Fluoride and Tooth Surface PDF

Summary

This document discusses the history, properties, and application of fluoride in dentistry, focusing on its role in caries prevention. It outlines the stages of fluoride deposition, modes of action, and potential consequences like fluorosis. The document also covers the history of fluoride use in water fluoridation, highlighting key studies and debates surrounding this practice.

Full Transcript

Fluoride and the Tooth Surface

Oral and Dental Science

Josh Hudson
GDC Learning Outcomes:
1.1.8 Describe the properties of relevant medicines and
therapeutic agents and discuss their application to patient
management
1.10.2 Provide patients with comprehensive and accurate
preventative education and instruction in a manner which
encourages self care and motivation
1.10.3 Underpin all patient care with a preventative approach
that contributes to the patient's long-term oral health and
general health
1.10.4 Advise on and apply a range of preventative materials
and treatment as appropriate
2.3 Describe and evaluate the role of health promotion in terms
of the changing environment, community and individual
 Pre-reading
Caries
‘Aetiology of Dental Caries’ Lecture
Susceptible tooth

surface

Plaque Bacteria
Time

Fermentable

Carbohydrate
Pre-reading

‘Histology of enamel and dentine’
Lectures
Intended learning outcomes

By the end of this session you will be able to..

List the key milestones in the history of fluoride and its
use in caries prevention
Outline and describe the stages in fluoride deposition
Describe the modes of action of fluoride
Explain how fluorosis occurs
Identify fluorosis and assess its severity
Refresher session…

Normal enamel is mainly made up of hydroxyapatite
This makes up 96% of enamel
This is made of a lattice structure
It is primarily made of phosphate and calcium ions

Ca10 (PO4)6 (OH)2
Refresher session..
Decreasing pH

As pH lowers below the
critical
pH (5.5 for hydroxyapatite), Ca 10 (PO4)6 (OH)2
the
tooth surface will
demineralise and break
Demineralisation
down into its component
ions.
If the pH regularly remains
low Ca 2+ , PO4 3- + OH-
and does not neutralise, (hydroxyl ion)
extensive
Refresher session..

Infrequent attacks mean
less time below critical PH
and less
Stephen Curves
demineralisation (lower
caries risk)

Frequent attacks mean
more time below the
critical PH and hence
more demineralization
(higher caries risk)
How is fluoride
relevant to you
as dental
professionals?
Fluorine

Before we can
effectively link fluoride
to dentistry, we need to
understand what it
actually is and its
history..
Fluorine
 Has the symbol
F and atomic
number 9

Highly
Is a Halogen reactive with
within the
periodic table
Fluorin metals to form
salts or
e halides
(referred to as
fluoride)

Found naturally
in water, rocks,
soil and tea
 1892 1901
Frederick 1902
1874 Sir James Crichton-
McKay Sale of fluorine
Dr Browne
compound
Erhardt 1909
Investigation of Colorado
Stain
1931
1930 Staining on teeth in
Bauxite, Arkansas 1912
Dr HT Dean ‘shoe leather’/
McKay investigates
‘21 cities’ studies
1916 similar staining in
GV Black paper published Naples, Italy
on Colorado Stain

1945
1932 First experiment of artificial water
McKay link between fluoridation
1933
mottling and caries
Ainsworth UK water 1940
reduction
fluoride comparison 1955
studies Artificial water fluoridation tried
out in the UK

1960
1964 Anti-fluoride
Birmingham campaigns
fluoridated
1976 2000
The Royal College of The York Study
Physicians‘ enquiry into
1980
water fluoridation 1985
Mrs McColl’s
opposition of water KNOX report The Future…
fluoridation
Fluoride History
1. Colorado stain
identification
2. HV Churchill
water testing
07 01
7. Cochrane
review
02
06
3. Identification
fluoride may reduce
caries
03
6. York report 05
04
4. Shoe leather
surveys/21 cities surveys
5. Knox report
1) Colorado Stain - 1916

Dr Frederik McKay
documented a ‘stain’ on
some teeth when working in
Colorado springs
He was the first to document
this appearance and went on
to investigate its cause
Enlisted the help of GV Black
to investigate
GV Black published a paper
on the Colorado Stain
2) Water Sampling - 1931

Following identification of this
stain by McKay, Churchill, who was
a chemist for a local mining
company in Arkansas, realised
local children developed a similar
effect following their water source
changing
Concerned this may be linked to
his companies aluminium mine, he
investigated the water
He identified higher fluoride
content in water where mottling
was present
Advised although there is higher
3) Identification Fluoride may reduce caries - 1932

Although this had been
postulated previously, in
1932 McKay suggested
that the same compound
that caused the mottling
may reduce caries
McKay had identified
although mottled, these
teeth developed no greater
chance of decay that teeth
which are normally
calcified
4) Shoe leather studies/21 cities studies – 1930-
1940

Following McKay’s claims, the head
of the US public health service
assigned Dr H Trendley-Dean to
research the links between fluoride
in water, mottling and caries
reduction.
His subsequent studies
demonstrated;
Increased mottling with
increased fluoride
Decreased caries if water
fluoridated
1ppm fluoride appeared to be
the optimal level
He developed an ‘Index for
 Benefits
discovere
d
Water
Fluoridate
d
Caries
reduction

Campaigns
against
‘mass
medication’
5) Knox Report - 1985

Review of papers looking at the
links between fluoride and
cancer
Concluded that there is no link
and fluoridated drinking water
6) York Report - 2000
is safe

Reviewed evidence from
hundreds of studies into water
fluoridation
No association found between
water fluoridation and bone
fractures, or water fluoridation
 Based on older
research (no Fluoridation increased the
modern percentage of children with
research no decay in deciduous
available) teeth by 15%

Insufficient evidence on effect in adults
73% of studies
focussed on areas with
natural fluoridation

Cochrane Review 2015
Fluoridated water
Fluoridation
reduces caries in
increased the
children's permanent
percentage of
teeth by 26%
children with no
Fluoridation of 0.7ppm decay in
gives a 12% chance Fluoridated water permanent teeth
of Fluorosis (mottling) reduces caries in by 14%
that may cause deciduous (baby)
aesthetic concerns teeth by 35%
Modern Day

Controversy still remains
for artificial water
fluoridation
Currently in the UK
approximately 10% of the
population has fluoride in
the water
Have you lived in an area
with fluoride in the water?

Click this link to find out
Modern Day

Luckily, although water fluoridation
is not universal, the benefits of
fluoride use are well researched
and well advocated in caries
prevention

Cochrane Studies
Delivering Better Oral Health
NHS Website
NHS Review of Water Fluoridation

Patients will still question its use!
So how does
fluoride prevent
caries?
How does it work? - Uptake into
the tooth Pre-eruptive Post-eruptive
Ultimately, fluoride stage stage
is absorbed into the (systemic (topical
tooth surface fluoride) fluoride)
making it more
resistant to Matrix
demineralisation Secretion
from the caries
process. This occurs
at multiple stages; Maturati
on Stage
How is it absorbed? – Matrix
Secretion Stage
Fluoride absorbed from
systemic sources (swallowed
fluoride)
Travels to developing tooth
buds via blood and surrounding
tissue fluid
Deposited into the tooth during
enamel formation as
fluoroapetite
This fluoroapetite replaces the
usual hydroxyapetite
Excess fluoride can inhibit
ameloblast activity affecting
enamel development
 How is it absorbed? - Maturation
Stage

Fluoride absorbed from
1
systemic sources (swallowed
fluoride)
Occurs after
2
calcification but prior to
eruption
Deposition of fluoride continues 3
at the enamel surface from the
tissue fluid around the tooth
4
More fluoride is taken
up by outer layer
5
Also forms fluoroapetite
How is it absorbed? - Post-
Eruptive Stage
Loss of calcium
Healthy tooth Demineralised
Drop in PH and phosphate
surface tooth surface
due to from
bacterial hydroxyapatite
acid

Addition of
Increase in calcium and
Remineralisatio
PH phosphate
n
from saliva to
reform
hydroxyapatit
e
How is it absorbed? - Post-
Eruptive Stage
Loss of calcium
Healthy tooth Demineralised
Drop in PH and phosphate
surface tooth surface
due to from
bacterial hydroxyapatite
acid

Addition of
Increase in calcium and Remineralisatio
PH phosphate and n
fluoride from
saliva to form
fluoroapetite
How is it absorbed? - Post-Eruptive
Stage
Key Points
The most fluoride is acquired during the 2-3 years post-eruption
This is because it is more porous which facilitates diffusion and
uptake
Demineralised enamel also absorbs fluoride more easily for this
reason
Fluoride reacts strongly with calcium so does not penetrate
deeply if used topically
Maximum uptake cannot be exceeded but fluoride can be
replaced as the surface is abraded

It is therefore more essential for fluoride to be used to
reduce the progression of caries rather than purely
So it works by
producing
fluoroapetite but
why is this
important?
Why is fluoroapetite important?

Formed by fluoride ions
replacing hydroxyl ions
during remineralisation

This newly formed molecule
is more stable due to
improved hydrogen bonds,
fewer imperfections and
larger crystals

Helps inhibit
Fluoroapetite’s critical demineralisation and
promote remineralisation
PH = 4.5
Why is fluoroapetite important?

Due to the lower critical PH,
fluoroapetite is less soluble.

This makes the tooth more
resistant to future acid
attacks

This, therefore, reduces
demineralisation This ultimately
reduces caries
incidence
Where does the fluoride come
from?
Topical applications of fluoride create a reservoir of
fluoride in saliva
This fluoride bonds to calcium in saliva forming CaF2
When an acid attack occurs and PH drops, the fluoride
is released
This can then enter the tooth during remineralisation

It is therefore essential that there is a
regular supply of low-level fluoride to
Ways to ensure this regular supply is
maintained are summarised here
Topical Fluoride Source Fluoride Level Prescription?
Toothpaste (Stannous/Sodium 1450-5000ppm YES if 2800 or 5000ppm
Fluoride)
Mouth rinse 225ppm EITHER
Restorative materials (e.g. 0.8-1.2ppm dropping -
Glass Ionomer Cements) over time
Fluoride Varnish 22,600ppm YES
Water Fluoridation 0.7-1ppm generally NO
Fluoride Tablets Made up to 0.3- YES
0.7ppm
How does that
work in real life?
 C
a

C
a

C
a
PH
C
a
DRO
F
P
C
a =
C Hydroxyapatit
a e
=
Fluoroapatite
C
a
 pH
RISE
F

=
Hydroxyapatit
e
=
Fluoroapatite
Does fluoride
have any other
mechanisms of
action?
 H
H

H

H

H H

H
H
Action on bacterial plaque
At concentrations over 1% (such as
professionally applied fluoride), a
bactericidal effect is demonstrated

This means fluoride can be toxic to
bacteria such as strep mutans

When the PH drops, H+ and F- bond
to form HF which then diffuses
across the bacterial cell wall

This then inhibits glycolysis by preventing
the uptake of glucose through the cell wall
and its breakdown. It also inhibits enzyme
systems involved in the conversion and
transport of sugars
This cuts of the bacteria’s food
supply meaning it cannot metabolise
sugars into acid
F
Action on enamel surface

Fluoride reduces the It has also been
surface energy of suggested that
enamel. This has the 0 fluoride on the tooth
03 surface can ‘push
effect of decreasing the
wettability of enamel
1 away’ proteins
and hence ability for which reduces
bacteria to adhere pellicle formation

Less pellicle
This prevents the formation, less
formation of plaque and less
pellicle so plaque bacterial
cannot 02 04 adhesion leads
accumulate as to a reduced
easily likelihood of
caries
Action on tooth morphology
Some evidence
suggests that
systemic fluoride 0
may alter tooth
morphology 1
during their
development These may
therefore
03 make the
tooth more
This can result in; cleansable
Shallower pits
Reduced
fissure depth 02
Lower cusp
height
What about the other
tooth surfaces?
(Dentine and
Cementum)
Root Caries Recap

As these are
Gingival recession
mineralised
exposes dentine
surfaces, these are
and cementum
also
susceptible to
decay
This is root caries

This is more
As they are less
common in;
mineralised,
xerostomia patients
decay can
(patients with
progress
limited saliva) and
faster
radiotherapy
patients
 How does fluoride prevent root
caries?
1. Incorporating into surface during
remineralisation
2. Reducing surface wettability
3. Antibacterial effects

(Kato et al, 1997)
What does the research say?

Topical Fluoride to Prevent Root Caries: Systematic Review
with Network Meta-analysis

Professionally applied fluoride (Silver diamine fluoride, fluoride
varnish) reduces risk of root caries at 2 years
Self-applied fluoride (various concentrations of sodium fluoride
mouth rinse, and fluoride tooth paste) reduces risk of root caries
at 1 year

Therefore, professionally and self-applied fluoride is essential for
caries prevention in patients with exposed root surfaces (dentine
and cementum) at risk of caries. Will become more of an issue as
the population continues to age.
Fluorosis

What is fluorosis and
how does it form?
What is it?

“The term given to changes in the enamel which are associated
with excess ingestion of fluoride…it can vary from white opacities,
lines or flecks to more severe brown-yellow mottling of the enamel.
The precise effect depends on the dose of fluoride (from all
sources), duration for which it was taken, and the age of the
patient at the time of ingestion.”

Clinical Textbook of Dental Hygiene and Therapy (Edited by
Robert Ireland, 2006)
Mechanism of fluorosis
If excess fluoride is present it is
thought to inhibit normal ameloblast
activity during the matrix formation
and maturation phases, and
hypomineralised (and hypoplastic)
enamel will form.

Due to the hypomineralisation, the
enamel becomes more porous and
hence more readily takes up stain
which can cause more obvious
discolouration.

It is important to remember that
enamel defects can result from other
causes, not just fluorosis. For
example: trauma, disease, drugs and
genetics.
What are the aetiological agents?

The ingestion of the below can cause fluorosis;
1. Dietary fluoride supplements
2. Drinking water
3. Toothpaste
4. Topical applications
The most critical time is from 0-8 years as the teeth develop
Due to the staggered nature of tooth development, not all teeth
will always be affected depending on the timing of the fluoride
exposure
Is it fluorosis?
Indices for recording fluorosis
The two main indices are the
Dean Index (1942) and the
Thylstrup and Fejerskov index
(1978)
The Thylstrup and Fejerskov
index is shown to the right
Score 0 the enamel has normal
translucency
Scores 1-4 has increasing levels
of fluorosis with no loss of the
outermost enamel
Scores 5-9 has increasing
degrees of loss of the
outermost enamel
Summary
Summary
Action on
hydroxyapatite

Action on
Action on tooth Mode of Action of
bacterial
morphology Fluoride
enzymes

Action on
enamel surface
Summary

https://www.youtube.com/watch?v=TyVV0UDQ_f4

https://www.youtube.com/watch?v=TyVV0UDQ_f4
Thank
You!