一种用于监测伤口敷料对手术部位感染(SSIs)和慢性伤口的抗菌活性的传感器。

IF 0.8 Q4 SURGERY
Marcus J Swann, Neville J Freeman, Fergus Watson, Stephen J Law, Steven L Percival
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引用次数: 0

摘要

抗菌浸渍伤口敷料是管理、预防和控制手术部位感染(SSIs)和感染性慢性伤口的关键工具。然而,当长期使用时,敷料的持续抗微生物治疗活性不能在体内轻易确定。因此,经常更换敷料以确保其抗菌活性得到保持。虽然频繁更换敷料可以对伤口进行评估,但这很耗时,可能会破坏伤口床,损害愈合过程。此外,这增加了患者和医院的医疗成本。本文介绍了一种新的概念,用于监测伤口敷料中抗菌成分的治疗水平,确保伤口敷料保持“适用性”,避免滥用防腐剂。这可能有助于告知临床医生抗菌药物是否仍在以治疗水平提供,以及何时更换敷料,以确保及时获得积极的临床结果。银在历史上一直被用作抗菌剂,在当代抗菌伤口敷料中无处不在。然而,由于银离子在氯化物存在下的溶解性差,以及敷料和伤口生态系统中其他成分(尤其是血清蛋白)的络合作用,其活性是复杂的。在本文中,我们详细介绍了一种使用铂(Pt)纳米带阵列电极构建的电化学银传感器(5D专利保护WO2023275553A1),并表征了其对银离子的响应。这是在存在牛血清白蛋白(BSA)和含有氯化物的模拟伤口液(SWF)的情况下测定的,并使用SWF成分的原子分析进行合理化。将SWF中的传感器响应与银在浮游和生物膜状态下对铜绿假单胞菌的抗菌活性进行比较,作为硝酸银添加量的函数。在低浓度下,SWF中的银具有良好的溶解性,但由于银与BSA的结合,抗菌效果降低,如传感器响应所示。在10ppm以上的中等浓度下,银对浮游微生物和微生物浸渍的生物膜都有效,并且很容易用传感器检测到。在高浓度下,银沉淀,溶液中的银和传感器响应都趋于平稳。这些数据证明了传感器如何与银在体外的抗菌活性相关,以及如何将其用于体内主动监测抗菌药物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Sensor for Monitoring the Antimicrobial Activity of Wound Dressings for Both Surgical Site Infections (SSIs) and Chronic Wounds.

Antimicrobial impregnated wound dressings are a critical tool for the management, prevention, and control of surgical site infections (SSIs) and infected chronic wounds. However, the sustained therapeutic antimicrobial activity of the dressing when employed for extended periods cannot be readily determined in vivo. Consequently, dressings are changed frequently to ensure that their antimicrobial activity is maintained. Whilst frequent dressing changes allow the wound to be assessed, this is time-consuming and can cause disruption to the wound bed impairing the healing process. Furthermore, this increases medical costs for the patient and hospitals. This paper introduces a novel concept to monitor the therapeutic levels of an antimicrobial component within a wound dressing ensuring the wound dressing remains "fit for purpose" and avoiding indiscriminate use of antiseptics. This could help to inform clinicians whether the antimicrobial is still being delivered at therapeutic levels and as such when to change the dressing ensuring timely positive clinical outcomes. Silver has been used historically as an antimicrobial agent and is ubiquitous in current generations of antimicrobial wound dressings. However, its activity is complex due to the poor solubility of silver ions in the presence of chloride and the effect of complexation by other components in the dressing and wound ecosystem, not least by serum proteins. In this paper, we detail an electrochemical silver sensor (5D patent protected - WO2023275553A1), constructed using a platinum (Pt) nanoband array electrode, and characterise its response to silver ions. This is determined in the presence of bovine serum albumin (BSA) and simulated wound fluid (SWF) containing chloride and rationalised using atomic analysis of the composition of the SWF. The sensor response in SWF is compared with the antimicrobial activity of silver against Pseudomonas aeruginosa in the planktonic and biofilm state, as a function of the amount of silver nitrate added. At low concentrations, silver in SWF has good solubility but reduced antimicrobial effect due to binding of silver by BSA as shown by the sensor response. At intermediate concentrations, above 10ppm, the silver was efficacious on both planktonic microorganisms and biofilm impregnated with microorganisms and readily detected with the sensor. At high concentrations, silver precipitates and both the silver in solution and the sensor response plateaus. The data demonstrates how the sensor correlates with the antimicrobial activity of the silver in vitro and how this could be used to actively monitor antimicrobials in vivo.

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