Management of Loading Forces Distribution in Mandibular Distal-extension Prostheses

Study Description

Brief Summary

The two structures that support a mandibular distal extension removable partial denture differ markedly in their visco-elastic response to loading. The difference between the resilience of the residual ridge tissues and the teeth permitted by the periodontal ligament presents a disparity of support that is in contrast to the uniform support accorded a tooth-supported removable partial denture. Hence the denture tends to rotate about its most distal abutments, inducing heavy torsional stresses on alveolar ridges.

Many methods have been used to control this movement, some of them:

1. Implant support on distal extension removable.

2. Stress breakers provide a mean of interposing a flexible connection between the tooth-borne retainer portion of removable partial denture and its distally extended tissue-borne segment.

3. Altered-cast technique.

4. Design development by using mesial indirect retainers rather than distal ones.

The purpose of this study is: (1) to compare bone absorption around abutment teeth nearby the free saddle; (2) denture displacement and pressure on the soft tissue under the denture base of distal extension RPD (Removable Partial Denture) (3) cellular changes in the soft tissue under the denture base of distal extension RPD.

Detailed Description

Removable partial dentures (RPD) have an essential role in treating partly edentulous. patients with large toothless spaces, or without posterior dental support (Kennedy Class I).

Rehabilitation with Distal-Extension Removable Partial Denture (DERPD) deserves special attention because of the difference in resilience between the remaining mucosa of the edentulous area and the periodontal ligament of the abutment tooth. When occlusal forces affect the bases, the difference in resilience between the mucosa of the edentulous area and the periodontal ligament of the abutment teeth creates a rotating movement whose axis is located on the occlusal rests on the abutment teeth. This may induce horizontal forces and mainly lateral forces upon them, causing inflammation, gingival retraction, increase in dental mobility and distal residual ridge resorption. This movement may cause a reduction in function, discomfort and trauma to the RPD supporting tissues.

MATERIAL AND METHODS:

Patients will be recruited from the Department of Prosthodontics at the University of Damascus Dental School. Thirty patients will be randomly divided into three groups (A, B, and C). A mandibular bilateral distal-extension removable partial denture will be used for patients in all groups. But every group will have its own specific method of distributing loading forces.

In Group A: A Removable partial dentures will be made by using altered-cast technique for free saddle.The investigators will make a primary impression using stock tray. This will be followed by a final impression by individual tray. After metal framework try-in, ridge regions are removed from uncorrected master cast with saw. Then, corrective impression of ridges will be obtained with soft ZOE impression paste. Therefore, a metal framework with associated corrective impression will be repositioned on tooth portion of master cast prior to altering distal-extension bases.

In Group B: Removable partial dentures will be made by using precision attachments which will be located on the last abutment tooth. At first, crowns will be prepared to receive the precision attachment, then these are cemented to their respective abutment teeth. So that a mean of interposing a flexible connection between the tooth-borne retainer portion of a removable partial denture and its distally extended tissue-borne base will be provided.

In Group C: Removable partial dentures will be made by using resilient-layer in the distal extension of the removable partial denture.

Study Design

Outcome Measures

Primary Outcome Measures

1. Soft-tissue vertical displacement (STVD) [This variable will be measured at one month, three months and six months following appliance first delivery]

   Soft tissue vertical displacement will be measured using an impression technique at the free end saddles.

Secondary Outcome Measures

1. Bone absorption of abutment teeth [This variable will be measured at one month, three months and six months following appliance first delivery]

   The amount bone absorption will be measured using apical radiography.

2. Cellular changes of the supporting tissues [This variable will be measured at one month, three months and six months following appliance first delivery]

   A brush will be used to have a smear of the underlying soft tissues. Cellular changes will be evaluated microscopically. The changes observed will be analysed quantitatively.

Eligibility Criteria

Criteria

Inclusion Criteria:

• Bilateral distal extension in the mandible (Class I Kennedy's Classification).

• Stable systemic health, including absence of a history of cardiovascular disease.

• No evidence of infection or trauma in the oral region.

• Negative history of syndromes or temporomandibular disorders and parafunction.

Exclusion Criteria:

• Other Classes of Kennedy's Classification

• Patients with ages beyond the accepted age range.

Contacts and Locations

Locations

Sponsors and Collaborators

• Damascus University

Investigators

• Principal Investigator: Fadi Alhaji Jnaid, DDS MSc, PhD student, Department of Removable Prosthodontics, University of Damascus Dental School, Damascus
• Study Director: Alaa' Salloum, DDS MSc PhD, Senior Lecturer, Removable Prosthodontics Department, University of Damascus Dental School, Damascus

Study Documents (Full-Text)

More Information

Publications

• Aydinlik E, Akay HU. Effect of a resilient layer in a removable partial denture base on stress distribution to the mandible. J Prosthet Dent. 1980 Jul;44(1):17-20.
• Holmes JB. Influence of impression procedures and occlusal loading on partial denture movement. 1965. J Prosthet Dent. 2001 Oct;86(4):335-41.
• Igarashi Y, Ogata A, Kuroiwa A, Wang CH. Stress distribution and abutment tooth mobility of distal-extension removable partial dentures with different retainers: an in vivo study. J Oral Rehabil. 1999 Feb;26(2):111-6.
• Kratochvil FJ, Thompson WD, Caputo AA. Photoelastic analysis of stress patterns on teeth and bone with attachment retainers for removable partial dentures. J Prosthet Dent. 1981 Jul;46(1):21-8.
• Leupold RJ, Flinton RJ, Pfeifer DL. Comparison of vertical movement occurring during loading of distal-extension removable partial denture bases made by three impression techniques. J Prosthet Dent. 1992 Aug;68(2):290-3.
• Pellizzer EP, Ferraço R, Tonella BP, Oliveira BJ, Souza FL, Falcón-Antenucci RM. Influence of ridge type on mandibular distal extension removable partial denture. Acta Odontol Latinoam. 2010;23(1):68-73.
• Saito M, Miura Y, Notani K, Kawasaki T. Stress distribution of abutments and base displacement with precision attachment- and telescopic crown-retained removable partial dentures. J Oral Rehabil. 2003 May;30(5):482-7.
• Tebrock OC, Rohen RM, Fenster RK, Pelleu GB Jr. The effect of various clasping systems on the mobility of abutment teeth for distal-extension removable partial dentures. J Prosthet Dent. 1979 May;41(5):511-6.
• Vahidi F. Vertical displacement of distal-extension ridges by different impression techniques. J Prosthet Dent. 1978 Oct;40(4):374-7.