Evaluation of the efficacy of modal analysis in predicting the pullout strength of fixation bone screws

Einafshar, Mohammadjavad; Hashemi, Ata; Kiapour, Ata

doi:10.1002/jsp2.1220

Cited by 5 publications

(2 citation statements)

References 43 publications

(111 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Given the material used in their study had a much higher density and modulus than that in our study, such a large difference in results could be expected. The boundary and support conditions in their study are such that the implant has more vibration limitations, all of which lead to an increase in the NF ( 11 ).…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Is Acoustic modal analysis a reliable substitution for Osstell® device in dental implant stability assessment? An experimental and finite element analysis study

Alimoradi,

Einafshar,

Amid

et al. 2024

Med Oral

View full text Add to dashboard Cite

Background Different methods have been proposed to investigate the fixation stability of dental implants, each of which has its limitations. Among these methods, resonance frequency analysis (RFA) has been widely utilized to measure dental implant stability. This study aimed to assess dental implants with two non-destructive RFA and acoustic modal analysis (AMA) validated with a finite element simulation of the fundamental natural frequency (NF) of the bone analog-implant structure. Material and Methods A total number of 18 implants were inserted into two Polyurethane (PU) bone blocks with different densities (0.16 g/cc and 0.32 g/cc). AMA was used to measure NF; First, the sound originating from the axial tapping of the implant was recorded with a simple microphone. Secondly, a fast Fourier transformation algorithm was conducted to determine the NF of the implant-bone analog structure. In parallel, the ISQ (Implant Stability Quotient) value was measured using the Osstell® device. Finally, using finite element analysis (FEA), the implant-bone analog structure was modeled for validation. Results Doubling the bone analog density resulted in an average increase of 82% and 47% in the NF and ISQ using AMA and Osstell®, respectively (P-value<0.05). Furthermore, a strong linear relationship (R2= 0.93) was observed between the measured NF and ISQ values in the linear regression analysis. The NF of the dental implant predicted by FEA was overestimated by about 15.2% and 15.0% than those in the low- and high-density PUs, respectively. Moreover, the FEA predicted an increase of 83% in NF by increasing the bone analog density from 0.16 to 0.32 g/cc. Conclusions Having required the minimum process combined with easily available equipment makes it an ideal method for fixation strength studies. The good correspondence between the ISQ values and NFs, in addition to the good accuracy and reliability of the later method, confirms its application for fixation stability assessment. Key words: Acoustic modal analysis, primary stability, modal analysis, natural frequency, Osstell® test.

show abstract

Section: Discussionmentioning

confidence: 99%

“…The acoustic modal analysis (AMA) is one of the different modal analysis approaches. In this approach, the sound generated by tapping the implant is recorded and then processed by the fast Fourier transformation (FFT) algorithm ( 11 ).…”

Section: Introductionmentioning

confidence: 99%

Is Acoustic modal analysis a reliable substitution for Osstell® device in dental implant stability assessment? An experimental and finite element analysis study

Alimoradi,

Einafshar,

Amid

et al. 2024

Med Oral

View full text Add to dashboard Cite

show abstract

Nondestructive acoustic modal analysis for assessing bone screw stability: An ex vivo animal study

Einafshar,

Najafidoust,

Bastami

et al. 2024

Journal Orthopaedic Research

View full text Add to dashboard Cite

Conventional insertion torque and pull‐out tests are destructive and unsuitable for clinical bone screw fixation. This study evaluates screw stability using acoustic modal analysis (AMA) and Periotest compared to traditional methods in an ex vivo animal model. Titanium self‐tapping screws (STS) and nonself‐tapping screws (N‐STS) were implanted in the proximal tibia of 12 rabbits. Four testing methods were used to assess screw stability: peak insertion torque (PIT) during implantation, AMA for natural frequency (NF), Periotest for Periotest value (PTV), and pull‐out test for peak pullout force (PPF). Euthanization was performed at 0 (primary stability), 4, and 8 weeks (secondary stability). No significant difference in primary stability was found between STS and N‐STS except for AMA (STS: NF 2434 ± 67 Hz, N‐STS: NF 2572 ± 43 Hz; p = 0.62). Secondary stability increased significantly over time for both screw types (4‐week: NF 3687 ± 36 vs. 3408 ± 45 Hz, PTV 1.4 ± 1.6 vs. −1.5 ± 1.8, PPF 236 ± 29 vs. 220 ± 34 N; 8‐week: NF 3890 ± 39 vs. 3613 ± 31 Hz, PTV −3.2 ± 2.5 vs. −2 ± 4.3, PPF 248 ± 25 vs. 289 ± 28 N). Higher NF values for given PTV/PPF indicate potential clinical advantages. Significant differences between primary and secondary stabilities suggest osteointegration was mainly achieved in the 4‐week group.

show abstract

On the importance of precision in cortical bone drilling: Integrating experimental validation and computational modeling

Einafshar,

Rajaeirad,

Babazadeh Ghazijahani

et al. 2024

Journal of Orthopaedics

View full text Add to dashboard Cite

Evaluation of the efficacy of modal analysis in predicting the pullout strength of fixation bone screws

Cited by 5 publications

References 43 publications

Is Acoustic modal analysis a reliable substitution for Osstell® device in dental implant stability assessment? An experimental and finite element analysis study

Is Acoustic modal analysis a reliable substitution for Osstell® device in dental implant stability assessment? An experimental and finite element analysis study

Nondestructive acoustic modal analysis for assessing bone screw stability: An ex vivo animal study

On the importance of precision in cortical bone drilling: Integrating experimental validation and computational modeling

Contact Info

Product

Resources

About