Rynio Paweł, Galant Katarzyna, Wójcik Łukasz, Grygorcewicz Bartłomiej, Kazimierczak Arkadiusz, Falkowski Aleksander, Gutowski Piotr, Dołęgowska Barbara, Kawa Miłosz
Department of Vascular Surgery, Pomeranian Medical University in Szczecin, Powstańców Wielkopolskich 72, 70-111 Szczecin, Poland.
Department of Microbiology, Immunology and Laboratory Medicine, Pomeranian Medical University in Szczecin, Powstańców Wielkopolskich 72, 70-111 Szczecin, Poland.
Int J Mol Sci. 2022 Mar 24;23(7):3539. doi: 10.3390/ijms23073539.
Three-dimensionally-printed aortic templates are increasingly being used to aid in the modification of stent grafts in the treatment of urgent, complex aortic disorders, often of an emergency nature. The direct contact between the aortic template and the stent graft implies the necessity of complete sterility. Currently, the efficacy of sterilizing aortic templates and the effect of sterilization on the geometry of tubular aortic models are unknown. A complex case of aortic arch dissection was selected to prepare a 3D-printed aortic arch template, which was then manufactured in six popular printing materials: polylactic acid (PLA), nylon, polypropylene (PP), polyethylene terephthalate glycol (PETG), and a rigid and flexible photopolymer resin using fused deposition modeling (FDM) and stereolithography (SLA). The 3D models were contaminated with broth and The sterilization was performed using three different methods: heat (105 °C and 121 °C), hydrogen peroxide plasma, and ethylene oxide gas. Before and after sterilization, the aortic templates were scanned using computed tomography to detect any changes in their morphology by comparing the dimensions. All sterilization methods were effective in the elimination of microorganisms. Steam sterilization in an autoclave at 121 °C caused significant deformation of the aortic templates made of PLA, PETG, and PP. The other materials had stable geometries, and changes during mesh comparisons were found to be submillimeter. Similarly, plasma, gas, and heat at 105 °C did not change the shapes of aortic templates observed macroscopically and using mesh analysis. All mean geometry differences were smaller than 0.5 mm. All sterilization protocols tested in our study were equally effective in destroying microorganisms; however, differences occurred in the ability to induce 3D object deformation. Sterilization at high temperatures deformed aortic templates composed of PLA, PETG, and PP. This method was suitable for nylon, flexible, and rigid resin-based models. Importantly, plasma and gas sterilization were appropriate for all tested printing materials, including PLA, PETG, PP, nylon, flexible and rigid resins. Moreover, sterilization of all the printed models using our novel protocol for steam autoclaving at 105 °C was also 100% effective, which could represent a significant advantage for health centers, which can therefore use one of the most popular and cheap methods of medical equipment disinfection for the sterilization of 3D models as well.
三维打印的主动脉模板越来越多地被用于辅助修改支架型人工血管,以治疗紧急、复杂的主动脉疾病,这些疾病通常具有紧急性质。主动脉模板与支架型人工血管之间的直接接触意味着必须保证完全无菌。目前,主动脉模板的灭菌效果以及灭菌对管状主动脉模型几何形状的影响尚不清楚。我们选择了一例复杂的主动脉弓夹层病例来制备3D打印的主动脉弓模板,然后使用六种常见的打印材料制造该模板:聚乳酸(PLA)、尼龙、聚丙烯(PP)、聚对苯二甲酸乙二醇酯(PETG),以及一种刚性和柔性光聚合物树脂,采用熔融沉积建模(FDM)和立体光刻(SLA)技术。将3D模型用肉汤污染,然后使用三种不同的方法进行灭菌:加热(105℃和121℃)、过氧化氢等离子体和环氧乙烷气体。灭菌前后,通过计算机断层扫描对主动脉模板进行扫描,通过比较尺寸来检测其形态的任何变化。所有灭菌方法在消除微生物方面都是有效的。在121℃的高压灭菌器中进行蒸汽灭菌会导致由PLA、PETG和PP制成的主动脉模板发生显著变形。其他材料的几何形状稳定,在网格比较过程中发现的变化小于亚毫米级。同样,105℃的等离子体、气体和加热在宏观观察和使用网格分析时均未改变主动脉模板的形状。所有平均几何形状差异均小于0.5毫米。我们研究中测试的所有灭菌方案在杀灭微生物方面同样有效;然而,在诱导3D物体变形的能力方面存在差异。高温灭菌会使由PLA、PETG和PP组成的主动脉模板变形。这种方法适用于尼龙、柔性和刚性树脂基模型。重要的是,等离子体和气体灭菌适用于所有测试的打印材料,包括PLA、PETG、PP、尼龙、柔性和刚性树脂。此外,使用我们新颖的105℃蒸汽高压灭菌方案对所有打印模型进行灭菌也具有100%的效果,这对于医疗中心来说可能是一个显著的优势,因此医疗中心也可以使用最常用且廉价的医疗设备消毒方法之一来对3D模型进行灭菌。
