall J (June 2002). "A gene network model accounting for development and evolution of mammalian teeth". Proceedings of the National Academy of Sciences of the United States of America 99 (12): 8116–20. doi:10.1073/pnas.132069499. PMC 123030. PMID 12048258. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=123030. 
  77. ^ Gregory W.K. (1920). "The Origin and Evolution of the Human Dentition : A Palaeontological Review. Part I". J Dent Res 2 (1): 89–183. doi:10.1177/00220345200020011101. http://jdr.sagepub.com/content/2/1/89.citation. 
  78. ^ Gregory W.K. (1921). "The Origin and Evolution of the Human Dentition : A Palaeontological Review. Part II". J Dent Res 3 (1): 87–228. doi:10.1177/00220345210030011101. http://jdr.sagepub.com/content/3/1/87.citation. 
  79. ^ Sander Kranenbarg. "Skeletal tissue differentiation in fish". Wageninger University. http://www.ezo.wur.nl/UK/MSc+projects/Skeletal+tissue+differentiation+in+fish/. Retrieved 2009-10-24. 
  80. ^ Owen, Richard (1859). The principal forms of the skeleton and the teeth as the basis for a system of natural history and comparativa anatomy. Houlston and Wright. http://books.google.com/?id=SAYAAAAAQAAJ. Retrieved 24 October 2009. 
  81. ^ Dave Abbott, Sharks, found here [9].
  82. ^ Boyne PJ (1970). "Study of the chronologic development and eruption of teeth in elasmobranchs". Journal of Dental Research 49 (3): 556–60. doi:10.1177/00220345700490031501. PMID 5269110. http://jdr.sagepub.com/cgi/pmidlookup?view=long&pmid=5269110. 
  83. ^ Sasagawa I (June 1989). "The fine structure of initial mineralisation during tooth development in the gummy shark, Mustelus manazo, Elasmobranchia". Journal of Anatomy 164: 175–87. PMC 1256608. PMID 2606790. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=1256608. 
  84. ^ Jason Buchheim, A Quick Course in Ichthyology, found here [10].
  85. ^ Michael E. Williams, Jaws: The early years, found here [11].
  86. ^ Sire JY, Delgado SC, Girondot M (2008). "Hen's teeth with enamel cap: from dream to impossibility". BMC Evolutionary Biology 8: 246. doi:10.1186/1471-2148-8-246. PMC 2542379. PMID 18775069. http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pmcentrez&artid=2542379. 
  87. ^ "Class Mammalia, Order Tubulidentata, Family Orycteropodidae, Species Orycteropus afer," University of Michigan Museum of Zoology. Page accessed November 16, 2009.
  88. ^ Frandson and Spurgeon, Anatomy and Physiology of Farm Animals., p. 305.
  89. ^ Caceci. Veterinary Histology with subtitle "Digestive System: Oral Cavity" found here [12].
  90. ^ Fejerskov O (March 1979). "Human dentition and experimental animals". Journal of Dental Research 58 (Spec Issue B): 725–34. doi:10.1177/002203457905800224011. PMID 105027. http://jdr.sagepub.com/cgi/pmidlookup?view=long&pmid=105027. 
  91. ^ Randall-Bowman's April 2004 "Gummed Out: Young Horses Lose Many Teeth, Vet Says." See reference here [13].
  92. ^ Encarta, whose link can be found here [14]

References

External links