Biomechanical performance of resin composite on dental tissue restoration: A finite element analysis

Ouldyerou, Abdelhak; Mehboob, Hassan; Mehboob, Ali; Merdji, Ali; Aminallah, Laid; Mukdadi, Osama M.; Barsoum, Imad; Junaedi, Harri

doi:10.1371/journal.pone.0295582

Cited by 4 publications

(1 citation statement)

References 53 publications

(62 reference statements)

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“…By enhancing the bond strength between the composite and tooth structure, optimized materials can reduce the risk of restoration failure and the need for costly retreatment. Enhanced biomechanical properties, such as increased stiffness and flexural strength, can improve the longevity and performance of dental restorations [ 61 , 62 ]. Materials with higher mechanical strength can withstand chewing forces more effectively, reducing the risk of fracture and wear over time.…”

Section: Discussionmentioning

confidence: 99%

Dental biomaterials redefined: molecular docking and dynamics-driven dental resin composite optimization

Saini,

Binduhayyim,

Gurumurthy

et al. 2024

BMC Oral Health

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Background Dental resin-based composites are widely recognized for their aesthetic appeal and adhesive properties, which make them integral to modern restorative dentistry. Despite their advantages, adhesion and biomechanical performance challenges persist, necessitating innovative strategies for improvement. This study addressed the challenges associated with adhesion and biomechanical properties in dental resin-based composites by employing molecular docking and dynamics simulation. Methods Molecular docking assesses the binding energies and provides valuable insights into the interactions between monomers, fillers, and coupling agents. This investigation prioritizes SiO2 and TRIS, considering their consistent influence. Molecular dynamics simulations, executed with the Forcite module and COMPASS II force field, extend the analysis to the mechanical properties of dental composite complexes. The simulations encompassed energy minimization, controlled NVT and NPT ensemble simulations, and equilibration stages. Notably, the molecular dynamics simulations spanned a duration of 50 ns. Results SiO2 and TRIS consistently emerged as influential components, showcasing their versatility in promoting solid interactions. A correlation matrix underscores the significant roles of van der Waals and desolvation energies in determining the overall binding energy. Molecular dynamics simulations provide in-depth insights into the mechanical properties of dental composite complexes. HEMA-SiO2-TRIS excelled in stiffness, BisGMA-SiO2-TRIS prevailed in terms of flexural strength, and EBPADMA-SiO2-TRIS offered a balanced combination of mechanical properties. Conclusion These findings provide valuable insights into optimizing dental composites tailored to diverse clinical requirements. While EBPADMA-SiO2-TRIS demonstrates distinct strengths, this study emphasizes the need for further research. Future investigations should validate the computational findings experimentally and assess the material's response to dynamic environmental factors.

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Section: Discussionmentioning

confidence: 99%

Dental biomaterials redefined: molecular docking and dynamics-driven dental resin composite optimization

Saini,

Binduhayyim,

Gurumurthy

et al. 2024

BMC Oral Health

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Equivalence study of the resin-dentine interface of internal tunnel restorations when using an enamel infiltrant resin with ethanol-wet dentine bonding

Kielbassa,

Summer,

Frank

et al. 2024

Sci Rep

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This preregistered ex vivo investigation examined the dentinal hybrid layer formation of a resinous infiltrant (Icon), with reference to both thickness (HLT) and homogeneity when combined with modified tunnel preparation (occlusal cavity only) and internal/external caries infiltration. The adhesives Syntac and Scotchbond MP were used as controls (Groups 1 and 3) or in combination with Icon (Groups 2 and 4). A split-tooth design using healthy third molars from 20 donors resulted in 20 prepared dentine cavities per experimental group. The cavity surfaces (n = 80) were etched (37% H3PO4), rinsed, and air-dried. Rewetting with ethanol was followed by application of the respective primers. After labeling with fluorescent dyes, either Syntac Adhesive/Heliobond or Scotchbond MP Adhesive was used alone or supplemented with Icon. HLT, as evaluated by scanning electron microscopy, did not significantly differ (P > 0.05), and confocal laser scanning microscopy revealed homogeneously mixed/polymerized resin-dentine interdiffusion zones in all groups. Icon can be successfully integrated into an ethanol-wet dentine bonding strategy, and will result in compact and homogeneous hybrid layers of comparable thickness considered equivalent to the non-Icon controls, thus allowing for preservation of the tooth’s marginal ridge and interdental space in the case of internal/external infiltration of proximal caries.

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Material properties and finite element analysis of adhesive cements used for zirconia crowns on dental implants

Satpathy,

Pham,

Shah

2024

Computer Methods in Biomechanics and Biomedical Engineering

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Biomechanical performance of resin composite on dental tissue restoration: A finite element analysis

Cited by 4 publications

References 53 publications

Dental biomaterials redefined: molecular docking and dynamics-driven dental resin composite optimization

Dental biomaterials redefined: molecular docking and dynamics-driven dental resin composite optimization

Equivalence study of the resin-dentine interface of internal tunnel restorations when using an enamel infiltrant resin with ethanol-wet dentine bonding

Material properties and finite element analysis of adhesive cements used for zirconia crowns on dental implants

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