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For a better understanding of complete maxillary retention and stability
Abstract
Aims of this paper
1.0 Introduction
2.0 Retentions:
2.1 What is retention?
2.2 Physiological retentions
2.2.1 Border seal
2.2.2 Accuracy of fit
2.3 Anatomical retentions
2.3.1 Bony undercut
2.3.2 Oral musculature
3.0 Stability
3.1 What is stability?
3.2 Some Stability Factors
3.2.1 Base shape and fitting surface
3.2.2 Tooth position
3.2.3 Polished surface
3.2.4 Occlusal surface
4.0 Saliva
4.1 Adhesion
4.2 Cohesion
4.3 Surface tension
4.4 Viscosity
4.5 Professional attitude towards Denture adhesion
1
4.6 Patient Education
5.0 Postpalatal seal
5.1 What is Postpalatal Seal?
5.2 Objectives
6.0 Ill-fitting of the maxillary denture
6.1 Problems with the denture
6.1.1 Impression surface
6.1.2 Polished surface
6.1.3 Occlusal surface
6.2 Problems with the denture wearers
6.2.1 Poor neuromuscular control
6.2.2 Unstable foundation
6.2.3 Inadequate saliva
7.0 Conclusion
8.0 References
2
Abstract:
A successfully functioning maxillary and mandibular denture relies on the amalgamation
of the patients’ general oral functions and the psychological acceptance of their denture.
The aforementioned are dependant largely on the patients’ denture stability during
mastication and general day-to-day oral functions in combination with the aesthetic affect
on the patients’ facial appearance. Some edentulous people face functional problems with
their complete maxillary dentures. Several factors contribute to this failure especially when
it comes to the function of speech and mastication. Therefore it is imperative that during
production of the denture to include features into its design that aid in improving retention
and overall stability of the denture. Knowledge and implementation of techniques that take
advantage of key physiological, anatomical and psychological factors will aid clinicians
and technicians to create a maxillary denture with good retention and stability, giving the
patient a functional and usable appliance. In addition, patient education and professional
attitude will play an important role in achieving the goal of a successful prosthetic
appliance. The aim of this paper is to aid the practitioner in comprehending which
elements and factors are pertinent to a complete maxillary denture’s retention and stability.
Border seal, accuracy of fit, bony undercut, oral musculature, base shape, fitting surface,
tooth position, polished surface, occlusal surface, saliva, adhesion, viscosity, surface
tension, cohesion, professional attitude towards denture adhesion, patient education, post-
palatal problems with denture, and problems with denture wearers have all been considered
to have a strong relationship with retention and stability of the complete maxillary denture.
3
Aims:
The aims of this paper are :
1 -To provide the practitioner with key characteristics that is involved in creating a
complete maxillary denture with ideal retention and stability.
2 -To aid and influence the complete maxillary denture’s efficiency by understanding and
implementing factors that amplify retention and stability.
3 -To explain the probable causes of ill-fitting dentures and to make suggestions on its
administration.
4
1. Introduction:
Although the use of dental implants is expanding, the preferred method of treating
edentulous patients is still with the conventional complete denture (Celebic et la. 2003).
People who wear complete maxillary and mandibular dentures will have anticipations in
relation to mastication, aesthetics and confidence. Edentulous people, that use complete
dentures, will have to learn the required oral motor skills to make sure that they can utilise
the prostheses during common functional movements such as speech and mastication (Zarb
et al. 1997). Many of these patients may incur problems during functional movements
while wearing complete dentures (Garrett et al. 1996). It remains an enigma why some
patients are capable of controlling their complete dentures more efficiently than others,
even when the alveolar ridge morphology seems compromised (Scott and Hunter 2008).
Moreover, many practitioners have treated patients who posses well designed and
manufactured dentures, however some of these patients struggle to function with these
appliances, on the other hand there are patients who function sufficiently with prostheses
that have large amounts of damage and are supported by an inferior base. The
aforementioned features stress the importance of understanding and implementing factors
that affect retention and the stability of complete dentures. This paper will focus on five
main factors that contribute to the retention and stability of complete maxillary dentures.
First, the concept of retention, which is defined as 'the quality inherent in the prosthesis
acting to resist the forces of dislodgment along the path of placement' (Driscoll et al. 2004,
p. 567). Retention can be divided into two categories physiological retention, which
includes border seal and accuracy of fit, and anatomical retention which includes bony
undercuts and oral musculature. Second, stability which may defined as the quality of a
denture to be fixed, stable, or strict, to resist displacement by functional horizontal or
rotational pressures (Van Blarcom, 1999). Four stability factors are covered in detail which
5
are; base shape and fitting surface, tooth position, polished surface and occlusal surface.
Third, saliva which is considered to be the most important factor of complete maxillary
denture retention (Husham, 2006) has been divided into six components; adhesion,
cohesion, surface tension, viscosity, professional attitude towards denture adhesion and
patients’ education. Fourth, the post-palatal seal has a crucial effect on the retention of the
complete upper denture (Tsirmbas and Vlissidis, 1989) thus its objectives will be
mentioned. Fifth, the problems and reasons that cause ill-fitting dentures will be explained.
It is divided into two main areas which are problems with dentures and issues with denture
wearers. Fifth, the problems and reasons that cause ill-fitting dentures will be explained. It
is divided into two main areas which are problems with dentures and issues with denture
wearers.
6
2.0 Retentions:
2.1 What is retention?
Definitions of the complete denture retention is a ‘resistance of a denture to vertical
movement away from tissues’ as well as ‘that quality inherent in the prosthesis acting to
resist the forces of dislodgement along the path of insertion’ (Darvell and Clark 2000, p.
248) and ‘any movement in the vertical plane’ (Rendell et al. 1995, p. 344). It is therefore
obvious that retention is a feature that belongs to the denture more than to the patient
(Darvell and Clark 2000). When the denture is inserted in the patient’s mouth, it should
usually stay in place while the mouth is open. The maxillary complete denture ought to
provide resistance when pulled in a downward direction by a finger and thumb gripping the
incisors (Basker and Davenport 2002).
2.2 Physiological retentions
2.2.1 Border seal
For supreme retention, the denture border must be formed so that the channel between the
sulcus tissues and the denture is as minute as possible (Basker and Davenport, 2002).
Because the depth of the sulcus differs during function, it is not difficult to keep a close
approximation between the denture border and the reflection of the mucosa in the sulcus at
all times. The construction of the denture has to be done so that the border follows the most
superficial point that the sulcus reflection can reach in ordinary functions. This signifies
that the denture will be moderately under-extended for some of the time while the patient
is at rest. If an extended procedure is done on the denture to provide a tight seal in this
spot, displacement may happen during the functional movement of the sulcus tissues. The
problem of having a stable border seal can be solved by laterally extending the denture
7
flanges so that the buccal and labial mucosa are contacted and marginally displaced by the
flanges to create a facial seal (see Figure 1.1 below).
Figure 1.1 lateral lengthening of the buccal flange to provide a facial seal (Basker and
Davenport, 2002).
The facial seal along the posterior border of the maxillary denture can be possibly
produced as it crosses the palate. In this spot, another approach is to produce as narrow
space as possible between the denture and mucosa. A post-dam is done on the working cast
so that there is a raised lip at the posterior border of the accomplished denture that becomes
embedded into the palatal mucosa (Basker and Davenport, 2002).
There is a double contact of acrylic and soft tissue in the majority of the denture border
such that displacing the denture in the sense of separation does not open a space along that
border. There are two results from this. Firstly, the cross section that saliva should fill in is
small, whereas the displacement viscous retardation is great. Secondly, the lowered
8
pressure under the denture, which is caused by displacement, is likely to embrace the
buccal tissues in place in close estimation.
2.2.2 Accuracy of fit
It has been recommended that when a denture is positioned in place a solid seating, force
be engaged as this helps retention (Darvell and Clark 2000).The forces of retention are
increased when the saliva film between the denture and underlying mucosa become
thinner (Basker and Davenport 2002). The thinnest possible saliva film and viscosity will
act to prevent displacement of the denture. Nevertheless, this should also be accomplished
with the sacrifice of some displacement of the sustaining soft tissue, and if this provides a
superior fit, it will not remain long as that tissue elastically rebounded (Darvell and Clark
2000). Therefore, achieving the best possible an accurate fit of the denture is a very
important aspect.
An inadequate fitting of the denture will increase the density of the saliva film and develop
air bubbles within the film. The action of these bubbles is to minimize the retention of the
denture. Moreover, the expansion of the air bubbles and their extension to the border area
might cause a breaking of the border seal when the pressure of the saliva film drops due to
displacing forces affecting the denture (Basker and Davenport 2002). The endurance
secretion from mucosal glands will also offset any instant advantage. It might, however, be
helpful for the intentional seating force to exclude air that causes problems in retention
(Davell and Clark 2000).
9
2.3 Anatomical retentions
2.3.1 Bony undercut
The pliability of the mucosa and submucosa covering the basal bone creates some
moderate undercuts that will improve retention (Zarb and Bolender 2004). The retention
could be modified by supplying a prosthesis that uses these undercut spots. To be able to
accomplish this without any problem on the mucosa on placement and stripping of the
prosthesis, extensive consideration is needed in designing the path of insertion (Basker and
Davenport 2002). In spite of overstated bony undercuts or less obvious ones overlaid by
fine epithelium, they might compromise the retention of the denture by requiring broad
internal modifying of the denture, less austere lateral tuberosities undercuts, premolar
spots of the maxillary denture areas can be excessively useful for the retention of the
dentures.
Few “undercuts” are simply undercuts regarding the path of insertion (Zarb and Bolender
2004). Even if the undercuts region is firstly placed and the reminder of the denture base
can be carried into closeness with the basal seat on rotation of the denture about the
undercut piece that previously placed, this “rotational path” will create vertical
displacement resistance. An obvious or equal undercut anterior alveolus might determine a
path of insertion that starts with placing the anterior in a posterior position and finish with
rotation of the posterior border behind of the tuberosities. This concept has increased
significantly as other retentive methods fail in power. For example, with a patient who has
gone through waste of ordinary anatomical contours caused by tumour resection or trauma,
surgically provided undercuts might imply the dissimilarity between denture triumph and
failure (Zarb and Bolender 2004).
10
2.3.2 Oral musculature
Dentures have been worn by patients successfully, because they have learned to grasp their
dentures with the muscles in their lips, cheeks and tongue. This ability may progress to a
high level so that the denture which looks loose to the dentist may be quite acceptable in
the patient’s opinion. In some cases, patients can eat without any problems even when the
prosthesis has shattered into two or more pieces (Basker and Davenport 2002).
Studies reveal that complete dentures change a few millimetres regarding the underlying
structure through mastication (Basker and Davenport 2002). As a result, during chewing,
loose physical retention commonly occurs; therefore, muscular control is essential. The
proficient muscular control of the prosthesis is based on two elements. First, the denture
shape and design and the muscles of the oral cavity (lips, cheeks and tongue) manage the
bolus of food, move it around the oral cavity and put it between the teeth’s occlusal
surfaces. In this way, the muscles press on the polished surfaces of the prosthesis. If these
surfaces have been designed correctly, this muscular force will place the dentures on the
underlying mucosa (see Figure 1.3). Besides this working muscular fixation of the dentures
during mastication, there is a definite amount of passive fixation in the rest of the muscles,
as the relaxed soft tissue is placed on the dentures; thus, they can be maintained in position.
In contrast, an inaccurately designed prosthesis causes displacement of the denture by the
force of the muscles.
The second element in the proficient muscular control of the prosthesis is the required skill
that patients need, that is, the ability of the patients to attain the required abilities to
manage new dentures, which is referred to as the biological age. Overall, as the patient gets
older, the learning phase becomes longer. In severe cases, dentures that are technically
perfect will not fit elderly or senile patients who cannot attain this skill. For this purpose,
11
denture replacement for an older patient must be performed in such a way that the skill of
the patient in managing the preceding denture designs can be directly moved to the
replacements. This is accomplished by duplicating the old prosthesis as closely as possible.
When a patient incises, it is a particular instance of the muscular control of the prosthesis.
The posterior border is fell down because of the forces that tend to tip the maxillary
denture. This action is usually resisted by the dorsum of the tongue which pushes against
the denture and replaces it (see Figure 1.4). Patients who suffer from obstacles when
incising with dentures which look to be perfect must be inspected with caution to
determine whether or not the control of the tongue exists. If it does not, the dentist must
explain the problem to the patient and provide suitable training. This takes the form of
teaching the main role of the tongue, lips and cheeks in managing the prosthesis and giving
particular advice, such as sustaining the posterior border of the maxillary denture with the
tongue during functioning. The capability of the patient to manage the dentures, which will
reduce the displacement forces, can be attained by giving advice; for instance, before
inserting the food into the mouth, it should be cut into small pieces, ground on both sides
of the denture, and always begin with softer foods before moving on to bigger morsels.
Without the patient’s awareness of muscular action, the replacement prosthesis will not
address the patient’s complaint.
Muscular control takes a long time to master when the denture is first fitted, which mostly
causes ill fitting dentures. Therefore, the physical forces of retention are especially
essential during this primary learning period. When these forces become stronger, the
patient will need little effort in controlling the dentures. On the other hand, if the physical
forces are poor, the dentures will be loose so that the patient will refuse to wear them
(Basker and Davenport 2002).
12
Figure 1.3 Influence of soft tissue forces on dentures: (a) seating the dentures when the
polished surfaces are correctly shaped, (b) displacing the dentures when the polished
surfaces are incorrectly shaped (Basker and Davenport 2002).
Figure 1.4 as the patient incises, the upper denture is controlled by the tongue pressing
against the posterior border (Basker and Davenport 2002).
13
3.0 Stability
3.1 What is stability?
Denture stability is the minimum movement occurring in relation to the underlying bone
throughout function. It is amazing that dentures remain seated in place at all, as they are
surrounded by a very active muscular medium. They remain in place if the retention forces
being applied on the dentures are more than the displacing forces and when adequate
support has been provided to the denture. This support is decided on by the shape and
consistency of the denture bearing tissue and the precision of fit of the denture (Basker and
Davenport 2002).
Specifically, denture stability has been defined as ‘the resistance of a denture to
displacement by functional forces’ (Ogden 1996, p. 71). According to this statement, the
denture has been made in function. The definition of denture support is the denture
resistance of the directed occlusal loads. When the patient who has no teeth at all
(edentulous case), the support is achieved from the soft tissue of the denture-bearing spot
and the underlying bone. Functional stability can be affected by one or more of these
factors. For instance, an effective border seal may cause a good denture retainer. However,
when there is an anterior fibrous maxillary ridge, the denture retainer may simply be
compromised on occlusal loading during masticatory function, because the post-dam seal
might break if a tipping force is applied to the denture. As a result, the following factors
are essential when attempting to achieve complete dentures that are stable in function
(Scott and Hunter 2008). These factors have been summarized in Figure 3.1 (Basker and
Davenport 2002).
14
Figure 3.1 Relationship of factors contributing to denture stability ((Basker and Davenport
2002).
3.2 Some Stability Factors
3.2.1 Base shape and fitting surface
The denture fitting surface is that part which directly contacts the tissues of the denture-
bearing spot. The periphery of the denture may be affected due to the design of the base
which is impacted by the soft tissue attachments (Scott and Hunter 2008). Consequently,
these objectives should be attained by the master impression. In order to record fine details
of the surface, adequate impression materials should be used. The master cast’s
impression trays must be ideally lengthened over the entire of the denture-bearing area.
The significant tissue features of the maxillary denture-bearing area are: labial fraenum,
root of zygomatic arch, buccinators, and hamular notch, vibrating line, palatal rugae,
incisive papilla and remnant of palatal gingival vestige (Scott and Hunter 2008). The shape
of the border may be affected by a number of muscle attachments and these must be
permitted for when the particular trays are evaluated in the mouth. The critical part for
denture retention is the posterior border of the maxillary denture, and the shape of a post-
dam is included. The posterior border of the denture must be lengthened to the vibrating
line (Scott and Hunter 2008). This line is defined as ‘the line of junction between the
moving tissues of the soft palate and the static tissues anterior to them’ (Ogden 1996, p.
71). An inadequate posterior seal often results when the posterior border reclines short of
the vibrating line. It can be broken if it extends beyond the vibrating line when the soft
palate lifts during mastication. Because of that, the vibrating line, known as the ‘ah-line’,
15
must be inspected with caution, and the clinician must be convinced that it has been
accurately prepared on the master cast (Scott and Hunter 2008).
The maxillary complete denture retention might be influenced by a number of elements
related to the fitting surface. It might not be easy to extend the denture base ideally due to
the problem of gagging that occurs with some patients. This usually affects the posterior
seal (Lamb 1993). Examining the overextension of the maxillary denture is easy. If the
denture is expelled by drawing the modiolus downwards and forwards, a lengthening is
determined over the insertion of the buccinator into the maxilla. Drawing the modiolus
downwards and backwards will check for an extension of the labial flange over the
insertion of the muscles of the upper lip. During the time when the minor slips of the
orbicularis oris are inserted into the maxilla and defined, the depth of the anterior sulcus
can be examined by pulling the upper lip down manually, which might be simpler to
permit the patient to perform the movements themselves. Any displacement of the denture
should be examined, which happens when the patient contracts their lips and protrudes
them in a pouting action. If an overextension is detected, the denture is laid over the
suitable muscle. This is done slowly, and the patient is asked about the level of
improvement to ensure that maximum stable extension is retained (Lamb 1993).
3.2.2 Tooth position
The accurate positioning of the artificial teeth is crucial for accomplishing stability in
mastication. Any unsuitable arrangement of the teeth of the denture can cause the
prosthesis being displaced simply throughout function. Some elements that are essential in
achieving greatest stability by accurate positioning of the teeth are explained in Table 1
(Scott and Hunter 2008).
16
To achieve a maximum effective role of the tongue, the occlusal planes of the prostheses
must be arranged at a suitable degree (Devlin and Hoad-Reddick 2001). The sitting of the
maxillary occlusal planes is often carried out by alteration of an occlusal rim so that a
suitable amount of tooth is observed and the occlusal plane inclination is parallel with the
inter-papillary and ala-tragal planes (Scott and Hunter 2008).
17
Elements to studyStability points
Degree of occlusal planes regarding
anatomical spots; for example, vermillion
border of the lip.
Occlusal vertical dimension and freeway
space
Suitable degree of occlusal table for
effective function of the tongue.
Teeth sitting in away that will accord
with the function of the muscle.
Neutral zone
Suitable positioning of teeth to prevent
denture displacement throughout
mastication function.
Sitting the mandibular teeth regarding the
underlying ridge.
Posterior shelf of the prosthesis
Suitable positioning of teeth to permit the
tongue to stabilize the mandibular
denture.
Table 1 The ideal points to study for ensuring greatest stability through elements related to
the tooth sitting and the complete dentures occlusal surfaces (Scott and Hunter 2008).
18
3.2.3 Polished surface
The polished surface of the prosthesis stretches from the borders of the base to the
synthetic teeth (Scott and Hunter 2008). This surface contains the form of the plate as fine
as the buccal and lingual surfaces of the acrylic in touch with the tongue, lips and cheeks
(Basker and Davenport 2002). Because of this, these pieces of dentures must be formed in
a suitable way to permit the function of the muscles to accord with the prosthesis form.
Regions of the polished surface form might affect dissimilar actions, for instance, the
palatal vault of the upper prosthesis regarding speech (Scott and Hunter 2008).
The expression “neutral zone” is an area between the tongue on one side and the cheeks
and the lips on the other where the muscular displacing forces playing on a denture are the
least. This is also known as the zone of minimal conflict (Basker and Davenport 2002) and
is usually used to illustrate the positioning of the synthetic teeth in a place in which
stability is obtained. This can often be accomplished by the clinician and technician
following the mentioned outlines. Nevertheless, in some stages, it might be required to
register an impression of the zone to permit maximum arrangement of the synthetic teeth
and the accurate forming of the polished surfaces (Gahan and Walmsley 2005). This can be
obtained by fabricating a solid denture base with occlusal stops placed at the accurate
vertical dimension. A tissue conditioner is an appropriate material to register a functional
impression that will show the dimension of the neutral zone. The denture teeth are now
formed and placed to accord with this, and the polished surfaces are also formed so that
they rest within this described zone. The resulting teeth might well be very thin; however,
as they are sited in a maximum location for stability, the patient might be able to manage
the prosthesis throughout function more efficiently (Scott and Hunter 2008).
19
Uncommonly, instability of the maxillary denture is due to the coronoid process touching
an enormously thick buccal flange throughout opening. Suffering on opening is a common
symptom, but might be covered by a destabilizing intervention which can be the main
complaint (Lamb, 1993). The muscles of the cheeks, lips and tongue, along with being of
basic significance in the retention of dentures, are also able to cause instability to the
dentures. Displacement will happen if the polished surfaces have an adverse slope (see
Figure 3.2) and also if the prosthesis intervenes with the normal position and functional
action of the surrounding musculature. For instance, distal movement of a lower prosthesis
might be created too far labially. The teeth must therefore be sited distant enough lingually
to avoid this displacement, but not so far away as to permit excessive tongue pressure
(Basker and Davenport 2002).
Figure 3.2 Pressure from the bolus on the posterior part of the lower occlusal table, which
overlies a sloping part of the ridge, causes the lower denture to slide forwards ( Basker and
Davenport 2002).
20
3.2.4 Occlusal surface
The occlusal surface of the denture is the portion that creates touch with the similar surface
of the other prosthesis (Basker and Davenport 2002). For ideal function, the prosthesis
must be fabricated at the accurate vertical dimension, making certain that a suitable
freeway space is obtained. The vertical dimension of the dentures in occlusion is reliant on
how the synthetic teeth are placed and, subsequently, the degree of the occlusal plane on
both dentures is related to this (Scott and Hunter 2008).
All occlusal deficiency must be rectified at an earlier phase, if a check register or amount
procedure has been carried out. Nonetheless, when patients have dentures on for the first
time or after an extended period of wearing an imperfect denture, their normal jaw
relationships may still be efficient. It can then be discussed that it is more complete to
leave the check record until the recall phase when the faulty reflexes have had the chance
of being missing when the occlusal error can then disclose itself in a compliant of
looseness that is removed after the check register. It can also be discussed that when
putting dentures on a denture-bearing area that reveals areas of erythema caused by
previous ill-fitting dentures, few resolutions of inflammation might exist during the post-
insertion stage. Here, too, the alterations in the denture-bearing areas may reveal
previously unnoticed occlusal imperfections and looseness, which may be rectified by a
check record at the recall phase (Lamb 1993).
In the exact way as at the insertion stage, occlusal modification can occasionally be made
in the mouth. If an early contact exists, the symptom will be tipping of the prosthesis.
Premature contacts can be determined with articulating paper. Unless the premature
21
contact is great, which at this phase is improbable, a deepening of opposing fossa is the
treatment required (Lamb 1993).
4.0 Saliva
Saliva has four fundamental properties which are adhesion, cohesion, surface tension and
viscosity (Escoe and Escoe 2008). These elements are fundamental to the oral health of
denture wearers. Saliva is essential for the retention of the complete standard denture.
Saliva should adhere to the denture surface. The film of saliva between the mucosa and the
denture must be greatly cohesive and, as a result, tough to break. The denture’s outer
surface where it joins the mucosa is wet with saliva. Because of surface tension, this outer
common layer of saliva should be difficult to break. The viscosity of saliva is required so
that it flows with difficulty during the displacement of denture. In fact, a whole industry of
denture adhesives is based on augmenting the physical saliva attributes in the retention of
denture (Escoe and Escoe 2008).
4.1 Adhesion
Adhesion is described as the physical attraction of dissimilar molecules to each other
(Basker and Davenport 2002). The saliva adhesion to the mucous membrane and the base
of the denture is obtained through the ionic forces between charged salivary glycoproteins
and surface epithelium or acrylic resin. Adhesion works to further improve the retentive
force of interfacial surface tension through its promoting contact of saliva to both the oral
tissue and the denture base. Adhesion that is shown between denture bases and the mucous
membranes themselves is considered to be another version. The material of the denture
base seems to cohere to the dry mucous membrane of the basal seat and other oral surfaces.
22
Similarly, adhesion is not that efficient for retaining dentures and predisposes to mucosal
abrasions and ulceration because of the deficiency of the salivary lubrication. It is irritating
for patients to experience denture bases sticking to the cheeks, lips and tongue. Ethanol-
free rinsing consisting of aloe or lanolin, a water-soluble lubricating jelly or saliva
substitute consisting of carboxymethylcelluose (CMC) or mammalian mucin can be helpful
in this condition. For patients who have a dry mouth because of irradiation or an
autoimmune disorder, a salivary encourager through a prescription of 5 to 10 mg of oral
pilcarpine three times daily can be very useful if the patient can bear the possible
contraindication effect of increased perspiration and, sometimes, excess lacrimation (Zarb
and Bolender 2004).
The retention amount given by adhesion is proportionate to the area covered by the
denture. Lower jaw dentures cover less surface area than upper dentures; therefore,
adhesive and other retentive forces are of less concern. Likewise, for some patients with
small jaws or very flat alveolar ridges, or small basal seats , retention may not be as
significant as in patients with a large jaw or obvious alveoli. Therefore, the dentures must
be lengthened to the limits of the health and function of the tissues in the oral cavity, and
efforts must be made at all times to maintain the alveolar height to maximize retention
(Zarb and Bolender 2004).
4.2 Cohesion
Cohesion is the physical attraction between similar molecules for each other (Basker and
Davenport 2002). It is considered to be a retentive force due to its occurrence within the
layer of fluid, mostly saliva that exists between the denture base and the mucosa, and
23
works to keep the integrity of the interposed fluid. Cohesiveness is not the main character
of normal saliva so that most of the retentive force of the denture-mucousa interface is
obtained from adhesive and interfacial factors (Zarb and Bolender 2004).
4.3 Surface tension
Surface tension is another important factor in maxillary complete denture retention. It is an
interfacial force that resists division between two parallel surfaces which is conveyed by a
thin layer of liquid between them (Zarb and Bolender 2004). Viscous tension is important
regarding interfacial surface tension. The outcome from a film of liquid between any
parallel planes of hard materials is called surface tension. It is the capability of a thin layer
of the fluid to “wet” the hard surrounding material. With a substance that has a low surface
tension, such as oral mucosa, the fluid will increase its contact with the substance surface,
thus wetting it quickly and extending in a thin film. On the other hand, with material that
has a high surface tension, fluid will reduce its contact area with the material which leads
to creating beads on the material’s surface.
The surface tension of the denture base materials (also termed wettability) is varied. The
surface tension of all denture base materials is higher than oral mucosa; however, their
surface tension is reduced when coated by salivary pellicle which allows maximizing the
contact area between the denture base and the liquid. The thin layer of liquid between the
denture and the mucosa of the basal seat provides a retentive power by the disposition of
the liquid to increase its contact with both surfaces (Zarb and Bolender 2004).
One of the outcomes of the surface tension of fluids is the tendency to reduce the zone of
the free surface, producing the recognized curved surface of a raindrop and menisci
24
(Darvell and Clark 2000). The curved surface provides a pressure difference over that
surface. The pressure is higher within the drop than without if the surface is convex, which
is described as positive pressure. In contrast, the pressure is negative if the total curvature
is negative. The essential essence is that negative pressure applies a force willing to pull
the fingertips together. This is the power that keeps two wet microscope slides together to
resist a straight draw (not a slipping move). A very thin film of water is at the edge, with a
great negative curvature, because the division of the slides is small; thus, the force is huge.
As a result, trying to pull the denture which is wetted by saliva creates a fine, highly
negatively-curved saliva surface along its boundary. Consequently, a retentive force and
reduced pressure in the liquid filled space is tested (Darvell and Clark 2000). The pressure
within the liquid film surrounded by a meniscus is smaller than the pressure of the
enclosing medium, and the difference of this pressure supplies a retentive force. The
significance of this power has been measured for parallel planes unconnected by a film of
saliva, and it has been recommended that the retention of complete dentures can be
maintained by this force (Barbenel 1971). This power is dependent on the denture base
wettability by saliva, which is considered to be a factor of significance (Darvell and Clark
2000).
Capillary attraction, or capillarity, is another aspect in understanding surface tension in
denture retention. When the space between the denture base and the mucosa is at
maximum close, this space filled with a thin film of saliva acts as a capillary tube in that
the liquid looks to maximize its contact with both the denture base and the surface of the
mucosa. Hence, the denture will be maintained by capillarity (Zarb and Bolender 2004).
25
4.4 Viscosity
Of significant concern is the saliva’s rheology and the location of its viscosity (Darvell and
Clark 2000). As a denture is drawn away from the tissues, saliva is pulled into the gap
being made under the denture. As a result of the viscous properties of the saliva and the
dimensions of the channel through which it flows, the generation of the retentive force is
caused by a resistance of this flow of saliva. It follows that the higher the viscosity of the
saliva and the narrower the channel, the more efficient must be the retention. This
definitely holds true clinically for the channel dimension; however, it seems that very
viscous saliva is associated with comparatively poor retention. It might be that retention is
low in this case, because the enormous viscosity of the saliva ends in a thick and
discontinuous film between the denture and the mucosa. All discontinuities, like air
bubbles, in the saliva film decrease retention greatly, because the flow of air is present
more than the saliva and therefore offers a little resistance to denture displacement (Basker
and Davenport 2002).
It is essential to consider the buccal channel walls through which the saliva flows alter
from each other. The flange of the denture is hard, while the soft tissues of the lips or
cheeks are mobile. If displacement of the denture occurs, the pressure inside the saliva film
drops and the mucosa is drawn tautly against the surface of the denture; thus, the channel
between the two becomes narrow. The resistance, as a result, becomes extremely great to
the flow of saliva and corresponding retention increases. Coincidentally, this will also raise
retention due to surface tension, because narrowing of the channel increases the pressure
difference between the saliva film and the air. If the denture is fabricated with flanges that
are too thin, ending in a wide buccal channel, there will be no impaction of the buccal
mucosa, and the saliva and air will be quickly pulled towards the impression surface as the
26
denture is dislocated. Retention in this case will be insufficient (Basker and Davenport
2002).
The mechanism of retention from the viscosity of the saliva and the valve-like movement
of the soft tissues is best to oppose large displacing forces of brief duration. Small forces
acting over an extended duration of time, for example the influence of gravity on the
maxillary denture, end in a little pressure differential between the saliva film and the air,
because they allow saliva to be pulled gradually into the gap being made under the denture.
A progressive downwards movement of the maxillary denture is likely to happen, if the
effect of gravity is unopposed, until eventually all retention is lost and the denture drops.
Nevertheless, in this condition, restoring the denture to its former location is done by
occlusal forces. Whenever the patient occludes, for example throughout swallowing too
much saliva that has accumulated under the prosthesis is squeezed out once again, the
denture is re-seated and retention is re-created (Basker and Davenport 2002).
27
4.5 Professional attitude towards denture adhesives
Denture adhesives entered dentistry at the end of the 18th century. The first patent
associated with adhesives was announced in 1913, and succeeded in the 1920s and 1930s
(Grasso 2004). Research found that by using denture adhesives, the retention of a full
prosthesis is enhanced (Fakhri et al. 2009). Products of denture adhesives can increase the
patient’s satisfaction, comfort, fulfilment and function with dentures (Zarb and Bolender
2004). In spite of the benefits of the denture adhesives for a large number of edentulous
patients, dental professionals have only been accepting them slowly as a material to
improve denture retention, stability and function (Neill and Roberts 1973). Although
clinical studies have revealed that denture adhesives have no effect on damaging tissue
(Feller et al. 1986), many dental professionals consider that denture adhesives might
increase the alveolar ridge resorption and cause hyperplasia to the soft tissue (Fakhri et al.
2009). In addition, denture adhesives are usually regarded as unpleasing and obstruct a
dentist’s capability to precisely note the health of a patient’s oral tissues and the real nature
of denture adaptation. The fact that poor fitting dentures are usually kept in place with a
great amount of adhesive material has unfortunately driven many dentists to presume a
relationship between denture adhesive and severe alveolar ridge resorption. Nonetheless,
the latest surveys of denture faculties at U.S dental schools recommend that these doubts
about the adhesive materials may be diminishing (Zarb and Bolender 2004). If a
correspondence did in fact exist between the use of denture adhesive and the high
resorption of the alveolar ridge, this would be a sound basis for warning patients against
using these products, yet there is no scientific evidence for assuming this claimed
correlation (Zarb and Bolender 2004).
28
Denture adhesives cannot make use of the forces that would increase resorption (Zarb and
Bolender 2004). Adhesives are fluid materials which are no more able to direct pressure
than saliva. There is no such method through which adhesives can apply pressure to further
increased resorption. As liquids, adhesives will transmit occlusal forces evenly to basal
tissues, just like an intimately fitted acrylic base. If they were unsuccessful in doing so in
one or more spots, the patient will undergo soreness and seek professional advice (Zarb
and Bolender 2004).
Denture adhesives merely decrease the level of lateral movements that dentures, even
excellently fitted ones, go through while in contact with basal tissues. In fact, this
advantage can cause a patient to disregard their need for professional help when dentures
really become ill fitting. This is an intrinsic risk during the use of any sort of adhesive
treatment. Nevertheless, it must not prevent sensible clinical strategies. Denture adhesives
are a fundamental part of a professional service, and their appendage advantages must be
identified (Zarb and Bolender 2004).
4.6 Patient education
The dentist must be the major and significant resource of the vital and critical information
for the patients, not television advertisements and magazines or references of relatives and
friends (Zarb and Bolender 2004). Nonetheless, it is not compulsory for dentists to teach
and educate patients with dentures about denture adhesives: their use, maltreatment,
benefits, troubles, and alternative choices. They think that well-fitting prostheses will
preserve supporting tissues in excellent health and satisfy patients by enhancing oral
function and self steam (Garrett et al. 1996).
29
The selection between cream and powder is greatly subjective, but particular facts might
underline a patient’s choice. The formulation of powder, as a rule, does not grant a similar
level of “hold”, nor does their implementation remain as long as the comparable
formulation of cream. Nevertheless, powders can be utilized in small quantities, are
commonly easier to wash out of dentures and soft tissues, and are not regarded as “sloppy”
by patients. In addition, the primary hold for powders is accomplished faster than it is with
cream formulations.
Acquiring the maximum benefit of an adhesive material is reliant on its correct usage. For
powder and cream materials, the amount of material that should be used by the patient is
minimal. This is approximately 0.5 to 1.5 grams per denture unit (extra for a larger alveolar
ridge, less for smaller ones). For powders, the cleaned prosthesis must be wetted and then a
film, even coating of adhesive scattered onto the tissue surface of the denture. The
overflow is eliminated and the denture is seated firmly. If the patient has insufficient or
lack of saliva, the sprayed prosthesis must be wetted lightly with water before being
inserted. For creams, two methods are considered to be workable. The majority of
producers suggest placement of film beads of the adhesive in the depths of the moistureless
denture in the incisor and molar areas. Moreover, an anteroposterior bead must be seated
along the midpalate in the upper denture. However, to achieve a more even distribution of
the adhesive product, small drops of cream are spread all over the fitting surface of the
dried prosthesis. Irrespective of the form chosen, the prosthesis is then inserted and placed
firmly. As with powders, the use of cream adhesives with xerostomia requires that the
adhesive material be wetted with water before inserting the denture (Zarb and Bolender
2004).
30
When the using the material, the patient must be advised to remove the adhesive product
from the tissue surfaces of the prosthesis every day. Removal is simple by soaking the
denture in water or a soaking solution overnight, at which time the product will be fully
solubilised. New adhesive material needs to be seated again. Removal of the adhesive is
facilitated by putting the denture under hot water and at the same time rubbing the tissue
surface of the prosthesis with a suitable hard bristle denture brush. The best removal of an
adhesive that has adhered to the alveolar ridge and palate is by firmly wiping the spot with
gauze or a washcloth saturated with warm water (Zarb and Bolender 2004).
Patients should also be educated about the controls of prosthesis adhesive. Their anxiety
will not be resolved by positioning a “cushioning layer” of adhesive on the prosthesis.
Actually, irritation and discomfort signals the need for professional involvement. A
gradual increase in the amount of adhesive needed for a acceptable fit of the prosthesis is
also a sound indicator to look for professional care. On the whole, denture patients should
be recalled every twelve months for oral mucosa examination and denture assessment;
however, they also need to be educated about the warning signs that must alert them to
seek professional attention between check-ups (Zarb and Bolender 2004).
31
5.0 Postpalatal seal
5.1 What is postpalatal seal?
The postpalatal seal (PPS) is described as ‘a region of soft tissue next to the junction of the
hard and soft palate on which pressure, within physiologic limits of the tissues, can be used
by a denture to help in its retention’ (Ettinger and Scandrett 1980). The closeness of
peripheral contact between the denture and its supporting tissues is the primary method to
secure a complete maxillary denture. Alterations that occur during and after the processing
of the denture may lead to deformity and an inadequate fit, especially at the vital posterior
palatal border. As a result, insecurity of the complete maxillary denture is the usual cause
for referral for consultant advice (Basker et al. 1988). In identifying this trouble, many
researchers have tested the deformity involved in the processing of denture, particularly the
important alterations at the posterior palatal border, and have applied it to a mixture of
polymerization shrinkage, different thermal contractions, sorption of water and relaxation
of stress (McCartney, 1984). In spite of studying many clinical elements thought to affect
its importance, such examinations have been done under conditions that either failed to
imitate the shape of the object being processed, or after removing and replacing the
sample, a process likely to include replacement faults (Lamb et al. 2005).
5.2 Objectives:
The postpalatal seal function in the maxillary complete denture involves improving
retention, the denture base sealing with underlying tissue to avoid food and debris from
entering, to decrease gagging, to compensate for volumetric shrinkage of the acrylic resin
in this area, and to produce raised thickness of the posterior border, ending in increased
strength (Boucher 1944). Although techniques in processing dentures and materials have
improved, the dimensional alterations of acrylic resin from polymerization and thermal
32
shrinkage end in a gap between the tissue and the dentures’ intaglio surface. Because of
this, a balancing mechanism is required. The techniques for accomplishing a postpalatal
seal of an upper complete denture involve arbitrarily scraping the model before processing
the denture. The position and the integration of the postpalatal seal on the upper cast are
usually done by a dentist or dental laboratory technician. However, these procedures must
be the responsibility of the dentist, as the tissue displacement can only be identified
clinically. An inadequate postpalatal seal may result in poor retention and/or irritation of
tissue (Chang et al. 2006).
The aim of the post dam, or posterior palatal seal, is to make certain that the saliva film is
as thin as feasible at the posterior border of the upper denture; therefore, maximum
retention is obtained (Lamb 1993). Consequently, the post dam must be an area at the
distal border where the soft tissues are pressurized. The perfect location has been matter of
debate. All concur that the line of the pressurized tissue must pass through the hamular
notches; however, experts differ as to the location of the intermediate portion and good
retention being accomplished when putting the post dam at either of two defined positions.
Some instruct that it be placed over the hard palate at a point where the underlying bone
has the adequate soft tissue over it to permit compression of pressure ulceration of the
mucosa (Lamb 1993). Others suggest that the line of the post dam must be positioned at
the vibrating line that indicates the junction between the mobile and immobile regions of
the functioning soft palate (Lamb 1993). It has been illustrated by ultra-sound examination
that the two sites rarely coincide, and that the vibrating line is roughly 3 mm distal to the
bony margin of the hard palate in the midline. The examination also affirmed that a
particular amount of latitude occur in the determination of the most efficient post dam site
(Lamb 1993).
33
When attempting to fabricate an arbitrary post dam, the suggested location has to be
identified on the palate. This could be performed by marking the palpation of the palate
with an instrument that has a ball-ended shape to indicate compressible location, and if the
try-in extends far enough, using it to move the mark to the cast. As another alternative, the
vibrating line can be indicated by vision when the patient repeats the sound of “ah”, by
marking and transferring the location in a similar way. An easier technique than both
methods is to indicate the location of the palatal foveae on either side of the midline near
the junction of the hard or soft palate. If obvious on the cast, the location of the post dam is
marked just in front; if not obvious on the cast, they are indicated in the mouth, marked
and transferred as before (Lamb, 1993).
In the easiest method for performing the cast, the post dam is cut first like a slit with a
scalpel into the plaster from one hamular notch to the other via the indicated junction,
making the slit 1 mm deep at the hamular notches and midline and deeper where there is
more soft tissue mainstay (Lamb 1993). Using the chisel end of a spatula or any similar
instrument, the anterior margin of the slit is bevelled into a bow form, taking the
convexities of the bow further interiorly where the early slit is deeper. After the palatal
margin has been processed, it is reduced from the lingual surface to a near knife-edge. The
bevel is useful, because it can be reduced in depth by cutting it slightly back postero-
anteriorly if the post dam causes over-compression and pain. A more sensible approach to
the method of fabricating a post dam is to study the process of denture manufacture and
find the actual cause for its existence. After a flask has been flasked, the acrylic dough is
heated to bring about polymerization and, arising from the polymerization, volumetric
shrinkage of the resin takes place. The uniform shrinkage is not even, but takes place first
34
in those places where the exotherm of reaction increases the temperature and starts a more
rapid reaction, namely the thicker parts of the base over the crest of the alveolus. The
dough contraction takes place towards the locations of initial polymerization and, because
the form of the space consisting of the dough contributes a physical constraint, a gap is
made between the polymerizing dough and palate of the cast. The space in the midline is
approximately 0.5 mm wide, becoming thinner as it passes laterally. On this basis, it is
recommended that the cast should be relieved at the junction of the hard and soft palate by
cutting a groove with a number 6 round burs to compensate for the shrinkage and re-
establishing contact between the denture and palate. Tooth movement can occur due to
polymerization shrinkage of this type and account for the occlusal deformities that can
damage the most careful technical work. This sort of change is likely to occur in all non-
injection moulded work. Although diverse methods have been explained for the production
of arbitrary post dams, including changeable depths of relief and varying levels of
bevelling (Avant 1973), all work to the amount that fills in the space caused by
polymerization shrinkage and further thin the saliva film in the post dam area is by
applying compression on the tissue. Their intricacy is difficulty to support without being
able to calculate exactly the total addition required. Until it can be accurately accounted
for, it is perhaps better to apply a functional post dam at the denture delivery phase (Lamb
1993).
35
6.0 Ill-fitting maxillary denture
Looseness of the dentures has been the most common complaint. There were important
relationships between insufficient retention and incorrect intermaxillary relationships and
patient complaints of looseness (Brunello and Mandikos, 1998). The reasons for looseness
can be split into those ascribed to the denture and those ascribed to the patients (Jagger and
Harrison 1999).
6.1 Problems with the denture
6.1.1 Impression surface
If the impression surface of the denture does not accurately represent that of the denture-
bearing tissues, impounded air and saliva will fill up the space and denture retention will
decrease as a result (Jagger and Harrison 1999). This can be prevented by ensuring the
following procedures:
1. Use of a special tray that is cautiously adapted to the underlying tissues such that it
provides a uniform thickness of the impression material.
2. The choice and use of suitable impression material for the working impression, such as
zinc oxide eugenol, light or medium bodied silicone, or alginate.
3. Adequate support of the border of the material.
4. Pouring the impression material as soon as possible to prevent deformity.
In the blemished working model, the retention and stability of the dentures are determined
by the accuracy of the working models. As a result of time and effort spent on making high
quality preliminary and final impressions, the models should then be carefully accurate. If
the working model is blemished, this probably occurred on removal of the impression;
therefore, the technician must consider sectional removal of the special tray. The
36
technician should trim the casts, but make certain that reproduction of the depth and width
of the borders of the impressions and the sulci are maintained (see Figure 5.1).
In a warped denture, the change of dimensions during processing can be avoided by using
caution to manage the proper processing procedure to fully polymerise the poly (methyl
methacrylate). When the laboratory phases are complete, the denture must be kept wet,
since drying might alter the form.
Regarding extreme palatal relief chambers, relief chambers are rarely required.
Nevertheless, in conditions where the mucosa is more compressible over the ridge than the
midline, or where there is an obvious palatal torus, it might be required to incorporate one
with the prosthesis base to avoid excessive flexing of the prosthesis. An extensive relief
chamber may cause an easy break of the retentive seal and looseness of the denture.
Epithelial proliferation can occur beneath the palatal relief chamber.
For a missing or inaccurate post-dam, an inadequate post dam in the form of a narrow line
is usually included at the posterior border of the maxillary denture. To obtain effective
function of the post dam, it should be placed at the junction line between the hard and soft
palate (the vibration line) and extended laterally to the mucosa overlying the hamular
notch. The post dam should be marked and carved on the working model by the dentist,
because a technician cannot be conscious of its anatomical position. A missing post dam
should be rectified in the laboratory following a reline impression (Zarb and Bolender,
2004)
37
6.1.2 Polished surface
It is important to provide an efficient border seal to avoid the ingress of saliva and air and a
corresponding decrease in retention (Jagger and Harrison 1999). In an under extended
border in depth and width, the prosthesis must fill and shape a seal, each with the full
functional depth and width of the sulci and the posterior border. Throughout prosthesis
fabrication, this can be performed with the usage of:
1. Cautiously trimmed particular trays.
2. Suitable border moulding of the boundaries with impression tracing compound.
3. An adequate impression technique to register the functional depth and width of the sulci
and maintenance of this detail on the working cast and following denture.
Overextended peripheries in depth and width, the peripheries should be identified by direct
vision using a soft revealing cream or wax if required. Small spots can usually be rectified
by cautious trimming and polishing, nevertheless, for flagrant overextension it might be
required to decrease the peripheries short of the functional sulci and to border mould with
tracing compound succeeded by a reline impression.
Polished surface not the neutral zone, if the polished surfaces of the denture or teeth put
outside the neutral zone, they are more probably to be displaced by the oral musculature
and result in ill fitting denture. In these situations the prosthesis contours should either be
reformed or, if required, remade using the neutral zone procedure.
38
6.1.3 Occlusal surface
Forces which are likely to create the prosthesis during speech and chewing are usually
connected with occlusal irregularities (Jagger and Harrison 1999). A pre centric (no tooth
contact) register must be done, the prosthesis mounted on an articulator and adjusted to
provide a balanced occlusion with independence of movement from retruded contact
location to intercuspal location. The process is done in two phases. First, the rectification
of the centric occlusion at the right centric relation and vertical dimension and then the
development of eccentric balancing contacts. To rectify centric occlusion (phase one):
1. Reduce the cusp if it is high in both centric and eccentric positions.
2. Deepen the fossa if a cusp is high in the centric but not in the eccentric position.
3. Go to phase two if the cusp is only high in the eccentric position.
To enhance eccentric contacts, selective grinding is done according to the BULL rule
(reduction of the buccal upper/lingual lower) (phase two), which is no reduction in both of
the maxillary lingual and mandibular buccal cusps, and no deepening of the fossa on any
tooth. Adjusting the occlusion on the working side should be carried out by decreasing the
inner inclines of the maxillary buccal cusps and the mandibular lingual cusps and on the
balancing side by reducing the inner inclines of the mandibular buccal or the maxillary
palatal cusps. Grinding the mesial inclines of the maxillary cusps, the distal incline of the
mandibular cusp, the lingual surfaces of the lingual surfaces of the upper anterior teeth and
the labial surfaces of the incisal edges of the mandibular teeth should be done to adjust the
occlusion in protrusion position.
39
For premature occlusal contact, small errors can be corrected by selective occlusal
adjustment at the chair side. The denture base must be accurately placed and articulating
paper used to record and mark premature contacts. For more significant errors, a precentric
register must be taken, making certain that the teeth do not contact. The dentures are
remounted on an articulator and adjustment of occlusion is done in the laboratory. For
obvious inconsistencies, it might be necessary to take off the teeth, replace with wax
occlusal rims and rerecord the centric jaw relationship. The teeth should then be rearranged
for a new wax rim trail.
Locked occlusion in some people, particularly the elderly who might be used to worn flat
occlusal surfaces, is usually hard to adapt to a cusp fossa occlusal relationship or a deep
anterior overbite. In this situation, it might be required to grind the occlusal surfaces to
permit freedom of movement, especially in lateral excursions, and to decrease the overbite.
Reasonable wear of the occlusal surfaces often permit free jaw movement and must not
cause a problem of looseness. Nevertheless, extreme wear, with a loss of occlusal vertical
dimension, can cause a class III jaw relationship following the locking of the lower
anterior teeth in front of the uppers. This difficulty can be corrected by recreating a suitable
vertical dimension and occlusal relationship by summing up autopolymerising acrylic resin
to the lower occlusal surfaces of the posterior teeth, in phases, to permit for a time of
adaptation to the growth in height.
For an incorrect occlusal plane, if the occlusal plane is not parallel in relation to the ridge,
pressure of forces can displace the denture. If the occlusal plane of the lower prosthesis is
too high, the movement of the tongue by resting it on the teeth will be difficult and will
40
lead to displacing the prosthesis rather than help keep it. In this situation, if the occlusal
plane on the maxillary denture is adequate, the lower occlusal plane will be raised at the
expense of the freeway space and it will be required to remark the lower denture at the
accurate occlusal vertical dimension.
6.2 Problems with the denture wearers
6.2.1 Poor neuromuscular control
There are many neuromuscular disorders, for example Parkinson’s disease and
cerebrovascular causes which can influence the development of complete dentures because
of a diminished muscular rule (Jagger and Harrison 1999). As it is important to supply
dentures with maximum retention and stability, the use of non-anatomic teeth together with
a neutral zone procedure must be considered.
6.2.2 Changeable foundation
If the bases of the denture are adverse, for flabby ridge of the upper anterior, lower ridge
atrophy, attachments of fraenal or noticeable mylohyoid ridges, it might be required to
consider the use of particular impression technique or even prosthetic surgery to provide an
enhanced anatomy and ideal denture. For the flabby ridge of the upper anterior, it is
essential that the flabby tissue must not be displaced by the upper anterior. The might be
well adapted if the flabby tissue is displaced when undergoing occlusal pressure; however,
it is likely to be displaced by elastic recoil of the displaced tissue when the teeth are away.
The pumping action will damage the fibrous tissue and the tooth contact causes the
movement of the denture. It is possible to use a spaced particular tray with a low viscosity
material if there is only minimal displacement of the flabby ridge, for example impression
plaster or low viscosity alginate. It is better to use a two-part impression technique with
41
marked displacement. An impression of the undisplaced mucosa can be taken in zinc oxide
eugenol impression material through a close fitting special tray with a window over the
flabby area. The impression is examined, replaced in the mouth, and a flabby ridge
impression is taken by adding impression plasters to the window area (Pankhurst et al.
1996).
6.2.3 Inadequate saliva
To reinforce retention in the denture wearer, adequate saliva is essential. For some patients
with xerostomia, for example Sjogren’s syndrome, retention can be quite a problem.
Dentures must be supplied which maximise retention and stability together with the
provision of a synthetic saliva replacement where suitable. The use of denture fixative is an
option.
Figure 5.1Examples of the similar casts; the one on the right has been adequately trimmed
while the one on the left is an incorrect and over trimmed cast (Jagger and Harrison 1999).
42
Conclusion
This paper has been explained in detail for the practitioner some of the inessential elements
for retention and stability of the complete maxillary denture. This explanation will guide
both the practitioner and the technician to control the complete maxillary denture, either at
clinical or laboratory procedure, with great efficiency. It is crucial to consider the aspects
needed to make supreme retention and stability for a patient who has to wear complete
maxillary denture. Obviously, cautious attention is needed in relation to recognizing the
crucial features of the prosthesis shape to gain supreme retention and stability during
function. There are many opinions regarding which factor is most involved in the retention
and stability of maxillary complete denture. Some studies suggest that surface tension is a
major factor in complete denture retention, whereas other studies believe that adhesion is
the most important factor (Stamoulis 1962). Furthermore, this dilemma is also found in
factors considered to be not important in the maxillary complete denture such as
atmospheric pressure, vacuum, surface roughness and gravity (Darvell and Clark 2002). It
is agreed that the factors that provide retention and stability are related. In fact, some
authors have recommended that the interaction between stability and retention creates
indistinguishable factors (Jacobson and Krol 1983). It is strongly suggested that
researching for retention and stability in the mandibular complete denture will amalgamate
the efforts for the optimal understanding of the retention and stability of maxillary and
mandibular complete dentures.
43
References
Avant, W. 1973, A comparison of the retention of complete denture bases having different types of posterior palatal seal. The Journal of prosthetic dentistry, 29, 484.
Barbenel, J. C. 1971, Physical retention of complete dentures. Journal of Prosthetic Dentistry, 26, 592-600.
Basker, R. & Davenport, J. 2002a, Prosthetic treatment of the edentulous patient, Munksgaard, Blackwell.
Basker, R. M., Harrison, A. & Ralph, J. P. (1988) A survey of patients referred to restorative dentistry clinics. British Dental Journal, 164, 105-8.
Basker, R. M. & Davenport, J. C. (Eds.) 2002b, Prosthetic Treatment of the Edentulous Patient, Oxford, Blackwell Munksgaard.
Boucher, C. 1944, Complete denture impressions based upon the anatomy of the mouth. Journal of the American Dental Association, 31, 1174-1181.
Brunello, D. L. & Mandikos, M. N. (1998) Construction faults, age, gender, and relative medical health: factors associated with complaints in complete denture patients. Journal of Prosthetic Dentistry, 79, 545-54.
Celebic, A., Knezovic-zlataric, D., Papic, M., Carek, V., Baucic, I. & Stipetic, J. (2003) Factors related to patient satisfaction with complete denture therapy. Journals of Gerontology Series A-Biological Sciences & Medical Sciences, 58, M948-53.
Chang, B. M., Wright, R. F., Chang, B. M. W. & Wright, R. F. (2006) Accurate location of postpalatal seal area on the maxillary complete denture cast. Journal of Prosthetic Dentistry, 96, 454-5.
Darvell, B. W. & Clark, R. K. 2000, The physical mechanisms of complete denture retention. British Dental Journal, 189, 248-52.
Devlin, H. & Hoad-Reddick, G. 2001, Biological guides to the positioning of the artificial teeth in complete dentures. Dental Update, 28, 492.
Driscoll, C. F., Masri, R. M., Driscoll, C. F. & Masri, R. M. Single maxillary complete denture. Dental Clinics of North America, 48, 567-83.
Escoe, R. & Escoe, R. 2008, Saliva and dentures. Journal of the American Dental Association, 139, 1028; author reply 1028-9.
Ettinger, R. & Scandrett, F. 1980, The posterior palatal seal. A review. Australian dental journal, 25, 197.
Fakhri, H., Fayaz, A., Faramarzi, F. & Javaheri, H. 2009, The knowledge and attitude of general dentists toward denture adhesives in Tehran. Indian Journal of Dental Research, 20, 164.
Felleer, R., Saunders, M. & Kohut, B. 1986, Effect of a new form of adhesive on retention and stability of complete maxillary dentures. Special Care in Dentistry, 6, 87-89.
Gahan, M. & Walmsley, A. 2005, The neutral zone impression revisited. British Dental Journal, 198, 269-272.
Garrett, N. R., Kapur, K. K. & Perez, P. (1996) Effects of improvements of poorly fitting dentures and new dentures on patient satisfaction. Journal of Prosthetic Dentistry, 76, 403-13.
Garrett, N. R., Perez, P., Elbert, C. & Kapur, K. K. (1996) Effects of improvements of poorly fitting dentures and new dentures on masticatory performance. Journal of Prosthetic Dentistry, 75, 269-75.
Grasso, J. 2004, Denture adhesives. Dental Clinics of North America, 48, 721-733.Husham, A. M., Al-bazirgan, M. H., Husham, A. M. & Al-bazirgan, M. H. K. (2006)
Effect of air-particle abrasion on the retention and texture of the maxillary complete denture. American Journal of Dentistry, 19, 115-22.
44
Jacobson, T. E. & Krol, A. J. (1983) A contemporary review of the factors involved in complete dentures. Part II: stability. Journal of Prosthetic Dentistry, 49, 165-72.
Jagger, D. & Harrison, A. 1999, Complete Dentures - Problem Solving, London, British Dental Association.
Lamb, D. J. (Ed.) 1993, Problems and Solutions in Complete Denture Prosthodontics London, Quintessence.
Lamb, D. J., Samara, R. & Johnson, A. 2005, Palatal discrepancies and postdams. Journal of Oral Rehabilitation, 32, 188-92.
McCartney, J. 1984, Flange adaptation discrepancy, palatal base distortion, and induced malocclusion caused by processing acrylic resin maxillary complete dentures. The Journal of prosthetic dentistry, 52, 545.
Neill, D. & Roberts, B. 1973, The effect of denture fixatives on masticatory performance in complete denture patients. Journal of dentistry, 1, 219.
Pankhurst, C. L., Dunne, S. M. & Rogers, J. O. (1996) Restorative dentistry in the patient with dry mouth: Part 2. Problems and solutions. Dental Update, 23, 110-14.
Rendell, J., Grasso, J. E. & Gay, T. 1995, Retention and stability of the maxillary denture during function. Journal of Prosthetic Dentistry, 73, 344-7.
Stamoulis, S. (1962) Physical factors affecting the retention of complete dentures. Journal of Prosthetic Dentistry, 12, 857-64.
Tsirmbas, M. & Vlissidis, D. (1989) [The effect of postpalatal seal on the retention of a full upper denture]. Hellenika Stomatologika Chronika, 33, 269-73.
Van blarcom, C. (1999) Glossary of prosthodontic terms, 7 th edn. Journal of Prosthetic Dentistry, 81, 39.
Zarb, G., Chl, B. & GE, C. (1997) Boucher’s prosthodontic treatment for edentulous patients. 11de druk. St. Louis: The CV Mosby Company.
Zarb, G. A. & Bolender, C. L. (Eds.) 2004, Prosthodontic Treatment for Edentulous Patients, Philadelphia, Mosby.
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