Institute of Biomedical Engineering, University of Toronto, Toronto, Canada.
Department of Materials Science and Engineering, University of Toronto, Toronto, Canada.
Sci Rep. 2023 May 11;13(1):7691. doi: 10.1038/s41598-023-34217-5.
Elastomers such as silicone are common in medical devices (catheters, prosthetic implants, endoscopes), but they remain prone to microbial colonization and biofilm infections. For the first time, our work shows that rates of microbial surface attachment to polydimethylsiloxane (PDMS) silicone can be significantly affected by mechanical deformation. For a section of bent commercial catheter tubing, bacteria (P. aeruginosa) show a strong preference for the 'convex' side compared to the 'concave' side, by a factor of 4.2. Further testing of cast PDMS materials in bending only showed a significant difference for samples that were manually wiped (damaged) beforehand (1.75 × 10 and 6.02 × 10 cells/mm on the convex and concave sides, respectively). We demonstrate that surface microcracks in elastomers are opened under tensile stress (convex bending) to become 'activated' as sites for microbial colonization. This work demonstrates that the high elastic limit of elastomers enables these microcracks to reversibly open and close, as 'dynamic defects'. Commercial catheters have relatively high surface roughness inherent to manufacturing, but we show that even manual wiping of newly-cast PDMS is sufficient to generate surface microcracks. We consider the implication for medical devices that feature sustained, surgical, or cyclic deformation, in which localized tensile conditions may expose these surface defects to opportunistic microbes. As a result, our work showcases serious potential problems in the widespread usage and development of elastomers in medical devices.
弹性体,如硅酮,在医疗器械(导管、义体植入物、内窥镜)中很常见,但它们仍然容易受到微生物定植和生物膜感染。我们的工作首次表明,微生物对聚二甲基硅氧烷(PDMS)硅酮表面附着的速率可以受到机械变形的显著影响。对于一段弯曲的商业导管管,与凹面相比,细菌(铜绿假单胞菌)对凸面表现出强烈的偏好,比率为 4.2。进一步仅在弯曲时对 PDMS 材料进行的测试表明,对于事先手动擦拭(损坏)的样品有明显差异(凸面和凹面分别为 1.75×10 和 6.02×10 个细胞/mm)。我们证明,在拉伸应力(凸面弯曲)下,弹性体中的表面微裂纹会张开,成为微生物定植的“活性”部位。这项工作表明,弹性体的高弹性极限使这些微裂纹能够可逆地打开和关闭,成为“动态缺陷”。商业导管具有制造过程中固有的相对较高的表面粗糙度,但我们表明,即使是对新铸造的 PDMS 进行手动擦拭,也足以产生表面微裂纹。我们考虑了在具有持续、手术或周期性变形的医疗器械中的应用,在这些器械中,局部拉伸条件可能会使这些表面缺陷暴露于机会性微生物。因此,我们的工作展示了弹性体在医疗器械中的广泛使用和开发中存在的严重潜在问题。
