ABSTRACT
AIM: To evaluate the microleakage at the implant-abutment (I-A) interface of Morse tapered implants inoculated with different volumes of bacterial suspension. METHODS: Morse tapered I-A sets were selected and divided in two groups depending on the type of abutment: passing screw (PS) and solid (S), and then subdivided into four subgroups (n=6) according to the suspension volume: PS1: 0.1 µL; PS3: 0.3 µL; PS5: 0.5 µL; PS7: 0.7 µL; S1: 0.1 µL; S3: 0.>3 µL; S5: 0.5 µL and S7: 0.7 µL. A control test was performed to verify the presence of external contamination during the inoculation and the implants were incubated for microbiological analysis. The microleakage was evaluated every 24 h for 7 days by the clarity of solution. After this period, the implants were disassembled for confirmation of bacterial viability. RESULTS: All the specimens with 0.7 µL and one sample of S5 presented turbidity in the control test indicating external contamination, and were excluded from the study. After 7 days of observation, none of the specimens presented positive results for microleakage and the bacterial viability was confirmed in all specimens. The 0.1 µL and 0.3 µL volumes did not present bacterial microleakage, meaning that these volumes may be inadequate for analysis. CONCLUSIONS: None of the sets evaluated showed bacterial microleakage at the I-A interface and the volume of 0.7 µL exceeded the internal capacity of the implants...
Subject(s)
Humans , Dental Implant-Abutment Design , Dental Abutments/microbiology , Escherichia coli , Dental Implants/microbiology , MicrobiologyABSTRACT
OBJECTIVES: This study evaluated the microleakage at the implant/abutment interface of external hexagon (eH) implants and abutments with different amounts of bacteria and tightening torques. MATERIAL AND METHODS: A bacterial suspension was prepared to inoculate the implants. The first phase of this study used nine EH implants and abutments that were divided into three groups with different amounts of bacterial suspension (n=3): V0.5: 0.5 µL; V1.0: 1.0 µL e V1.5: 1.5 µL, and tightened to the manufacturer's recommended torque. The second phase of this experiment used 27 assemblies that were similar to those used in the first phase. These samples were inoculated with 0.5 µL of bacterial suspension and divided into three groups (n=9). T10: 10 Ncm; T20: 20 Ncm and T32: 32 Ncm. The samples were evaluated according to the turbidity of the broth every 24 hours for 14 days, and the bacteria viability was tested after that period. The statistical evaluation was conducted by Kruskal-Wallis testing (p<.05). RESULTS: During the first phase, groups V1.0 and V1.5 was presented with bacterial contamination in all samples after 24 h. During the second phase, two samples from group T10 and one from T20 presented positive results for bacterial contamination. Different amounts of bacterial solution led to overflow and contamination during the first 24 h of the experiment. The tightening torques did not statistically affect the microleakage in the assemblies. However, the group that was tightened to 32 Ncm torque did not show any bacterial contamination. CONCLUSION: After 14 days of experimentation, the bacteria were proven to remain viable inside the implant internal cavity.
Subject(s)
Humans , Dental Abutments/microbiology , Dental Implant-Abutment Design/methods , Dental Implants/microbiology , Dental Leakage/microbiology , Torque , Bone Screws , Escherichia coli/growth & development , Materials Testing , Statistics, Nonparametric , Time FactorsABSTRACT
Preload loss can favor the occurrence of implant-abutment interface misfit, and bacterial colonization at this interface may lead to implant failure. The aim of this study was to evaluate the preload loss and bacterial penetration through the implant-abutment interface of conical and external hexagon connection systems subjected to thermal cycling and mechanical fatigue (TM). Four different implant-abutment connection systems were evaluated (n=6): external hexagon with universal post, Morse taper with universal post, Morse taper with universal post through bolt, and locking taper with standard abutment. The assemblies (implant-abutment) were subjected to a thermal cycling regimen (1,000 cycles of 5°C and 55°C) and to mechanical fatigue (1.0 million cycles, 1.0 Hz, 120 N). The assemblies were immersed in Tryptic Soy + Yeast Extract broth containing Streptococcus sanguinis and incubated at 37°C and 10 percent CO2 for 72 h. Detorque values were recorded. The bacterial penetration was assessed and the abutments were observed by scanning electron microscopy. The preload data were analyzed statistically by two-way ANOVA and Tukeys test at 5 percent significance level. All screw abutment systems showed significantly higher (p<0.05) detorque values when subjected to TM and all conical systems presented bacterial penetration. The results show no relationship between the preload loss and the bacterial penetration.
A perda da pré-carga pode favorecer o desajuste da interface implante-pilar e a colonização bacteriana nesta interface pode levar a perda de implantes. O objetivo deste estudo foi avaliar a perda de pré-carga e a infiltração bacteriana através da interface implante-pilar de sistemas de conexão cônica e hexágono externo, submetidos à ciclagem térmica e fadiga mecânica (CF). Quatro diferentes sistemas de conexão implante-pilar foram avaliados (n=6): hexágono externo com munhão universal, cone Morse com munhão universal, cone Morse com munhão universal parafuso passante e cônica justaposição com pilar padrão. Os espécimes (implante-pilar) foram submetidos à ciclagem térmica (1000 ciclos a 5°C e 55°C) e à fadiga mecânica (1,0 milhão de ciclos, 1,0 Hz, 120 N). Os espécimes foram imersos em caldo Tryptic Soy + Yeast Extract contendo Streptococcus sanguinis e incubados a 37°C e 10 por cento de CO2 por 72 h. Os valores de destorque foram registrados. A infiltração bacteriana foi avaliada e os pilares foram observados por microscopia eletrônica de varredura. Os dados de pré-carga foram analisados estatisticamente por ANOVA a dois critérios e teste de Tukey, com nível de significância de 5 por cento. Todos os sistemas de pilares parafusados apresentaram maiores valores de destorque quando submetidos à CF (p<0,05) e todos os sistemas cônicos apresentaram infiltração bacteriana. Os resultados mostram que não houve relação entre a perda da pré-carga e a infiltração bacteriana.
Subject(s)
Dental Prosthesis Design , Dental Restoration Failure , Dental Abutments/microbiology , Dental Implants/microbiology , Equipment Contamination/prevention & control , Analysis of Variance , Dental Prosthesis, Implant-Supported , Dental Stress Analysis , Dental Implantation, Endosseous/instrumentation , Dental Implants/classification , Denture Precision Attachment/microbiology , Random Allocation , Single-Blind Method , Statistics, NonparametricABSTRACT
The mouth is the portal of entry of food this provides access to a wide array of microbes, the majority of which become part of the transient oral flora. Microbiological studies on samples taken from gingival pockets surrounds overdenture abutment teeth revealed different types of bacteria. The design of the overdenture prosthesis and supporting abutments affect the nature and quantity of bacterial found and that will be revealed in this study. This study was conducted to compare the microbiological changes occurring in gingival and periodontal tissue and gingival crevicular fluid as indicators of the condition of periodontium around abutments with different designs of abutment teeth of tooth supported mandibular overdenture. Subgingival bacteriological samples were taken from abutment's gingival crevice at the time of denture insertion and after three months to evaluate the effect of abutments design on the bacterial types as well as counts. The collected samples were cultured, identified and counted. A total of 20 male patients were divided into two equal groups according to abutment's length [Group I and II]. The patients' abutments were subdivided into two equal groups according to abutment's covering [A and B]. This study revealed an increase in anaerobic bacteria in both groups, with significant increase in Group I-A [patients rehabilitated with long abutments with copings] while all other groups have shown to significant difference before and after denture insertion. Insertion of overdenture accompanied with increase of anaerobic bacteria
Subject(s)
Humans , Male , Dental Abutments/microbiology , Gingiva/microbiology , Bacteria, AnaerobicABSTRACT
The aim of this study was to evaluate surface free energy (SFE), surface roughness (SR) and surface hardness (SH) of two commercially available materials for fabricating dental implant abutments. In addition, the specimens were investigated by scanning electron microscopy (SEM) to determine the surface morphology. Twenty five discs (5 x 2 mm) of Ti-6Al-4V and Tilite (Ni-Cr-Ti) alloys were used in this study. Surface free energy was determined by the contact angle formed between a drop of distilled, deionized water and the surface of the specimen of each material. The surface roughness was measured with a mechanical profilometer and the surface hardness was evaluated by means of the Vickers hardness micro indentation test. SFE, SR and SH data were analyzed using one-way ANOVA (p < 0.05). Statistical differences (p < 0.05) were found between Ti-6Al-4V (36.2 erg.cm-2; 0.2 æm) and Tilite (30.9 erg.cm-2; 0.16 æm) for SFE and SR. However, the differences between the surface hardness values of Ti-6Al-4V (325.0 kg/mm²) and Tilite (324.3 kg/mm²) were not statistically significant (p > 0.05). Evaluations by SEM revealed different surface morphology. Within the limits of this study, it can be concluded that the Ti-6Al-4V and Tilite alloys showed differences in surface properties, except for surface hardness, suggesting that both alloys may be considered appropriate for producing abutments. Further studies are, however, necessary to elucidate the biological responses to implant abutments made with these alloys.
O objetivo deste estudo foi avaliar a energia livre de superfície (ELS), rugosidade superficial (RS) e dureza de superfície (DS) de dois materiais disponíveis comercialmente para fabricação de "abutments" de implante. Em acréscimo, os espécimes foram investigados por microscopia eletrônica de varredura (MEV) para determinar a morfologia de superfície. Vinte e cinco discos de ligas de Ti-6Al-4V e Tilite (Ni-Cr-Ti) (5 x 2 mm) foram usados neste estudo. A energia livre de superfície foi determinada pela mensuração do ângulo de contato formado entre uma gota de água destilada e deionizada e a superfície do espécime para cada material. A rugosidade superficial foi mensurada com uso de um rugosímetro e a dureza de superfície foi avaliada por meio do teste de microdureza Vickers. Os dados foram analisados usando Análise de variância (P < 0,05). Foram encontradas diferenças significantes (P < 0,05) para os valores de ELS e RS entre Ti-6Al-4V (36,2 erg.cm-2; 0,2 æm) e Tilite (30,9 erg.cm-2; 0,16 æm). Entretanto, os valores de dureza de superfície não foram diferentes para ambos os materiais (Ti-6Al-4V - 325,0 kg/mm² e Tilite - 324,3 kg/mm²) (P > 0,05). A análise topográfica dos materiais pela MEV revelou superfícies diferentes. Dentro das limitações deste estudo, concluiu-se que as ligas de Ti-6Al-4V e Tilite mostraram diferenças nas propriedades de superfícies, exceto dureza, sugerindo que ambas as ligas são adequadas para a confecção de "abutments". Entretanto, estudos são necessários para evidenciar as respostas biológicas aos "abutments" de implantes confeccionados com essas ligas.