Abstracts

IMPLANTOLOGY

Photoelastic analysis of stress distribution on parallel and angled implants after installation of fixed prostheses

Análise fotoelástica de distribuição de tensões em implantes paralelos e angulados após a instalação de próteses fixas

Cristiane Ueda^I; Roberto Adrian Markarian^II; Cláudio Luiz Sendyk^II; Dalva Cruz Laganá^II

Department of Prosthodontics, School of Dentistry, University of São Paulo:

^IGraduate Students

^IIAssistant Professors

ABSTRACT

The longevity of implant-supported prosthetic rehabilitation depends largely on how the masticatory forces are transferred to the implants and surrounding bone. Anatomical conditions, bone morphology and aesthetics usually dictate implant placement in less than ideal positions for prosthetic rehabilitation and sometimes it is possible to find them with different inclinations. The purpose of this paper was to compare, through photoelastic analysis, the stress distribution in a fixed prosthesis with 3 parallel implants, to the stress distribution in the same prosthesis in the existence of an angled central implant. Two photoelastic resin models were made and a polariscope was used in the visualization of isochromatic fringes formed in the models when axial loads of 2 kg, 5 kg and 10 kg were applied to a unique central point of the prosthesis. The presence of inducted tensions (preloads) was observed in the models after applying torque to the retention screws. Preloads were intensified with the incidence of occlusal forces. In the parallel implants, the force dissipation followed the long axis. The angled implant had a smaller quantity of fringes and the stresses were located mostly around the apical region of the lateral implants.

Descriptors: Dental implantation, endosseous; Prosthesis implantation.

RESUMO

A longevidade das reabilitações orais implanto-suportadas depende, em grande parte, de como as forças mastigatórias são transferidas aos implantes e ao osso que os circunda. Condições anatômicas, morfologia óssea e estética muitas vezes ditam a colocação de implantes em posições que não são ideais para a reabilitação protética, e podemos encontrá-los com diferentes inclinações. A proposta deste trabalho foi comparar, através de análise fotoelástica, a dissipação de tensões em uma prótese fixa com 3 implantes paralelos entre si com a dissipação de tensões na mesma prótese na existência do implante central angulado. Foram confeccionados dois modelos de resina fotoelástica. Utilizou-se um polariscópio para visualização das franjas isocromáticas que se formaram nos modelos fotoelásticos quando cargas axiais de 2 kg, 5 kg e 10 kg foram aplicadas em um mesmo ponto central da prótese. Verificou-se a indução de tensões (pré-tensões) nos modelos após o apertamento dos parafusos de retenção das próteses. As pré-tensões foram agravadas com a incidência de forças oclusais. Nos implantes paralelos, a dissipação de forças seguiu os longos eixos. No implante angulado houve menor quantidade de franjas, e as tensões estavam localizadas principalmente ao redor da região apical dos implantes laterais.

Descritores: Implante dentário endoósseo; Implante de prótese.

INTRODUCTION

An important difference between natural teeth and dental implants is the fact that dental implants do not move in response to applied loads. As titanium implants do not have a periodontal ligament, intensive loads are transmitted and distributed to the adjacent bone. However, it is desirable in the implant-supported prosthesis that masticatory loads are distributed evenly.

There is a physiological limit of bone tolerance to tensile and compressive strengths and bone-resorption may occur. The loading threshold tolerated by the bone is not well-known and the failure of osseointegration can be caused by bone resorption as a result of unfavorable stress concentrations¹¹. In accordance to Kohn¹⁶ (1992), tension distribution is one of the important factors related to implant success; the tensions should be transferred to the adjacent bone, preferentially in an orientation and magnitude that keep the tissues viability near a physiologic state.

According to Canay et al.⁵ (1996), there is little information about the magnitude of stress threshold to initiate bone resorption. A great number of local and systemic factors influence bone behavior and some researchers accept the concept that loading represents the main factor for regulation of bone remodelling during life.

Photoelastic stress analysis is based on the property that some transparent materials exhibit colorful patterns when submitted to loads and viewed with polarized light. This array of colored patterns is called isochromatic fringes. Studies with photoelastic analysis have been throughly conducted to determine the stress distribution around natural teeth, abutments of removable partial prosthesis and fixed partial prosthesis⁸; around endosseous implants under complete dentures^9,14 or to determine stresses around endosseous implants supporting fixed prosthesis^{1,6,8,12,13,15,17}.

The stress distribution around implants placed in the first molar mandibular area was biomechanically analyzed in a two-dimensional mathematical model according to the work of Canay et al.⁵ (1996). Vertical and angled implants were submitted to vertical loads of 100 N and lateral loads of 50 N. The stress-inducted difference in the surrounding bone, in vertical and angled implants, was higher around the cervical region and lower around the middle third and apical regions. The long-term success of dental implants seems to be critically related to bone presence in the cervical region of dental implants.

Federick, Caputo⁹ (1996) used photoelastic models to verify the loads transferred from overdentures to implants with: Hader splinting bar, Hader splinting bar with distal resilient cap ERA^® system, and only with the ERA^® resilient cap system, with 2 vertical implants parallel to each other and with 2 convergent inclined implants for occlusion with 17º of inclination. The ERA^® system generated tensions with smaller intensity and more uniform distribution. They concluded that regardless of the overdenture retention system used, the higher stress concentration was found in the distal surfaces of the inclined implants. Brosh et al.³ (1998) also verified that vertical loads applied in angled abutments produced higher stresses at the coronal zone of the implant compared with straight abutments.

Guichet et al.¹² (2000) compared cement-retained or screw-retained implant restorations, using a photoelastic model with three implants. The marginal gaps were measured with a microscope before and after the cementation or screwing of the prosthesis. The photoelastic analysis revealed that the cement-retained prosthesis had a more equal stress ditribution than its screw-retained counterparts.

The previous planning of implant localization interferes in the stress distribution and because of some differences observed the use of parallel implants rather than angled ones is preferable. The longevity of the treatment can be increased if load distribution on bone is better understood^2,4,7.Thus, every effort should be made to achieve an ideal implant location and occlusion should be meticulously determined to avoid eccentric loading.

The aim of the present study was to compare, through photoelastic analysis, the distribution of stress of a fixed prosthesis with 3 parallel implants to the distribution of stress in the same prosthesis with an angled central implant, under vertical loading.

MATERIAL AND METHODS

Two photoelastic resin blocks were made in the following dimensions: 30 mm in height, 75 mm in width and 12 mm in thickness. In order to obtain the models in resin, a preliminary plaster model was made using 3 drillings to place 3 implants in the corresponding positions of the first premolar, second premolar and first molar. All of them were placed parallel to each other with a distance of 4 mm between implants (model P). In the second model (A) the implant corresponding to the inferior second pre-molar had its mesiodistal angle changed to 30º.

Three implant analogs were positioned in the drillings. Upon these analogs the impressioned copings were positioned. This impression was the photoelastic resin modeling pattern. Three Conexão^® implants, (Conexão Master, São Paulo, Brazil) 10.0 mm in length and 3.75 mm in diameter, were fixed in their impression copings, in the silicon molding. The PL-2 Liquid Plastic resin (Measurement Group Inc., Raleigh, USA) was poured in order to obtain the photoelastic model with the implants transferred. The complete osseointegration is supposed to allow a contact of the polymerized resin and the implants.

A metallic structure was manufactured using prefabricated cylindrical titanium tubes, Conexão^® (Conexão Master, São Paulo, Brazil), that were laser welded. A three element threaded structure to the implants was then obtained. The fit of the metallic structure over the implants was verified through a Laboval 4 microscope (Carl Zeiss, Jena, Switzerland) with a 170 X lens. A torque control (Lifecore Biomedical Inc., California, USA) was used in the attachment of the prosthesis to the implants, with a calibrated force of 20 N, according to manufacturer's specifications.

The prosthesis was subjected to loads of 2 kg, 5 kg, and 10 kg through a tip connected to the central point of the prosthesis. The model was immersed in mineral oil to decrease the light refraction of the surface and to facilitate the observation of the isochromatic fringes, according to Federick, Caputo⁹ (1996).

High-resolution digital photos were taken with a Mavica FD 97 camera (Sony, California, USA). The stresses generated in photoelastic models for each loading application were observed. The analysis was made using a circular polariscope, specially manufactured for this study, an analyser, and a source of white light to produce internal colored pattern stresses in the photoelastic material (Figure 1).

After the photographic recordings of model P, the same prosthesis was installed in model A. The visual interpretation of the isochromatic fringes of the photoelastic model was performed by two examiners and to help qualitative analysis, the area around each implant was divided into three points: left cervical, apical, and right cervical, identified by the letters of the alphabet (Figure 2).

Each fringe represented a stress level and for analysis, two factors were considered, according to French et al.¹⁰ (1989):

RESULTS

Observing the photographic records of the models without load application, we did not observe fringes in the photoelastic resin model, which indicates the absence of tension¹⁴ (Figures 3 and 4).

The first analyzed condition was the torque of the screws during the installation of the prosthesis, when a small stress was observed, in both the parallel and angled implants (Figures 5 and 6).

The load application in the parallel implants showed lower stress intensity, better distribution and uniformity among them, with a larger concentration in the apical region, mostly in the central implant. In the angled implant, the intensity of the stress was higher and the location of this stress in the central implant was smaller. The concentration was higher in the implants located on both extremities. In the two models, a higher intensity of the stress was observed when a greater load was applied (Figures 7 to ¹² ).

Upon the application of 5 kg of load, the stress increased in the two models (Figures 9 and 10). We can note that in the three parallel implant model, the tensions were concentrated on the middle implant just in the central location of the load application. In the model with the angled implant, this one maintained a lower stress concentration when compared to the other two lateral parallels.

The apical region of the implants had a higher stress concentration when 10 kg of load was applied (^{Figures 11} and ¹² ), following the same concentration standard of lower loads. In model P, with the parallel implants, the concentration of stress was higher in the central implant and in model A, the stress concentration was higher in the lateral implants.

For quantitative analysis of the stress distribution a sequential table was used following color sequences of fringes (Table 1).

The values of the isochromatic fringes expressed through the respective numbers of order were harvested in points selected from models P and A (Figure 2). The results of readings were expressed in Table 1 and Graphs 1 and 2.

DISCUSSION

According to the research by Deines et al.⁸ (1993) and French et al.¹⁰ (1989), factors such as concentration and magnitude of stress are related to variables such as the antagonistic tooth, occlusal force, number of implants to distribute the load, position of the implant, rigidity of the prosthesis and geometry of the implant distribution. These results are in accordance to the work presented by Kenney, Richards¹⁴ (1998) that had the same lengths, the same widths and equal formats in their angulations, thus validating the comparisons studied. These principles were applied in our study.

In this model the force applied on the prosthesis was axial. However, it is known that in an in vivo situation, transversal and lateral forces are also present. We used only axial loads because of our agreement with the works of Deines et al.⁸ (1993) and Canay et al.⁵ (1996) that considered these forces more relevant in clinical conditions.

Photoelastic analysis has been widely used in dentistry to study the biomechanical stress transfer in several kinds of prosthesis. The photoelastic model is a different homogeneous plastic material that simulates human bone constituted of cortical bone and cancellous bone. We realized that the magnitude of the stresses in real bone can be different from those in a model. However, the location and general standard of these stresses are similar¹⁵. The technique used also facilitates a two-dimensional view of the stress concentration¹⁴.

Waskewicz et al.¹⁷ (1994) affirmed that stress generation is initiated with the fixation of the prosthesis to the abutments and according to them this force can decrease with a well-settled structure. This study recommends the section of the prosthesis for soldering. Our work also verified a low stress generation when turning the screws of the prosthesis. Considering that the prosthesis was passively settled, such tensions were not considered very significant. Guichet et al.¹² (2000) studied the difference between cement-retained and screw-retained implanted prosthesis and concluded that the significant decrease in the marginal fit was obtained with the screw-retained prosthesis that was associated with higher stress generation. On the other hand, an increase of the marginal fit of the cement-retained prosthesis was associated to lower stress generation in the photoelastic resin model. We believe that this occurred because part of the occlusal loads are dissipated by the cement layer, suggesting that the cementation layer can be broken with consequent detachment of the prosthesis.

According to Canay et al.⁵ (1996) and Brosh et al.³ (1998) the angled implants generated excessive tensions in the cervical region when submitted to vertical loads. This fact has an importance in the longevity of the implants since bone loss in the cervical region can compromise the stability of the implant, promoting the penetration of pathogenic bacteria, causing inflammation, bone loss and mobility of the implant. The researchers affirm that the angulated implants, usually planned in the posterior region where vertical loads are common, should be avoided. Federick, Caputo⁹ (1996) agree that a perpendicular placement of implants to the occlusal surface can reduce the intensity of the tensions and the stress concentration around them.

Our study found a smaller tension concentration in the angled implant, unlike the results found in other studies^3,6,9. This can be explained by the fact that in our work we evaluated three implants and a fixed prosthesis and not only one or two implants.

In our research, the angled implant was positioned between two other parallel implants which could be considered interesting in rehabilitation planning where parallel implant placement is not possible. This is also interesting considering that we did not find a higher concentration of stress in the cervical region of the angled implant.

CONCLUSIONS

Considering some limitations of our study we were able to conclude that:

ACKNOWLEDGMENTS

FAPESP (The State of São Paulo Research Foundation), for research funding conceded in 2001 and 2002 (process 00/12921-3); Conexão Systems, for the supply of the implants and components; Titanium Central Laboratory, for technical works.

Received for publication in Feb 07, 2003

Sent for alterations in Apr 25, 2003

Accepted for publication in Feb 15, 2004

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