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Building the Edentulous Impression: A Layering Technique Using Multiple Viscosities of Impression Material

October 20, 2008
Joseph Mossad image
Joseph J. Massad, DDS

In a recent internet survey (n=701), dentists reported that many edentulous patients complained of poor-fitting dentures (Dental Economics Survey Primary Research, October 2005). The patients perceived looseness or movement of the denture and generalized soreness. To provide a more detailed and customized impression of the edentulous patient, a procedure using both the static and functional concepts of impression making in one application will be described.

The Static Impression Technique is used to create an accurate impression of undisturbed and uncompressed tissue.1,2 The Functional Impression Technique explains the need to make an impression based on the differing degrees of tissue function.3,4,5

Evaluation and Classification of Tissue Quality

After a thorough patient history has been obtained, the intraoral and extraoral structures should be evaluated closely. Inspecting intraoral tissue will permit the clinician to determine the character and mobility of the overlying soft tissue. Classifying the tissue after examination based on the differences between tissue character and mobility will give the clinician a simple method for selecting the appropriate viscosity to make the impression.

The clinician uses tactile manipulation to assess the character of the tissue overlying the bony support in the edentulous arches and classifies the tissue as coarse and fibrotic, average, or thin and fragile. For example, if a patient’s tissue quality is determined to be coarse and fibrotic covering the residual ridges, it is generally thought that the patient is able to tolerate a removable complete prosthesis better than if the supporting tissue is classified as thin and fragile.

Figure 1

Figure 1: The tissue character can be assessed using digital/tactile evaluation.

The soft tissue overlying the residual ridges should be assessed using a blunt instrument to determine the relative amount of displacement or mobility. After tactile assessment, the tissue can then be classified and recorded as one of the following: attached, low mobility, low displacement; average, clinically acceptable displacement; or high mobility, high displacement. Soft tissue that is categorized as attached and less mobile quality overlying the alveolar ridge generally results in better adaptation of the removable prosthesis. Conversely, soft tissue quality that is categorized as high mobility and high displacement typically represents a clinical condition that is more difficult to manage and prepare for well-fitting complete dentures6 (Fig. 1).

The soft tissue overlying the residual ridges should be assessed using a blunt instrument to determine the relative amount of displacement or mobility.  

Materials

It has been demonstrated that the type of impression materials used for making the final impression can have a critical effect on the pressures produced during the impression making procedure; therefore, tray modifications have less significant influence when the amount of pressure produced needs to be controlled.7

In an attempt to select the most appropriate material for the technique, a review of the types of impression materials was completed. Materials considered included plaster, impression compound, zinc oxide eugenol, alginate, polysulfide, polyether, condensation silicone and polyvinylsiloxane (addition-reaction silicone). Next, the important characteristics required to make a simultaneous static and functional impression were recorded8,9,10 (Table 1).

Table 1

Table 1

It is important to use an impression material that maintains dimensional stability during removal and reinsertion while making an impression that must be seated beyond anatomical undercuts.8 This requires a material with a high percentage of recovery from deformation.8 It is also important that the clinician be allowed to apply varying viscosities sequentially and simultaneously that will set to form a homogeneous mass of impression material, regardless of the viscosity used. The materials selected for this technique must exhibit high tear strength (resistance to tearing) across the multiple viscosities used in this procedure.8,9 The use of the multiple viscosities of impression material should be such that there is a co-lamination between the layers of material and an anatomically correct and detailed reproduction that captures all aspects of the edentulous arches.

Based on the characteristics of the materials reviewed (Table 1), polyvinylsiloxane (PVS) materials appear to meet all the requirements that support use of this layering impression technique. The impression material used to demonstrate this technique is a hydrophilic, polyvinylsiloxane material and a specially designed disposable edentulous tray. The authors chose Aquasil Ultra PVS (DENTSPLY Caulk; Milford, Del.). Other polyvinylsiloxane materials available are Clone™ Bite and Chromaclone® PVS Super Light (Ultradent Products; South Jordan, Utah), Imprint™ (3M™ ESPE™; St. Paul, Minn.), and Extrude® (Kerr Corporation; Orange, Calif.).

Based on the characteristics of the materials reviewed, polyvinylsiloxane materials appear to meet all the requirements that support use of this layering impression technique.”  

Clinical Application

Figure 2

Figure 2: The patient or a dental assistant can help provide adequate tissue retraction when building the impression. In this instance, a patient is shown holding cheek retractors in preparation for the procedure.

For optimal intraoral access, appropriate lip and cheek retraction is made to assist the clinician during the impression-making procedures of the maxillary and mandibular arches (Fig. 2). The high viscosity PVS impression material with low strain in compression is used initially to create tissue stops before proceeding (Fig. 3). The low strain property of the material during compression helps reduce tissue movement or rebound after polymerization8 and helps to create predictable tissue stops when reinserting the tray during subsequent steps. The tissue stops create adequate tissue relief for the impression material, help to reposition the impression intraorally, center and stabilize the tray on the edentulous residual ridge. The tissue stops provide the clinician with a predictable position on tray reinsertion, helping to prevent over-seating the tray during functional border molding.

Figure 3

Figure 3: Use the high viscosity PVS impression material to create tissue stops in the stock impression tray.

Figure 4

Figure 4: After creating tissue stops in the tray, add high viscosity PVS onto the tray flanges and border mold to define the vestibular areas.

The impression tray is removed and excess impression material is trimmed. High viscosity PVS is then added to the borders of the maxillary impression tray, then border molded. The medium viscosity PVS is placed on the borders of the mandibular impression tray, then border molded. Each tray is border molded separately within the stated setting times (Fig. 4). The high viscosity PVS used in this study captured anatomical details such as frena and the vestibular sulcus throughout and extended sufficiently to capture the postpalatal area in the border-molding procedure for the maxillary arch. For the mandibular arch, it is important to preserve and maintain all frena, vestibular sulcus, retromylohyoid space and the retromolar pads (Figs. 5, 6).

Figure 5

Figure 5: The maxillary master cast is highlighted to demonstrate the anatomical features that should be reproduced in the final impression.

Figure 6

Figure 6:The mandibular master cast is highlighted to demonstrate the anatomical features that should be reproduced in the final impression.

Dry the impression and place the appropriate viscosity impression material onto the basal seat (load-bearing area) as a thin, “wash” impression; the appropriate viscosity of impression material selected is based on evaluation of the tissue character and mobility classification (Figs. 7, 8). For example, the premaxilla and anterior mandibular areas displayed poor tissue character and mobility, which required the extra light viscosity material, while the posterior maxillary and mandibular arches displayed average tissue character and mobility, which suggested the need for low or average viscosity PVS material (Figs. 9, 10). The clinician should inspect the accuracy of the impressions to ensure that all tissue details have been captured before pouring the master cast.

To preserve and protect the peripheral detail of the vestibular borders of the impressions, each final impression is boxed using the alginate boxing method. It is extremely important to maintain the peripheral borders of both the maxillary and mandibular impressions when boxing and to avoid over-trimming the master cast, which could compromise anatomical details of the vestibular borders (Fig. 11). The selection and use of an appropriate dental stone is made in consideration of selecting one with controlled expansive/contractive properties9 (Fig. 12).

Figure 7

Figure 7: Multiple viscosities of PVS impression materials are being dispensed in the maxillary tray. In this instance, the ultra low viscosity is applied to the premaxilla area, which had been evaluated as loose and having a spongy character upon tactile evaluation. The low viscosity was applied to the mid-maxillary area where the tissue exhibited average tissue character and average mobility. 

Figure 8

Figure 8: Multiple viscosities of PVS materials are being dispensed in the mandibular tray. In this instance, the ultra low viscosity was applied to the anterior mandibular area because of fragile, loose, unsupported tissue. The low viscosity was applied to the posterior mandibular areas where the tissue was of average mobility and average tissue character.

Figure 9

Figure 9: The final impression of the edentulous maxillary arch shows use of four viscosities of PVS impression material, as defined by the various colors. The high viscosity was used initially to create the base tissue stops and to border mold the vestibular areas.

Figure 10

Figure 10: The final impression of the edentulous mandibular arch shows use of three viscosities of PVS impression materials, as defined by the various colors. The high viscosity was used initially to create the base tissue stops and to border mold the vestibular areas.

Figure 11

Figure 11: The final impressions are boxed to create a dense master cast and to preserve the peripheral flanges carefully created intraorally.

Figure 12

Figure 12: The master casts have been poured, allowed to set completely, and trimmed. Note the peripheral flanges have been preserved as the boxing procedure creates a “land area” around the periphery of the anatomical areas of the impression.

Figure 13

Figure 13: The sectioned impression shows the multiple layers of impression material in cross-section.

An evaluation of the adequacy of the bond between the various viscosities of impression material was performed. Four different viscosities of impression material were used to build and complete the final impression (Fig. 13). High viscosity (green), medium viscosity (purple), low viscosity (teal) and ultra low viscosity (orange) impression materials were used to record the maxillary impression used in this clinical situation. The high viscosity material was used to create the tissue stops and border molding, each being applied and allowed to set separately. The remaining three viscosities were applied sequentially in the predetermined areas of the tray, reinserted intraorally, and allowed to set simultaneously. After the material set and the impression was removed, the impression was sectioned longitudinally using a sharp blade to demonstrate the various layers of impression materials used and the relation to the anatomical area reproduced intraorally (Fig. 13). Note the approximation of material layers and co-lamination of the various viscosities in the cross-sectional view, evident in the thinly layered sections.

Based on informal testing, it was found that the different viscosities, applied and allowed to set simultaneously, could not be separated. However, the materials that were applied in separate layers (such as in a dual technique) exhibited more than adequate adhesion to each other and could only be separated with difficulty after several attempts. It should be noted that adhesion between impression layers was enhanced when the layers were dried before placing the subsequent layer. Even in the presence of slight moisture contamination, the co-lamination between layers was sufficient to pour and create the master cast.

Conclusion

Making acceptable final impressions when fabricating complete dentures is an important requirement for the successful treatment of an edentulous patient. Diagnosing the tissue condition and classifying the edentulous arch11 should be determining factors when selecting an impression technique for a specific patient.

The layering technique presented in this article represents an alternate impression technique for the clinician who thoroughly understands the basic principles in complete prosthodontics and has the clinical ability to evaluate and assess intraoral tissues of the edentulous patient. The clinician can use multiple viscosities of an impression material and a stock edentulous tray (in this example, a well-designed disposable edentulous impression tray) to border mold and create an impression of the edentulous arch efficiently and accurately, as an effective clinical solution for the contemporary practice of treatment of the edentulous patient.

References

  1. ^ Bohannan HM. A critical analysis of the mucostatic principle. J Prosthet Dent. 1954;4:232-41.
  2. ^ Addison PI. Mucostatic impressions. J Am Dent Assoc. 1944;31:941-6.
  3. ^ Pendleton EC. The positive pressure technique of impression taking. Dent Cosmos. 1931;73:1045-56.
  4. ^ Frank RP. Controlling pressures during complete denture impressions. Dent Clin North Am. 1970 Jul;14(3):453-70.
  5. ^ Boucher CO. A critical analysis of mid-century impression techniques for full dentures. J Prosthet Dent. 1951 Jul;1(4):472-91.
  6. ^ Massad JJ, Goljan KR. A method of prognosticating complete denture outcomes. Compendium. 1994 Jul;15(7):900-9.
  7. ^ Masri R, Driscoll CF, Burkhardt J, et al. Pressure generated on a simulated oral analog by impression materials in custom trays of different designs. J Prosthodont. 2002 Sep;11(3):155-60.
  8. ^ Anusavice KJ. Phillips’ science of dental materials. 10th ed. Philadelphia: Saunders; 1998.
  9. ^ Albers HF. Impressions: a text for selection of materials and techniques. 2nd ed. Santa Rosa (CA): Alto Books; 1990.
  10. ^ Ferracane JL. Materials in dentistry: principles and applications. 2nd ed. Philadelphia: Lippincott Williams & Wilkins; 2001.
  11. ^ McGarry TJ, Nimmo A, Skiba JF, et al. Classification system for complete edentulism. The American College of Prosthodontics. J Prosthodont. 1999 Mar;8(1):27-39.

To contact Dr. Massad, call 888-336-8729, visit gdit.us or joemassad.com, or email using the contact message form at joemassad.com.

Reprinted from Compendium: Massad J, Lobel W, Garcia LT, et al. Building the edentulous impression: a layering technique. 2006;27(8):446-52. Copyright ©2006, with permission from AEGIS Publications, LLC.