Publication:
Physiochemical and mechanical characterisation of orthodontic 3D printed aligner material made of shape memory polymers (4D aligner material)

dc.contributor.authorGhoneima, Ahmed
dc.contributor.authorElshazly, Tarek
dc.date.accessioned2024-03-27T06:16:44Z
dc.date.available2024-03-27T06:16:44Z
dc.date.issued2023
dc.description.abstractAbstract: Objectives: To conduct a physiochemical and mechanical material analysis on 3D printed shape-memory aligners in comparison to thermoformed aligners. Materials and methods: Four materials were examined, including three thermoformed materials: CA Pro (CP), Zendura A (ZA), Zendura FLX (ZF), and one 3D printed material: Tera Harz (TC-85). Rectangular strips measuring 50 × 10 × 0.5 mm were produced from each material. Five tests were conducted, including differential scanning calorimetry (DSC), dynamic mechanical analysis (DMA), shape recovery tests, three-points bending (3 PB), and Vickers surface microhardness (VH). Results: DSC recorded glass transition temperatures (Tg) at 79.9 ◦C for CP, 92.2 ◦C for ZA, 107.1 ◦C for ZF, and 42.3 ◦C for TC-85. In DMA analysis at 20–45 ◦C, a prominent decrease in storage modulus was observed, exclusively for TC-85, as the temperature increased. Notably, within the temperature range of 30–45 ◦C, TC-85 exhibited substantial shape recovery after 10 min, reaching up to 86.1 %, while thermoformed materials showed minimal recovery (1.5–2.9 %). In 3 PB test (at 30, 37, 45 ◦C), ZA demonstrated the highest force at 2 mm bending, while TC-85 exhibited the lowest. Regarding VH at room temperature, there was a significant decrease for both ZA and ZF after thermoforming. ZA had the highest hardness, followed by ZF and TC-85, with CP showing the lowest values. Conclusions: TC-85 demonstrates exceptional shape memory at oral temperature, improving adaptation, reducing force decay, and enabling, together with its higher flexibility, extensive tooth movement per step. Additionally, it maintains microhardness similar to thermoformed sheets, ensuring the durability and effectiveness of dental aligners.en_US
dc.identifier.other304-2023.55
dc.identifier.urihttps://repository.mbru.ac.ae/handle/1/1430
dc.language.isoenen_US
dc.subjectClear alignersen_US
dc.subjectSmart polymersen_US
dc.subject3D printingen_US
dc.subjectOrthodontic removable applianceen_US
dc.subjectGraphyen_US
dc.subjectBiomaterialsen_US
dc.titlePhysiochemical and mechanical characterisation of orthodontic 3D printed aligner material made of shape memory polymers (4D aligner material)en_US
dc.typeArticleen_US
dspace.entity.typePublicationen_US

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