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| Saliva
and Tooth Dissolution |
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The problems of
teeth
Teeth, like all mineralised tissue, must
be able to withstand chemical as well as
physical trauma. The major chemical threat is
dissolution. This is countered by using a
mineral which is only sparingly soluble and by
surrounding it with a solution which is
supersaturated with respect to the salts which
comprise the mineral. In the case of bone and
the roots of teeth, this is interstitial fluid.
Those parts of teeth above the gum margin are
protected by saliva.
In order to understand how saliva
prevents tooth dissolution it is first
necessary to understand the concepts of
ionic product and solubility product , the
meaning of pK in relation to the effect of
pH on hydroxyapatite dissolution and the
dissociation equilibria of hydroxyapatite which
is dealt with below. |
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The mineral of
teeth and bone is similar to calcium
hydroxyapatite
There are a number of calcium phosphate
salts which differ in the Ca:P ratio and
solubility. Some of these are present in tooth
mineral to a greater or lesser extent but the
most common by far is an impure form of calcium
hydroxyapatite commonly called "Biological
apatite" or sometimes just "Apatite".
The impurities, which include sodium,
magnesium, potassium, lead, strontium, barium
and especially carbonate introduce defects into
the hydroxyapatite crystal which render it
significantly more soluble.
More information on biological apatite and
solubility is available here. Complicating
the issue even further is the fact that the
mineral in enamel has been shown to contain
2-3% of its phosphate in the form of
mono-hydrogen phosphate which itself is a
component of the hydroxyapatite dissociation
equilibrium equation.
Biological apatite is not well defined
because of the variability in the impurities.
For this reason the dissolution of calcium
hydroxyapatite will be described. |
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The
dissociation equilibrium of hydroxyapatite
The dissolution of hydroxyapatite in an
aqueous system is governed by the law of mass
action. The net loss of calcium phosphate from
the solid phase (tooth) is governed by the
ionic product of the relevant ions in solution.
In the case of hydroxyapatite these ions are
calcium, phosphate and hydroxyl. Note that the
important phosphate ion in this respect is the
unprotonated form.
At equilibrium there is no net loss/gain
of ions in solution or in the solid phase and
the ionic product is known as the solubility
product (Ksp). The Ksp is difficult to measure
accurately because of a number of technical
problems, however, a commonly used value is
2.34 x 10^-59. |
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| Two equations are used to
describe hydroxyapatite. The one
shown above is the stoichiometric
formula of the hydroxyapatite unit
cell. The formula used to calculate
Ksp is shown below. |
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The situation
in the mouth
In the mouth teeth are bathed in saliva
which is constantly being replenished. The
calcium and phosphate ion concentrations in
saliva are variable but on average are both
about 1.5 mMoles/Litre. Of course, not all the
phosphate is in the unprotonated form but this
amount can be
calculated and at neutral pH is
approximately 5 nanomoles/Litre.
At neutral pH the natural level of
calcium phosphate in saliva is sufficient to
supersaturate it with respect to
hydroxyapatite. |
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Calcium phosphate in saliva
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| The calculation shows the
ionic product of salivary calcium
phosphate with respect to
hydroxyapatite. At pH7 saliva is
supersaturated with respect to
hydroxyapatite (IP>>Ksp) |
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| Teeth, however,
are made from biological apatite which is more
soluble than hydroxyaptite. When powdered human
enamel is allowed to equilibrate in aqueous
solution the ionic product is significantly
greater than the Ksp of hydroxyaptite and
significantly less than the the ionic product
of saliva. This means that at neutral
or near neutral pH saliva is supersaturated
with respect to both hydroxyapatite and
biological apatite. |
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The effect of
pH
The dissociation equilibrium of
hydroxyapatite is very sensitive to the pH of
the surrounding medium and exerts its effect by
altering the concentration of both unprotonated
phosphate ions and hydroxyl ions. |
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| At neutral pH
(7.0) saliva is supersaturated with calcium
phosphate with most of the phosphate present in
either the mono- or di-hydrogen phosphate form.
However, as the pH becomes more acid the degree
of supersaturation decreases until a point is
reached where the saliva ceases to be saturated
with respect to the tooth mineral. This is
known as the "Critical pH".
Conversely, if the pH becomes more alkaline the
degree of saturation with respect to tooth
mineral increases and eventually the calcium
phosphate in solution becomes unstable and
precipitates, not as hydroxyapatite but as the
more readily formed mineral, brushite. This
precipitation is promoted by nucleating centres
within dental plaque and is called calculus.
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The Critical pH
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tooth becomes increasingly acidic a
point is reached when it ceases to
be supersaturated and any further
decrease in pH results in mineral
dissolution. This is known as the
"Critical pH" and is normally in
the region of pH 5.2-5.5 depending
on the particular saliva
composition of the individual. |
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Clinical Implications
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Caries and
erosion
One of the main functions of saliva is to
protect teeth against dissolution via
either a cariogenic challenge or dental
erosion. This is achieved this by controlling
the pH of the oral cavity by means of secreted
bicarbonate ions and by maintaining a
supersaturated state with respect to the
mineral phase of teeth. Although bicarbonate
can exert an independent effect by neutralising
acid it is important to remember that it also
controls the degree of calcium phosphate
saturation of saliva, with respect to tooth
mineral, especially since the concentration of
these ions does not vary greatly outside of
dental plaque.
Why is mineral not deposited on erupted
teeth?
Since saliva is supersaturated with respect to
tooth mineral it should follow that the mineral
crystals comprising the very surface of teeth,
should grow as more calcium phosphate is
deposited which is the basis of crystal
gardening kits for junior scientists. This does
not happen because a solution of calcium
phosphate requires a nucleating centre for
hydroxyapatite deposition and the very surface
of teeth are coated in an aquired pellicle of
proteinaceous material derived from saliva
which masks the underlying crystals. Saliva
also contains a variety of peptides including
the "Proline Rich Peptide" family which serve
to stabilise soluble calcium phosphate in
vivo. |
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Interproximal caries
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Dental erosion
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| Caries
initially presents as a sub-surface
lesion caused by organic acids in
the overlying plaque. This lesion
may then cavitate and spread to
give the characteristic lesion such
as the one shown above. |
Erosion is a
surface event caused by frequent
exposure of the tooth to acidic
conditions. Excessive consumption
of carbonated drinks can cause
erosion as can frequent vomiting.
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Calculus
The degree of calcium phosphate
saturation in saliva is so high that the
solution borders on instability (technically it
is metastable). A small rise in pH as a result
of, say, increased flow rate when the
bicarbonate concentration rises
dramatically can be enough to instigate calcium
phosphate precipitation.
Salivary bicarbonate is in equilibrium
with the intra-oral gaseous carbon dioxide. At
elevated concentrations it can be rapidly lost
with a resulting drop in salivary pH. The
highest bicarbonate concentrations are found
adjacent to the openings of the salivary ducts
where an equilibrium has not had chance to
establish. This, therefore, is the region where
salivary calcium phosphate is at its most
unstable. The calcium phosphate precipitates in
these regions, helped by certain plaque
bacteria which can act as nucleating centres
and further de-stabilising the system. |
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Advanced Calculus
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| This is advanced dental
calculus which has formed on the
buccal surfaces of anterior teeth
in the region of the opening of the
submandibular-sublingual salivary
glands. |
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Fluoride and
remineralisation
The profound effect of fluoride on
reducing the incidence of caries is well
documented. A number of different mechanisms
are thought to operate but the main effect is
that fluoride promotes the remineralisation of
teeth which have been subjected to a cariogenic
challenge. These challenges occur at the base
of dental plaque adjacent to the tooth surface.
The fluid within plaque is high in calcium
phosphate and may also contain fluoride ions
sourced from the water supply, toothpaste,
mouthrinses or the diet. |
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| Calcium fluorapatite is
closely related to hydroxyapatite although it
is very much more stable with a much lower Ksp.
Fluoride can replace hydroxyl ions in
hydroxyapatite crystals and such hybrid
crystals are sometimes referred to as fluor-hydroxyapatite. |
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| If some fluoride
is added to a system in which calcium
hydroxyapatite is in equilibrium with the ions
in the surrounding aqueous phase the
equilibrium will shift quite sharply to favour
deposition of mineral (calcium fluorapatite) by
acting as a
common ion. Only very small concentrations
of fluoride are required because at equilibrium
the concentration of hydroxyl ions is extremely
low.
Even at 1 ppm, the concentration of
fluoride used in artificially fluoridated water
supplies, fluoride will be many thousands of
times more concentrated than hydroxyl ions.
This relative difference will increase by a
factor of 10 for each drop in pH by 1 pH unit.
Furthermore, in dental plaque fluid, the
concentration of fluoride can often be orders
of magnitudes greater than that found in water
especially if it has been recently applied
topically in the form of a dentifrice or
mouthrinse. Typical dentifrices contain 1500ppm
fluoride ion. |
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| Clearly some fluoride will
be incorporated at neutral and even alkaline pH
but as the pH becomes more acid, the
concentration of hydroxyl becomes very much
reduced and the effect of fluoride enhanced. |
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SUMMARY |
| 1. |
The mineral of teeth is a
defective hydroxyapatite called
biological apatite (apatite) which
is sparingly soluble at near
neutral pH. |
| 2. |
Tooth dissolution is
prevented by saliva which is
supersaturated with respect to
biological apatite.
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| 3. |
As conditions become more
acidic the dissociation equilibrium
favours apatite dissolution to
replace unprotonated phosphate ions
and hydroxyl ions which have been
reduced in concentration.
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| 4. |
The reverse happens when
conditions become more alkaline. |
| 5. |
Caries and tooth erosion are
clinical effects of tooth mineral
dissolution. Calculus is caused by
precipitation of a calcium
phosphate salt called brushite when
the salivary calcium phosphate is
destabilised by alkaline
conditions. |
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Pellicle shields the surface
of teeth from saliva and prevents
fresh calcium phosphate from being
continuously laid down. |
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The presence of fluoride ion
promotes remineralisation by acting
as a common ion. |
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