Development of an in vitro ventricular shunt material testing model and utility of PEG as antifouling coating.

IF 2.1 3区医学 Q3 CLINICAL NEUROLOGY

Journal of neurosurgery. Pediatrics Pub Date : 2024-04-26 Print Date: 2024-07-01 DOI:10.3171/2024.2.PEDS23456

Nicholas J Prindeze, Stephen G Szeto, Neta Glaser, Cyan B Brown, Dan E Azagury, Cormac O Maher

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Abstract

Objective: CSF shunts, most commonly the ventriculoperitoneal shunt, remain a first and last line of management for children and adults with hydrocephalus. However, the failure rates of these shunts are extremely high, leaving many patients with the need for revision surgical procedures. The objective of this study was to develop a model to assess the efficacy of a nonfouling ventricular catheter. A second objective was to test polyethylene glycol (PEG) as an antifouling coating.

Methods: Microglial cells were grown on medical-grade catheter silicone with biofouling simulated by collagen incubation over a range of concentrations from 31 to 103 µg/ml and durations from 2 to 18 hours. After ideal fouling conditions were identified, catheter silicone was then coated with PEG as an antifouling surface, and cell growth on this surface was compared to that on uncoated standard catheter silicone.

Results: Collagen biofouling increased cell growth on silicone surfaces with an ideal concentration of 69 µg/ml and incubation of 6 hours. PEG coating of silicone catheter material yielded 70-fold lower cell growth (p < 0.0001), whereas collagen-fouled PEG-coated silicone yielded 157-fold lower cell growth (p < 0.0001).

Conclusions: Catheter coating significantly reduced cell growth, particularly in the setting of biofouling. The application of antifouling surfaces to ventricular shunts shows considerable promise for improving efficacy.

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开发体外心室分流材料测试模型和 PEG 作为防污涂层的实用性。

目的：脑脊液分流术（最常见的是脑室腹腔分流术）仍然是治疗儿童和成人脑积水的首选和最后手段。然而，这些分流术的失败率极高，导致许多患者需要进行翻修手术。本研究的目的是开发一个模型，以评估不结垢脑室导管的功效。第二个目的是测试聚乙二醇（PEG）作为防污涂层的效果：方法：在医用导管硅胶上培养小胶质细胞，通过胶原蛋白孵育模拟生物污垢，浓度范围为 31 至 103 µg/ml，持续时间为 2 至 18 小时。在确定了理想的堵塞条件后，导管硅胶表面涂上了 PEG 作为防堵塞表面，并将该表面上的细胞生长情况与未涂覆的标准导管硅胶上的细胞生长情况进行了比较：结果：在理想浓度为 69 µg/ml 和培养 6 小时的情况下，胶原生物污垢会增加硅胶表面的细胞生长。硅胶导管材料的 PEG 涂层使细胞生长速度降低了 70 倍（p < 0.0001），而胶原生物污垢 PEG 涂层硅胶使细胞生长速度降低了 157 倍（p < 0.0001）：结论：导管涂层能明显减少细胞生长，尤其是在生物污垢的情况下。在心室分流管上应用防污表面有望提高疗效。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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