导尿管表面修饰

IF 2.4 4区 材料科学 Q3 MATERIALS SCIENCE, COATINGS & FILMS
L. Gopal, T. Sudarshan
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The invasive nature of catheters comes with risks of microbial growth and incompatibility with the human system, leading to infection, inflammation and device rejection and the need to change them frequently especially in the elderly. Catheter-associated urinary infections (CAUTIs) pose a significant concern, contributing to increased mortality rates and substantial economic burdens. UTIs account for 20 to 40% of hospital-associated infections, with an estimated 80% linked to urinary catheters [3]. There has been increasing interest in developing surface modification techniques to afford microbicidal properties and biocompatibility to catheter surfaces, as seen in the increasing number of publications in the area [Figure 2]. These surface modification methods involve the use of coatings or physical microand nano-dimensional surface modifications [4]. Coatings can be classified based on their mechanism of action: passive strategies include antifouling surfaces, while active approaches involve antimicrobial coatings that disrupt biological pathways. Antifouling coatings, especially hydrogels [5], poly (tetrafluoroethylene) [6], polyzwitterions [7], and poly (ethylene glycol) [8] are being explored. These coatings are often loaded with antimicrobial agents such as antibiotics, biocidal enzymes, and bacteriophages [9]. The agents prevent CAUTIs through mechanisms such as the slow release of microbicidal chemicals, modifying catheter surfaces to prevent microbial adherence, and disrupting biofilms that allow pathogen colonization. For example, researchers developed a poly(sulfobetaine methacrylate)-tannic acid hydrogel coating loaded with antimicrobials (poly(vinylpyrrolidone)-iodine, copper ions, and nitrofurazone) through non-covalent interactions. The coating exhibited pH-responsive release of the antibacterial agents under alkaline conditions, offering improved antibacterial activity against urease-producing bacteria [10]. Urinary catheters have been coated with thin layers of silver in the form of silver oxide or silver alloy, as well as noble metal alloys (gold, silver, and palladium), to reduce bacterial adherence to their surfaces [Figure 3]. Polymeric coatings have been loaded with these noble metal species as well [11]. Diamond-like coatings (DLC) are biocompatible and offer advantageous properties like low friction, smoothness, and abrasion resistance, making them ideal for medical devices. In a recent study, DLC was deposited into 2 mm inner diameter silicon catheter tubes. Bacterial adhesion and biofilm formation were evaluated using clinical isolates. Results showed reduced adherence and biofilm formation on the DLC-coated samples compared to uncoated ones, indicating their potential for medical applications [13]. Antibiotics such as nitrofurazoneon [14] and minocycline–rifampicin [15] have been immobilized on catheter surfaces. Two approaches have been used for the immobilization. In the first approach, a layer of antibiotic is applied to cover the surface, leading to rapid drug elution. Alternatively, the antibiotic can be directly impregnated into the device polymer during production, either with or without excipients to control the drug release rate. A successful two-step polydopamine-based surface modification strategy has been reported to coimmobilize an antimicrobial peptide (Palm) and an enzyme targeting a crucial component of biofilm matrix (DNase I) on polydimethylsiloxane surfaces. This approach provided the surfaces with both antiadhesive and antimicrobial properties against relevant bacteria, both in single and dual-species scenarios. The modified surfaces demonstrated excellent stability, biocompatibility, and anti-biofilm capabilities. 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Benjamin Franklin’s 1752 invention of a silver catheter made of hinged segments of tubes may be considered the first flexible catheter in recorded history [Figure 1]. The modern balloon-based self-retaining catheter, introduced in 1933, marked a turning point in catheter design and development. Today, three main types of catheters are used: indwelling, external, and short-term catheters, which are available in various sizes, materials (including latex, silicone, Teflon, PVC, etc.), and types (straight or coude tip). The invasive nature of catheters comes with risks of microbial growth and incompatibility with the human system, leading to infection, inflammation and device rejection and the need to change them frequently especially in the elderly. Catheter-associated urinary infections (CAUTIs) pose a significant concern, contributing to increased mortality rates and substantial economic burdens. UTIs account for 20 to 40% of hospital-associated infections, with an estimated 80% linked to urinary catheters [3]. There has been increasing interest in developing surface modification techniques to afford microbicidal properties and biocompatibility to catheter surfaces, as seen in the increasing number of publications in the area [Figure 2]. These surface modification methods involve the use of coatings or physical microand nano-dimensional surface modifications [4]. Coatings can be classified based on their mechanism of action: passive strategies include antifouling surfaces, while active approaches involve antimicrobial coatings that disrupt biological pathways. Antifouling coatings, especially hydrogels [5], poly (tetrafluoroethylene) [6], polyzwitterions [7], and poly (ethylene glycol) [8] are being explored. These coatings are often loaded with antimicrobial agents such as antibiotics, biocidal enzymes, and bacteriophages [9]. The agents prevent CAUTIs through mechanisms such as the slow release of microbicidal chemicals, modifying catheter surfaces to prevent microbial adherence, and disrupting biofilms that allow pathogen colonization. For example, researchers developed a poly(sulfobetaine methacrylate)-tannic acid hydrogel coating loaded with antimicrobials (poly(vinylpyrrolidone)-iodine, copper ions, and nitrofurazone) through non-covalent interactions. The coating exhibited pH-responsive release of the antibacterial agents under alkaline conditions, offering improved antibacterial activity against urease-producing bacteria [10]. Urinary catheters have been coated with thin layers of silver in the form of silver oxide or silver alloy, as well as noble metal alloys (gold, silver, and palladium), to reduce bacterial adherence to their surfaces [Figure 3]. Polymeric coatings have been loaded with these noble metal species as well [11]. Diamond-like coatings (DLC) are biocompatible and offer advantageous properties like low friction, smoothness, and abrasion resistance, making them ideal for medical devices. In a recent study, DLC was deposited into 2 mm inner diameter silicon catheter tubes. Bacterial adhesion and biofilm formation were evaluated using clinical isolates. Results showed reduced adherence and biofilm formation on the DLC-coated samples compared to uncoated ones, indicating their potential for medical applications [13]. Antibiotics such as nitrofurazoneon [14] and minocycline–rifampicin [15] have been immobilized on catheter surfaces. Two approaches have been used for the immobilization. In the first approach, a layer of antibiotic is applied to cover the surface, leading to rapid drug elution. Alternatively, the antibiotic can be directly impregnated into the device polymer during production, either with or without excipients to control the drug release rate. 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引用次数: 0

摘要

导管自古以来就是医疗实践中不可或缺的工具,其使用可追溯到公元前六世纪,由印度外科医生Sushruta[1]使用。导管最初使用金、银、铁和木材等材料制成,几个世纪以来,导管在世界各地发展成为先进的设计。Benjamin Franklin于1752年发明了一种由铰接管段制成的银色导管,这可能被认为是有记录以来第一种柔性导管[图1]。1933年推出的现代球囊自持导管标志着导管设计和开发的转折点。如今,使用了三种主要类型的导管:留置导管、外部导管和短期导管,它们有各种尺寸、材料(包括乳胶、硅胶、特氟龙、PVC等)和类型(直式或coude尖端)。导管的侵入性带来了微生物生长和与人体系统不兼容的风险,导致感染、炎症和设备排斥,需要经常更换,尤其是在老年人中。导管相关泌尿系统感染(CAUTIs)引起了人们的极大关注,导致死亡率增加和巨大的经济负担。尿路感染占医院相关感染的20%至40%,估计80%与导尿管有关[3]。从该领域越来越多的出版物中可以看出,人们对开发表面改性技术以提供导管表面的杀微生物性能和生物相容性越来越感兴趣[图2]。这些表面改性方法涉及使用涂层或物理微纳米表面改性[4]。涂层可以根据其作用机制进行分类:被动策略包括防污表面,而主动方法包括破坏生物途径的抗菌涂层。防污涂料,特别是水凝胶[5]、聚四氟乙烯[6]、两性离子[7]和聚乙二醇[8]正在探索中。这些涂层通常装有抗菌剂,如抗生素、杀生物酶和噬菌体[9]。这些药剂通过减缓杀微生物化学物质的释放、修饰导管表面以防止微生物粘附以及破坏允许病原体定植的生物膜等机制来预防CAUTI。例如,研究人员开发了一种通过非共价相互作用负载抗菌剂(聚乙烯吡咯烷酮-碘、铜离子和呋喃西林)的聚甲基磺基甜菜碱-单宁酸水凝胶涂层。该涂层在碱性条件下表现出抗菌剂的pH响应性释放,提高了对产脲酶细菌的抗菌活性[10]。导尿管涂有氧化银或银合金形式的薄层银,以及贵金属合金(金、银和钯),以减少细菌粘附在其表面[图3]。聚合物涂层也负载了这些贵金属物种[11]。类金刚石涂层(DLC)具有生物相容性,具有低摩擦、光滑和耐磨等优点,是医疗器械的理想选择。在最近的一项研究中,DLC被沉积在内径为2毫米的硅导管中。使用临床分离物评估细菌粘附和生物膜形成。结果显示,与未涂覆的样品相比,DLC涂层样品的粘附性和生物膜形成减少,表明其具有医疗应用的潜力[13]。呋喃西林[14]和米诺环素-利福平[15]等抗生素已固定在导管表面。固定化有两种方法。在第一种方法中,在表面覆盖一层抗生素,从而实现快速药物洗脱。或者,抗生素可以在生产过程中直接浸渍到装置聚合物中,使用或不使用赋形剂来控制药物释放速率。据报道,一种成功的基于聚多巴胺的两步表面修饰策略可使抗微生物肽(Palm)和靶向生物膜基质关键成分的酶(DNase I)在聚二甲基硅氧烷表面共聚。在单物种和双物种的情况下,这种方法为表面提供了抗粘附和抗微生物的特性。改性表面表现出优异的稳定性、生物相容性和抗生物膜能力。[16] 最近,使用“细菌干扰”用乳酸杆菌益生菌对导管表面进行了改性
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Surface modification of urinary catheters
Catheters have been an indispensable tool in medical practice since ancient times, their use dating back to the sixth century BC by the Indian surgeon Sushruta [1]. Originally made using materials like gold, silver, iron, and wood, catheters have evolved into advanced designs over the centuries across the world. Benjamin Franklin’s 1752 invention of a silver catheter made of hinged segments of tubes may be considered the first flexible catheter in recorded history [Figure 1]. The modern balloon-based self-retaining catheter, introduced in 1933, marked a turning point in catheter design and development. Today, three main types of catheters are used: indwelling, external, and short-term catheters, which are available in various sizes, materials (including latex, silicone, Teflon, PVC, etc.), and types (straight or coude tip). The invasive nature of catheters comes with risks of microbial growth and incompatibility with the human system, leading to infection, inflammation and device rejection and the need to change them frequently especially in the elderly. Catheter-associated urinary infections (CAUTIs) pose a significant concern, contributing to increased mortality rates and substantial economic burdens. UTIs account for 20 to 40% of hospital-associated infections, with an estimated 80% linked to urinary catheters [3]. There has been increasing interest in developing surface modification techniques to afford microbicidal properties and biocompatibility to catheter surfaces, as seen in the increasing number of publications in the area [Figure 2]. These surface modification methods involve the use of coatings or physical microand nano-dimensional surface modifications [4]. Coatings can be classified based on their mechanism of action: passive strategies include antifouling surfaces, while active approaches involve antimicrobial coatings that disrupt biological pathways. Antifouling coatings, especially hydrogels [5], poly (tetrafluoroethylene) [6], polyzwitterions [7], and poly (ethylene glycol) [8] are being explored. These coatings are often loaded with antimicrobial agents such as antibiotics, biocidal enzymes, and bacteriophages [9]. The agents prevent CAUTIs through mechanisms such as the slow release of microbicidal chemicals, modifying catheter surfaces to prevent microbial adherence, and disrupting biofilms that allow pathogen colonization. For example, researchers developed a poly(sulfobetaine methacrylate)-tannic acid hydrogel coating loaded with antimicrobials (poly(vinylpyrrolidone)-iodine, copper ions, and nitrofurazone) through non-covalent interactions. The coating exhibited pH-responsive release of the antibacterial agents under alkaline conditions, offering improved antibacterial activity against urease-producing bacteria [10]. Urinary catheters have been coated with thin layers of silver in the form of silver oxide or silver alloy, as well as noble metal alloys (gold, silver, and palladium), to reduce bacterial adherence to their surfaces [Figure 3]. Polymeric coatings have been loaded with these noble metal species as well [11]. Diamond-like coatings (DLC) are biocompatible and offer advantageous properties like low friction, smoothness, and abrasion resistance, making them ideal for medical devices. In a recent study, DLC was deposited into 2 mm inner diameter silicon catheter tubes. Bacterial adhesion and biofilm formation were evaluated using clinical isolates. Results showed reduced adherence and biofilm formation on the DLC-coated samples compared to uncoated ones, indicating their potential for medical applications [13]. Antibiotics such as nitrofurazoneon [14] and minocycline–rifampicin [15] have been immobilized on catheter surfaces. Two approaches have been used for the immobilization. In the first approach, a layer of antibiotic is applied to cover the surface, leading to rapid drug elution. Alternatively, the antibiotic can be directly impregnated into the device polymer during production, either with or without excipients to control the drug release rate. A successful two-step polydopamine-based surface modification strategy has been reported to coimmobilize an antimicrobial peptide (Palm) and an enzyme targeting a crucial component of biofilm matrix (DNase I) on polydimethylsiloxane surfaces. This approach provided the surfaces with both antiadhesive and antimicrobial properties against relevant bacteria, both in single and dual-species scenarios. The modified surfaces demonstrated excellent stability, biocompatibility, and anti-biofilm capabilities. [16] More recently, catheter surfaces were modified with Lactobacilli probiotics using a ‘bacterial interference’
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来源期刊
Surface Engineering
Surface Engineering 工程技术-材料科学:膜
CiteScore
5.60
自引率
14.30%
发文量
51
审稿时长
2.3 months
期刊介绍: Surface Engineering provides a forum for the publication of refereed material on both the theory and practice of this important enabling technology, embracing science, technology and engineering. Coverage includes design, surface modification technologies and process control, and the characterisation and properties of the final system or component, including quality control and non-destructive examination.
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