|Classification and external resources|
Destruction of a tooth by cervical decay from dental caries. This type of decay is also known as root decay.
Dental caries (Latin, "rot"), also known as tooth decay or a cavity, is an infection, bacterial in origin, that causes demineralization and destruction of the hard tissues of the teeth (enamel, dentin and cementum). It is a result of the production of acid by bacterial fermentation of food debris accumulated on the tooth surface. If demineralization exceeds saliva and other remineralization factors such as from calcium and fluoridated toothpastes, these once hard tissues progressively break down, producing dental caries (cavities or carious lesions, that is, holes in the teeth). Today, caries remains one of the most common diseases throughout the world. Cariology is the study of dental caries.
Depending on the extent of tooth destruction, various treatments can be used to restore teeth to proper form, function, and aesthetics, but there is no known method to regenerate large amounts of tooth structure. Instead, dental health organizations advocate preventive and prophylactic measures, such as regular oral hygiene and dietary modifications, to avoid dental caries.
- 1 Signs and symptoms
- 2 Cause
- 3 Pathophysiology
- 4 Diagnosis
- 5 Prevention
- 6 Treatment
- 7 Epidemiology
- 8 History
- 9 References
- 10 External links
Signs and symptoms
A person experiencing caries may not be aware of the disease. The earliest sign of a new carious lesion is the appearance of a chalky white spot on the surface of the tooth, indicating an area of demineralization of enamel. This is referred to as a white spot lesion, an incipient carious lesion or a "microcavity". As the lesion continues to demineralize, it can turn brown but will eventually turn into a cavitation ("cavity"). Before the cavity forms, the process is reversible, but once a cavity forms, the lost tooth structure cannot be regenerated. A lesion that appears dark brown and shiny suggests dental caries were once present but the demineralization process has stopped, leaving a stain. Active decay is lighter in color and dull in appearance.
As the enamel and dentin are destroyed, the cavity becomes more noticeable. The affected areas of the tooth change color and become soft to the touch. Once the decay passes through enamel, the dentinal tubules, which have passages to the nerve of the tooth, become exposed, resulting in pain that can be transient, temporarily worsening with exposure to heat, cold, or sweet foods and drinks. A tooth weakened by extensive internal decay can sometimes suddenly fracture under normal chewing forces. When the decay has progressed enough to allow the bacteria to overwhelm the pulp tissue in the center of the tooth a toothache can result and the pain will become more constant. Death of the pulp tissue and infection are common consequences. The tooth will no longer be sensitive to hot or cold, but can be very tender to pressure.
Dental caries can also cause bad breath and foul tastes. In highly progressed cases, infection can spread from the tooth to the surrounding soft tissues. Complications such as cavernous sinus thrombosis and Ludwig angina can be life-threatening.
There are four main criteria required for caries formation: a tooth surface (enamel or dentin), caries-causing bacteria, fermentable carbohydrates (such as sucrose), and time. However, it is also known that these four criteria are not always enough to cause the disease and a sheltered environment promoting development of a cariogenic biofilm is required. The caries process does not have an inevitable outcome, and different individuals will be susceptible to different degrees depending on the shape of their teeth, oral hygiene habits, and the buffering capacity of their saliva. Dental caries can occur on any surface of a tooth that is exposed to the oral cavity, but not the structures that are retained within the bone.
The bacteria most responsible for dental cavities are the mutans streptococci, most prominently Streptococcus mutans and Streptococcus sobrinus, and lactobacilli. If left untreated, the disease can lead to pain, tooth loss and infection.
Tooth decay disease is caused by specific types of bacteria that produce acid in the presence of fermentable carbohydrates such as sucrose, fructose, and glucose. The mineral content of teeth is sensitive to increases in acidity from the production of lactic acid. To be specific, a tooth (which is primarily mineral in content) is in a constant state of back-and-forth demineralization and remineralization between the tooth and surrounding saliva. For people with little saliva, especially due to radiation therapies and autoimmune disorders, such as Sjögren's syndrome, that may destroy the salivary glands, there also exists therapies such as saliva substitutes and remineralization products. These patients may be susceptible to dental caries. When the pH at the surface of the tooth drops below 5.5, demineralization proceeds faster than remineralization (meaning that there is a net loss of mineral structure on the tooth's surface).
All caries occur from bacterial acid demineralization that exceeds saliva and fluoride remineralization, and acid demineralization occurs where bacterial plaque is left on teeth. Because most plaque-retentive areas are between teeth and inside pits and fissures on chewing surfaces where brushing is difficult, over 80% of cavities occur inside pits and fissures. Areas that are easily cleansed with a toothbrush, such as the front and back surfaces (facial and lingual), develop fewer cavities.
Some foods have an acidic pH of 5.5 or lower which can result in demineralisation in the absence of bacteria. This is known as erosion, rather than caries, because the acid is not bacterial in origin. Attack by acid from systemic complications such as bulimia and stomach difficulties as well as vomiting can cause tooth erosion.
There are certain diseases and disorders affecting teeth that may leave an individual at a greater risk for cavities. Amelogenesis imperfecta, which occurs between 1 in 718 and 1 in 14,000 individuals, is a disease in which the enamel does not fully form or forms in insufficient amounts and can fall off a tooth. In both cases, teeth may be left more vulnerable to decay because the enamel is not able to protect the tooth.
In most people, disorders or diseases affecting teeth are not the primary cause of dental caries. Approximately 96% of tooth enamel is composed of minerals. These minerals, especially hydroxyapatite, will become soluble when exposed to acidic environments. Enamel begins to demineralize at a pH of 5.5. Dentin and cementum are more susceptible to caries than enamel because they have lower mineral content. Thus, when root surfaces of teeth are exposed from gingival recession or periodontal disease, caries can develop more readily. Even in a healthy oral environment, however, the tooth is susceptible to dental caries.
The evidence for linking malocclusion and/or crowding to the dental caries is weak; however, the anatomy of teeth may affect the likelihood of caries formation. Where the deep developmental grooves of teeth are more numerous and exaggerated, pit and fissure caries are more likely to develop (see next section). Also, caries are more likely to develop when food is trapped between teeth.
The mouth contains a wide variety of oral bacteria, but only a few specific species of bacteria are believed to cause dental caries: Streptococcus mutans and Lactobacilli among them. These organisms can produce high levels of lactic acid following fermentation of dietary sugars, and are resistant to the adverse effects of low pH, properties essential for cariogenic bacteria. As the cementum of root surfaces is more easily demineralized than enamel surfaces, a wider variety of bacteria can cause root caries including Lactobacillus acidophilus, Actinomyces spp., Nocardia spp., and Streptococcus mutans. Bacteria collect around the teeth and gums in a sticky, creamy-coloured mass called plaque, which serves as a biofilm. Some sites collect plaque more commonly than others, for example sites with a low rate of salivary flow (molar fissures). Grooves on the occlusal surfaces of molar and premolar teeth provide microscopic retention sites for plaque bacteria, as do the interproximal sites. Plaque may also collect above or below the gingiva where it is referred to as supra- or sub-gingival plaque, respectively.
Bacteria in a person's mouth convert glucose, fructose, and most commonly sucrose (table sugar) into acids such as lactic acid through a glycolytic process called fermentation. If left in contact with the tooth, these acids may cause demineralization, which is the dissolution of its mineral content. The process is dynamic, however, as remineralization can also occur if the acid is neutralized by saliva or mouthwash. Fluoride toothpaste or dental varnish may aid remineralization. If demineralization continues over time, enough mineral content may be lost so that the soft organic material left behind disintegrates, forming a cavity or hole. The impact such sugars have on the progress of dental caries is called cariogenicity. Sucrose, although a bound glucose and fructose unit, is in fact more cariogenic than a mixture of equal parts of glucose and fructose. This is due to the bacteria utilising the energy in the saccharide bond between the glucose and fructose subunits. S.mutans adheres to the biofilm on the tooth by converting sucrose into an extremely adhesive substance called dextran polysaccharide by the enzyme dextransucranase.
The frequency of which teeth are exposed to cariogenic (acidic) environments affects the likelihood of caries development. After meals or snacks, the bacteria in the mouth metabolize sugar, resulting in an acidic by-product that decreases pH. As time progresses, the pH returns to normal due to the buffering capacity of saliva and the dissolved mineral content of tooth surfaces. During every exposure to the acidic environment, portions of the inorganic mineral content at the surface of teeth dissolves and can remain dissolved for two hours. Since teeth are vulnerable during these acidic periods, the development of dental caries relies heavily on the frequency of acid exposure.
The carious process can begin within days of a tooth's erupting into the mouth if the diet is sufficiently rich in suitable carbohydrates. Evidence suggests that the introduction of fluoride treatments have slowed the process. Proximal caries take an average of four years to pass through enamel in permanent teeth. Because the cementum enveloping the root surface is not nearly as durable as the enamel encasing the crown, root caries tends to progress much more rapidly than decay on other surfaces. The progression and loss of mineralization on the root surface is 2.5 times faster than caries in enamel. In very severe cases where oral hygiene is very poor and where the diet is very rich in fermentable carbohydrates, caries may cause cavities within months of tooth eruption. This can occur, for example, when children continuously drink sugary drinks from baby bottles (see later discussion).
Other risk factors
Reduced salivary flow rate is associated with increased caries since the buffering capability of saliva is not present to counterbalance the acidic environment created by certain foods. As a result, medical conditions that reduce the amount of saliva produced by salivary glands, in particular the submandibular gland and parotid gland, are likely to dry mouth and thus to widespread tooth decay. Examples include Sjögren's syndrome, diabetes mellitus, diabetes insipidus, and sarcoidosis. Medications, such as antihistamines and antidepressants, can also impair salivary flow. Stimulants, most notoriously methylamphetamine ("meth mouth"), also occlude the flow of saliva to an extreme degree. Tetrahydrocannabinol, the active chemical substance in cannabis, also causes a nearly complete occlusion of salivation, known in colloquial terms as "cotton mouth". Moreover, 63% of the most commonly prescribed medications in the United States list dry mouth as a known side-effect. Radiation therapy of the head and neck may also damage the cells in salivary glands, somewhat increasing the likelihood of caries formation.
The use of tobacco may also increase the risk for caries formation. Some brands of smokeless tobacco contain high sugar content, increasing susceptibility to caries. Tobacco use is a significant risk factor for periodontal disease, which can cause the gingiva to recede. As the gingiva loses attachment to the teeth due to gingival recession, the root surface becomes more visible in the mouth. If this occurs, root caries is a concern since the cementum covering the roots of teeth is more easily demineralized by acids than enamel. Currently, there is not enough evidence to support a causal relationship between smoking and coronal caries, but evidence does suggest a relationship between smoking and root-surface caries.
Intrauterine and neonatal lead exposure promote tooth decay. Besides lead, all atoms with electrical charge and ionic radius similar to bivalent calcium, such as cadmium, mimic the calcium ion and therefore exposure may promote tooth decay.
Forms are available for risk assessment for caries when treating dental cases; this system using the evidence-based Caries Management by Risk Assessment (CAMBRA). It is still unknown if the identification of high-risk individuals can lead to more effective long-term patient management that prevents caries initiation and arrests or reverses the progression of lesions.
Enamel is a highly mineralized acellular tissue, and caries act upon it through a chemical process brought on by the acidic environment produced by bacteria. As the bacteria consume the sugar and use it for their own energy, they produce lactic acid. The effects of this process include the demineralization of crystals in the enamel, caused by acids, over time until the bacteria physically penetrate the dentin. Enamel rods, which are the basic unit of the enamel structure, run perpendicularly from the surface of the tooth to the dentin. Since demineralization of enamel by caries, in general, follows the direction of the enamel rods, the different triangular patterns between pit and fissure and smooth-surface caries develop in the enamel because the orientation of enamel rods are different in the two areas of the tooth.
As the enamel loses minerals, and dental caries progresses, the enamel develop several distinct zones, visible under a light microscope. From the deepest layer of the enamel to the enamel surface, the identified areas are the: translucent zone, dark zones, body of the lesion, and surface zone. The translucent zone is the first visible sign of caries and coincides with a one to two percent loss of minerals. A slight remineralization of enamel occurs in the dark zone, which serves as an example of how the development of dental caries is an active process with alternating changes. The area of greatest demineralization and destruction is in the body of the lesion itself. The surface zone remains relatively mineralized and is present until the loss of tooth structure results in a cavitation.
Unlike enamel, the dentin reacts to the progression of dental caries. After tooth formation, the ameloblasts, which produce enamel, are destroyed once enamel formation is complete and thus cannot later regenerate enamel after its destruction. On the other hand, dentin is produced continuously throughout life by odontoblasts, which reside at the border between the pulp and dentin. Since odontoblasts are present, a stimulus, such as caries, can trigger a biologic response. These defense mechanisms include the formation of sclerotic and tertiary dentin.
In dentin from the deepest layer to the enamel, the distinct areas affected by caries are the advancing front, the zone of bacterial penetration, and the zone of destruction. The advancing front represents a zone of demineralised dentine due to acid and has no bacteria present. The zones of bacterial penetration and destruction are the locations of invading bacteria and ultimately the decomposition of dentin. The zone of destruction has a more mixed bacterial population where proteolytic enzymes have destroyed the organic matrix. The innermost dentine caries has been reversibly attacked because the collage matrix is not severely damaged, giving it potential for repair. The outer more superficial zone is highly infected with proteolytic degradation of the collagen matrix and as a result the dentine is irreversibly demineralised.
The structure of dentin is an arrangement of microscopic channels, called dentinal tubules, which radiate outward from the pulp chamber to the exterior cementum or enamel border. The diameter of the dentinal tubules is largest near the pulp (about 2.5 μm) and smallest (about 900 nm) at the junction of dentin and enamel. The carious process continues through the dentinal tubules, which are responsible for the triangular patterns resulting from the progression of caries deep into the tooth. The tubules also allow caries to progress faster.
In response, the fluid inside the tubules bring immunoglobulins from the immune system to fight the bacterial infection. At the same time, there is an increase of mineralization of the surrounding tubules. This results in a constriction of the tubules, which is an attempt to slow the bacterial progression. In addition, as the acid from the bacteria demineralizes the hydroxyapatite crystals, calcium and phosphorus are released, allowing for the precipitation of more crystals which fall deeper into the dentinal tubule. These crystals form a barrier and slow the advancement of caries. After these protective responses, the dentin is considered sclerotic.
Fluids within dentinal tubules are believed to be the mechanism by which pain receptors are triggered within the pulp of the tooth. Since sclerotic dentin prevents the passage of such fluids, pain that would otherwise serve as a warning of the invading bacteria may not develop at first. Consequently, dental caries may progress for a long period of time without any sensitivity of the tooth, allowing for greater loss of tooth structure.
In response to dental caries, there may be production of more dentin toward the direction of the pulp. This new dentin is referred to as tertiary dentin. Tertiary dentin is produced to protect the pulp for as long as possible from the advancing bacteria. As more tertiary dentin is produced, the size of the pulp decreases. This type of dentin has been subdivided according to the presence or absence of the original odontoblasts. If the odontoblasts survive long enough to react to the dental caries, then the dentin produced is called "reactionary" dentin. If the odontoblasts are killed, the dentin produced is called "reparative" dentin.
In the case of reparative dentin, other cells are needed to assume the role of the destroyed odontoblasts. Growth factors, especially TGF-β, are thought to initiate the production of reparative dentin by fibroblasts and mesenchymal cells of the pulp. Reparative dentin is produced at an average of 1.5 μm/day, but can be increased to 3.5 μm/day. The resulting dentin contains irregularly shaped dentinal tubules that may not line up with existing dentinal tubules. This diminishes the ability for dental caries to progress within the dentinal tubules.
The incidence of cemental caries increases in older adults as gingival recession occurs from either trauma or periodontal disease. It is a chronic condition that forms a large, shallow lesion and slowly invades first the root’s cementum and then dentin to cause a chronic infection of the pulp (see further discussion under classification by affected hard tissue). Because dental pain is a late finding, many lesions are not detected early, resulting in restorative challenges and increased tooth loss.
The presentation of caries is highly variable. However, the risk factors and stages of development are similar. Initially it may appear as a small chalky area (smooth surface caries), which may eventually develop into a large cavitation. Sometimes caries may be directly visible. However other methods of detection such as X-rays are used for less visible areas of teeth and to judge the extent of destruction. Lasers for detecting caries allow detection without ionizing radiation and are now used for detection of interproximal decay (between the teeth). Disclosing solutions are also used during tooth restoration to minimize the chance of recurrence.
Primary diagnosis involves inspection of all visible tooth surfaces using a good light source, dental mirror and explorer. Dental radiographs (X-rays) may show dental caries before it is otherwise visible, in particular caries between the teeth. Large dental caries are often apparent to the naked eye, but smaller lesions can be difficult to identify. Visual and tactile inspection along with radiographs are employed frequently among dentists, in particular to diagnose pit and fissure caries. Early, uncavitated caries is often diagnosed by blowing air across the suspect surface, which removes moisture and changes the optical properties of the unmineralized enamel.
Some dental researchers have cautioned against the use of dental explorers to find caries, in particular sharp ended explorers. In cases where a small area of tooth has begun demineralizing but has not yet cavitated, the pressure from the dental explorer could cause a cavity. Since the carious process is reversible before a cavity is present, it may be possible to arrest the caries with fluoride and remineralize the tooth surface. When a cavity is present, a restoration will be needed to replace the lost tooth structure.
At times, pit and fissure caries may be difficult to detect. Bacteria can penetrate the enamel to reach dentin, but then the outer surface may remineralize, especially if fluoride is present. These caries, sometimes referred to as "hidden caries", will still be visible on x-ray radiographs, but visual examination of the tooth would show the enamel intact or minimally perforated.
Caries can be classified by location, etiology, rate of progression, and affected hard tissues. These forms of classification can be used to characterize a particular case of tooth decay in order to more accurately represent the condition to others and also indicate the severity of tooth destruction. In some instances, caries are described in other ways that might indicate the cause.
Early childhood caries
Early childhood caries (ECC) or "Baby bottle caries," "baby bottle tooth decay," or "Bottle Rot" is a pattern of decay found in young children with their deciduous (baby) teeth. The teeth most likely affected are the maxillary anterior teeth, but all teeth can be affected. The name for this type of caries comes from the fact that the decay usually is a result of allowing children to fall asleep with sweetened liquids in their bottles or feeding children sweetened liquids multiple times during the day.
Another pattern of decay is "rampant caries", which signifies advanced or severe decay on multiple surfaces of many teeth. Rampant caries may be seen in individuals with xerostomia, poor oral hygiene, stimulant use (due to drug-induced dry mouth), and/or large sugar intake. If rampant caries is a result of previous radiation to the head and neck, it may be described as radiation-induced caries. Problems can also be caused by the self-destruction of roots and whole tooth resorption when new teeth erupt or later from unknown causes.
Rate of progression
Temporal descriptions can be applied to caries to indicate the progression rate and previous history. "Acute" signifies a quickly developing condition, whereas "chronic" describes a condition that has taken an extended time to develop, in which thousands of meals and snacks, many causing some acid demineralization that is not remineralized, eventually results in cavities.
Recurrent caries, also described as secondary, are caries that appears at a location with a previous history of caries. This is frequently found on the margins of fillings and other dental restorations. On the other hand, incipient caries describes decay at a location that has not experienced previous decay. Arrested caries describes a lesion on a tooth that was previously demineralized but was remineralized before causing a cavitation. Fluoride treatment can help recalcification of tooth enamel as well as use of Amorphous calcium phosphate.
Affected hard tissue
Depending on which hard tissues are affected, it is possible to describe caries as involving enamel, dentin, or cementum. Early in its development, caries may affect only enamel. Once the extent of decay reaches the deeper layer of dentin, "dentinal caries" is used. Since cementum is the hard tissue that covers the roots of teeth, it is not often affected by decay unless the roots of teeth are exposed to the mouth. Although the term "cementum caries" may be used to describe the decay on roots of teeth, very rarely does caries affect the cementum alone. Roots have a very thin layer of cementum over a large layer of dentin, and thus most caries affecting cementum also affects dentin.
Personal hygiene care consists of proper brushing and flossing daily. The purpose of oral hygiene is to minimize any etiologic agents of disease in the mouth. The primary focus of brushing and flossing is to remove and prevent the formation of plaque or dental biofilm. Plaque consists mostly of bacteria. As the amount of bacterial plaque increases, the tooth is more vulnerable to dental caries when carbohydrates in the food are left on teeth after every meal or snack. A toothbrush can be used to remove plaque on accessible surfaces, but not between teeth or inside pits and fissures on chewing surfaces. When used correctly, dental floss removes plaque from areas that could otherwise develop proximal caries but only if the depth of sulcus has not been compromised. Other adjunct oral hygiene aids include interdental brushes, water picks, and mouthwashes.
However oral hygiene is probably more effective at preventing gum disease (periodontal disease) than tooth decay. Food is forced inside pits and fissures under chewing pressure, leading to carbohydrate-fueled acid demineralisation where the brush, fluoride toothpaste, and saliva have no access to remove trapped food, neutralise acid, or remineralise demineralised tooth like on other more accessible tooth surfaces food to be trapped. (Occlusal caries accounts for between 80 and 90% of caries in children (Weintraub, 2001).) Chewing fibre like celery after eating forces saliva inside trapped food to dilute any carbohydrate like sugar, neutralise acid and remineralise demineralised tooth. The teeth at highest risk for carious lesions are the permanent first and second molars due to length of time in oral cavity and presence of complex surface anatomy.
Professional hygiene care consists of regular dental examinations and professional prophylaxis (cleaning). Sometimes, complete plaque removal is difficult, and a dentist or dental hygienist may be needed. Along with oral hygiene, radiographs may be taken at dental visits to detect possible dental caries development in high risk areas of the mouth, along with compliance to strict radiographic guidelines established by dental associations such as the American Dental Association and American Dental Hygienists' Association.
For dental health, frequency of sugar intake is more important than the amount of sugar consumed. In the presence of sugar and other carbohydrates, bacteria in the mouth produce acids that can demineralize enamel, dentin, and cementum. The more frequently teeth are exposed to this environment the more likely dental caries are to occur. Therefore, minimizing snacking is recommended, since snacking creates a continuous supply of nutrition for acid-creating bacteria in the mouth. Also, chewy and sticky foods (such as dried fruit or candy) tend to adhere to teeth longer, and, as a consequence, are best eaten as part of a meal. Brushing the teeth after meals is recommended. For children, the American Dental Association and the European Academy of Paediatric Dentistry recommend limiting the frequency of consumption of drinks with sugar, and not giving baby bottles to infants during sleep (see earlier discussion). Mothers are also recommended to avoid sharing utensils and cups with their infants to prevent transferring bacteria from the mother's mouth.
It has been found that milk and certain kinds of cheese like cheddar cheese can help counter tooth decay if eaten soon after the consumption of foods potentially harmful to teeth. Also, chewing gum containing xylitol (a sugar alcohol) is widely used to protect teeth in many countries now. Xylitol's effect on reducing dental biofilm is, it is presumed, due to bacteria's inability to utilize it like other sugars. Chewing and stimulation of flavor receptors on the tongue are also known to increase the production and release of saliva, which contains natural buffers to prevent the lowering of pH in the mouth to the point where enamel may become demineralized.
The use of dental sealants is a means of prevention. A sealant is a thin plastic-like coating applied to the chewing surfaces of the molars to prevent food from being trapped inside pits and fissures. This deprives resident plaque bacteria carbohydrate preventing the formation of pit and fissure caries. Sealants are usually applied on the teeth of children, as soon as the tooth erupt but adults are receiving them if not previously performed. Sealants can wear out and fail to prevent access of food and plaque bacteria inside pits and fissures and need to be replaced so they must be checked regularly by dental professionals.
Calcium, as found in food such as milk and green vegetables, is often recommended to protect against dental caries. Fluoride helps prevent decay of a tooth by binding to the hydroxyapatite crystals in enamel. The incorporated calcium makes enamel more resistant to demineralization and, thus, resistant to decay. Topical fluoride is now more highly recommended than systemic intake such as by tablets or drops to protect the surface of the teeth. This may include a fluoride toothpaste or mouthwash or varnish. Many dental professionals include application of topical fluoride solutions as part of routine visits and recommend the use of xylitol and Amorphous calcium phosphate products.
|No carious lesion||No treatment|
|Carious lesion||Inactive lesion||No treatment|
|Active lesion||Non-cavitated lesion||Non-operative treatment|
|Cavitated lesion||Operative treatment|
|Existing filling||No defect||No replacement|
|Defective filling||Ditching, overhang||No replacement|
|Fracture or food impaction||Repair or replacement of filling|
|Inactive lesion||No treatment|
|Active lesion||Non-cavitated lesion||Non-operative treatment|
|Cavitated lesion||Repair or replacement of filling|
Most importantly, whether the carious lesion is cavitated or noncavitated dictates the management. Clinical assessment of whether the lesion is active or arrested is also important. Noncavitated lesions can be arrested and remineralization can occur under the right conditions. However, this may require extensive changes to the diet (reduction in frequency of refined sugars), improved oral hygiene (toothbrushing twice per day with fluoride toothpaste and flossing), and regular application of topical fluoride. Such management of a carious lesion is termed "non-operative" since no drilling is carried out on the tooth. Non-operative treatment requires excellent understanding and motivation from the individual, otherwise the decay will continue.
Once a lesion has cavitated, especially if dentin is involved, remineralization is much more difficult and a dental restoration is usually indicated ("operative treatment"). Before a restoration can be placed, all of the decay must be removed otherwise it will continue to progress underneath the filling. Sometimes a small amount of decay can be left if it is entombed and the there is a seal which isolates the bacteria from their substrate. This can be likened to placing a glass container over a candle, which burns itself out once the oxygen is used up. Techniques such as stepwise caries removal are designed to avoid exposure of the dental pulp and overall reduction of the amount of tooth substance which requires removal before the final filling is placed. Often enamel which overlies decayed dentin must also be removed as it is unsupported and susceptible to fracture. The modern decision-making process with regards the activity of the lesion, and whether it is cavitated, is summarized in the table.
Destroyed tooth structure does not fully regenerate, although remineralization of very small carious lesions may occur if dental hygiene is kept at optimal level. For the small lesions, topical fluoride is sometimes used to encourage remineralization. For larger lesions, the progression of dental caries can be stopped by treatment. The goal of treatment is to preserve tooth structures and prevent further destruction of the tooth. Aggressive treatment, by filling, of incipient carious lesions, places where there is superficial damage to the enamel, is controversial as they may heal themselves, while once a filling is performed it will eventually have to be redone and the site serves as a vulnerable site for further decay.
In general, early treatment is quicker and less expensive than treatment of extensive decay. Local anesthetics, nitrous oxide ("laughing gas"), or other prescription medications may be required in some cases to relieve pain during or following treatment or to relieve anxiety during treatment. A dental handpiece ("drill") is used to remove large portions of decayed material from a tooth. A spoon, a dental instrument used to carefully remove decay, is sometimes employed when the decay in dentin reaches near the pulp. Once the decay is removed, the missing tooth structure requires a dental restoration of some sort to return the tooth to function and aesthetic condition.
Restorative materials include dental amalgam, composite resin, porcelain, and gold. Composite resin and porcelain can be made to match the color of a patient's natural teeth and are thus used more frequently when aesthetics are a concern. Composite restorations are not as strong as dental amalgam and gold; some dentists consider the latter as the only advisable restoration for posterior areas where chewing forces are great. When the decay is too extensive, there may not be enough tooth structure remaining to allow a restorative material to be placed within the tooth. Thus, a crown may be needed. This restoration appears similar to a cap and is fitted over the remainder of the natural crown of the tooth. Crowns are often made of gold, porcelain, or porcelain fused to metal.
In certain cases, endodontic therapy may be necessary for the restoration of a tooth. Endodontic therapy, also known as a "root canal", is recommended if the pulp in a tooth dies from infection by decay-causing bacteria or from trauma. During a root canal, the pulp of the tooth, including the nerve and vascular tissues, is removed along with decayed portions of the tooth. The canals are instrumented with endodontic files to clean and shape them, and they are then usually filled with a rubber-like material called gutta percha. The tooth is filled and a crown can be placed. Upon completion of a root canal, the tooth is now non-vital, as it is devoid of any living tissue.
An extraction can also serve as treatment for dental caries. The removal of the decayed tooth is performed if the tooth is too far destroyed from the decay process to effectively restore the tooth. Extractions are sometimes considered if the tooth lacks an opposing tooth or will probably cause further problems in the future, as may be the case for wisdom teeth. Extractions may also be preferred by patients unable or unwilling to undergo the expense or difficulties in restoring the tooth.
Worldwide, approximately 2.43 billion people (36% of the population) have dental caries in their permanent teeth. In baby teeth it affects about 620 million people or 9% of the population. The disease is most prevalent in Latin American countries, countries in the Middle East, and South Asia, and least prevalent in China. In the United States, dental caries is the most common chronic childhood disease, being at least five times more common than asthma. It is the primary pathological cause of tooth loss in children. Between 29% and 59% of adults over the age of fifty experience caries.
The number of cases has decreased in some developed countries, and this decline is usually attributed to increasingly better oral hygiene practices and preventive measures such as fluoride treatment. Nonetheless, countries that have experienced an overall decrease in cases of tooth decay continue to have a disparity in the distribution of the disease. Among children in the United States and Europe, twenty percent of the population endures sixty to eighty percent of cases of dental caries. A similarly skewed distribution of the disease is found throughout the world with some children having none or very few caries and others having a high number. Australia, Nepal, and Sweden have a low incidence of cases of dental caries among children, whereas cases are more numerous in Costa Rica and Slovakia.
The classic "DMF" (decay/missing/filled) index is one of the most common methods for assessing caries prevalence as well as dental treatment needs among populations. This index is based on in-field clinical examination of individuals by using a probe, mirror and cotton rolls. Because the DMF index is done without X-ray imaging, it underestimates real caries prevalence and treatment needs.
There is a long history of dental caries. Over a million years ago, hominids such as Australopithecus suffered from cavities. The largest increases in the prevalence of caries have been associated with dietary changes. Archaeological evidence shows that tooth decay is an ancient disease dating far into prehistory. Skulls dating from a million years ago through the neolithic period show signs of caries, excepting those from the Paleolithic and Mesolithic ages. The increase of caries during the neolithic period may be attributed to the increased consumption of plant foods containing carbohydrates. The beginning of rice cultivation in South Asia is also believed to have caused an increase in caries.
A Sumerian text from 5000 BC describes a "tooth worm" as the cause of caries. Evidence of this belief has also been found in India, Egypt, Japan, and China. Unearthed ancient skulls show evidence of primitive dental work. In Pakistan, teeth dating from around 5500 BC to 7000 BC show nearly perfect holes from primitive dental drills. The Ebers Papyrus, an Egyptian text from 1550 BC, mentions diseases of teeth. During the Sargonid dynasty of Assyria during 668 to 626 BC, writings from the king's physician specify the need to extract a tooth due to spreading inflammation. In the Roman Empire, wider consumption of cooked foods led to a small increase in caries prevalence. The Greco-Roman civilization, in addition to the Egyptian, had treatments for pain resulting from caries.
The rate of caries remained low through the Bronze Age and Iron Age, but sharply increased during the Middle Ages. Periodic increases in caries prevalence had been small in comparison to the 1000 AD increase, when sugar cane became more accessible to the Western world. Treatment consisted mainly of herbal remedies and charms, but sometimes also included bloodletting. The barber surgeons of the time provided services that included tooth extractions. Learning their training from apprenticeships, these health providers were quite successful in ending tooth pain and likely prevented systemic spread of infections in many cases. Among Roman Catholics, prayers to Saint Apollonia, the patroness of dentistry, were meant to heal pain derived from tooth infection.
There is also evidence of caries increase in North American Indians after contact with colonizing Europeans. Before colonization, North American Indians subsisted on hunter-gatherer diets, but afterwards there was a greater reliance on maize agriculture, which made these groups more susceptible to caries.
During the European Age of Enlightenment, the belief that a "tooth worm" caused caries was also no longer accepted in the European medical community. Pierre Fauchard, known as the father of modern dentistry, was one of the first to reject the idea that worms caused tooth decay and noted that sugar was detrimental to the teeth and gingiva. In 1850, another sharp increase in the prevalence of caries occurred and is believed to be a result of widespread diet changes. Prior to this time, cervical caries was the most frequent type of caries, but increased availability of sugar cane, refined flour, bread, and sweetened tea corresponded with a greater number of pit and fissure caries.
In the 1890s, W.D. Miller conducted a series of studies that led him to propose an explanation for dental caries that was influential for current theories. He found that bacteria inhabited the mouth and that they produced acids that dissolved tooth structures when in the presence of fermentable carbohydrates. This explanation is known as the chemoparasitic caries theory. Miller's contribution, along with the research on plaque by G.V. Black and J.L. Williams, served as the foundation for the current explanation of the etiology of caries. Several of the specific strains of lactobacilli were identified in 1921 by Fernando E. Rodriguez Vargas.
In 1924 in London, Killian Clarke described a spherical bacterium in chains isolated from carious lesions which he called Streptococcus mutans. Although Clarke proposed this organism was the cause of caries the discovery was not followed up. Later, in the 1950s in the USA, Keyes and Fitzgerald working with hamsters showed that caries was transmissible and caused by an acid-producing Streptococcus. It was not until the late 1960s that it became generally accepted that the Streptococcus isolated from hamster caries was the same as S. mutans described by Clarke.
Tooth decay has been present throughout human history, from early hominids millions of years ago, to modern humans. The prevalence of caries increased dramatically in the 19th century, as the Industrial Revolution made certain items, such as cane sugar and refined flour, readily available. The diet of the “newly industrialized English working class”  then became centered on bread, jam, and sweetened tea, greatly increasing both sugar consumption and caries.
- MedlinePlus Encyclopedia Dental Cavities
- Oral Health Topics: Cleaning your teeth and gums. Hosted on the American Dental Association website. Page accessed August 15, 2006.
- Health Promotion Board: Dental Caries, affiliated with the Singapore government. Page accessed August 14, 2006.
- Richie S. King (November 28, 2011). "A Closer Look at Teeth May Mean More Fillings". The New York Times. Retrieved November 30, 2011. "An incipient carious lesion is the initial stage of structural damage to the enamel, usually caused by a bacterial infection that produces tooth-dissolving acid."
- Johnson, Clarke. "Biology of the Human Dentition." Page accessed July 18, 2007.
- Tooth Decay, hosted on the New York University Medical Center website. Page accessed August 14, 2006.
- Cavernous Sinus Thrombosis, hosted on WebMD. Page accessed May 25, 2008.
- MedlinePlus Encyclopedia Ludwig's Anigna
- Hartmann, Richard W. Ludwig's Angina in Children, hosted on the American Academy of Family Physicians website. Page accessed May 25, 2008.
- Southam JC, Soames JV (1993). "2. Dental Caries". Oral pathology (2nd ed.). Oxford: Oxford Univ. Press. ISBN 0-19-262214-5.
- Smith B, Pickard HM, Kidd EAM (1990). "1. Why restore teeth?". Pickard's manual of operative dentistry (6th ed.). Oxford [Oxfordshire]: Oxford University Press. ISBN 0-19-261808-3.
- Cavities/tooth decay, hosted on the Mayo Clinic website. Page accessed May 25, 2008.
- Hardie JM (May 1982). "The microbiology of dental caries". Dent Update 9 (4): 199–200, 202–4, 206–8. PMID 6959931.
- Holloway PJ; Moore, W.J. (September 1983). "The role of sugar in the etiology of dental caries". J Dent 11 (3): 189–213. doi:10.1016/0300-5712(83)90182-3. PMID 6358295.
Moore WJ; Moore, W.J. (September 1983). "1. Sugar and the antiquity of dental caries". J Dent 11 (3): 189–90. doi:10.1016/0300-5712(83)90182-3. PMID 6358295.
Rugg-Gunn AJ, Murray JJ (September 1983). "2. The epidemiological evidence". J Dent 11 (3): 190–9. doi:10.1016/0300-5712(83)90183-5. PMID 6358296.
Edgar WM (September 1983). "3. The physiochemical evidence". J Dent 11 (3): 199–205. doi:10.1016/0300-5712(83)90184-7. PMID 6358297.
Drucker DB (September 1983). "4. The microbiological evidence". J Dent 11 (3): 205–7. doi:10.1016/0300-5712(83)90185-9. PMID 6358298.
Ryan LA (September 1983). "5. Confectionery and dental caries". J Dent 11 (3): 207–9. doi:10.1016/0300-5712(83)90186-0. PMID 6358299.
Shaw JH (September 1983). "6. Evidence from experimental animal research". J Dent 11 (3): 209–13. doi:10.1016/0300-5712(83)90187-2. PMID 6417207.
- Rogers AH (editor). (2008). Molecular Oral Microbiology. Caister Academic Press. ISBN 978-1-904455-24-0.
- Neville, B.W., Douglas Damm, Carl Allen, Jerry Bouquot. "Oral & Maxillofacial Pathology." 2nd edition, 2002, p. 89. ISBN 0-7216-9003-3.
- Neville, B.W., Douglas Damm, Carl Allen, Jerry Bouquot. "Oral & Maxillofacial Pathology." 2nd edition, 2002, p. 94. ISBN 0-7216-9003-3.
- Ten Cate's Oral Histology, Nanci, Elsevier, 2013, page 122
- Dawes C (December 2003). "What is the critical pH and why does a tooth dissolve in acid?". J Can Dent Assoc 69 (11): 722–4. PMID 14653937.
- Mellberg JR (1986). "Demineralization and remineralization of root surface caries". Gerodontology 5 (1): 25–31. doi:10.1111/j.1741-2358.1986.tb00380.x. PMID 3549537.
- Borzabadi-Farahani, A; Eslamipour, F; Asgari, I (2011). "Association between orthodontic treatment need and caries experience". Acta Odontol Scand 69 (1): 2–11. doi:10.3109/00016357.2010.516732. PMID 20923258.
- Sherif Mohamed, Al-Sakiti, Ahmed Awadh, Mostafa, Yehya Ahmed. Dental crowding as a caries risk factor: A systematic reviewHafez, Hend Salah, Shaarawy, American Journal of Orthodontics & Dentofacial Orthopedics. 2012;142(4):443-50
- Douglass, JM; Li, Y; Tinanoff, N. (Sep–Oct 2008), "Association of mutans streptococci between caregivers and their children.", Pediatric Dentistry 30 (5): 375–87
- Silverstone LM (May 1983). "Remineralization and enamel caries: new concepts". Dent Update 10 (4): 261–73. PMID 6578983.
- Madigan M.T. & Martinko J.M. Brock - Biology of Microorganisms. 11th Ed. Pearson, USA. pp. 705
- "Dental Health", hosted on the British Nutrition Foundation website, 2004. Page accessed August 13, 2006.
- Dental Caries, hosted on the University of California Los Angeles School of Dentistry website. Page accessed August 14, 2006.
- Summit, James B., J. William Robbins, and Richard S. Schwartz. "Fundamentals of Operative Dentistry: A Contemporary Approach." 2nd edition. Carol Stream, Illinois, Quintessence Publishing Co, Inc, 2001, p. 75. ISBN 0-86715-382-2.
- Neville, B.W., Douglas Damm, Carl Allen, Jerry Bouquot. "Oral & Maxillofacial Pathology." 2nd edition, 2002, p. 398. ISBN 0-7216-9003-3.
- Oral Complications of Chemotherapy and Head/Neck Radiation, hosted on the National Cancer Institute website. Page accessed January 8, 2007.
- See Common effects of cancer therapies on salivary glands at http://ebd.ada.org/SystematicReviewSummaryPage.aspx?srId=66bffb53-0043-4892-a8ab-f0cfe2231928
- Neville, B.W., Douglas Damm, Carl Allen, Jerry Bouquot. "Oral & Maxillofacial Pathology." 2nd edition, 2002, p. 347. ISBN 0-7216-9003-3.
- Tobacco Use Increases the Risk of Gum Disease, hosted on the American Academy of Periodontology. Page accessed January 9, 2007.
- Banting, D.W. "The Diagnosis of Root Caries." Presentation to the National Institute of Health Consensus Development Conference on Diagnosis and Management of Dental Caries Throughout Life, in pdf format, hosted on the National Institute of Dental and Craniofacial Research, p. 19. Page accessed August 15, 2006.
- Executive Summary of U.S. Surgeon General's report titled, "The Health Consequences of Smoking: A Report of the Surgeon General," hosted on the CDC website, p. 12. Page accessed January 9, 2007.
- Brudevold F, Steadman LT (1956). "The distribution of lead in human enamel". J Dent Res 35 (3): 430–437. doi:10.1177/00220345560350031401. PMID 13332147.
- Brudevold F, Aasenden R, Srinivasian BN, Bakhos Y (1977). "Lead in enamel and saliva, dental caries and the use of enamel biopsies for measuring past exposure to lead.". J Dent Res 56 (10): 1165–1171. doi:10.1177/00220345770560100701. PMID 272374.
- Goyer RA (1990). "Transplacental transport of lead". Environ Health Perspect (Brogan &) 89: 101–105. doi:10.2307/3430905. JSTOR 3430905. PMC 1567784. PMID 2088735.
- Moss ME, Lamphear BP, Auinger P (1999). "Association of dental caries and blood lead levels". JAMA 281 (24): 2294–2298. doi:10.1001/jama.281.24.2294. PMID 10386553.
- Campbell JR, Moss ME, Raubertas RF (2000). "The association between caries and childhood lead exposure". Environ Health Perspect (Brogan &) 108 (11): 1099–1102. doi:10.2307/3434965. JSTOR 3434965. PMC 1240169. PMID 11102303.
- Gemmel A, Tavares M, Alperin S, Soncini J, Daniel D, Dunn J,Crawford S, Braveman N, Clarkson TW, McKinlay S, Bellinger DC (2002). "Blood Lead Level and Dental Caries in School-Age Children". Environ Health Perspect 110 (10): A625–A630. doi:10.1289/ehp.021100625. PMC 1241049. PMID 12361944.
- Billings RJ, Berkowitz RJ, Watson G (2004). "Teeth". Pediatrics 113 (4): 1120–1127. PMID 15060208.
- Leroy N, Bres E. (2001). "Structure and substitutions in fluorapatite.". Eur Cell Mater. 2: 36–48. PMID 14562256.
- Arora M, Weuve J, Schwartz J, Wright RO (2008). "Association of environmental cadmium exposure with pediatric dental caries". Environ Health Perspect. 116 (6): 821–825. doi:10.1289/ehp.10947. PMC 2430240. PMID 18560540.
- DYE, B. (2010). Trends in Oral Health by Poverty Status as Measured by Healthy People 2010 Objectives. Public Health Reports, 125(6), 817.
- Selwitz, R. H., Ismail, A. I., & Pitts, N. B. (2007). Dental caries" Lancet 369(9555), 51-59
- Caries Risk Assessment Form Completion Instructions, American Dental Association at http://public.health.oregon.gov/PreventionWellness/oralhealth/FirstTooth/Documents/ADA-CAMBRA.pdf
- Tellez, M., Gomez, J., Pretty, I., Ellwood, R., Ismail, A.Evidence on existing caries risk assessment systems: are they predictive of future caries? Community Dent Oral Epidemiol. 2012
- Kidd EA, Fejerskov O (1 July 2004). "What constitutes dental caries? Histopathology of carious enamel and dentin related to the action of cariogenic biofilms". J Dent Res. 83 (Spec No C): C35–8. doi:10.1177/154405910408301S07. PMID 15286119.
- Darling AI (1963). "Resistance of the Enamel to Dental Caries". J Dent Res. 42 (1): 488–96. doi:10.1177/00220345630420015601. PMID 14041429.
- Robinson C, Shore RC, Brookes SJ, Strafford S, Wood SR, Kirkham J (2000). "The chemistry of enamel caries". Crit Rev Oral Biol Med. 11 (4): 481–95. doi:10.1177/10454411000110040601. PMID 11132767.
- Ten Cate's Oral Histology, Nanci, Elsevier, 2013, page 121
- "Teeth & Jaws: Caries, Pulp, & Periapical Conditions," hosted on the University of Southern California School of Dentistry website. Page accessed June 22, 2007.
- Ross, Michael H., Gordon I. Kaye, and Wojciech Pawlina, 2003. Histology: a text and atlas. 4th edition, p. 450. ISBN 0-683-30242-6.
- Ten Cate's Oral Histology, Nanci, Elsevier, 2013, page 166
- Summit, James B., J. William Robbins, and Richard S. Schwartz. "Fundamentals of Operative Dentistry: A Contemporary Approach." 2nd edition. Carol Stream, Illinois, Quintessence Publishing Co, Inc, 2001, p. 13. ISBN 0-86715-382-2.
- Dababneh RH, Khouri AT, Addy M (December 1999). "Dentine hypersensitivity - an enigma? A review of terminology, mechanisms, aetiology and management". Br Dent J 187 (11): 606–11; discussion 603. doi:10.1038/sj.bdj.4800345a. PMID 16163281.
The referred to theory is the widely accepted hydrodynamic theory of sensitivity.
- Smith AJ, Murray PE, Sloan AJ, et al. (August 2001). "Trans-dentinal Stimulation of Tertiary Dentinogenesis". Advances in Dental Research 15 (1): 51–4. doi:10.1177/08959374010150011301. PMID 12640740.
- Summit, James B., J. William Robbins, and Richard S. Schwartz. "Fundamentals of Operative Dentistry: A Contemporary Approach." 2nd edition. Carol Stream, Illinois, Quintessence Publishing Co, Inc, 2001, p. 14. ISBN 0-86715-382-2.
- Illustrated Embryology, Histology, and Anatomy, Bath-Balogh and Fehrenbach, Elsevier, 2011
- Rosenstiel, Stephen F. Clinical Diagnosis of Dental Caries: A North American Perspective. Maintained by the University of Michigan Dentistry Library, along with the National Institutes of Health, National Institute of Dental and Craniofacial Research. 2000. Page accessed August 13, 2006.
- Summit, James B., J. William Robbins, and Richard S. Schwartz. "Fundamentals of Operative Dentistry: A Contemporary Approach." 2nd edition. Carol Stream, Illinois, Quintessence Publishing Co, Inc, 2001, p. 31. ISBN 0-86715-382-2.
- Zadik Yehuda, Bechor Ron (June–July 2008). "Hidden Occlusal Caries - Challenge for the Dentist" (PDF). New York State Dental Journal 74 (4): 46–50. PMID 18788181. Retrieved 2008-08-08.
- Baelum, edited by Ole Fejerskov and Edwina Kidd ; with Bente Nyvad and Vibeke (2008). Dental caries : the disease and its clinical management (2nd ed. ed.). Oxford: Blackwell Munksgaard. p. 67. ISBN 978-1-4051-3889-5.
- Sonis, Stephen T. (2003). Dental Secrets (3rd ed.). Philadelphia: Hanley & Belfus. p. 130. ISBN 1-56053-573-3.
- ADA Early Childhood Tooth Decay (Baby Bottle Tooth Decay). Hosted on the American Dental Association website. Page accessed August 14, 2006.
- Statement on Early Childhood Caries, American Dental Association at http://www.ada.org/2057.aspx
- Radiographic Classification of Caries. Hosted on the Ohio State University website. Page accessed August 14, 2006.
- ADA Methamphetamine Use (METH MOUTH). Hosted on the American Dental Association website. Page accessed February 14, 2007.
- Introduction to Dental Plaque. Hosted on the Leeds Dental Institute Website. Page accessed August 14, 2006.
- A Guide to Oral Health to Prospective Mothers and their Infants, hosted on the European Academy of Paediatric Dentistry website. Page accessed August 14, 2006.
- Oral Health Topics: Baby Bottle Tooth Decay, hosted on the American Dental Association website. Page accessed August 14, 2006.
- Guideline on Infant Oral Health Care, hosted on the American Academy of Pediatric Dentistry website. Page accessed January 13, 2007.
- Ly KA, Milgrom P, Roberts MC, Yamaguchi DK, Rothen M, Mueller G (2006). "Linear response of mutans streptococci to increasing frequency of xylitol chewing gum use: a randomized controlled trial [ISRCTN43479664]". BMC Oral Health 6: 6. doi:10.1186/1472-6831-6-6. PMC 1482697. PMID 16556326.
- Bots CP, Brand HS, Veerman EC, van Amerongen BM, Nieuw Amerongen AV (June 2004). "Preferences and saliva stimulation of eight different chewing gums". Int Dent J 54 (3): 143–8. PMID 15218894.
- Mejare I, Lingstrom P, Petersson LG, Holm AK, Twetman S, Kallestal C, Nordenram G, Lagerlof F, Soder B, Norlund A, Axelsson S, Dahlgren H. Caries-preventive effect of fissure sealants: a systematic review. Acta Odontol Scand. 2003;61(6):321-30
- Ten Cate's Oral Histology, Nanci, Elsevier, 2013, page 7.
- Ross, Michael H., Gordon I. Kaye, and Wojciech Pawlina, 2003. "Histology: a text and atlas." 4th edition, p. 453. ISBN 0-683-30242-6.
- Limited evidence suggests fluoride varnish applied twice yearly is effective for caries prevention in children at http://ebd.ada.org/SystematicReviewSummaryPage.aspx?srId=876816cd-5f69-4bd5-b320-3502a1bbd8ea
- Russell, MW; Childers, NK, Michalek, SM, Smith, DJ, Taubman, MA (May–Jun 2004). "A Caries Vaccine? The state of the science of immunization against dental caries.". Caries research 38 (3): 230–5. doi:10.1159/000077759. PMID 15153693.
- Ole Fejerskov, Edwina Kidd (2004). Dental caries : the disease and its clinical management. Copenhagen [u.a.]: Blackwell Munksgaard. ISBN 9781405107181.
- Oral Health Topics: Anesthesia Frequently Asked Questions, hosted on the American Dental Association website. Page accessed August 16, 2006.
- Summit, James B., J. William Robbins, and Richard S. Schwartz. "Fundamentals of Operative Dentistry: A Contemporary Approach." 2nd edition. Carol Stream, Illinois, Quintessence Publishing Co, Inc, 2001, p. 128. ISBN 0-86715-382-2.
- "Aspects of Treatment of Cavities and of Caries Disease" from the Disease Control Priorities Project. Page accessed August 15, 2006.
- Oral Health Topics: Dental Filling Options, hosted on the American Dental Association website. Page accessed August 16, 2006.
- What is a Root Canal?, hosted by the Academy of General Dentistry. Page accessed August 16, 2006.
- FAQs About Root Canal Treatment, hosted on the American Association of Endodontists website. Page accessed August 16, 2006.
- Wisdom Teeth, packet in pdf format hosted by the American Association of Oral and Maxillofacial Surgeons. Page accessed August 16, 2006.
- "WHO Disease and injury country estimates". World Health Organization. 2009. Retrieved Nov 11, 2009.
- Vos, T (Dec 15, 2012). "Years lived with disability (YLDs) for 1160 sequelae of 289 diseases and injuries 1990-2010: a systematic analysis for the Global Burden of Disease Study 2010.". Lancet 380 (9859): 2163–96. doi:10.1016/S0140-6736(12)61729-2. PMID 23245607.
- The World Oral Health Report 2003: Continuous improvement of oral health in the 21st century – the approach of the WHO Global Oral Health Programme, released by the World Health Organization. (File in pdf format.) Page accessed August 15, 2006.
- Healthy People: 2010. Html version hosted on Healthy People.gov website. Page accessed August 13, 2006.
- Frequently Asked Questions, hosted on the American Dental Hygiene Association website. Page accessed August 15, 2006.
- "Dental caries", from the Disease Control Priorities Project. Page accessed August 15, 2006.
- World Health Organization website, "World Water Day 2001: Oral health", p. 2. Page accessed August 14, 2006.
- Touger-Decker R, van Loveren C (1 October 2003). "Sugars and dental caries". Am J Clin Nutr. 78 (4): 881S–92S. PMID 14522753.
- "Table 38.1. Mean DMFT and SiC Index of 12-Year-Olds for Some Countries, by Ascending Order of DMFT", from the Disease Control Priorities Project. Page accessed January 8, 2007.
- Epidemiology of Dental Disease, hosted on the University of Illinois at Chicago website. Page accessed January 9, 2007.
- Suddick RP, Harris NO (1990). "Historical perspectives of oral biology: a series". Crit Rev Oral Biol Med. 1 (2): 135–51. doi:10.1177/10454411900010020301. PMID 2129621.
- Richards MP (December 2002). "A brief review of the archaeological evidence for Palaeolithic and Neolithic subsistence". Eur J Clin Nutr 56 (12): 16 p following 1262. doi:10.1038/sj.ejcn.1601646. PMID 12494313.
- History of Dentistry: Ancient Origins, hosted on the American Dental Association website. Page accessed January 9, 2007.
- Dig uncovers ancient roots of dentistry: Tooth drilling goes back 9,000 years in Pakistan, scientists say, hosted on the MSNBC website . Page accessed January 10, 2007.
- Anderson T (October 2004). "Dental treatment in Medieval England". Br Dent J 197 (7): 419–25. doi:10.1038/sj.bdj.4811723. PMID 15475905.
- Elliott, Jane. Medieval teeth 'better than Baldrick's', hosted on the BBC news website. October 8, 2004. Page accessed January 11, 2007.
- Gerabek WE (March 1999). "The tooth-worm: historical aspects of a popular medical belief". Clin Oral Investig 3 (1): 1–6. doi:10.1007/s007840050070. PMID 10522185.
- McCauley, H. Berton. Pierre Fauchard (1678-1761), hosted on the Pierre Fauchard Academy website. The excerpt comes from a speech given at a Maryland PFA Meeting on March 13, 2001. Page accessed January 17, 2007.
- Kleinberg I (1 March 2002). "A mixed-bacteria ecological approach to understanding the role of the oral bacteria in dental caries causation: an alternative to Streptococcus mutans and the specific-plaque hypothesis". Crit Rev Oral Biol Med. 13 (2): 108–25. doi:10.1177/154411130201300202. PMID 12097354.
- Baehni PC, Guggenheim B (1996). "Potential of diagnostic microbiology for treatment and prognosis of dental caries and periodontal diseases". Crit Rev Oral Biol Med. 7 (3): 259–77. doi:10.1177/10454411960070030401. PMID 8909881.
- Newbrun, E. 1989 Cariology. Quintessence Books, Chicago
- Selwitz, RH. "Dental caries". PubMed. Lancet. Retrieved 1 October 2013.
- Suddick, Richard P. "Historical Perspectives of Oral Biology: A Series". Sage Pub. Sage Pub. Retrieved 1 October 2013.
- Dental caries at DMOZ
- Centers for Disease Control, Dental Caries at http://www.cdc.gov/healthywater/hygiene/disease/dental_caries.html