Residual Ridge Resorption (RRR) PDF

Summary

This document discusses residual ridge resorption (RRR), a chronic, progressive, and irreversible process of bone loss that occurs after tooth extraction. It details the structural elements of alveolar bone and the factors that influence resorption rates. It also covers different types of residual ridge configuration, the pathogenesis of RRR, and potential consequences, like reduced sulcus width and depth.

Full Transcript

Residual Ridge Resorption (RRR)
Lec. 4,5 ‫ غسق هشام‬.‫ د‬.‫م‬.‫ا‬

Alveolar bone : is bony portion of the maxilla or the mandible in which roots of
teeth are held by fiber of periodontal ligament.
Residual Ridge :- Is a term used to describe the shape of the alveolar ridge after
healing of bone and soft tissues following tooth extraction.

Post tooth extraction, many inflammatory reactions is immediately activated, and
the extraction socket is temporarily sealed by blood clotting. Epithelial tissues begin
its proliferation and migration within the first week and the disrupted tissue integrity
is quickly restored.

Histologic evidence of active bone formation in the bottom of the socket is seen
as early as 2 weeks after the extraction and the socket is progressively filled with
newly formed bone in bout 6 months, even after the healing of wounds, the residual
ridge alveolar bone undergoes a lifelong remodeling. The size of the residual ridge
is reduced most rapidly in the first six months, but the bone resorption activity of the
residual ridge continues throughout life at a slower rate, resulting in removal of a
large amount of jaw structure.

The rate of RESIDUAL RIDGE RESORPTION (RRR) is different among
persons and even at different times and sites in the same person. Residual ridge
remodeling affects the function of removable prostheses. Hence treatment of
edentulous patients requires a maintenance phase that must be carried out
throughout the life of a patient.
R.R.R. is chronic, progressive, irreversible and cumulative.

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Structural characteristics of alveolar bone:
Alveolar bone has two structural characteristics. A hard compact outer layer is
superimposed on a spongy somewhat resilient substructure. Beneath the compact
bone is the spongy bone. The spaces between the trabeculae communicate
throughout the spongy bone. Bone is constantly undergoing changes in response to
replacement and functional demands.
The structural elements of bone are:
A. Osteocytes: These are cells responsible for metabolic activity of bone.
B. intercellular substance or bone matrix consisting of fibrils or called
Calcified cementing substance Mineral salts namely calcium carbonate and
phosphates are bound to these protein substances.
C. Osteoblasts: the active bone forming cells, their function of forming and
calcifying the intercellular substance, and surround the bone in a continuous
layer. In the course of bone formation, some osteoblasts get engulfed in the
intercellular substance and become osteocytes.
D. Osteoclasts: Osteoclasts are the cellular components of bone that are
responsible for bone resorption. Bone resorption always requires the
simultaneous elimination of the organic and inorganic components of the
intercellular substance.

Pathology of RRR:
Actually, the basic change in RRR is a reduction in the size of the bony ridge under
the mucoperiosteum. It is primarily a localized of bone structure. Sometimes it may
leave the overlying mucoperiosteum excessive and redundant. There exists a wide
variety of shapes and sizes of residual ridges.

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They are categorized into common residual ridge configuration in a system of six
orders given by Atwood Order:
order 1
Pre-extraction: The lower central incisor is in its socket with very thin labial and lingual
cortical plates with the lamina dura.
order 2
Post-extraction: The healing period includes clot formation, clot organization, filling of
the socket to the height of the cortical plates with new trabecular bone, and
epithelization over the socket site.

order 3
High, Well-Rounded Residual Ridge: The cortical plates are rounded, narrowing of the
crest of the ridge has begun, and remodeling of the internal trabecular structure has taken
place.
order 4
Knife edged Residual Ridge: There is marked narrowing of the labiolingual
diameter of the crest of the ridge.
order 5
Low-Well Rounded Residual Ridge: The end result of progressive labiolingual
narrowing of a knife edged ridge is the disappearance of the knife edged portion. A more
widely rounded, but considerably lower residual ridge remains.
order 6
Depressed Residual Ridge: Resorption has continued below the level of the genial
tubercle.

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Pathogenesis of RRR:

Immediately following the extraction (order II), any sharp edges remaining are
rounded off by external osteoclastic resorption, leaving a high well rounded residual
ridge (order III). As resorption continues from the labial and lingual aspects, the
crest of the ridge becomes increasingly narrow ultimately becoming knife-edged
(order IV). As the process continues, the knife-edge becomes shorter and even
eventually disappears, leaving a low well rounded or flat ridge (order V). Eventually,
this too resorbs, leaving a depressed ridge (order VI). RRR is chronic, progressive,
irreversible and cumulative.

According to the American college of prosthodontists: Based on Bone Height
(Mandible only)

Type I : Residual bone height of 21 mm or greater measured at the least vertical
height of the mandible.

Type II : Residual bone height of 16 - 20 mm measured at least vertical height of
the mandible.

Type III : Residual alveolar bone height of 11 - 15 mm measured at the least vertical
height of the mandible.

Type IV : Residual vertical bone height of 10 mm or less measured at the least
vertical height of the mandible Direction of bone resorption.

Maxilla resorbs upward and inward to become progressively smaller because
of the direction and inclination of the roots of the teeth and the alveolar
process.
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 The opposite is true of the mandible, which inclines outward and becomes
progressively wider.

This progressive change of the edentulous mandible and maxilla makes many
patients appear prognathic.

Thus, RRR is centripetal in maxilla and centrifugal in mandible.

Patterns of bone resorption
✓ In the Mandible, large proportions of bone loss occurs in the
labial side of anterior residual ridge,
equally on the buccal and lingual side in premolar region and
lingually in the posterior or molar region.

✓ In the Maxilla bone loss primarily occurs on the labial or buccal aspect.

Therefore, while teeth arrangement we should try to restore the natural
position of the teeth before they were lost, Hence
Teeth in the maxillary arch are arranged slightly labially and buccally.
While in the mandible, teeth in the anterior region are arranged labially, on the
center of the ridge in the premolar region and slightly lingually in the molar region.

Maxilla V/s Mandible
 It is a clinically acknowledged fact that the anterior mandible resorbs 4 times
faster than the anterior maxilla.

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  Woelfel et al have cited the projected maxillary denture area to be 4.2 sq in
and 2.3 sq in for the mandible; which is in the ratio of 1.8:1.
 If a patient bites with a pressure of 50 lbs, this is calculated to be 12 lbs/sq in
under the maxillary denture and 21 lbs/sq under the mandibular denture.
 The significant difference in the two forces may be a causative factor to cause
a difference in the rates of resorption.
 Cancellous bone is ideally designed to absorb and dissipate the forces it is
subjected to.
 The maxillary residual ridge is often broader, flatter, and more cancellous than
the mandibular ridge.
 Trabeculae in maxilla are oriented parallel to the direction of compression
deformation, allowing for maximal resistance to deformation.
 The stronger these trabeculae are, the greater is the resistance

Consequences of Residual Ridge Resorption (RRR)
1- There is apparent loss of sulcus width and depth.
2- Muscle attachments are displaced closer to the crest of the residual ridge.
3- Due to loss of VDO lower face height is reduced and mandible is rotated
anteriorly.
4- Patient may develop habitual prognathic appearance. Inter-alveolar ridge
relationship is altered.
5- Morphological changes in residual ridge may appear such as sharp, spiny, uneven
residual ridges.
6- Resorption of the mandibular canal wall and exposure of the mandibular nerve.
7- Location of the mental foramina close to the top of the mandibular residual ridge.

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8- Residual ridge resorption provides serious problems to the clinician on how to
provide adequate support, stability and retention of the denture.

ETIOLOGY & FACTORS AFFECTING RESIDUAL RIDGE
RESORPTION (RRR).:
RRR is a multi-factorial, biomechanical disease that results from a combination
of anatomic, metabolic and mechanical determinants. These factors vary among
patients.
1) Anatomic Factors:
RRR Anatomic factors as amount of bone and quality of bone.

A- Amount of Bone:
Some large ridges resorb rapidly and some knife edge ridges may remain with
little changes for long periods of time. Although the broad ridge may have a greater
potential for bone loss, the rate of vertical bone loss may actually be slower than that
of a small ridge because there is more bone to be resorbed per unit of time and
because the rate of resorption also depends on the density of bone.

B- Quality of Bone:
The denser the bone, the slower the rate of resorption because there is more bone
to be resorbed per unit of time.

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 2) Metabolic factors:
RRR varies directly with certain systemic or localized bone resorptive factors and
inversely with certain bone factors formation.

General body metabolism is the net sum of all the building up (anabolism) and
the tearing down (catabolism) going on in the body. In equilibrium the two
antagonistic actions (of osteoblasts and osteoclasts) are in balance.
In growth, although resorption is constantly taking place in the remodeling of
bones as they grow increased osteoblastic activity more than makes up for the
bone destruction.
A..Hormonal Factors

1.Pituitary Glands and Hypophysis
2. Thyroid Glands
They are responsible for the regulation of the rate of metabolism. Hyperthyroidism
increases the metabolic rate leading to negative nitrogen balance. Such a balance is
equivalent to protein deficiency, which can be a direct cause of osteoporosis.
Thyroxin also has a direct influence on the kidneys, causing an increased excretion
of calcium and phosphorus. This depletion of calcium and phosphorus results in
decreased bone apposition and increased osteoclastic activity.
3.Parathyroid Glands
Parathormone maintains blood calcium by mobilizing it from the bones through
osteoclastic activity.
4.Islets of Langerhans
The failure of these glands to produce sufficient insulin for proper utilization of
glucose causes diabetes mellitus. The syndrome of poor healing, low tissue tolerance
and rapid resorption of bone is associated with the diabetic patient.
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5.Suprarenal Glands
The adrenal cortex produces steroid hormones called corticoids. The prolonged use
and administration of such steroids are considered very dangerous to bone tissue.
However, one of the beneficial effects of corticoids is to control the defense
mechanism of inflammation.
6. Gonads
In general, the sex hormone (androgens and estrogens) promotes a protein anabolic
action on all tissues including bone

B..Dietary Factors
Food is classified as proteins, carbohydrates, fats, vitamins and inorganic elements.

1.Protein
Protein is necessary to build and maintain tissue and to supply energy. The synthesis
of osteoid tissue in protein starved people is compromised and calcification is
decreased since the protein matrix is embarrassed..
Inadequate incorporation of protein in diet (3 ounces/ day) will cause slow growth
of bone. Bone apposition cannot keep up with normal osteoclastic activity and a
negative bone factor exists.
2.Vitamins
The action of vitamins in many respects is said to be same as that of hormones. The
relationship of vitamins and hormones can be explained on the basis that the
endocrine glands produce intrinsic hormones and the vitamins are extrinsic
hormones.
Vitamin A: A deficiency of vitamin A may result in poor development and
calcification of bone. Prolonged deficiency of vitamin A causes renal damage by
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hornification of tubules, which then lose the capacity to reabsorb phosphorus. The
imbalance of the calcium: phosphorus ratio leads to osteoporosis.

Vitamin B complex: are necessary for bone cell metabolism.

Vitamin C: Lack of vitamin causes decalcification of the bone and has been held
responsible for diffuse alveolar atrophy. The apposition of new bone slows down
dramatically because osteoblastic activity is impaired. The collagen content of bones
is also reduced in vitamin deficiency. The periosteum thickness and the cells appear
immature and resemble fibroblasts. This condition may make the periosteum easily
prone to injury by the denture base.

Vitamin D: It is necessary for the calcium phosphorus balance to remain within
tolerable limits. Vitamin D would be unnecessary if the exact required ratio of
calcium and phosphorus were available in the diet. When bone loses its ability to
calcify the matrix, administration of vitamin D will cause calcification and denser
bone. Moderate overdosage causes excessively mineralized bone, but gross
overdosage causes bone resorption.

3.Carbohydrates (Starch and Sugars)
They provide the chief source of energy. They are related only indirectly to bone
resorption through association with diabetes and by substitution for more favorable
foods.

4.Fats and Organic Substances
They are those, which yield heat and energy and only secondarily build/repair tissue.

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5.Inorganic Elements
Calcium salts (calcium carbonate and calcium phosphate)
form the rigid supporting structure of bones. Phosphorus in the form of calcium and
magnesium phosphate, gives hardness to bone. Abnormalities of the calcium
phosphorus elements of the blood stream may be associated with alveolar resorption
or rarefaction.
The body requires 0.7 gm of calcium/day, The phosphorus need is about1.5 to 3 gm
daily dependent upon the form.
Edentulous patients should follow a prescribed dietary regimen. The normal
equilibrium may be upset and pathologic bone loss may occur if either bone
resorption is increased or bone formation is decreased, or if both occur.
The thyroid hormone affects the rate of metabolism of cells in general and hence
the activity of both, the osteoblasts and osteoclasts.
Parathyroid hormone influences the excretion of phosphorous in the kidney and
also directly influences osteoclasts.
The degree of absorption of Ca, P and proteins determines the amount of building
blocks available for the growth and maintenance of bone.

Osteoporosis and residual ridge modeling:
The clinical and patho physiologic views of osteoporosis has been refined recently
to the concept of Type I and II osteoporosis.
▪ Type I osteoporosis is defined as the specific consequence of menopausal
estrogen deprivation, and characteristically presents the bone mass loss,
notably in the trabecular bone.
▪ Type II osteoporosis reflects a composite of age related changed in intestinal,
renal and hormonal function. Both cortical and trabecular bone are affected in
Type II osteoporosis.
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 3) Mechanical :

A. Functional Factors:
Functional factors include the frequency, intensity, duration and direction of forces
applied to bone which are translated into cellular activity, resulting in either bone
formation or bone resorption, depending upon on the patients’ individual resistance
to these forces.
Wolff’s law postulates that all changes in the function of bone are attended by
definite alterations in its internal structure. Forces within physiologic limits of bone
are beneficial in their massaging effect. On the other hand, increased or sustained
pressure, through its disturbance to the circulatory system, produces bone resorption.
The amount and frequency of stress and its distribution and direction are important
factors in treatment planning. Although the total amount of the necessary
masticatory stress cannot be diminished, increasing tissue coverage and decreasing
the length and width of the occlusal table may lessen the load/unit area.
The frequency of stress application modifies the reaction of alveolar bone to external
forces. Constant pressure on bone causes resorption, while intermittent forces favor
bone formation. Since recurrent forces over short intervals of time have essentially
the same resorbing effect as constant pressure, a rest period between meals is
beneficial. For this reason, the patient should be warned that gum chewing has a
destructive effect on the bone.
Bruxism is an expression of nervous tension, which manifests itself as gnashing,
grinding or clenching of the teeth while the patient is asleep or awake. Since most
denture patients do grind their teeth in sleep, the dentures should not be worn during
this period. Thus the supporting structures are afforded the rest period essential to
the maintenance of the alveolar bone. While grinding of the teeth when the patient

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is awake may be a habit of tension, it may also be caused due to lack of interocclusal
distance.
The principal concern should be in the pattern and position of the posterior teeth.
There are two mandibular movements associated with mastication: a closing/cutting
movement and a lateral or grinding movement. A sharp cusp will penetrate a bolus
of food with less force than a flat occlusal form. However, a law of physics explains
that forces applied to an inclined plane produce a resultant force or vector
perpendicular or right angles to the plane. Applying this principle to occlusal form,
the resultant force of the steep incline of high cusps would produce a lateral force,
which might cause alveolar resorption.
Stress distribution favorable to healthy alveolar bone maintenance is dependent
principally upon bilateral balanced occlusion. Balanced occlusion is that
arrangement of the teeth, which will permit the necessary mandibular movements
without tending to dislodge the denture or traumatize the supporting structure

B. Prosthetic Factors:
1- Excessive stress resulting from artificial environment
2- Abuse tissues from lack of rest.
3- Long continued use of ill-fitting denture.
4- Lack of freeway space due to increase vertical dimension of occlusion
5- In correct centric relation record.

These prosthetic factors include
broad-area coverage (to reduce the force per unit area);
decreased number of dental units,
decreased bucco-lingual width of teeth,

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 and improved tooth form (to decrease the amount of force required to
penetrate a bolus of food);
avoidance of inclined planes (to minimize dislodgement of dentures and shear
forces);
centralization of occlusal contacts (to increase stability of dentures and to
maximize compressive forces);
provision of adequate tongue room (to increase stability of denture in speech
and mastication);
adequate inter-occlusal distance during rest jaw relation (to decrease the
frequency and duration of tooth contacts).

TREATMENT AND PREVENTION OF RRR
The best way to manage the problem of residual ridge resorption is by using every
means to prevent it.
A- prevention of loss of natural teeth.

Clinicians must try to retain residual roots whenever feasible.
B- proper design of dentures and maintenance.

1- Optimal tissue health prior to making impression.
2- Impression procedures.
▪ Minimal pressure impression technique.
▪ Selective pressure impression technique places stress on those areas
that
▪ best resist functional force.
▪ Adequate relief on non- stress bearing areas..

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3- During Teeth Arrangement
o Avoidance of inclined planes to minimize dislodgement of dentures and
shear forces.
o Centralization of occlusal contacts to increase stability
o Occlusal table should be narrow.
o Provision of adequate tongue room to improve stability of.denture in
speech and mastication.
o Adequate interocclusal distance during jaw rest to decrease
the.frequency and duration of tooth contact.
o Broad area of coverage helps in reducing the force /unit area( Snow
Shoe Effect ) increased denture bearing area can greatly reduce the load
per unit area on the underlying mucosa and improve denture comfort,
always assuming that the OVD is not excessive
o
C. Nutrition.
It has been seen that one of the cofactor in RRR is low calcium and vitamin
D metabolism. Diet counseling for prosthodontic patients is necessary.
Denture patients with excessive RRR report lower calcium intake and poorer
calcium phosphorus ratio, along with less vitamin D.

D. Pre Prosthetic Surgery
Excessive RRR leads to loss of sulcus width and depth with displacement
of muscle attachment more to the crest of residual ridge.
Osseous reconstruction surgeries, removal of high frenal attachments,
augmentation procedures(bone graft) Vestibuloplasty –etc.

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 E. Immediate Denture.
Some authors claim that extraction followed by immediate dentures reduces
the ridge resorption.

F. Over Denture
Help to minimize ridge resorption and contribute to enhanced retention, stability and
support of prosthesis along with preservation of proprioception.
A study was conducted with overdentures supported by canines and it seen that, the
bone loss was 0.6mm where as 5mm in conventional complete dentures.

G- Implants.

The introduction of dental implants has revolutionized clinical practice. Use of
implants for providing implant supported or implant assisted prosthesis also helps
avert continuing residual ridge resorption.

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