Influence of high insertion torque on implant placement: an anisotropic bone stress analysis

Sotto-Maior, Bruno Salles; Rocha, Eduardo Passos; Almeida, Érika Oliveira de; Freitas-Júnior, Amilcar C.; Anchieta, Rodolfo Bruniera; Cury, Altair Antoninha Del Bel

doi:10.1590/s0103-64402010000600005

Cited by 27 publications

(21 citation statements)

References 19 publications

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“…From a biomechanical point of view, the connection between abutment and implant must minimize the stress generated at the implant/bone interface [10], avoiding fatiguepromoted micro strains and consequently, bone resorption [11]. Another factor that promotes overloading is the use of short implants, as the crown/implant correlation is unfavorable [12] and provides a larger vertical lever arm.…”

Section: Introductionmentioning

confidence: 99%

Stress and strain distributions on short implants with two different prosthetic connections – an in vitro and in silico analysis

Tribst

Piva

Rodrigues

et al. 2017

BDS

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101 ResumoObjetivo: Uma biomecânica ideal que minimiza a tensão entre implante e osso pode proporcionar sucesso para implantes osseointegrados. Este estudo avaliou a concentração de deformação no tecido circundante e a tensão nos componentes de dois implantes com diferentes conexões protéticas através de métodos in vitro e in silico. Material e Métodos: Vinte blocos de poliuretano foram divididos em dois grupos (n = 10), seguido da instalação de hexágono interno (IH) (AS Tecnologia -Titanium Fix, São José dos Campos, Brasil) ou de implantes cone morse (LT) (Bicon Dental Implants). Para o método da extensometria (SG), foram colocados quatro sensores ao redor dos implantes. Para a análise por elementos finitos (FEA), o mesmo bloco foi modelado e analisado. Foi aplicada uma carga axial (30 kgf) para ambas as metodologias. Os valores de tensão e deformação foram analisados quanto à correlação com o SG. Resultados: Para SG, LT apresentou uma média de deformação mais agressiva (-932) que IH (-632). Para FEA, a LT mostrou menor tensão (-547) que IH (-1169). Conclusão: Para os dois sistemas implantes, os valores de microdeformação capazes de induzir remodelação óssea indesejada não foram medidos. No entanto, para o implante IH, a presença de um parafuso de retenção tem a desvantagem de concentrar a tensão, enquanto um pilar sólido dissipa a carga axial através do implante, o que sugere um melhor desempenho para o grupo LT. ABsTRACTObjective: An ideal biomechanics minimizes the stress between implant and bone that can provide success for osseointegrated implants. This study evaluated the strain concentration in surrounding tissue and stress in the components of two implants with different prosthetic connections through an in vitro and in silico methods. Methods: Twenty polyurethane blocks were divided into two groups (n=10) followed by the installation of internal hexagon (IH) (AS Technology -Titanium Fix, São José dos Campos, Brazil) or locking taper implants (LT) (Bicon Dental Implants). For strain gauge (SG) method, four sensors were placed around the implants. For finite element analysis (FEA), the same block was modeled and analyzed. An axial load (30 kgf) was applied for both methodologies. The values of stress and strain were analyzed for correlation to SG. Results: For SG, LT presented a mean of strain most aggressive (-932) than IH (-632). For FEA, LT showed less stress (-547) then IH (-1169). Conclusion: For two implant's system, microstrain values capable to induce unwanted bone remodeling were not measured. However, for IH implant, the presence of a retention screw has the disadvantage to concentrate stress while a solid abutment dissipates the axial load through the implant that suggests a better performance for LT group.

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Section: Introductionmentioning

confidence: 99%

Stress and strain distributions on short implants with two different prosthetic connections – an in vitro and in silico analysis

Tribst

Piva

Rodrigues

et al. 2017

BDS

View full text Add to dashboard Cite

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“…After being placed in the selected site, implant must achieve primary stability in the surrounding bone which is important in the bone healing, by resisting micromovement and the resultant damage to the bone healing process. 7 Micromovement or motion between freshly placed implant and bone can jeopardise osseointegration. Therefore primary stability immediately post implant placement and in the early healing phase is necessary till the time secondary stability is gained by bone remodelling and osseointegration.…”

Section: Discussionmentioning

confidence: 99%

“…It can be measured by non-invasive clinical methods such as Periotest, Resonance Frequency Analysis (RFA) and the Insertion Torque. 1,2,7 Insertion torque can provide assessment of bone quality as a function of density and hardness, either subjectively in experienced hands or quantitatively by electronic drill devices which measure the torque required to insert implant in the bone. 3 Torque is a measure of the turning force on an object such as a bolt.…”

mentioning

confidence: 99%

Evaluation of dental implant insertion torque using a manual ratchet

Goswami

Kumar²,

Vats³

et al. 2015

Medical Journal Armed Forces India

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a b s t r a c tBackground: Dental implant insertion torque is crucial for the success of the implant and the prosthesis. This in-vivo study was undertaken to determine the average insertion torque being applied to the dental implant while surgically placing it with a non-calibrated manual ratchet.Methods: Three dental surgeons placed a total of 45 dental implants (Touareg, ADIN, Afula, Israel) in 42 selected patients. Each surgeon placed 15 implants. Standardised protocols were followed to prepare the site to place the dental implant. Each implant was placed using a manual non-calibrated implant ratchet first. Once the implant was nearly placed, a manual calibrated torque gauge ratchet was used to place the implant in its final position and at that instance, the maximum final torque applied was noted on the torque gauge scale.

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“…Insertion torque needs to be balanced as high insertion torque was found to cause tensile and compressive stress to both cortical and cancellous bone tissue, and excessive stress could cause irreversible damage to the bone. 28 On the other hand, very low tensile stress during placement can be insufficient to properly stimulate bone repair.…”

Section: Discussionmentioning

confidence: 99%

Mechanical stability assessment of novel orthodontic mini-implant designs: Part 2

Hong¹,

Truong²,

Song³

et al. 2011

The Angle Orthodontist

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; Won Moon a ABSTRACT Objective: To assess the mechanical stability of a newly revised orthodontic mini-implant design (N2) compared with a design introduced in Part 1 of the study (N1) and the most widely-used commercially-available design (CA). To evaluate the mean buccal bone thickness of maxillary and mandibular posterior teeth using cone-beam computed tomography (CBCT). Materials and Methods: From the CBCT scans of 20 patients, six tomographic cross-sections were generated for each tooth. Buccal bone thickness was measured from the most convex point on the bone to the root surface. CA (1.5 mm in diameter and 6 mm in length), N1, and N2 (shorter and narrower than N1) were inserted in simulated bone with cortical and trabecular bone layers. Mechanical stability was compared in vitro through torque and lateral displacement tests. Results: The bone thickness ranged from 2.26 to 3.88 mm. Maximum insertion torque was decreased significantly in N2 compared to N1. However, force levels for all displacement distances and torque ratio were the highest in N2, followed by N1 and CA (a 5 .05). Conclusions: Both torque and lateral displacement tests highlighted the enhanced stability of N2 compared with CA. Design revisions to N1 effectively mitigated N1's high insertion torque and thus potentially reduced microdamage to the surrounding bone. The N2 design is promising as evidenced by enhanced stability and high mechanical efficiency. Moreover, N2 is not limited to placement in interradicular spaces and has the capacity to be placed in the buccal bone superficial to the root surface with diminished risk of endangering nearby anatomic structures during placement and treatment. (Angle Orthod. 2011;81:1001-1009

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Influence of high insertion torque on implant placement: an anisotropic bone stress analysis

Cited by 27 publications

References 19 publications

Stress and strain distributions on short implants with two different prosthetic connections – an in vitro and in silico analysis

Stress and strain distributions on short implants with two different prosthetic connections – an in vitro and in silico analysis

Evaluation of dental implant insertion torque using a manual ratchet

Mechanical stability assessment of novel orthodontic mini-implant designs: Part 2

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