清洗后处理程序对光聚合牙科模型材料制造精度的影响。
Influence of the Rinsing Postprocessing Procedures on the Manufacturing Accuracy of Vat-Polymerized Dental Model Material.
机构信息
AEGD Residency Comprehensive Dentistry Department, College of Dentistry, Texas A&M University, Dallas, TX.
Rutgers School of Dental Medicine, Newark, NJ.
出版信息
J Prosthodont. 2021 Aug;30(7):610-616. doi: 10.1111/jopr.13288. Epub 2021 Mar 16.
PURPOSE
To evaluate the influence of rinsing solvents, namely isopropyl alcohol (IPA) and tripropylene glycol monomethyl ether (TPM), and rinsing times (5-, 7-, 9-, and 11-minutes) for the postprocessing procedures on the manufacturing accuracy of an additively manufactured dental model resin material.
MATERIAL AND METHODS
The standard tessellation language (STL file) of the digital design of a bar (15 mm × 4 mm × 3 mm) was obtained. A resin dental material (E-Model Light; Envisiontec, Dearborn, MI) and a 3D printer (VIDA HD; Envisiontec) was selected to manufacture all the specimens using the STL file following the recommended printing parameters at a room temperature of 23 °C. Two groups were generated based on the rinsing solvent used on the postprocessing procedures, namely isopropyl alcohol (IPA-group) and tripropylene glycol monomethyl ether (TPM-group). Each group was further divided into 4 subgroups (IPA-1 to IPA-4 and TPM-1 to TPM-4) depending on the rinsing time performed (5-, 7-, 9-, and 11-minutes). Twenty specimens per subgroup were fabricated. The dimensions (length, width, and height) of all the specimens were measured using a low force digital caliper (Absolute Low Force Caliper Series 573; Mitutoyo, Takatsu-ku, Kawasaki, Kanagawa). Each measurement was performed 3 times and the mean value determined. The volume of each specimen was calculated using the formula V = l × w × h. Shapiro-Wilk test revealed that the data were not normally distributed. Data were analyzed using Kruskal-Wallis (α = 0.05), followed by pairwise Mann-Whitney U tests (α = 0.0018).
RESULTS
The IPA groups obtained significantly lower trueness and precision values compared with TPM groups (p < 0.0018). Among the IPA groups, IPA-1 subgroup obtained the highest trueness and precision values compared to the rest of the IPA subgroups. The TPM-1 and TPM-2 subgroups obtained the highest trueness and prevision values among the TPM group and among all the groups tested. No significant difference was found between the TMP-1 and TPM-2 subgroups (p > 0.0018).
CONCLUSIONS
None of the manufacturing workflows tested were able to manufacture a perfect match of the bar virtual design dimensions. TPM solvent group obtained higher trueness and precision values compared to the IPA solvent group. The IPA-1 subgroup that replicated the manufacturer´s recommendations obtained the highest manufacturing accuracy among the IPA subgroup. TPM solvent used in a rinsing ultrasonic bath between 3 and 4 minutes followed by a second ultrasonic clean bath between 2 and 3 minutes of the just printed vat polymerized dental model specimens obtained the highest manufacturing accuracy values.
目的
评估冲洗溶剂(异丙醇(IPA)和三丙二醇单甲醚(TPM))和冲洗时间(5、7、9 和 11 分钟)对后处理程序对增材制造牙科模型树脂材料制造精度的影响。
材料和方法
获得数字设计棒(15 毫米×4 毫米×3 毫米)的标准 tessellation language(STL 文件)。选择树脂牙科材料(E-Model Light;Envisiontec,Dearborn,MI)和 3D 打印机(VIDA HD;Envisiontec),按照推荐的打印参数在室温为 23°C 的情况下使用 STL 文件制造所有样本。根据后处理程序中使用的冲洗溶剂,将两组分为两组,即异丙醇(IPA 组)和三丙二醇单甲醚(TPM 组)。每个组根据冲洗时间进一步分为 4 个亚组(IPA-1 至 IPA-4 和 TPM-1 至 TPM-4)(5、7、9 和 11 分钟)。每组制作 20 个样本。使用低力数字卡尺(Mitutoyo,Takatsu-ku,Kawasaki,Kanagawa)测量所有样本的尺寸(长度、宽度和高度)。每次测量进行 3 次,并确定平均值。使用公式 V = l×w×h 计算每个样本的体积。Shapiro-Wilk 检验表明数据不是正态分布的。使用 Kruskal-Wallis(α=0.05)进行数据分析,然后进行两两 Mann-Whitney U 检验(α=0.0018)。
结果
IPA 组的准确性和精度值明显低于 TPM 组(p<0.0018)。在 IPA 组中,IPA-1 亚组与其他 IPA 亚组相比,获得了最高的准确性和精度值。TPM-1 和 TPM-2 亚组在 TPM 组和所有测试组中获得了最高的准确性和精度值。TPM-1 和 TPM-2 亚组之间没有发现显著差异(p>0.0018)。
结论
测试的制造工作流程均无法制造出与棒虚拟设计尺寸完全匹配的产品。与 IPA 溶剂组相比,TPM 溶剂组获得了更高的准确性和精度值。在 IPA 亚组中,复制制造商建议的 IPA-1 亚组获得了最高的制造精度。在刚刚打印的 vat 聚合物牙科模型样本中使用冲洗超声浴 3 到 4 分钟的 TPM 溶剂,然后再使用冲洗超声浴 2 到 3 分钟,可获得最高的制造精度值。
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