Combining Traditional and CAD/CAM Techniques for Simplifying Dental Implant Therapy

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Journal of Medical Implants & Surgery
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  • Case Report   
  • J Med Imp Surg, Vol 1(1)

Combining Traditional and CAD/CAM Techniques for Simplifying Dental Implant Therapy

Matthias Karl1* and Georg Schmidtler2
1Prosthodontics Division, University of Erlangen-Nuremberg, Germany
2Dental Laboratory, Schönthal, Germany
*Corresponding Author: Matthias Karl, Prosthodontics Division, University of Erlangen-Nuremberg, Glückstraße 11, 91054, Erlangen, Germany, Tel: +49 9131- 8535802, Email: Matthias.Karl@uk-erlangen.de

Received: 11-Jan-2016 / Accepted Date: 28-Jan-2016 / Published Date: 04-Feb-2016

Abstract

Despite the undisputed advantages of dental implant therapy, a considerable number of patients cannot benefit from such treatment due to limited financial resources. In addition to the advent of reliable low-cost implant systems, the use of Computer Aided Design/Computer Aided Manufacturing (CAD/CAM) for fabricating implant-supported restorations may help to overcome this problem. This article presents a clinical case of two implants inserted in the fourth quadrant and restored with a cementretained Fixed Dental Prosthesis (FDP). The implant system used featured a pre-mounted multipurpose abutment used for implant insertion, impression making and as a basis for the definitive restoration. Following manual adaptation of these abutments for achieving a common path of insertion, a three-unit FDP was manufactured using a CAD/CAM system. By combining old-school and up-to-date prosthetic fabrication techniques it was possible to successfully restore this patient in a reliable and esthetic way.

Keywords: CAD/CAM; Implant therapy; Esthetics; Predictability

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Introduction

Dental implant therapy provides undisputed benefits for several indications particularly when pristine neighboring teeth are present or when the patient could otherwise only be restored using removable dental prostheses [1,2]. However, in many instances, limited financial resources hinder patients from seeking implant therapy [3]. While on the top-end of the spectrum incredible options exist for improving the planning phase [4], the hard and soft tissue situation as well as the restorative outcome of a specific patient, little attempts have been made for reducing treatment costs [5].

Given the high level of experience and predictability gathered with premium dental implant systems [2], several companies emerged over the past years offering low-cost dental implants often with a limited number of prosthetic options. Similarly, CAD/CAM technology in the laboratory field has in some areas overcome conventional labor-intense fabrication techniques e.g. for manufacturing restorative frameworks [6]. Furthermore, the advent of zirconia ceramic led to the replacement of expensive noble alloys in many indications [7].

It is therefore the goal of this case presentation to show the predictable implant treatment of a patient combining a low-cost implant system as well as traditional and modern fabrication techniques for reducing treatment cost.

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Case Report

A 75-year old female patient presented with a failing fixed dental prosthesis supported by the lower right second premolar and second molar ( Figure 1). Both teeth were symptomatic and after an unsuccessful attempt of endodontic treatment, it was decided to extract both teeth and to place dental implants immediately ( Figure 2a). Due to the patient’s limited financial resources, a low-cost dental implant system with a pre-mounted multi-purpose abutment ( Figure 2b) was used (MAX implant, Alfa Gate, Kfar Qara, Israel). While the anterior implant could be installed in the extraction socket of the first premolar ( Figure 2c), the posterior implant was placed mesial to the extraction site of the molar where sufficient bone quantity was available ( Figure 2d). Cover screws were placed on both implants for submerged healing prior to radiographically verifying the implant positions (Figures 2e,2f). After a healing period of three months (Figure 3a), the implants were uncovered trying to optimize soft tissue conditions by manipulating existing gingival volume (Figure 3b). Six weeks thereafter, the patient presented with healthy peri-implant mucosal conditions ( Figures 4a,4b) suitable for impression making. To this end, the multipurpose abutments were again tightened on the implants and the screw access holes were covered with cotton pellets (Figure 5a) prior to the closed tray one stage putty-wash impression (Figures 5b,5c) using addition silicone (Affinis, Coltene Whaledent, Langenau, Germany). The multipurpose abutments were then connected to laboratory analogs (Figure 5d) and repositioned into the impression (Figure 5e) before the master cast was poured in stone (Figure 6a) and mounted in an articulator. A manual milling machine was utilized for creating a common path of insertion and definitive margins for both of the multipurpose abutments (Figures 6b-6e). For simplifying the abutment insertion process in the patient’s mouth, a tooth-supported stent was made from autopolymerizing resin (Figure 6f). The master cast with the modified abutments in place was digitized by means of a laboratory based scanner (DEGOS STAR Z –SCAN Ultra 4000, DEGOS Dental, Regenstauf, Germany) and a framework for a three-unit restoration was designed virtually (Figure 7). Afterwards, the framework was milled from Zirconia ceramic in an external milling center (Zirkondioxid HT, Cadstar, Bischofshofen, Austria). Manual veneering of the framework (Cercon Ceram Kiss, Degudent, Hanua, Germany) was then performed for achieving adequate function and esthetics of the final restoration (Figures 8a-8e). After the laboratory phase, the abutments were tightened on the implants in the patient’s mouth using the resin guide and a torque of 25Ncm (Figures 9a-9c). With the crown margins located exactly at the gingival level, the FDP could easily be cemented with zinc-phosphate cement.

medical-implants-surgery-initial-presentation

Figure 1: Initial presentation of the pa tient showing an insufficient threeunit fixed dental prosthesis supported by teeth 45 and 47.

medical-implants-surgery-intraoperative

Figure 2a: Intraoperative situation following the extraction of the two abutment teeth showing abundant bone quantity.

medical-implants-surgery-alfa-gate

Figure 2b: AlfaGate MAX implant with pre-mounted multi-purpose abutment

medical-implants-surgery-mesial-implant

Figure 2c: While the mesial implant was inserted in the extraction site of tooth 45.

medical-implants-surgery-distal-implant

Figure 2d: The distal implant was placed mesially to the posterior extraction site of tooth 47.

medical-implants-surgery-cover-screws

Figure 2e: Cover screws were then placed for submerged healing.

medical-implants-surgery-inserted-extraction

Figure 2f: A panoramic radiograph showing the implant positions.

medical-implants-surgery-clinical-situation

Figure 3a: Clinical situation after thre e months of healing prior to incision making for second stage surgery done by a crestal incision and by forming Palacci flaps for augmenting inter-implant soft tissue volume.

medical-implants-surgery-healing-abutments

Figure 3b: Healing abutments 4mm in height support the soft tissue.

medical-implants-surgery-six-weeks

Figure 4a: Six weeks following implant uncovery, the patient presents with healthy peri-implant soft tissue

medical-implants-surgery-epithelialized

Figure 4b: Epithelialized gingival drapes surrounding both healing abutments.

medical-implants-surgery-impression-making

Figure 5a: For impression making, the multi-purpose abutments were retightened on the implants and the screw access holes were filled with cotton pellets.

medical-implants-surgery-one-stage

Figure 5b: A one stage putty-wash impression was made using light body and heavy-body vinylpolisiloxane.

medical-implants-surgery-putty-wash

Figure 5c: One stage putty-wash impression.

medical-implants-surgery-multi-purpose

Figure 5d: The multi-purpose abutments were removed from the patient’s mouth and tightened onto laboratory analogs.

medical-implants-surgery-subsequently

Figure 5e: Which were subsequently repositioned into the impression.

medical-implants-surgery-based-impression

Figure 6a: Based on the impression, a master cast with soft tissue mask was fabricated.

medical-implants-surgery-abutments

Figure 6b: The abutments were manually milled in order to achieve a common path of insertion and to create crown margins with adequate thickness and shape.

medical-implants-surgery-emergence profile

Figure 6c: The adequacy of the emergence profile created was verified from buccal aspects.

medical-implants-surgery-lingual-aspects

Figure 6d: The adequacy of the emergence profile created was verified from lingual aspects.

medical-implants-surgery-occlusal aspects

Figure 6e: The adequacy of the emergence profile created was verified from occlusal aspects.

medical-implants-surgery-polymerizing

Figure 6f: Auto polymerizing resin was then used for generating a splint which helped to properly orient the individualized abutments in the patient’s mouth.

medical-implants-surgery-model situation

Figure 7: The model situation was subsequently scanned and a framework for a three-unit FDP was designed to be milled from Zirconia ceramic.

medical-implants-surgery-zirconia-substructure

Figure 8: (a) The Zirconia substructure was veneered ceramically with special emphasis on characterizing the cervical aspects and (b) The occlusal surfaces.

medical-implants-surgery-final restoration

Figure 8c: (c) The final restoration shows adequate fit on the individualized abutments both from the buccal and (d) Lingual aspect.

medical-implants-surgery-oversized molar

Figure 8e: Instead of creating an oversized molar supported by the posterior implant, it was decided to form premolar-units facilitating dental hygiene.

medical-implants-surgery-laboratory-fabricated

Figure 9: (a) Using the laboratory-fabricated splint, the two abutments were tightened on the implants in the patient’s mouth with the (b) Gingiva forming a tight drape around them.

medical-implants-surgery-zinc-phosphate

Figure 9c: Zinc-phosphate cement was then used for cementing the restoration

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Discussion

From a prosthetic point of view it has been argued that low-cost dental implants may result in compromised long-term performance due to increased levels of micromotion at the implant abutment interface as compared to established implant systems [8]. While such statements are often based on in vitro research, clinical data on this question is widely missing. The implant system used here is characterized by an internal hexagon prosthetic platform which is in widespread use in a variety of implant systems [9].

The multipurpose abutment [10] used here allows the clinician to visualize the implant position during the insertion process while the antirotational feature (flat outer surface) ensures proper positioning of the laboratory implant - abutment assembly into the closed tray impression. During the laboratory stage, the wall thickness of this abutment allows for compensating non-parallelism of implants. However, depending on the degree of implant disparallelism, this may be a labor intensive process and it should be checked whether preangled abutments might constitute an alternative option.

CAD/CAM fabrication of prosthetic frameworks from zirconia ceramic followed by veneering has come into wide-spread use with excellent long-term results being reported in current publications [11]. The use of cement-retention seemed to be unproblematic in this patient as the finish lines have been raised by the individualized abutments so that potentially harmful cement remnants could easily be removed [12] which should be conducive to long-term survival of the restoration.

Instead of strictly following either the traditional or the modern CAD/CAM way for restoring dental implants, the advantages of both options were combined here. In addition to transfer components, traditional fabrication techniques require stock abutments which in combination with waxing sleeves form the basis for modelling a specific restoration which is subsequently cast using metal alloy. The framework obtained can subsequently be ceramic veneered either by layering or overpressing. The major disadvantages of this approach are the greater number of implant components needed plus the cost for alloy which may be substantial when high-noble material is used. As waxing, casting and finishing procedures are time consuming, the approach chosen here only included the individualization of abutments purchased in combination with the implants. Strictly adhering to CAD/ CAM principles would have meant that following model scanning requiring a scanbodies, CAD/CAM abutments would have been fabricated involving additional cost. Instead, the modified abutments were scanned and comparably inexpensive restorative material was used for obtaining the framework.

Overall, this case certainly not presents high-end implant dentistry with respect to planning, implant positioning, loading protocol and pink esthetics but it demonstrates how regular patients can be restored predictably with a minimum of interventions and cost.

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References

Citation: Karl M, Schmidtler G (2016) Combining Traditional and CAD/CAM Techniques for Simplifying Dental Implant Therapy. J Med Imp Surg 1: 103.

Copyright: © 2016 Karl M, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

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