Acidic proteins such as γ-carboxyglutamate-containing proteins (Gla-proteins) are found in dentine in low amounts. It is not known what their function is, but their acidic nature allows them to bind strongly to hydroxyapatite crystallites, and therefore they may play some role in directing or guiding mineral deposition as predentine matures through to dentine. The other acidic proteins, osteopontin and osteonectin, may also be important in directing mineralization, and these are classically associated with bone. Dentine matrix protein is another acidic phosphorylated protein found in dentine and bone, and may also be involved in regulating nucleation of mineral crystals.

The two dentine phosphoproteins, dentine sialoprotein (DSP) and dentine phosphoprotein (DPP) are post-transcriptionally cleaved from the same gene product from the dentine sialophosphoprotein (DSPP) gene. The two proteins may have similar, but slightly different roles:

Dentine contains a cocktail of bioactive proteins called growth factors. Such growth factors are sequestered into the dentine during dentinogenesis and are thought to be held within the mineralized matrix, bound to proteoglycans or latency-associated peptides. Such factors include TGF-β1, BMP-2, 4 and 7, IGF and the angiogenic growth factor VEGF. Such factors have been shown to be important in regulating dentinogenesis and tooth development, and it is possible that release of these factors during trauma or disease (and possibly cavity lining) directs the tertiary dentinogenic response which the pulp-dentine complex exhibits.

The odontoblast process contains vesicles, microtubules and intermediate filaments. The main organelles associated with protein synthesis (e.g. rough endoplasmic reticulum Golgi material) are present in the odontoblast cell body but do not extend into the process. The extent of the odontoblast process inside the dentinal tubule has not been established with certainty due to considerable technical difficulties. Evidence suggests that, with age and with the formation of peritubular dentine, it is limited to the inner third of dentine. A thin, proteinaceous membrane termed the lamina limitans may be seen lining the wall of the dentinal tubule and its presence may give rise to the erroneous impression of an odontoblast process.

Sensory nerve terminals may be seen adjacent to the odontoblast processes. They are limited mainly to the dentine of the crown beneath the cusps (where they may be found in 50–80% of the tubules) and project up to 200 μm from the pulp. Fewer tubules are innervated in the midcoronal dentinal regions and fewer than 5% of tubules are innervated in the cervical and root dentine. The axon is narrower than the odontoblast process and often contains mitochondria; there is no evidence of any specialized contacts between the nerve and the odontoblast process.

Reactionary dentine refers to the tertiary dentine forming in response to an insult in which, although some damage has been sustained, the existing odontoblasts upregulate their synthetic and secretory functions and continue to form dentine.

Reparative dentine relates to the tertiary dentine forming after a stimulus in which the original odontoblasts in the associated region have been destroyed and new calcified tissue (reparative dentine) has been formed by newly differentiated cells (referred to as ‘odontoblast-like’ cells). This matrix is rapidly deposited and has a dysplastic, irregular structure. No DPP is present and high levels of bone-associated proteins can be identified. This reparative dentine has also been referred to as osteodentine.

Once the initial thin layer of mantle dentine has formed, the fully differentiated odontoblasts continue retreating pulpwards, trailing out an odontoblast process around which the odontoblast continues to secrete the predentine associated with circumpulpal dentine. Compared with that of mantle dentine, the collagen fibrils are now oriented parallel to the enamel–dentine junction. When the predentine reaches a thickness of about 10–20 μm, it attains a state of maturity that will allow it to mineralize. At the mineralizing front, degradation of some molecules in predentine may occur, while other molecules may be added (e.g. dentine phosphophoryn) after being transported along the odontoblast process, thereby bypassing the bulk of the predentine layer. As the biochemistry of predentine will differ when compared with that of the organic matrix associated with mineralized dentine, predentine will stain differently. The main path of the retreating odontoblasts will give rise to the outline of the primary curvatures, whilst minor undulations in the odontoblast process will give rise to the secondary curvatures.

The outline of the mineralizing front indicates that two distinct patterns of mineralization can occur (and in the absence of matrix vesicles): a linear or a spherical (calcospheritic) pattern. In calcospherites, the crystallites are arranged in a radial pattern and, despite complete mineralization of dentine, this pattern can still be discerned using polarized light. Failure of calcospherites to fuse may result in the appearance of interglobular dentine, representing small regions of unmineralized matrix.

Concerning biochemical aspects of dentine mineralization, collagen fibril formation proceeds, with alignment of tropocollagen molecules being guided by non-collagenous proteins such as decorin. Pyridinoline cross-link formation between lysine and hydroxylysine residues increases as predentine is modified, allowing for mineralization to dentine. The collagen fibril orientation, along with the presence of proteoglycans, can be said to be the scaffold on which mineral can be deposited, and collagen itself is a good nucleator of hydroxyapatite. Hydroxyapatite crystals are initially deposited at the gap zone within collagen fibrils of mineralized dentine.

Following crown formation, the external enamel and internal enamel epithelia proliferate apically as the epithelial root sheath to map out the shape of the root. Internal to the root sheath lies the dental papilla, while the dental follicle is situated extenally. As in the crown, epithelial/mesenchymal interactions induce the peripheral cells of the dental papilla to differentiate into odontoblasts, which commence laying down the initial root dentine. Unlike dentinogenesis in the crown, the cells of the epithelial root sheath do not enlarge or become columnar, and do not differentiate into ameloblasts. Instead, they remain cuboidal. As the odontoblasts of the root migrate pulpwards, they do not initially trail behind a process and the resulting matrix contains some organic material derived from the odontoblasts (though with fewer collagen fibrils), as well as some enamel-related proteins secreted by the epithelial root sheath cells. This epithelial contribution is reflected in the structure of the internal enamel epithelial cells, which possess some of the intracellular organelles associated with protein synthesis and secretion (e.g. Golgi material and endoplasmic reticulum). The subsequent fate of the epithelial root sheath is considered further in relation to cementum formation.

This thin, initial, organic predentine layer in root dentine will mineralize to form the hyaline layer, which is continuous in the crown with the mantle layer. Unusually, mineralization begins a few microns in from the surface and continues pulpwards, allowing these outer few microns to undergo delayed mineralization outwards and provide a firm union with the initial collagen fibrils of the cementum.

Following the formation of the hyaline layer, the migrating odontoblasts trail behind their odontoblast processes. Initially these branch, loop and appear dilated and, when the dentine matrix around them becomes mineralized, give rise to the granular layer immediately beneath the hyaline layer. After this, the main odontoblast process is formed in a relatively straight horizontal plane as the remaining circumpulpal dentine of the root is formed.

Peritubular dentine is slowly deposited on the wall of the dentinal tubule, commencing soon after the formation of the dentinal tubule. It differs from intertubular dentine in containing more mineral and in lacking collagen fibres, its organic matrix consisting of non-collagenous proteins such as glycoproteins, proteoglycans and lipids. The inorganic component of peritubular dentine differs somewhat to that of intertubular dentine. Peritubular dentine formation may be under the control of the odontoblast and may incorporate plasma proteins that have diffused along the cell membrane.

Peritubular dentine will slowly narrow the diameter of the lumen of the dentinal tubule, initially about 3 μm in diameter. The lumen may be completely occluded by peritubular dentine and this happens consistently in the apical third of the root, giving rise to the appearance of translucent dentine. The amount of translucent dentine correlates very well with age.

The rate of dentine formation varies, producing incremental lines. There are both short-term (diurnal) and long-period rhythms:

An exaggerated line, the neonatal line, is present in all teeth mineralizing at birth and represents the dentine formed during the first few days after birth with its disturbed nutrition.

The dental pulp is a loose, soft, connective tissue derived from the dental papilla and is responsible for the formation and maintenance of dentine. It is contained within the pulp chamber and root canals of the tooth. At the apical constriction of the root canal it becomes continuous with the periodontal ligament. After a tooth has erupted into the oral cavity, the pulp forms secondary dentine slowly, but regularly, throughout life so that its size diminishes. It is able to respond to strong stimuli (such as caries, trauma, tooth movement and restorative procedures) by producing tertiary dentine. Some of the more specialized properties of the dental pulp relate to its situation, being almost completely encased in, and protected by, dentine.

As with other connective tissues, the dental pulp is made up of a combination of cells embedded in an extracellular matrix of fibres in a semifluid gel. It has a very rich blood and nerve supply. It contains 75% by weight of water and 25% organic material. The pulp is a dynamic functional matrix which has an important role in controlling the activity of the cells within it. The complex framework of collagen and associated proteoglycans and glycoproteins creates a scaffold to stabilize the structure of the pulp; however, the nature of the organic molecules within it allow it to influence cell migration, proliferation, adhesion, differentiation and function.

The pulp has a rich blood supply. Arterioles and venules enter and leave the dental pulp via the apical foramina. The largest of the arterioles are approximately 150 μm in diameter. They run longitudinally through the root canals, within which they send off side branches to the periphery. The vessels divide and branch profusely once they are within the coronal pulp and form a rich capillary plexus beneath the odontoblast layer. Capillary loops extend towards the dentine and pass between the odontoblasts and the predentine. Returning vessels connect to venules. The capillary n/>