Etiology Of Periodontal Diseases PDF

Summary

This document discusses the etiology of periodontal diseases, categorized into initiating factors, local predisposing factors, and systemic predisposing factors. It covers the definition and composition of dental plaque, including associated microorganisms, and how it forms. The document also explains the role of bacteria in health and diseases of the periodontal tissues.

Full Transcript

Etiology Of Periodontal Diseases

By/ Shaimaa Hamdy
 Introduction

Periodontal diseases are an inflammatory disorder in which
tissue damage occurs through complex interactions between
periodontal pathogens and components of the host
mechanisms
Periodontal diseases are a persistent polybacterial infection
causing chronic inflammation in periodontal tissues
Periodontitis is multi-factorial disease that cause tooth loss

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Definition:
Etiology:
The cause or origin of a disease or condition. In medical
contexts, it involves understanding the various factors
that contribute to the onset and progression of illnesses.
The term is derived from the Greek words "aitia," meaning
cause, and "logia," meaning study.

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Why etiology of periodontal diseases is needed to be well
understood ?

because of two major reasons:
First,
identification of etiological agents of periodontal diseases would
help in determination of suitable treatment strategies.
Second,
it would provide a useful therapeutic approach to control and
prevent periodontal diseases, e.g., manufacturing of vaccines.

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Etiology of periodontal disease

Initiating factor

Local predisposing factors

Systemic predisposing
factors

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 Initiating factor

Dental plaque (Biofilm(

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 Local predisposing factors

1. Calculus
2. Margins of Restorations
3. Malocclusion
4. Associated With Orthodontic Therapy
5. Habits.
6. Smokeless Tobacco
7. Iatrogenic Factors

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 Systemic predisposing factors

Identifying smoking and diabetes as the major potential risk factors

that can alter the staging of periodontal disease.

Recognition of “periodontitis as a manifestation of systemic disease”

such as Papillon Lefèvre Syndrome.

Systemic conditions affecting the periodontium when not related to

dental plaque will be considered as “Systemic Diseases or Conditions

Affecting the Periodontal Supporting Tissues”.
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 Initiating factor
bacterial dental plaque(Biofilm)
(periodontal microbiology)

Definition
Types of dental plaque (Biofilm)
Composition of dental biofilm
Formation of dental biofilm
Association of plaque bacteria with periodontal disease
Bacteria associated with periodontal health
Microorganism associated with specific periodontal diseases
The putative periodontal pathogens include
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 1. Dental plaque(Biofilm) definition:

Biofilm are defined as matrix enclosed bacterial population adherent to each

other and /or to tooth surface.

as the soft yellow –grayish, dense, non calcified microbial mass or deposits

that form the biofilm firmly adhering to the tooth surface or other hard

surfaces in the oral cavity , including removable and fixed restorations.

It resist to removed by rinsing or spray. It has to be mechanically removed.

Dental plaque is a host – associated biofilm.
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 Dental biofilm may be seen on the teeth after 1 to 2 days with
no oral hygiene.
During from 5 to 7 days if there is no hygiene of the oral cavity
the signs of the inflammation appear.
In any one individual, 1 gram of mature dental plaque may contain
around 2 × 1011 bacterial cells, belonging to 700 species
Dental plaque has to be differentiated from other deposits that
found on tooth surfaces such as : Materia alba ,dental pellicle ,
calculus.
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 Materia alba Dental plaque Calculus

White cheese like soft yellow -grayish Hard deposit that forms
accumulation deposits that form the by mineralization of
A soft accumulation of biofilm firmly adhering to dental plaque
salivary proteins ,some the tooth surface Generally covered by a
bacteria ,many desquamated Primarily composed of layer of un-minralized
epithelial cells ,and bacteria in a matrix of dental plaque
occasional disintegrating salivary glycoprotein's and
food debris extracellular polysaccharides
Lacks organized structure Impossible to remove by
and is therefore not as rinsing or the use of sprays
complex as dental plaque.
Easily displaced with a
water spray.

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2. Types and composition of dental biofilm

Based on its relationship to the gingival
margin, biofilm is differentiated into two
categories :
1. supragingival biofilm
2. subgingival biofilm

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 Types of dental
biofilm

Subgingival Supragingival
biofilm biofilm

attached unattached Coronal Marginal
biofilm biofilm biofilm biofilm

Tooth associated
Epithelium associated
Connective tissue associated
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 1- Supragingival biofilm
Types Supra-gingival biofilm

▪ Clinically detected by: ▪ it can be detected clinically only after it reached a certain thickness
after 1 to 2 days with no oral hygiene..small amount of plaque detected
by using Disclosing agent.

▪ Color ▪Grey to yellowish-grey
▪ Location ▪At or above the gingival margin

▪ Composition (matrix) ▪50% matrix
▪ Flora ▪Mostly gram positive
▪ Motile bacteria ▪Few
▪ Anaerobic/ aerobic ▪Aerobic unless thick

▪ Metabolism ▪Predominantly carbohydrates

✓ Types ✓Coronal plaque: only on tooth surface
✓Marginal plaque: which is associated with the tooth surface at the
gingival margin
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 1- Supragingival biofilm
It can be detected clinically only after it has reached a certain
thickness.
Small amounts of plaque can be visualized by using disclosing
agents.
The rate of formation and location of plaque vary among
individuals and is influenced by:
Diet.
Age.
Salivary secretion oral hygiene.
Tooth alignment.
systemic diseases and host factors.

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disclosing agents.

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 2- Subgingival biofilm
Types Subgingival biofilm

▪ Clinically detected by: ▪ Identified only by running the end of a probe around gingival
margin

▪ Color ▪ brown, black or green
▪ Location ▪ Within the gingival sulci or periodontal pocket
▪ Composition (matrix) ▪ Little or no matrix
▪ Flora ▪ mostly gram negative
▪ Motile bacteria ▪ Common
▪ Anaerobic/ aerobic ▪ Highly anaerobic

▪ Metabolism ▪ Predominantly proteins

✓ Types ✓ Unattached
✓ Attached(tooth associated, epithelium associated, connective
tissue associated)

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 2-Subgingival biofilm

It is usually thin,
contained within the gingival sulci or periodontal
pocket and thus CANNOT be detected by direct
observation.
Its presence can be identified only by running the end of
a probe around gingival margin

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 N.B Plaque can be assessed by

Direct vision
Supragingival biofilm
Using disclosing agents

Subgingival biofilm running the end of a probe around
gingival margin

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 3. COMPOSITION of dental biofilm

Dental plaque is mainly composed of microorganisms. The material present
between the bacteria in the dental plaque is called as intermicrobial matrix

1. Bacteria
I. Microorganisms 2. non-bacterial

1. Organic material
II. Intercellular
2. Inorganic material
matrix
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 I. Microorganisms

Bacterial:
There are approximately 700 distinct bacterial species
and 1 mg of dental plaque contains approximately 2 × 1011
bacteria.
Nonbacterial:
1. Mycoplasma
2. Yeasts
3. protozoa
4. viruses.
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 II. Intercellular matrix:

Accounts for 20% to 30% of the biofilm mass
Organic and inorganic materials
Derived from:
1. Saliva.
2. Gingival crevicular fluid.
3. Bacterial products.

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 Organic
components

Carbohydrates Proteins Lipids

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 4. Formation of dental biofilm
The biofilm formation is
divided into three phases:

1. Enamel Pellicle
formation

2. Initial Adhesion/Attachment
of Bacteria

3. Colonization and Biofilm
Maturation

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 Location and rate of plaque differ from one person to another depending on :
1. Oral hygiene
2. salivary composition and flow rate
3. diet.

1. Acquired Enamel Pellicle formation

❑ Acquired Enamel pellicle:
a homogenous, membranous, acellular film that covers the tooth surface and frequently
form the interface between the tooth & the dental biofilm.
❑ Derived from components of:
1. saliva and crevicular fluid
2. as well as bacterial and host tissue cell products
3. and food debris

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▪ the initial organic structure that forms on the surfaces of the teeth and
artificial prosthesis.
▪ The first stage in pellicle formation involves adsorption of salivary proteins to
apatite surfaces. The acquired enamel pellicle provides a substrate on which
bacteria can attach.
▪ The mechanism of selective adsorption includes electrostatic forces between
negatively charged hydroxyapatite and positively changed salivary
glycoproteins.
▪ The mean pellicle thickness varies from 100 nm at 2 hours to 500 to 1,000 nm.
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▪ The acquired enamel pellicle alters the charge and free energy of
the surface which in turn increases the efficiency of bacterial
adhesion (attachment).

Negative Salivary
Charged Phosphate macromolecules
group with opposite charged

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 2. Initial Adhesion/Attachment of
Bacteria
Phase 1: Transport to the Surface
Phase 2: Initial Adhesion
Phase 3: Strong Attachment

Phase 1: Transport to the Surface

Bacteria beginning to transport to enamel pellicle by:
1. Brownian motion
2. Sedimentation of microorganisms

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 Phase 2: Initial Adhesion

Reversible adhesion. During initial adherence, interactions occur mainly
between specific bacteria and the pellicle. They are:
1. Bacterial attachment via electrostatic
interaction
Oral bacteria bear an overall net negative charge,
negatively-charged components of the bacterial
surface and negatively-charged components of pellicle
become linked by cations such as calcium.

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 2. Bacterial attachment via
hydrophobic interaction

These interactions are based on the close structural
fit between molecules on the pellicle and bacterial
surfaces.

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 Phase 3: Strong Attachment

Strong irreversible phase
Adhesins
are protein in nature and have been identified on fimbriae of bacteria.
Fimbria are fibrous protein structure extending from bacterial cell surface.
Adhesins are able to bind to protein in acquired enamel pellicle so help in
bacterial adhesion.
Another mean of bacterial adhesion to the tooth surface is the formation of
extra-cellular polysaccharides produced by streptococci.

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Bacterial adhesion occur by:

1. Bacteria and pellicle
2. Bacteria and same species
3.Bacteria and different species
4.Bacteria and matrix

Then matrix formation occur

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 3. Colonization and Biofilm Maturation

Once the bacteria is adhered to the
pellicle, subsequent growth leads to
bacterial accumulation and increased
plaque mass. Dental plaque growth
depends on:
A.Growth via adhesion of new bacteria
B.Growth via multiplication of attached
bacteria
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 ❖ Colonization

Initial colonizers
Secondary colonizers
Plaque maturation

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 Initial colonizers
by predominantly Gram-positive facultative bacteria.
Streptococcus sanguis (Ss) is most dominant & Actinomyces viscosus (Av) are also
found in 24 h plaque. ( adhere to pellicle)

Initial Secondary Plaque maturation
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 Secondary colonizers

These bacteria are not able to initially colonize the tooth surface.
Secondary colonizers include Gram –ve anaerobic bacteria such
as:
Porphyromonas gingivalis,
Prevotella intermedia,
Fusobacterium nucleatum spp.
Campylobacter rectus.
Treponema denticola.
Tannerella forsythia.
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 They adhere to bacteria already adherent to the tooth by:

1. Coaggregation The ability of planktonic bacteria
(un attached) to adhere to one another.
The mechanism of coaggregation appears to be
mediated by specific receptor-adhesin interaction.
i.e. specific protein on the surface of one species
(adhesins) attach to specific carbohydrate on the
surface of the other (receptor).

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Well characterized interaction include the coaggregation of:
Fusobacterium nucleatum S. sanguis,
Prevotella loescheii A. viscosus
Capnocytophaga ochraceus A. viscosus

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 2. Co-adhesion
is the interaction between a sessile, already adhering organism and planktonic micro-
oganisms of a different strain or species

Some bacteria are unable to bind directly to the
conditioning film, but are able to interact with
molecules on bacteria that are already attached
(co-adhesion), also by adhesin-receptor
interactions.
One bacterium, Fusobacterium nucleatum, can
co-adhere with almost all other bacteria found in
dental plaque, and is considered to be a key bridging
organism between early and later colonizers.
 Plaque maturation.
As a result of ecologic changes, more Gram-negative strictly anaerobic
bacteria colonize secondarily and contribute to an increased pathogenicity
of the biofilm.

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 Streptococcus oralis
Primary colonizers
Streptococcus sanguinis

Actinomyces naeslundii

Actinomyces oris

Actinomyces viscosus

▪ Porphyromonas gingivalis
Secondary colonizers
▪ Treponema denticola

▪ Fusobacterium nucleatum spp.

▪ Aggregatibacter actinomycetemcomitans

▪ Prevotella intermedia

▪ Tannerella forsythia.

▪ Campylobacter rectus. 48
 Factors that influence complexity of plaque maturation
and ecology:

a) Oxygen levels:
With increasing thickness of dental plaque diffusion of oxygen into the
biofilm becomes more and more difficult so favor the growth of anaerobic
bacteria.
b) Nutritional sources:
Dietary products dissolved in saliva are an important source of nutrients for
bacteria in the supragingival plaque. Saccharolytic bacteria can ferment
sugar to provide energy for their growth and multiplication.

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 c) Interbacterial relation:

Beneficial interactions between bacteria may be in the form of:

1) One species provides growth conditions favorable to
another. Obligate aerobes utilize oxygen for growth so
provide suitable environment for growth of anaerobes.
2) One species facilitates attachment of another
resulting in the formation of different morphological
structures as corn-cobs.
3) One species provides growth factor utilized by other
species such as analogs of vitamin K.
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Antagonistic interactions between bacteria may be in the form of:
1) Competition for nutrients.
2) Competition for binding sites.
3) Production of substances by one species which limit growth of another
one: Streptococcus sanguis produces H2O2 which inhibits the growth of A.
actinomycetemcomitans

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 Clinical significance of plaque

Accumulation of plaque along the gingival margin leads to an
inflammatory reaction of the soft tissue.
The presence of this inflammation has a profound influence on local
ecology.
The availability of blood and gingival fluid components, associated
with inflammation, promotes the growth of Gram –ve bacterial
species. The bacteria breakdown these host molecules to amino acids
and utilize them for growth.
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 5. Association of plaque bacteria with
periodontal disease

It is clear that periodontal disease is associated with the presence of
dental plaque.
However, some individuals may show massive plaque accumulation
and signs of gingival inflammation (gingivitis) but never change into
periodontitis.
Based on these observations three theories have been proposed to
explain the association between periodontal diseases and bacteria in
dental plaque.

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 The three theories …..

(1)Specific theory
(2) Non-specific theory
(3)Unified theory: “Multiple pathogen or mixed infection
theory”

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 (1)Specific theory

It states that, not all plaque is pathogenic and its pathogenicity depends
on the presence of certain specific microbial pathogens in plaque.
This is based on the fact that, the specific microorganisms responsible for
periodontal diseases release certain damaging factors that mediates the
destruction of the host tissue.
treatment would be directed toward the elimination of the specific
pathogen from the mouth with appropriate narrow- spectrum antibiotic.
Thus plaque control would no long be necessary since plaque without the
specific pathogen would be non-pathogen.
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 2. Non-specific theory

▪ According to pure non-specific theory the inflammatory periodontal disease
develops when bacterial proliferation exceeds the threshold of host resistance,
the composition of plaque was not considered. i.e. there is a direct relation
between the total number of accumulated bacteria and the magnitude of tissue
destruction.
▪ If this was the case, why some patients have lifelong contained gingivitis
without developing periodontitis in spite of continuous plaque accumulation?
Based on bacteria quantity
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 3. Unified theory: “Multiple pathogen or mixed
infection theory”

It states that 6-12 bacterial species may be responsible for the majority of
destructive periodontal disease through synergistic interaction.

In acute necrotizing ulcerative gingivitis, synergy exists between spirochetes
and fusobacterium. Also, in chronic periodontitis, synergy exists between
fusobacterium nucleatum, Tannerella forsythus and campylobacter recuts

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 6. Bacteria associated with
periodontal health

Condition Micro-organism
Periodontal ▪ Gram +ve 90%: 1. S. sanguis,
health
2. S. mitis,
3. A. viscosus.
▪ Gram –ve 10%: 1. Prevotella intermedia,
2. fusobacterium nucleatum,
3. Capnocytophaga

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 7. Microorganism associated with specific
periodontal diseases
Gingivitis Gram +ve 50%: S. sanguis, A. viscosus.
Gram –ve 50%: P. intermedia, F. nucleatum.

periodontitis Gram –ve 75%, the anaerobes 90% Gram –ve anaerobes such as. Prevotella intermedia,. Porphyromonas gingivalis,. Fusobacterium nucleatum,. A. actinomycetemcomitans,.Tannerella forsythia. Spirochetes 30%

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Periodontal Fusobacterium nucleatum
abscesses
Prevotella intermedia
Tannerella forsythia
Porphyromonas gingivalis

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 Criteria For Defining Periodontal Pathogens

1. The microorganisms must be constantly present in every lesion of the
disease.
2. Elimination of the suspected organism should be eliminated or decreased
in sites where clinical resolution of disease with treatment has occurred.
3. Microbe should be able to demonstrate an altered host humoral or
cellular immune response.
4. Potential pathogens should be capable of producing virulence factors,
which cause destruction of the periodontal tissues.
5. Pathogens should be capable of causing the same disease in
experimental animal models
 8. The putative periodontal
pathogens include:
Aggrigatibacter actinomycetemcomitans (A.a)

Porphyromonus gingivalis

Tannerella forsythia

Spirochetes (Treponema denticola)

Prevotella intermedia
 Aggrigatibacter actinomycetemcomitans
(A.a)
It's a G-ve facultative anaerobe (microaerophilic) non-motile
coccoid bacillus. It correlates with periodontitis.
- It has several virulence factors;
- a) Leukotoxins, which kill or impair neutrophils & monocytes
function,
- b) Epitheliotoxins.
- c) Toxins affecting fibroblast function (Fibroblast cytotoxicity
factor).
- d) Capsule which resists phagocytosis & lysis by the
complement. 63
- e) They possess fimbriae (adhesion factor) & attach well to
oral surfaces.
- f) Lipopolysaccharide endotoxin which has a potent bone
resorbing activity & interfere with neutrophil function.
- g) Hydrolytic enzymes, & collagenase.
- h) May be tissue invasive, no fimbriated variants also may not
attach to granulocytes, thereby resisting phagocytosis &
allowing invasion of periodontal tissues.
- i) Epithelial cell destruction, affecting their integrity.

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 Porphyromonus gingivalis

It is a G-ve, anaerobic, non-motile assachrolytic short rods. It forms black-
brown colonies on blood agar. It's isolated from diseased mouth.
a) It produces numerous virulence factors or damaging toxins including;
collagenase, protease, fatty acids, ammonia, and H2S.
b) It forms membrane vesicles carrying with them the secreted proteases
(gingipain).
c) It has the ability to attach to epithelial cells, and invade soft tissues.
d) It has a carbohydrate capsule.
e) It forms the red complex with both (treponema denticola & tannerella
forsythia), that is highly associated with severe forms of periodontitis.

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Tannerella forsythia:

It's a G–ve anaerobic, spindle shaped pleomorphic rod, found in higher
numbers at sites of periodontitis rather than gingivitis.
It produces proteolytic enzymes that are able to destroy
immunoglobulins and complement components.
Spirochetes (Treponema denticola)
They are spiral, anaerobic motile microorganisms. In advanced periodontal
disease may constitute up to 47% of the observable bacteria in plaque.
It's associated with ANUG, periodontitis.
They produce potent hydrolytic enzymes, including collagenase,
proteases, & peptidase
T. denticola produce extracellular membrane vesicles, which have
hemagglutinating activity.
Spirochetes release destructive metabolic end products as ammonia &
H2S, which easily, permeates the tissues. 67
Prevotella intermedia:
G-ve anaerobic, black pigmented, short rod that can ferment both carbohydrates &
proteins.
It resists phagocytosis (probably by its capsule).
Its lipopolysaccharide (cell wall) contains unusual fatty acids having marked effects
on immune & bone cells. It also secretes toxins acting on epithelial cells.
It correlates with ANUG, periodontitis.
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