Dental caries

× Introduction

Loss of tooth substance may result from the action of oral microorganisms as in dental caries, or be due to non-bacterial causes. The latter include mechanical factors associated with attrition and abrasion, chemical erosion, and pathological resorption.

Dental caries may be defined as a bacterial disease of the calcified tissues of the teeth characterized by demineralization of the inorganic and destruction of the organic substance of the tooth. It is a complex and dynamic process involving, for example, physicochemical processes associated with the movements of ions across the interface between the tooth and the external environment, as well as biological processes associated with the interaction of bacteria in dental plaque with host defence mechanisms.

Dental caries has been recognized throughout history and exists around the world, although the prevalence and severity varies in different populations. In western industrialized countries there was a sharp increase in disease activity in the first half of the twentieth century, but during the 1970s and 1980s the prevalence of dental caries in children fell steadily, particularly following the widespread use of fluoride-containing toothpastes. The reduction was much greater for smooth surface as opposed to occlusal caries, which now accounts for most of the lesions seen in children. Epidemiological studies have shown that the decline in prevalence is continued into adult life and, as a result, more people are retaining more teeth for much longer than before. This reflects the increase in the prevalence of root surface caries as people grow older.

Despite the encouraging and sustained reduction in dental caries in industrialized countries, the prevalence is increasing in certain developing countries and is associated with urbanization and the increased availability of refined carbohydrates.

Aetiology of dental caries

Introduction

Various theories for the aetiology of dental caries have been proposed, but there is now overwhelming support for the acidogenic theory. This theory, which has remained virtually unchanged since first postulated by W. D. Miller in 1889, proposes that acid formed from the fermentation of dietary carbohydrates by oral bacteria leads to a progressive decalcification of the tooth substance with a subsequent disintegration of the organic matrix. Some of the evidence supporting the acidogenic theory is discussed below.

Role of bacteria and dental plaque

Experiments with germ-free animals have shown that bacteria are essential for the development of dental caries. Bacteria are present in dental plaque which is found on most tooth surfaces. Dental plaque is a biofilm consisting of a variety of different species of bacteria embedded in a matrix derived from salivary mucins and extracellular polysaccharide polymers (glucans and fructans) synthesized by the organisms.

A clean enamel surface is covered in a few seconds by an adsorbed layer of molecules comprising mainly glycoproteins from saliva, the acquired pellicle, to which microorganisms initially adhere. As they multiply and synthesize extracellular matrix polymers other bacteria may bind to them, rather than to the pellicle, resulting in a complex biofilm of spatially arranged species. The close proximity of different species allows for a variety of synergistic or antagonistic interactions. In a healthy mouth the bacterial composition of the plaque varies at different sites on the teeth, reflecting the different microenvironments available for colonization.

Dietary sugars diffuse rapidly through plaque where they are converted to acids (mainly lactic acid but also acetic and propionic acids) by bacterial metabolism. The pH of the plaque may fall by as much as 2 units within 10 minutes after the ingestion of sugar, but over the next 30 to 60 minutes the pH slowly rises to its original figure, due to the diffusion of the sugar and some of the acid out of the plaque, and the diffusion into the plaque of buffered saliva which helps to dilute and neutralize the acid. At the critical pH of 5.5 mineral ions are liberated from the hydroxyapatite crystals of the enamel and diffuse into the plaque. The pH curves of plaque in response to sugar (Stephan's curves) are similar in shape in caries-free and caries-active individuals. However, since the starting pH may be lower in caries-active mouths, the reduction in pH will be greater and the pH will be depressed below the critical level for a greater period of time. At a neutral or slightly alkaline pH the plaque becomes supersaturated with mineral ions derived both from the saliva and from those released from the hydroxyapatite crystals. Ions may now diffuse back into enamel and be redeposited in the crystal structure and this reprecipitation of mineral is aided by fluoride ions.

There is, therefore, a see-sawing of ions across the plaque- enamel interface as the chemical environment within the plaque changes. However, mineral ions may be lost from the system by diffusion out of the plaque and into the saliva during the acid phase, and repeated episodes lead to an overall demineralization and the initiation of enamel caries. Obviously the frequency and duration of the acid phase of plaque will affect the rate of development of caries, and this is why the reduction of carbohydrate intake between meals has such a beneficial effect in caries prevention. Once enamel caries has progressed to cavity formation, the plaque becomes progressively more removed from saliva and probably remains acidic for longer periods. Many plaque bacteria store carbohydrate as an intracellular glycogen-like polysaccharide which may be formed from a variety of sugars, and this may be broken down to acid when other sources of carbohydrate are absent, such as between meals. In addition, as mentioned above, plaque organisms can synthesize extracellular glucans from dietary sugars which may also be metabolized to acid when other sources of carbohydrate are absent. However, abundant extracellular polysaccharides have other important consequences in that they markedly increase the bulk of the plaque, thereby interfering with the outward diffusion of acids and the inward diffusion of saliva and its buffering systems. Such plaques are likely to be more cariogenic because they favour retention of acid at the plaque-enamel interface.

Fluoride ions are present in relatively high concentration in plaque compared with saliva. Fluoride favours the precipitation of calcium and phosphate ions from solution, and so when present at the plaque-enamel interface the deposition of free mineral ions in the plaque as hydroxy- and fluorapatite on the remaining enamel crystals is encouraged. Fluorapatite crystals may also be formed during enamel development if fluorides have been administered systemically (for example by water fluoridation). Fluorapatite is less soluble in acid than hydroxyapatite. Systemic fluoride also promotes the formation of hydroxyapatite crystals with a more stable crystal lattice. Fluoride ions in plaque inhibit bacterial metabolism and this provides an additional mechanism for the preventive action of fluoride in enamel caries.

Microbiology of dental caries

Acid is a general product of bacterial metabolism and no single bacterial species is uniquely associated with the development of enamel caries. Members of the 'mutans streptococci' group are the most efficient cariogenic organisms in animal experiments, and epidemiological data in humans indicates an association between the presence of S. mutans and S. sobrinus in plaque and the prevalence of caries. Some of the factors supporting an aetiological role for S. mutans in dental caries are summarized in. However, caries of enamel may develop in the absence of S. mutans and in some individuals high levels of S. mutans may be present on a tooth surface without the subsequent development of caries. Nevertheless, there is now a wealth of evidence from animal and human studies that the mutans streptococci, especially S. mutans, play a key role in the initiation of caries. Other bacteria, for example lactobacilli, may be important in the further progression of the lesion. Lactobacilli are also the pioneer organisms in dentine caries (see later).


Key points - In dental plaque
· cariogenic bacteria ferment carbohydrate to acid
· cariogenic bacteria can store carbohydrate intra and extracellularly
· extracellular polysaccharides increase plaque bulk
· bulky plaques interfere with outward diffusion of acid and inward diffusion of salivary buffers
· frequent intakes of carbohydrate can depress the pH below the critical level for long periods



Key points - Ionic exchanges in enamel caries
· ions see-saw across the plaque-enamel interface depending on pH
· ions in plaque can be redeposited into the enamel at a neutral pH or lost into the saliva
· enamel caries progresses when the net rate of loss of ions due to acid attack is greater than the net rate of gain due to remineralization
· fluoride ions encourage reprecipitation of minerals into enamel
· fluoride ions can replace hydroxyl ions in hydroxyapatite to form less acid-soluble fluorapatite



Key points - Microbiology of dental caries
· species that may be associated
- non-mutans streptococci, e.g. mitis group
- actinomycetes
· transmission of S. mutans occurs mainly from mother to child
· low plaque pH favours proliferation of mutans streptococci and lactobacilli
· level of mutans streptococci in plaque increased by sucrose consumption


Since caries occurs occasionally in the absence of S. mutans other bacteria can contribute to its development. A range of organisms has been isolated from such sites including several types of non-mutans streptococci, for example those belonging to the mitis, salivarius, anginosus, and sanguinis groups, and lactobacilli and actinomycetes. Although these organisms can induce experimental caries in animals their relative significance in the development of caries in humans is less clear. However, some are moderately acidogenic and as such may contribute to the acid pool of plaque as well as creating an environment favouring colonization by aciduric species such as mutans streptococci and lactobacilli. Because of the strong evidence that S. mutans and lactobacilli are major organisms associated with dental caries, simple screening tests to estimate the salivary levels of these bacteria have been developed as predictors of caries activity. However, the results from such tests need to be interpreted in conjunction with the assessment of other risk factors for caries in an individual patient. Infants become colonized by mutans streptococci from their mothers, and there is evidence that children of high-risk mothers become colonized at an earlier age and develop more carious lesions than children of low-risk mothers.

Role of carbohydrates

Numerous epidemiological studies have demonstrated a direct relationship between fermentable carbohydrate in the diet and dental caries. The evidence includes:

1. The increasing prevalence of dental caries in developing countries and previously isolated ethnic groups associated with westernization, urbanization, and the increasing availability of sucrose in their diet. Examples include Inuit, native North and South Americans, African tribes, and the rural population in countries in the Far East.

2. The decrease in the prevalence of caries during World War II because of sugar restriction, followed by a rise to previous levels when sucrose became available in the post-war period.

3. The Hopewood House study - a children's home in Australia where sucrose and white bread were virtually excluded from the diet. The children had low caries rates which increased dramatically when they moved out of the home.


Key points - Diet and dental caries
· caries prevalence increases when populations become exposed to sucrose-rich diets
· extrinsic sugars are more damaging than intrinsic sugars
· sucrose is the most cariogenic sugar
· frequency of sugar intake is of more importance than total amount consumed


Different carbohydrates have different cariogenic properties. Sucrose is significantly more cariogenic than other sugars, partly because it is readily fermented by plaque bacteria and partly because of its conversion by bacterial glucosyl transferase into extracellular glucans. Sucrose is also readily converted into intracellular polymers. Glucose, fructose, maltose, galactose, and lactose are also highly cariogenic carbohydrates in experimental caries in animals, but the principal carbohydrates available in human diets are sucrose and starches. Dietary sugars can be divided into intrinsic (mainly fruit and vegetables) and extrinsic sources (added sugars, milk, fruit juices). Dietary advice recommends that consumption of extrinsic sugars (except milk) should be reduced. Much of the epidemiological data incriminates sucrose. Its relative importance is also well illustrated in patients with hereditary fructose intolerance who cannot tolerate fructose or sucrose (ingestion may lead to coma and death) but who are able to consume starches. Such individuals have little or no caries. Starch solutions applied to bacterial plaque produce no significant depression in pH, due to the very slow diffusion of the polysaccharide into the plaque which must be hydrolysed by extracellular amylase before it can be assimilated and metabolized by plaque bacteria. However, cooked highly refined starches can cause caries, although much less than sucrose. The combination of cooked starch and sucrose together, such as in cakes and biscuits, is more cariogenic than sucrose alone. The main alternative non-sugar sweeteners, sorbitol and xylitol, are, to all intents and purposes, non-cariogenic. Xylitol is not fermented by oral bacteria and sorbitol is only fermented at a very slow rate.

Whilst there is no doubt that there is a direct relationship between dietary carbohydrates and caries, experimental evidence in humans has shown that the manner and form in which the carbohydrate is taken and the frequency of consumption are more important than the absolute amount of sugar consumed. The risk of caries is greatest if sugar is consumed between meals, thus supplying plaque bacteria with (in the case of habitual 'snackers') an almost constant supply of carbohydrate. It is also increased if the sugar is consumed in a sticky form likely to be retained on the surfaces of the teeth.

In children, prolonged sucking of a sweetened pacifier to about 2 years of age or beyond may be associated with rampant caries, involving particularly the smooth surfaces of the anterior maxillary teeth. A similar problem may also be seen in children given sweetened drinks in a nursing bottle, especially at night. Some studies have also shown an association between prolonged breast feeding beyond 2 years of age and extensive caries, but this is controversial as the results from different studies are conflicting.

Aetiological variables

Not all teeth or tooth surfaces are equally susceptible to caries, nor is the rate of progression of carious lesions constant. Factors influencing site attack and rates of progression in dental caries are largely unknown but may include:

Factors intrinsic to the tooth
Enamel composition - There is an inverse relationship between enamel solubility and enamel fluoride concentration. A graded increase in enamel resistance with age might account for selectivity of site attack.

Enamel structure - Developmental enamel hypoplasia and hypomineralization may affect the rate of progression but not the initiation of caries.

Tooth morphology - Deep, narrow pits and fissures favour the retention of plaque and food.

Tooth position - Malaligned teeth may predispose to the retention of plaque and food.

Factors extrinsic to the tooth
Saliva - Flow rate, viscosity, buffering capacity, availability of calcium and phosphate ions for mineralization, and the presence of antimicrobial agents such as immunoglobulins, thiocyanate ion, lactoferrin, and lysozyme may affect caries pattern.

Diet - The most important factor is the frequency of intake of sugary foods and drinks. Chewing sugar-free gum or eating a small portion of cheese after meals helps protect against dental caries. Phosphates in the diet, either organically bound or inorganic, may also reduce the incidence of caries.

Use of fluoride - In addition to an intrinsic effect, fluoride readily enters bacterial cells and can inhibit enzymes involved in the metabolism of sugar.

Immunity - See later.

Pathology of dental caries

Introduction

Clinically, dental caries may be classified according both to the location of the lesion on the tooth and to the rate of attack.

Classification by site of attack

Pit or fissure caries

This occurs on the occlusal surfaces of molars and premolars, on the buccal and lingual surfaces of molars, and the lingual surfaces of maxillary incisors. Early caries may be detected clinically by brown or black discoloration of a fissure in which a probe 'sticks'. The enamel directly bordering the pit or fissure may appear opaque, bluish-white as it becomes undermined by caries. Since the widespread use of fluoride-containing dentifrices early occlusal caries has become more difficult to diagnose. Apparently clinically sound enamel can overlay extensive dentine caries because of strengthening of the enamel by the formation of fluorapatite and the ability of fluoride to promote remineralization.

Smooth surface caries

This occurs on the approximal surfaces, and on the gingival third of the buccal and lingual surfaces. Approximal caries begins just below the contact point as a well-demarcated chalky-white opacity of the enamel . At this stage there is no loss of continuity of the enamel surface and the lesion cannot be detected by a probe or on routine radiographs. The white spot lesion may become pigmented yellow or brown and may extend buccally and lingually into the embrasures. As the caries progresses, the surrounding enamel becomes bluish-white. The surface of the lesion becomes roughened before frank cavitation occurs. There are no consistent radiographic features which enable unequivocal identification of enamel lesions that have cavitated from lesions where the surface is still intact. However, lesions with an underlying radiolucency involving half or more of the dentine thickness are always cavitated. For a radiolucency limited to the outer half of the dentine the probability of cavitation ranges from about 40 to 80 per cent in different studies. For radiolucencies limited to the enamel the probability of cavitation in most studies is low and such lesions should be treated by preventive measures and reviewed. Cervical caries extends occlusally from opposite the gingival margin on buccal and lingual tooth surfaces. It has a similar appearance to approximal caries, but almost always produces a wide open cavity.

Cemental or root caries

This occurs when the root face is exposed to the oral environment as a result of periodontal disease. The root face is softened and the cavities, which may be extensive, are usually shallow, saucer-shaped, with ill-defined boundaries.


Key points - Diagnosis of caries
· early occlusal caries may be difficult to detect
· radiolucencies in approximal enamel that do not reach the amelodentinal junction do not usually indicate enamel cavitation
· approximal lesions which on radiographs do not extend into dentine should be treated by preventive measures


Recurrent caries
This occurs around the margin or at the base of a previously existing restoration.

Classification by rate of attack

Rampant or acute caries
This is rapidly progressing caries involving many or all of the erupted teeth, often on surfaces normally immune to caries. The rapid coronal destruction and limited time for the protective responses of the pulpodentinal complex to occur lead to early involvement of the pulp.

Slowly progressive or chronic caries
This is caries that progresses slowly and involves the pulp much later than in acute caries. It is most common in adults and the slow progress allows time for defence reactions of the pulpodentinal complex (sclerosis and reactionary dentine formation) to develop.

Arrested caries
This is caries of enamel or dentine, including root caries, that becomes static and shows no tendency for further progression.

Enamel caries

Ground sections of teeth have been used extensively in histopathological studies of enamel caries and have been examined by transmitted and polarized light, and by microradiography. Electron microscopy and biochemical analysis of microdissected pieces of carious enamel have also been carried out. Most research has concentrated on smooth surface caries to avoid the problems of interpretation of histological features imposed by the anatomy of pits and fissures. However, the pathological features are essentially similar in both sites. The established early lesion (white spot lesion) in smooth surface enamel caries is cone-shaped, with the base of the cone on the enamel surface and the apex pointing towards the amelodentinal junction. The shape is modified in pit and fissure caries (see later). In ground sections it consists of a series of zones, the optical properties of which reflect differing degrees of demineralization. These zones are described below.

Translucent zone
This is the first recognizable histological change at the advancing edge of the lesion. It is more porous than normal enamel and contains 1 per cent by volume of spaces, the pore volume, compared with the 0.1 per cent pore volume in normal enamel. The pores are larger than the small pores in normal enamel which approximate to the size of a water molecule. Chemical analysis shows that there is a fall in magnesium and carbonate when compared with normal enamel, which suggests that a magnesium- and carbonate- rich mineral is preferentially dissolved in this zone. Dissolution of mineral occurs mainly from the junctional areas between the prismatic and interprismatic enamel. The prism boundaries, which are relatively rich in protein, allow ready ingress of hydrogen ions and the magnesium- and carbonate-rich mineral that is preferentially removed may represent the surface layers of crystallites at the prism boundaries. The translucent zone is sometimes missing, or present along only part of the lesion.

Dark zone
This zone contains 2-4 per cent by volume of pores. Some of the pores are large, but others are smaller than those in the translucent zone, suggesting that some remineralization has occurred due to reprecipitation of mineral lost from the translucent zone. It is thought that the dark zone is narrow in rapidly advancing lesions and wider in more slowly advancing lesions when more remineralization may occur.

Body of the lesion
This zone has a pore volume of between 5 and 25 per cent, and also contains apatite crystals larger than those found in normal enamel. It is suggested that these large crystals result from the reprecipitation of mineral dissolved from deeper zones. However, with continuing acid attack there is further dissolution of mineral both from the periphery of the apatite crystals and from their cores. The lost mineral is replaced by unbound water and to a lesser extent by organic matter, presumably derived from saliva and microorganisms. There is increased prominence of the striae of Retzius in the body of the lesion, the explanation for which is unknown.

Surface zone
This is about 40um thick and shows surprisingly little change in early lesions. The surface of normal enamel differs in composition from the deeper layers, being more highly mineralized and having, for example, a higher fluoride level and a lower magnesium level, and so interpretation of possible chemical changes in this zone is difficult. The surface zone remains relatively normal despite subsurface loss of mineral, because it is an area of active reprecipitation of mineral derived both from the plaque and from that dissolved from deeper areas of the lesion as ions diffuse outwards .

Histopathogenesis of the early lesion
The development of enamel caries can be traced through the following stages when ground sections are examined by transmitted light .

1. Development of a subsurface translucent zone, which is unrecognizable clinically and radiologically.

2. The subsurface translucent zone enlarges and a dark zone develops in its centre.

3. As the lesion enlarges more mineral is lost and the centre of the dark zone becomes the body of the lesion. This is relatively translucent compared with sound enamel and shows enhancement of the striae of Retzius, interprismatic markings, and cross-striations of the prisms. The lesion is now clinically recognizable as a white spot.

4. The body of the lesion may become stained by exogenous pigments from food, tobacco, and bacteria. The lesion is now clinically recognizable as a brown spot.

5. When the caries reaches the amelodentinal junction it spreads laterally, undermining the adjacent enamel, giving the bluish-white appearance to the enamel as seen clinically. Although lateral spread can occur before cavitation (see stage 6), it is more common and more extensive in lesions with cavity formation.

6. With progressive loss of mineral a critical point is reached when the enamel is no longer able to withstand the loads placed upon it and the structure breaks down to form a cavity. This stage may precede stage 5. Caries progression is a slow process and it usually takes several years before cavitation occurs.


Key points - Enamel caries
· a dynamic physicochemical process involving dissolution and repreciptation of mineral
· caries progression is usually a slow process
· zonation of the early (white spot) lesion reflects different degrees of demineralization
· four zones usually seen: translucent zone (1 per cent loss), dark zone (2-4 per cent loss), body (5-25 per cent loss), surface zone (intact)
· surface zone is an area of active remineralization
· the morphology of the lesion differs in pits and fissures compared with approximal surfaces


Caries in a fissure does not start at the base, but develops as a ring around the wall of the fissure, the histological features of the lesion being similar to those seen on smooth surfaces. As the caries progresses it spreads outwards into the surrounding enamel and downwards towards the dentine, and eventually coalesces at the base of the fissure. This produces a cone-shaped lesion, but the base of the cone is directed towards the amelodentinal junction and is not on the enamel surface as in smooth surface caries. The area of dentine ultimately involved is therefore larger than with smooth surface lesions.

Dentine caries

Dentine differs from enamel in that it is a living tissue and as such can respond to caries attack. It also has a relatively high organic content, approximately 20 per cent by weight, which consists predominantly of collagen. In dentine caries it is, therefore, necessary to consider both the defence reaction of the pulpodentinal complex and the carious destruction of the tissue which involves acid demineralization followed by proteolytic breakdown of the matrix. The defence reaction may begin before the carious process reaches the dentine, presumably because of irritation to the odontoblasts transmitted through the weakened enamel, and is represented by the formation of reactionary (or tertiary) dentine and dentinal sclerosis (see later). However, in progressive lesions the defence reaction is progressively overtaken by the carious process as it advances towards the pulp.


Key points - Processes in dentine caries
· defence reaction of pulpodentinal complex
- sclerosis
- reactionary dentine formation
- sealing of dead tracts
· carious destruction
- demineralization
- proteolysis


Caries of the dentine develops from enamel caries: when the lesion reaches the amelodentinal junction, lateral extension results in the involvement of great numbers of tubules .The early lesion is cone-shaped, or convex, with the base at the amelodentinal junction. Larger lesions may show a broadening of the apex of the cone as it approaches the circumpulpal dentine. In caries of dentine, demineralization by acid is always in advance of the bacterial front, the subsequent bacterial invasion being followed by breakdown of the collagenous matrix.

Because of the sequential nature of the changes, studies of ground and decalcified sections show a zoned lesion in which four zones are characteristically present.

Zone of sclerosis
The sclerotic or translucent zone is located beneath and at the sides of the carious lesion. It is almost invariably present, being broader beneath the lesion than at the sides, and is regarded as a vital reaction of odontoblasts to irritation. Two patterns of mineralization have been described. The first is the result of acceleration of the normal physiological process of centripetal deposition of peritubular dentine which eventually occludes the tubules. In the second, mineral first appears within the cytoplasmic process of the odontoblasts and the tubule is obliterated by calcification of the odontoblast process itself. Sclerosed dentine therefore has a higher mineral content.

Dead tracts may be seen running through the zone of sclerosis. They are the result of death of odontoblasts at an earlier stage in the carious process. The empty dentinal tubules contain air and the remains of the dead odontoblast process and such tubules can obviously not undergo sclerosis. However, they provide ready access of bacteria and their products to the pulp. To prevent this the pulpal end of a dead tract is occluded by a thin layer of hyaline calcified material, sometimes called eburnoid, which is derived from pulpal cells. Beyond this, further, often very irregular, reactionary dentine may form following differentiation of odontoblasts or odontoblast-like cells from the pulp.

Zone of demineralization
In the demineralized zone the intertubular matrix is mainly affected by a wave of acid produced by bacteria in the zone of bacterial invasion, which diffuses ahead of the bacterial front. The softened dentine in the base of a cavity is therefore sterile but, in clinical practice, it cannot be distinguished reliably from softened infected dentine (see later). It may be stained yellowish-brown as a result of the diffusion of other bacterial products interacting with proteins in dentine.

Zone of bacterial invasion
In this zone the bacteria extend down and multiply within the dentinal tubules, some of which may become occluded by bacteria .There are always, however, many empty tubules lying among tubules containing bacteria. The bacterial invasion probably occurs in two waves: the first wave consisting of acidogenic organisms, mainly lactobacilli, produce acid which diffuses ahead into the demineralized zone. A second wave of mixed acidogenic and proteolytic organisms then attack the demineralized matrix. The walls of the tubules are softened by the proteolytic activity and some may then be distended by the increasing mass of multiplying bacteria. The peritubular dentine is first compressed, followed by the intertubular dentine, resulting in elliptical areas of proteolysis-liquefaction foci. Liquefaction foci run parallel to the direction of the tubules and may be multiple, giving the tubule a beaded appearance . These changes are enhanced in the zone of destruction. The bacteria may show varying degrees of degeneration.

Zone of destruction
In the zone of destruction the liquefaction foci enlarge and increase in number. Cracks or clefts containing bacteria and necrotic tissue also appear at right angles to the course of the dentinal tubules forming transverse clefts. The mechanism of formation of transverse clefts is uncertain. They may follow the course of incremental lines, or result from the coalescence of liquefaction foci on adjacent tubules, or arise by extension of proteolytic activity along interconnecting lateral branches of odontoblast tubules. Bacteria are no longer confined to the tubules and invade both the peritubular and intertubular dentine. Little of the normal dentine architecture now remains and cavitation commences from the amelodentinal junction. In acute, rapidly progressing caries the necrotic dentine is very soft and yellowish-white; in chronic caries it has a brownish-black colour and is of leathery consistency.

Reactionary (or tertiary) dentine
A layer of reactionary (or tertiary) dentine is often formed at the surface of the pulp chamber deep to the dentine caries, this dentine being localized to the irritated odontoblasts. It varies in structure but the tubules are generally irregular, tortuous, and fewer in number than in primary dentine, or may even be absent. Microradiography shows variations in mineralization, but areas of hypermineralization when compared with primary dentine may be present. Its formation effectively increases the depth of tissue between the carious dentine and the pulp, and in this way delays involvement of the pulp.

Reactionary dentine is a non-specific response to odontoblast irritation, also being formed in reaction to tooth wear and cavity and crown preparations.


Key points - Dentine caries
· zoned lesion but zones not well demarcated
· demineralization precedes bacterial invasion
· bacterial invasion of tubules; acid produced by acidogenic organisms diffuses ahead
· proteolytic organisms in tubules break down demineralized dentine
· histological evidence of proteolysis - liquefaction foci, transverse clefts
· in the base of a cavity soft dentine must be removed; stained hard dentine can be retained


Clinical aspects of dentine caries
The dentine at the base of a cavity may be soft, hard, stained, or unstained. Excavation of the softened dentine removes the great majority of cariogenic bacteria. Hard stained dentine may harbour small numbers of bacteria but these are of no consequence. There is no need to remove hard stained dentine. Follow-up studies have shown that lesions treated in this way and then sealed do not progress, providing the seal remains intact, even though some infected dentine may remain. Various caries-detector dyes have been developed with the aim of distinguishing between infected and sterile dentine but their validity and reliability require further study and, at present, they are not recommended for routine use.

The technique of stepwise excavation of a deep carious lesion takes advantage of the fact that progression of caries can be prevented even if some bacteria still remain. The aim of the technique is to remove as much infected dentine as is safely possible at the first excavation, without risking pulpal exposure, in order to reduce the rate of progression. The tooth is then sealed for an interval (from 4 to 6 months in different studies) to allow time for the defence reactions of the pulpodentinal complex to develop, before final excavation.

Chemomechanical methods of removal of carious dentine have also been developed. Although these reduce the amount of cavity preparation and removal of sound tooth tissue that would have been required for access using conventional excavation, the early techniques were time-consuming and relatively inefficient. However, the recently introduced reagent Carisolv (Medi Team) appears more promising. Essentially, chemomechanical techniques involve the application of reagents to carious dentine which chlorinate degraded collagen, disrupting and softening it, facilitating its removal.

Root caries

The primary tissue affected in root caries is usually the cementum. The development of cemental caries is preceded by exposure of the root to the oral environment as a result of periodontal disease followed by bacterial colonization. Although Actinomyces species are present in large numbers and have been implicated in the disease, other organisms, including mutans streptococci and lactobacilli, are also associated with root caries.

Microradiographs of developing lesions show subsurface demineralization of the root which may extend into dentine. The surface layer is hypermineralized and is analogous to that seen in the early enamel lesion. It represents a zone of reprecipitation of mineral removed from the subsurface and of remineralization from minerals present in plaque/saliva. Fluoride is readily taken up by carious root surfaces and this enhances remineralization.

Despite the initial hypermineralization of the surface, progressive softening occurs with time in active lesions. Root caries is clinically diagnosed by a softening and brownish discoloration of the tissues. Demineralization is rapidly followed by bacterial invasion along the exposed collagen fibres and fracture and loss of successive layers of cementum. These fractures frequently occur parallel to the root surface and are associated with invasion of bacteria along the incremental bands in cementum which run as concentric layers around the root. This extension results in lesions that spread laterally around the root and often coalesce with other lesions so that eventually the carious process may encircle the root.

As the cementum is lost the peripheral dentine is exposed. The basic reactions and carious destruction of this tissue are the same as those described previously. Sclerosis may lead to arrested lesions and the surface of the exposed dentine may be covered by a hypermineralized layer.

Arrested caries

Enamel
Arrest of an approximal smooth surface lesion prior to cavity formation can occur when the adjacent tooth is lost so that the lesion becomes accessible to plaque control. Remineralization may then occur from saliva or from the topical application of calcifying solutions, but a normal crystalline structure is not necessarily reformed.

Dentine
Arrest of coronal dentinal caries may occur in lesions characterised by marked early dentinal sclerosis which limits the rate of inward spread of the caries. (In contrast, teeth involved by rampant caries show a minimal protective response.) As a result, there is extensive lateral spread of caries along the zone of the amelodentinal junction, which undermines the surface enamel. Fracture and loss of this unsupported enamel exposes the superficially softened carious dentine to the oral environment and it is then removed by attrition and abrasion, leaving a hard, polished surface. Such dentine is deeply pigmented brown-black in colour. Its surface is hypermineralized due to remineralization from oral fluids and has a high fluoride content.

Arrested lesions of root caries have a similar clinical appearance and develop in a similar manner following loss of the superficially softened cementum.

Immunological aspects of dental caries

Caries in man is associated with the development of serum and salivary antibodies against S. mutans, but in almost all individuals this natural active immunity appears to have little effect as caries is virtually universal in Western populations. This may be because S. mutans is only weakly antigenic.

However, artificial active immunity following experimental immunization in animal models has been shown to produce a significant reduction in caries. Early experiments used vaccines composed of whole cells of S. mutans, but these could induce antibodies in humans which cross-react with heart tissue. Subsequently, various subunits of the organism have been investigated, especially surface antigens involved in the attachment of the organism to tooth surfaces, which still confer protection against caries but without the risk of cross-reactivity.

Immunization evokes a humoral response and protection against S. mutans is provided largely by secretory IgA antibodies in saliva, although IgG and IgM class antibodies can also gain access to the mouth via the crevicular fluid. The salivary IgA antibodies act mainly by interfering with the attachment of the organism to tooth surfaces. In addition to active immunity, the development of genetically engineered antibodies (monoclonal antibodies) against specific mutans streptococcal antigens offer the prospect of passive immunization as a preventive strategy for the future.

Key Words : tooth tooth whitening tooth decay tooth pain tooth bleaching tooth filling

Disorders of development of teeth and craniofacial anomalies

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Introduction

The development of teeth and of the face is regulated by genes, but the genetic programme is very sensitive to disturbances in the environment such as exposure to infection or toxic chemicals, including drugs. The specific genetic abnormalities underlying some developmental disorders are now known, and for several others a strong genetic association has been established, even though the genes have yet to be identified. However, there remain many where the causes appear complex and multifactorial, involving the interaction of genetic and environmental factors.

Disorders of development of teeth

Disorders of development of teeth may be prenatal or postnatal in origin and may be inherited or acquired. Their recognition and evaluation require a thorough knowledge of the normal chronology of the human dentition and of the normal development and structure of the teeth.

Disorders of development of teeth may be due to abnormalities in the differentiation of the dental lamina and the tooth germs, causing anomalies in the number, size, and form of teeth (abnormalities of morphodifferentiation) or to abnormalities in the formation of the dental hard tissues resulting in disturbances in tooth structure (abnormalities of histodifferentiation). Abnormalities of histodifferentiation occur at a later stage in development than abnormalities of morphodifferentiation; in some disorders both stages of differentiation are abnormal.

Disturbances in number of teeth

Hypodontia, anodontia, and associated syndromes

The congenital absence of teeth may be referred to as hypodontia, when one or several teeth are missing, or anodontia when there is a complete absence of one or both dentitions.

Hypodontia is more common in the permanent dentition, occurring in about 2-10 per cent in different populations (excluding absent third molars) compared to the primary dentition where the prevalence is less than 1 per cent. It is more common in females and there are also racial differences. For example, the prevalence of missing mandibular permanent central incisors is much more common in Japanese and Swedish populations than in other groups studied. Hypodontia may be symmetrical when particular teeth or groups of teeth are involved, or haphazard when no pattern is discernible. Although it is very unusual for deciduous teeth to be congenitally absent, it is likely that in such cases the permanent successional tooth will also fail to form. Third molars, permanent maxillary lateral incisors, and mandibular second premolars are the teeth most frequently involved in symmetrical forms and a hereditary trait can sometimes be shown with missing maxillary lateral incisors.

Although the genetic basis of hypodontia is not yet understood, several regulatory genes involved in tooth development have been identified and it is likely that mutations in these result in tooth agenesis .These control or regulatory genes are not unique to tooth development but are the same genes that control the development of the face and of many other tissues and organs in the embryo. Thus, hypodontia may be associated with other craniofacial anomalies and developmental syndromes .

Hypohidrotic ectodermal dysplasia

Severe hypodontia and anodontia are rare and in most cases are associated with other defects, the most frequent being hereditary hypohidrotic ectodermal dysplasia which is characterized by the congenital absence of ectodermal structures. The disorder is rare and is usually inherited as an X-linked recessive trait, although a very rare autosomal recessive form has been described and sporadic cases have been reported. Affected patients have smooth, dry skin with fine, scanty hairs and partial or total absence of sweat glands which leads to hyperthermia. Some have a few teeth present, but these are often retarded in eruption, deformed, and frequently have conical crowns. Female carriers usually show only mild manifestations that may be restricted to minimal hypodontia, such as absent maxillary lateral incisors, but carriers may be detected by a reduced sweat pore count.

Supernumerary teeth (hyperdontia)

These are teeth additional to those of the normal series. They may develop in any tooth-bearing area but occur most frequently in the anterior and molar regions of the maxilla followed by the premolar region of the mandible. Occasionally, they are associated with other defects, such as cleft palate or cleidocranial dysplasia. They may prevent the eruption, or cause malposition or resorption of adjacent teeth, and may develop dentigerous cysts if unerupted. Supernumerary teeth are more common in females, are usually single and occur in about 1-3 per cent of the population in the permanent dentition. They are unusual in the deciduous dentition.


Key points - Hypodontia and Hyperdontia
Hypodontia
· more common in permanent than primary dentition
· may be associated with mutations in developmental control genes
· absence of primary teeth associated with absence of permanent successors
· may be associated with other developmental abnormalities
Severe Hypodontia/Anodontia
· rare
· associated most frequently with hypohidrotic ectodermal dysplasia (HED)
· HED usually X-linked recessive
Hyperdontia (supernumerary teeth)
· more common in maxilla than mandible
· occasionally associated with other developmental defects
· more common in females than males


Supernumerary teeth occurring at certain sites may be referred to by special terms. A mesiodens is a supernumerary tooth developing between the maxillary central incisors and is the most common of all supernumerary teeth. The majority have conical crowns and short roots. A paramolar arises alongside the maxillary molars and is usually buccally placed, and a distomolar develops distal to a third molar. Supernumerary teeth which morphologically resemble those of the normal series are called supplemental teeth but most are reduced in size.

Disturbances in size of teeth

Macrodontia and microdontia

The size of both the teeth and the jaws is influenced by genetic and environmental factors and considerable variation occurs. Studies of twins have shown that for the teeth, at least, genetic factors account for a large part of this variation. The terms 'macrodontia' and 'microdontia' are used to describe teeth which are larger or smaller than normal, respectively, but the limits of normal variation have never been adequately defined. Both macrodontia and microdontia may involve the entire dentition, or only one or two teeth symmetrically distributed in the jaws. Microdontia of the whole dentition may be associated with other defects, for example Down syndrome and congenital heart disease.

Whilst it is convenient to consider abnormalities in the number and the size of teeth separately the anomalies often occur together. For example, hypodontia and microdontia may occur together in several of the conditions listed in. More common examples are seen in patients with one missing permanent maxillary lateral incisor, in which case the contralateral tooth is frequently peg-shaped.

Disturbances in form of teeth

Introduction

Disturbances in tooth form may involve the crown, the root, or both. The most frequent variations of the crowns of teeth affect maxillary permanent lateral incisors, which may be peg-shaped or show an accentuated cingulum - either variation sometimes being associated with an invagination. Premolars or molars with an increased or decreased number of cusps are also frequently seen. Variations in the number, course, form, and size of roots are particularly common.

Dilaceration

The term dilaceration is used to describe a deformity in which the crown of the tooth is displaced from its normal alignment with the root, so that the tooth is severely bent along its long axis. Dilaceration is usually the result of acute mechanical trauma and most frequently involves the maxillary incisors.

Taurodontism

A taurodont tooth (bull-like tooth) is one in which the pulp chamber has a greater apico-occlusal height than in normal teeth, with no constriction at the level of the amelocemental junction. The result is that the chamber extends apically, well beyond the neck of the tooth. The anomaly affects multirooted teeth and is thought to be caused by the failure of Hertwig's sheath to invaginate at the proper horizontal level. It is rare in the primary dentition. Taurodont teeth may occur as incidental findings or be associated with other rare craniofacial or dental anomalies. There is also an association with abnormalities in the number of the sex chromosomes such as in Klinefelter and poly-X syndromes.

Double teeth

Double teeth is a descriptive term used to describe a developmental anomaly where two teeth appear joined together. The degree of union is variable and may involve the crown, the roots, or both. It is very unusual for teeth to be united by enamel only, joining of the dentine and also the pulp chamber being much more frequent.

A variety of other terms have been applied to this anomaly based on its supposed aetiology, such as fusion and gemination. These have been defined as:

Fusion - the union between dentine and/or enamel of two or more separate developing teeth.

Gemination - the partial development of two teeth from a single tooth bud following incomplete division.

However, the aetiology remains unclear although a genetic basis has been suggested. For this reason the general term 'double teeth', which describes the appearance with no implication regarding aetiology, is preferred. The developmental anomaly of double teeth must be distinguished from concrescence which is an acquired condition where teeth are joined by cementum only (see below).

Double teeth are more common in the primary than in the permanent dentition, the prevalence in different series ranging from 0.5-2.5 per cent for the primary and 0.1-0.2 per cent for the permanent dentitions. The incisors (and also the canines in the primary dentition) are most frequently affected and the condition may be bilaterally symmetrical. In the primary dentition the majority of cases involve the anterior mandibular teeth.

Concrescence

Concrescence is an acquired disorder in which the roots of one or more teeth are united by cementum alone after formation of the crowns. This is most frequently seen in the permanent dentition where the roots of teeth develop close together (for example, between maxillary second and third molars) or following hypercementosis associated with chronic inflammation.


Key points - Double teeth
· developmental anomaly
· teeth usually united by dentine (with or without pulp)
· more common in primary than permanent dentition
· anterior teeth mainly involved
Concrescence
· acquired anomaly
· union by cementum alone following hypercementosis

Disturbances in structure of teeth

Disturbances in structure of enamel

Enamel normally develops in two stages. In the first, or secretory, stage, the ameloblasts perform the dual function of matrix production and initial mineralization. Matrix production involves the synthesis and secretion of the matrix proteins, amelogenin, enamelin, ameloblastin, and tuftelin, of which amelogenin accounts for about 90 per cent. Initial mineralization occurs immediately after secretion. In the second stage, the maturation stage, there is withdrawal of protein and water from the enamel accompanied by increase in mineral content before the tooth erupts.

Most classifications of disturbances in enamel formation distinguish between those that affect the secretory stage, resulting in deficient matrix production and thin hypoplastic enamel, and those that affect the maturation stage, resulting in deficient mineral deposition and soft hypomineralized enamel. Although this distinction may at times be hard to sustain as some disturbances affect both matrix formation and mineralization, it remains a useful clinical division.

In enamel hypoplasia the ameloblasts fail to produce a normal volume of matrix but any matrix which is produced generally becomes as fully mineralized as normal enamel. Enamel hypoplasia presents clinically as pits or grooves in the enamel surface, or as a general reduction in the thickness of the whole enamel. The defective enamel has fewer prisms than normal and they may run in abnormal directions. In some cases no prism structure can be seen.

Hypomineralized enamel results from a failure of the ameloblasts to fully calcify the previously formed matrix, and generally such enamel appears clinically as white and opaque. After eruption it may become pigmented buff, orange, or brown and be quickly chipped and worn away. Much of the organic matrix of hypomineralized enamel remains acid-insoluble and is often preserved in sections of decalcified specimens.

Hypoplastic and hypomineralized enamel may result from disturbances affecting a single tooth, a group of teeth, or all of the teeth, and the structure of the enamel formed depends on the severity and duration of the disturbance as well as its nature. Most disturbances of ameloblast function can produce both hypoplasia and hypomineralization, but clinically one type usually predominates in a particular patient.

The classification given in is based on the aetiology of hypoplastic and hypomineralized enamel. It is not exhaustive but includes the common causes.


Key points - Defective amelogenesis
· defective matrix production - enamel hypoplasia
· defective maturation/mineralization - hypomineralized enamel


Localized causes

Local infection or trauma
Enamel hypoplasia or hypomineralization involving a single tooth is most commonly seen in permanent maxillary incisors, or maxillary or mandibular premolars. The usual cause of these abnormalities is infection or trauma related to the deciduous predecessor resulting in damage to the ameloblasts of the permanent successor. Such teeth are often called Turner teeth. Clinically, the defects range from yellowish or brownish pigmentation of the enamel to extensive pitting and irregularity of the surface, the crowns often being smaller than normal. The yellowish colour is sometimes due to the deposition of cementum on the enamel surface.

Enamel opacities
These are white, opaque spots seen in smooth-surface enamel, some of which become brown-stained after eruption . The opacities are common and are seen in as many as one in three children aged 12-14 years. They have a random distribution, and teeth in both the deciduous and the permanent dentition are affected. The maxillary permanent central incisor is most frequently involved. The cause is not known but the opacities are thought to be due to local rather than systemic factors. The prevalence is less in areas with one part per million of fluoride in the drinking water. Histological examination of the enamel shows the opaque spots to be hypomineralized.


Key points - Developmental abnormalities of enamel - aetiology
· local causes
· generalized causes
- environmental/systemic disturbances (chronological hypoplasia)
- genetically determined

Generalized causes

Chronological hypoplasias
Any serious nutritional deficiency or systemic disease occurring during the time of formation of the teeth can lead to enamel hypoplasia or hypomineralization, because ameloblasts are amongst the most sensitive cells in the body in terms of metabolic requirements. Such time-related disturbances are called chronological hypoplasia and most enamel hypoplasias due to environmental causes are of this type. A pitting type of hypoplasia usually results , although ridging and grooving may also be seen, and the disturbance produces a horizontal band of hypoplasia, the distribution of which is related to that enamel which was forming at the time of the disturbance . Thus a disturbance occurring at or soon after birth may affect the incisal edges of the permanent central incisors and the occlusal surfaces of the first permanent molars in addition to the deciduous teeth .

Congenital syphilis
This disease produces characteristic hypoplastic changes in the enamel of permanent incisors and first molars due to infection of the tooth germ by spirochaetes. The mesial and distal surfaces of the incisors taper towards the incisal edges rather than toward the cervical margin, giving a 'screw-driver' appearance, and the incisal edges usually have a central notch (Hutchinson's incisors).These changes are most obvious in the maxillary central incisors. The occlusal surfaces and occlusal thirds of the crowns of the first molars are covered by small globular masses of enamel (Moon's molars or mulberry molars).

Fluoride ions
Ingestion of excess fluoride during the period of tooth formation may result in dental fluorosis, producing hypomineralized or hypoplastic enamel. The development of fluorosis is dependent on the total amount of fluoride ingested from all sources and the duration and timing of exposure. The early maturation phase of enamel formation appears particularly sensitive whereas the secretory phase is the least sensitive. Clinically, dental fluorosis is characterized by faint white flecking of the enamel, white patches or striations, or in more severe cases by yellow or brownish-black discoloration, particularly in teeth most exposed to light. The term 'mottling' is often used to describe the appearances of dental fluorosis . Varying degrees of hypoplasia of the enamel may also seen. The severity of the lesions varies from tooth to tooth and between different areas of an individual tooth, reflecting variations in exposure and in the susceptibility of different phases of enamel formation with time. They are found mainly in the permanent dentition but the deciduous teeth may be involved in severe cases and in areas of endemic fluorosis.


Key points - Chronological hypoplasias; dental fluorosis
Chronological hypoplasias
· time related
· horizontal bands of pitting of enamel
· distribution of bands and tooth involvement reflect the chronology of tooth development
Dental fluorosis
· effects dependent on dose, duration, and timing of exposure
· mottled appearance of the teeth, usually widespread throughout the dentition
· hypomineralization of subsurface enamel; hypoplastic pitting in severe cases


Amelogenesis imperfecta
Amelogenesis imperfecta is a group of hereditary conditions affecting enamel formation. It is usually classified into two major and clinically distinct types depending on whether the abnormality is related to defective matrix production (hypoplastic type) or defective mineralization (hypomineralized/hypomaturation type). Within this broad division many subtypes have been described based on the modes of inheritance and clinical manifestations. It can be inherited as autosomal dominant, autosomal recessive or X-linked forms. Most cases of amelogenesis imperfecta are inherited as autosomal dominant or, less frequently, X-linked traits.

The patterns of inheritance are not related to particular variations in the clinical manifestations (phenotype). However, as the molecular basis for enamel formation is becoming better understood the corresponding genes are being identified. Mutations in these genes have been associated with amelogenesis imperfecta and in the future it may be possible to correlate specific genotypes with particular phenotypes. Amelogenin, the most abundant of the enamel matrix proteins, has been most extensively studied and is coded for by genes on both the X and the Y chromosomes. However, the gene on the X chromosome (AMELX gene) accounts for the great majority of the protein synthesized. The genes for ameloblastin, enamelin, and tuftelin have also been localized and mutations in these are linked to autosomal patterns of inheritance of amelogenesis imperfect.All types of amelogenesis imperfecta affect the deciduous and permanent dentitions and most of the enamel on all of the teeth is involved.

The hypomineralized/hypomaturation type is the most common form. Newly erupted teeth appear normal in size and shape and have enamel of normal thickness. However, the enamel is of a soft chalky consistency and exhibits variable white, opaque to mottled brownish-yellow appearances. Because of the deficient mineralization the enamel has a similar density to dentine on radiographs. It is rapidly lost by abrasion and attrition exposing the dentine. Gross attrition may result in the teeth being worn down to gum level.

In the hypoplastic types of amelogenesis imperfecta the enamel does not reach normal thickness and there is considerable variation in clinical appearances. In some cases, localized areas of hypoplasia are randomly distributed over the surface of the enamel producing generalized roughness and pitting or irregular vertical grooving and wrinkling. In the smooth form, the enamel over the whole of the crown is affected and the teeth have sharp, needle-like cusps. The enamel is very thin but hard and glassy. It lacks a normal prismatic structure and may be laid down in incremental bands parallel to the surface.

In the X-linked form, heterozygous females are less severely affected than males or homozygous females and tend to show alternating irregular vertical bands of normal and defective enamel, reflecting the random inactivation of one or other of the X chromosomes in different groups of ameloblasts (Lyonization effect).


Key points - Amelogenesis imperfecta
· hypomineralized/hypomaturation and hypoplastic types
· autosomal dominant pattern of inheritance the most common for both types
· X-linked forms associated with mutations in the amelogenin (AMELX) gene
· mutations in genes coding for other enamel proteins linked to autosomal patterns of inheritance
Hypomineralized/hypomaturation type
· normal tooth morphology when first erupt
· soft chalky enamel easily lost, exposing dentine
· teeth prone to attrition, sometimes severe
Hypoplastic type
· enamel of normal hardness but of variable thickness
· considerable variation in clinical appearances
· variable pitting/vertical grooving/generalized thinning
· teeth may appear small/show abnormal cuspal morphology

Disturbances in structure of dentine

Dentine is the first-formed dental hard tissue, the cells of the internal enamel epithelium inducing the adjacent mesenchymal cells of the dental papilla to differentiate into odontoblasts. Both the odontoblasts and subodontoblastic cells influence the development of the first-formed or mantle dentine, the subodontoblastic cells forming part of the collagenous matrix which is embedded in a ground substance rich in glycosaminoglycans. As more matrix is formed the odontoblasts migrate centripetally and their processes remain in the matrix which begins to mineralize when it is about 5 um thick. Calcification is initiated by small crystallites (which at first are probably budded from the odontoblasts) and completed by subsequent growth and fusion of discrete globules called calcospherites. Where fusion of calcospherites does not occur, hypomineralized areas of interglobular dentine remain. A layer of uncalcified matrix (predentine) is normally present at the pulpal surface. Peritubular dentine is formed along the internal surfaces of the dentinal tubules throughout life, the tubule diameter being progressively reduced or even obliterated.

Most of the clinically significant disturbances of dentinogenesis have a genetic aetiology, but some environmental or systemic disturbances affecting calcium metabolism or calcification may also produce abnormal dentine. The developmental abnormalities of dentine are listed in .Many are rare.

Dentinogenesis imperfecta (hereditary opalescent dentine)
Three types of dentinogenesis imperfecta are recognized: type 1, which is associated with osteogenesis imperfecta; type II, where only the teeth are affected; and type III, which only occurs in a rare racial isolate in the USA. Type II is the commonest type.

Dentinogenesis imperfecta type II is an autosomal dominant disorder with variable expressivity and is the most common dental genetic disease, involving approximately 1 in 6000 to 1 in 8000 of the population. It has been mapped to the long arm of chromosome 4 (4 q), as have some of the enamel matrix proteins, but the gene involved has not yet been isolated. Both the deciduous and permanent dentitions are affected. On eruption the teeth have a normal contour but an opalescent amber-like appearance . Subsequently, they may have an almost normal colour, following which they become translucent, and finally grey or brownish with bluish reflections from the enamel. Although in most cases the enamel is structurally normal, it is rapidly lost and the teeth then show marked attrition .

Radiological examination shows short, blunt roots with partial or even total obliteration of the pulp chambers and root canals by dentine Histological examination shows that apart from a thin layer of normal tubular mantle dentine (i.e. the dentine immediately adjacent to the enamel or cementum), the dentine contains a reduced number of tubules, many of which are wide and irregular, and areas of atubular dentine may be present. This abnormal dentine partly or totally obliterates the pulp chamber and root canal. Vascular inclusions are often found in the dentine, representing remnants of odontoblasts and pulp tissue.

Analysis of the dentine shows an increased water content and a decreased mineral content when compared with normal dentine. The microhardness of the dentine is low, explaining the rapid attrition of the teeth which occurs following loss of enamel. The latter may be due to the abnormal physical properties of the dentine which render it less able to withstand distortional forces. Caries is unusual in affected teeth, presumably due to the reduced number of invasion pathways in the dentine, with the caries being confined to the superficial layers which are quickly worn away. The pulp cavities in deciduous teeth may not be obliterated, the dentine may remain thin and the pulps may become exposed by attrition (see 'shell-teeth' below).

Dentinogenesis type I is associated with osteogenesis imperfecta and although the two conditions are closely related they are genetically distinct. In many patients with osteogenesis imperfecta the appearances of the teeth in the primary dentition are indistinguishable from those seen in dentinogenesis type II. However, the involvement of the permanent dentition in type I (associated with osteogenesis imperfecta) is very variable and tooth discoloration and attrition do not occur to the same extent.

A similar appearance is seen in dentinogenesis type III which occurs in a particular racial isolate group in southern Maryland, USA (the Brandywine isolate). Genetic studies have shown that type III overlaps with the same region on chromosome 4 as type I, but it is not yet known whether they are genetically distinct or represent variable expression of disease in different groups of patients.


Key points - Dentinogenesis imperfecta
Type I
· associated with osteogenesis imperfecta
· genetically distinct from dentinogenesis type II
· primary dentition more severely affected than permanent
· appearances in the primary dentition as for type II
Type II
· autosomal dominant, affecting teeth only
· primary and permanent dentition affected
· discoloration of teeth, opalescent amber-like appearance
· marked attrition following loss of enamel
· pulp obliteration and stunted roots
· abnormal dentine structure and composition.
Type III
· rare racial isolate in USA
· closely related to type II


Dentinal dysplasia
Two forms of this rare autosomal dominant disease are described. In type I (rootless teeth) the permanent teeth have normal crowns associated with roots composed of dysplastic dentine containing numerous calcified, spherical bodies. The pulp chamber and root canals are largely obliterated and the roots are usually very stunted. The abnormality is due to a defect in Hertwig's root sheath which fragments and is incorporated into the dental papilla where it induces formation of fused globular masses of abnormal dentine. The first sign may be premature exfoliation either spontaneously or with minor trauma.

Type II dentinal dysplasia (coronal dentine dysplasia) may not be a distinct entity. It has been linked to the same area on chromosome 4 as dentinogenesis imperfecta type II. The appearances in the primary dentition are the same but the permanent teeth are of normal colour and root length.

Metabolic disturbances affecting dentinogenesis
In the active phase of rickets the width of the predentine is increased and the recently formed dentine is incompletely calcified. Subsequently, bands and areas of interglobular dentine corresponding to the period of illness are seen in the dentine. Pronounced interglobular dentine is also a feature of vitamin D-resistant rickets (hypophosphataemia), but large pulp chambers and long pulp horns which may extend as clefts to the amelodentinal junction are also seen. The overlying enamel may also be cracked or defective allowing direct access of bacteria to the pulp, resulting in pulpitis and periapical sequelae without carious attack. Increased amounts of interglobular dentine and widening of the predentine may be seen in other environmental disorders affecting mineralization such as hypophosphatasia (see also hypocementosis) and nutritional deficiencies. The effects of drugs vary with the nature of the drug and period of administration. Cytotoxic agents often produce increased prominence of incremental lines coinciding with drug administration.

The teeth in juvenile hypoparathyroidism may be small with hypoplastic enamel. The roots may be stunted and there may be structural abnormalities in the radicular dentine.

Regional odontodysplasia (ghost teeth)
This is an uncommon developmental disorder of unknown aetiology associated with abnormalities of enamel, dentine, pulp, and the dental follicle. Both deciduous and permanent dentitions are affected and the number of teeth and number of quadrants involved varies. The defect occurs most frequently in the anterior part of the maxilla and is usually unilateral.

The teeth are delayed in eruption and generally have a very irregular shape with hypoplastic and irregularly mineralized enamel. The dentine is thinner than normal, hypomineralized, and contains large areas of interglobular dentine. Radiological examination shows reduced radiopacity of the teeth with loss of distinction between the enamel and dentine, described as a 'ghostly' appearance.

Disturbances in structure of cementum

The coronal third of the root is normally covered only by a narrow layer of acellular (primary) cementum, whereas the apical two-thirds and furcation areas are covered by an additional thicker layer of cellular (secondary) cementum. Cellular cementum continues to be formed throughout the life of the tooth and typically shows incremental lines of growth. The thickness of the cementum varies considerably between individuals, but generally increases with age and to compensate for occlusal wear.

Hypercementosis
Hypercementosis may be idiopathic or the result of local or general disorders. It may affect one or several teeth and may be associated with root ankylosis, when cementum is directly continuous with the alveolar bone, or with concrescence . Some causes are given below.

PERIAPICAL INFLAMMATION
Although resorption of cementum may occur close to the centre of the inflammatory focus, apposition of cementum may be stimulated a little further away. This produces a generalized thickening of the cementum or a localized knob-like enlargement.

MECHANICAL STIMULATION
Excessive forces applied to a tooth may produce resorption, but mechanical stimulation below a certain threshold may stimulate apposition of cementum.

FUNCTIONLESS AND UNERUPTED TEETH
Such teeth may show areas of cementum resorption, but excessive apposition of cementum may also occur. In unerupted teeth the cementum may even extend over the surface of the enamel if the reduced enamel epithelium is lost.

PAGET'S DISEASE OF BONE
Hypercementosis is often seen in teeth of patients with Paget's disease, the thickened cementum showing a mosaic appearance analogous to that seen in the bone. The cementum forms irregular masses and ankylosis is common.

Hypocementosis
Hypoplasia and aplasia of cementum are uncommon. In cleidocranial dysplasia there is a lack of cellular cementum following the deposition of acellular cementum. Aplasia of cementum is seen in hypophosphatasia :a recessive autosomal disease, characterized by a reduced serum alkaline phosphatase level and skeletal abnormalities. Premature loss of some or all deciduous and permanent teeth is seen. Dentine formation may also be abnormal.

Craniofacial anomalies

A bewildering array of craniofacial anomalies and associated syndromes have been, and continue to be, identified. The majority have a genetic basis and with the recent advances in molecular genetics the mechanisms underlying some of these conditions are being discovered. Many appear to be associated with abnormalities in the developmental genes, their signalling molecules, receptors, and transcription factors, as discussed previously in relation to hypodontia. Examples include cleidocranial dysplasia in which there is mutation of a master control gene of osteoblast function, and Crouzon syndrome in which there is mutation of a fibroblast growth factor receptor gene. However, others, particularly orofacial clefts (clefts of the lip and/or palate), have a multifactorial aetiology involving the interplay of genetic and environmental factors.

Orofacial clefts are amongst the commonest of all congenital structural birth defects and may occur alone or in combination with over 300 syndromes, although about 70 per cent are non-syndromic in type. The prevalence varies in different parts of the world but ranges from about 1 in 500 to about 1 in 1000 births in most cases. There is a higher incidence of clefts of the lip and palate compared with clefts of the palate alone and there is a family history in about 30% of the former and 15% of the latter.

About 20 possible (or candidate) genes have been suggested from different studies and although some occur more frequently than others, those associated with increased risk have still to be confirmed. In addition, clefts have also been associated with environmental factors, for example smoking, alcohol, and folic acid deficiency, but study of the interplay of these with genetic factors is at an early stage.

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