In vitro study of structural and mechanical properties of latex and non-latex intermaxillary orthodontic elastics

In vitro study of structural and mechanical properties of latex and non-latex intermaxillary orthodontic elastics

Purpose We evaluated bacterial endotoxin adhesion, superficial micromorphology and mechanical properties of latex and non-latex intermaxillary orthodontic elastics. Methods To quantify the adhered bacterial endotoxin, elastics were divided into 5 groups: experimental ( n  = 12) latex and non-latex e...

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Published in:Journal of orofacial orthopedics Vol. 84; no. Suppl 2; pp. 111 - 122
Main Authors: Lucisano, Marília Pacífico, Romero, Mónica Verónica Escalante, da Silva, Raquel Assed Bezerra, da Silva, Léa Assed Bezerra, Palma-Dibb, Regina Guenka, Faraoni, Juliana Jendiroba, Romano, Fábio Lourenço, Nelson-Filho, Paulo
Format: Journal Article
Language:English
Published: Heidelberg Springer Medizin 01-04-2023
Subjects:
Dental Stress Analysis
Dentistry
Elasticity
Materials Testing
Medicine
Oral and Maxillofacial Surgery
Original Article
Orthodontic Appliances
Stress, Mechanical
Degradation of force
Oberflächenrauheit
Internal diameter
Innerer Durchmesser
Degradation der Kraft
Bakterielles Endotoxin
Confocal microscopy
Surface roughness
Bacterial endotoxin
Konfokale Mikroskopie
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Summary:Purpose We evaluated bacterial endotoxin adhesion, superficial micromorphology and mechanical properties of latex and non-latex intermaxillary orthodontic elastics. Methods To quantify the adhered bacterial endotoxin, elastics were divided into 5 groups: experimental ( n  = 12) latex and non-latex elastics, previously contaminated by an endotoxin solution, negative control ( n  = 6) latex and non-latex elastics without contamination, and positive control ( n  = 6) stainless steel specimens (metallic replicas), contaminated by an endotoxin solution. In parallel, the structural micromorphology ( n  = 6) and surface roughness of latex and non-latex intermaxillary orthodontic elastics were assessed using confocal laser microscopy. Force degradation (g) and deformation of the internal diameter change (mm) were also evaluated. Structural micromorphology, surface roughness (µm), force degradation (g) and internal diameter (mm) change were evaluated at time 0 and after 24 and 72 h in a deformation test. Data were analyzed by the Shapiro–Wilk, Kruskal–Wallis, Dunn, ANOVA and Bonferroni tests (α = 5%) . Results Endotoxin adhered similarly to both types of elastics with scores of 3 (> 1.0 EU/mL). The surface microstructure of both types of elastics showed irregularities and porosities at all times. Initially, the latex elastics had a higher surface roughness ( p  < 0.001) than the non-latex ones. After 24 h loading, surface roughness of the latex elastics was significantly reduced ( p  < 0.001), while after 72 h, the values were similar for both types ( p  > 0.05). The non-latex elastics had significantly higher force generation values ( p  < 0.05) at 0, 24 and 72 h compared with the latex elastics, although there was a significant reduction ( p  < 0.001) in force over time for both elastics. Despite similar initial values, non-latex elastics had a significantly larger internal diameter ( p  < 0.001) after the loading periods of 24 and 72 h compared with the latex elastics. Conclusion Both elastics showed high affinity with endotoxin and microstructural irregularities of their surface. The non-latex elastics generated higher force values but demonstrated greater deformation of the internal diameter after loading.
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ISSN:1434-5293
1615-6714
DOI:10.1007/s00056-022-00395-6