Dental pulp
Dentin
Jan Krivanek
28. 4. 2021
(Krivanek et al., 2017)
The fundamental importance of the pulp:
a) Tooth vitality - nutrition and protection of
odontoblasts against foreign and infectious agents
b) Reparative processes - pool of undifferentiated cells
for pulp fibroblasts and odontoblast-like cells
Dental pulp shape depends on:
- Tooth Type
- Age of the individual
- Pathological and repair changes
Dentin-pulp complex
Summary term used for dental pulp and dentin
Tight developmental, histological and functional connections
Common development history (ectomesenchymal origin)
Dental pulp Fibroblasts Odontoblasts
Stromal pulp tissue
Support for odontoblasts
Support for blood vessels and nerves
Immune reactions
Stem cell niche
Dentin production
Living component of dentin
Reactions on tooth damage
(pain, immune response, reparative processes)
Interactions
Dentin-pulp complex
Odontoblasts
Interface of dentin and the pulp
Elongated shape, polarization (nucleus with organelles in basal third)
Single cell layer
Secretory vesicles on apical side
Odontoblasts function
- In healthy teeth, lifetime-active cells
- Odontoblasts‘ processes/fibres (Tomes Fibres) maintain dentin matrix formation, responsible for dentin viability
- Odontoblats‘ processes involved in the pain perception
- Periodontoblastic space between the tubule wall and Tomes fibre, contains dentinal fluid and
mucopolysaccharide material
Odontoblasts
Odontoblasts
Odontoblasts /
Pulp cells
Development of
odontoblasts
Development of odontoblasts
Enamel
Dentin
Microscopic structure of dental pulp, function
and changes during aging
Ectomesenchymal origin
Located in cavitas dentis
Reticular structure
In primary dentition structure similar to jelly-like connective tissue
Extracelular matrix (ECM)
• Fibres:
• Collagen
• Reticular fibres
• Amorphous matter:
• Glycosaminoglycans and glycoproteins
Cellular part
• Particularly fibroblasts,
• Immune system: macrophages, plasma cells, dendritic cells and tissue-residential blood cells (neutrophiles or
eosinophiles, granulocytes, lymphocytes)
• Glial cells
• Endothelial cells, pericytes
• Dental mesenchymal cells
Stem Cells in (human) teeth
Schematic of potential sources of adult stem cells in the oral environment
TGPCs tooth germ progenitor cells
DFSCs dental follicle stem cells
SGSCs salivary gland stem cells
SCAP stem cells of the apical papilla
DPSCs dental pulp stem cells
iPAPCs inflamed periapical progenitor cells
SHED stem cells from human exfoliated deciduous teeth
PDLSCs periodontal ligament stem cells
BMSCs bone marrow stem cells
OESCs oral epithelial stem cells
GMSCs gingival-derived mesenchymal stem cells
PSCs periosteal stem cells (Yang et al., 2017)
Two layers (crown part)
Outer - surface
Inner - central
centrální
zevní
Dental pulp
stratification
Unclear zonation in
root canal
Inner layer / central zone
Outer layer
Blood and lymph vessels
Very rich blood supply (especially at a young age)
Arteries (2-10)
- Oriented longitudinally through the center of the pulp
- Numerous side branches
- They divide into terminal networks – odontoblasts supply
Subodontoblastic capillary network
- Arteries with narrow lumen, thick wall reinforced by several
layers of smooth muscle cells
- Veins and venules wall very thin, which strikingly contrasts with
their wide luminosity
Lymph circulation begins with the lymph capillaries that connect
to small lymph vessels leaving the dental pulp together with
the blood and nerve vessels through the foramen of the
apicis radicis dentis
Pulp inervation
Both myelinated and non-myelinated
Myelinated nerve fibres in the dental pulp are rich in
branches and reach up to the odontoblast bases under
which they form a dense network:
Plexus subodontoblasticus Raschkowi
the nerve fibres ends on the bodies of the
odontoblasts, some enters the predentin and dentin
channels
Non-myelinated nerve fibres innervate blood vessels in
the dental pulp
Temperature changes, mechanical or
chemical stimuli, osmolarity changes
Theories of dental pulp perception
a) Nerve endings in pulp and dentin
b) Odontoblasts acting as sensory cells
c) Hydrodynamic theory
Nweeia et al., 2014
Pulp changes during aging
• Fastest development immediately after pruning
• Age-related changes: chemical composition, structure and volume
Chemické složení – amorphous matter loses its mucilaginous character
Structure – cell loss, increase of fibres - transformation into dense collagenous connective tissue
Volume – loss due to deposition of secondary and tertiary dentin and denticles formation
DENTIN
dentin
Podélný výbrus Dekalcifikovaný řez
Microstructure of dentin, dentin types,
clinical significance
The most abundant dental tissue
Living tissue - contains parts of living cells
No blood vessels nor bone-lamelar structure
Derives from ectomesenchyme
Functional and developmental connection with the pulp
(dentin-pulp complex)
Physical properties
Ivory color
Harder than bone or cementum, but softer than enamel
Refractive index 1.62 (same as enamel)
Specific weight 2.14 g/cm3 (lower than enamel)
Flexible and permeable (permeability decreases with age)
Thickness 2-4 mm (primary dentition half)
Comparison of the hard tooth tissues (and lamellar bone)
Enamel Dentin Cementum Lamellar bone
Colour White
(to light blue)
Ivory Brown-yellow Brown-yellow
Inorganic (%)
Organic (%)
H20 (%)
96 (86)
1 (2)
3 (11)
70 (45)
20 (30)
10 (25)
61 (33)
27 (31)
12 (36)
45 (23)
30 (37)
25 (40)
Collagen fibres NO YES
(perpendicular to the
dentinal tubules)
YES
(in all directions)
YES
(same direction in
lamellas)
Cells Ameloblasts
(missing in
adults)
Odontoblasts
(on the pulpal side of
dentin)
Cementoblasts
(cementocytes)
Osteoblasts
osteocytes
Blood vessels NO NO NO YES
(in Haversian
canals)
Nerves NO YES
(on entry of dentinal
tubules)
NO YES
(in Haversian
canals)
Dentin matrix
Consists of collagen fibrils (collagen type I) forming bundles
The fibres run parallel to the tooth surface from the root tip to the crown (perpendicular to the the dentin tubules)
Amorphous matrix - glycosaminoglycans, proteoglycans and lipids, impregnated with hydroxylapatite crystals
In the tubular dentinal matrix, the collagen fibers are missing, contain more hydroxylapatite crystals, compact
appearance, about 15% harder than the matrix between the channels
Dentin types
Primary Secondary Tertiary
Secondary dentin
Laid down after the root growth is finished, when the crowns have reached the occlusal plane and the teeth are
functionally loaded
Only for permanent dentition teeth
Stored slowly throughout the whole existence of a permanent tooth.
Can be separated from the primary dentin by a more pronounced incremental line
Secondary dentine deposition results in a reduction in the pulpal cavity
Mantle
Interglobular
Circumpulpal
Interdentin
Predentin
Distance from
enamel
Enamel
Pulp
Interdentin
Circumpulpal dentin
Dentin types
Primary Secondary Tertiary
Circumpulpal dentin
90 % of all dentin
Contains dentinal tubules
Interdentin
Thin layer between circumpulpal dentin and predentin
where dentin mineralization starts
Predentin
Non-calcified layer near odontoblasts
Forms a collagen skeleton for mineralization
In both temporary and permanent teeth
Interdentin
circumpulpal
Mantle
Interglobular
Circumpulpal
Interdentin
Predentin
Distance from
enamel
Enamel
Pulp
Dentin types
Primary Secondary Tertiary
Mantle dentin
Firstly-formed dentin, thickness around 30 um
Variable mineralization
Collagen fibres oriented perpendicular to the DEJ surface (Korff bundles)
Branched terminal parts of dentin tubules terminates here
Interglobular dentin
Imperfectly calcified dentin at the interface of mantle and circumpulpal dentin
Fusion of dentin globules is impaired
Peritubular
Intertubular
Relation of
odontoblast
processes
Mantle
Interglobular
Circumpulpal
Interdentin
Predentin
Distance from
enamel
Enamel
Pulp
Dentin types
Primary Secondary Tertiary
Circumpulpal dentin (von Ebner)
• Collagen fibres run obliquely to perpendicular to the course of tubules
• Mineralization is globular.
• Only minor branching of the dentinal tubules here.
ReactiveReparative
Damage extent
Primary Secondary Tertiary
Dentin types
Tertiary dentinogenesis
Tertiary dentinogenesis
Reparative dentin Reactionary dentin? ?
Reaction to larger dentin damage
Amorphous structure
NO
Newly differentiated from pulp
May be present (osteodentin)
Protection from infection
Minor stimuli
Arranged
YES
Odontoblasts
NO
Increase of tooth wall
Cause of formation:
Structure:
Dentinal tubules:
Dentin-forming cells:
Cell bodies:
Main function:
Tertiary dentinogenesis
Osteodentin
Adela Hupková et. Miroslav Králík, 2015
Chemical composition
Inorganic
70 %
• Hydroxylapatite crystals
• Crystals smaller than than in enamel
• Crystals attached to fibres
Water
10 %
Organic
20 %
• Collagens - collagen I (III a V) (90 %)
• Non-Collagenous Proteins (8%)
a) Phosphorins – Ca2+ and phosphate donors, crystal
growth control
b) Gla-proteins (gamma-carboxyglutamate proteins,
acidic character) + glycoproteins (osteonectin, osteopontin,
sialoprotein I and II) - calcium carriers, crystal growth
c) Proteoglycans - control of crystal growth
• Phospholipids (2%)
Junctional complex
Numerous connecting complexes among the
odontoblast apexes:
tight junctions, gap junctions, desmosomes synchronization
of odontoblasts
Above the connecting complexes, the apex slowly
changes into a thin and long, short-sided branch Tomes
fiber
A basal process may be present
Each fiber is has its own canal - Dentinal Canal (tubulus)
Tomes fibres
root
crown
Channels with Tomes fibres penetrate
the entire dentin and cause the dentinal
stripes
visible on stained sections as well as
ground sections
Dentinal tubules with Tomes fibres
(transversal section)
1 mm2 surface can contain around 50 000 tubules
Dentinal tubules
(transversal section)
Dentinal tubules shape
S-shaped (2 bends - primary bending) towards DEJ (or cemento-dentinal junction)
Schreger shapes
(Crown part of dentin)
Primary dential bending
In addition to S-shape primary bending, up to another 200 secondary bends Primary
and secondary tubular bending caused by migration movements of odontoblasts during
dentinogenesis
Diameter of the dentin tubules is around 1–4 um
Decreasind towards DEJ (or cemento-dentinal junction)
Neighboring tubules can be interconnected by anastomoses (tubicles)
Enamel spindles (fusus enameli)
Dentine tubules extension into enamel
Dentin incremental lines
Caused by gradual deposition and mineralization of dentin
• von Ebner lines - 4-8 um distance - daily increments
• Owen's lines - 15-30 µm distance - joint calcification of 4-5 day increments
• Neonatal line - Owen line in temporary teeth - separates fetal and postnatal dentine
Circular pattern on cross section
Sclerotic dentin
"Dead Dentin", more resistant to dental caries, color of amber
Origin of dentin tubule closure by the thicknessing of peritubular dentin until complete tubules termination
Formed in the crown part and increases with age - a sign of aging
According to its amount, the age of the individual is determined (forensic)
Thank you for your attention