纺织学报 ›› 2026, Vol. 47 ›› Issue (03): 77-86.doi: 10.13475/j.fzxb.20251004901

• 生物医用材料 • 上一篇    下一篇

植酸/苯扎氯铵一步共沉积涂层聚丙烯补片的制备及其抗菌性能

刘鹏碧, 任经岗, 张宽祥, 曹东阳, 刘熙, 郭昌盛()   

  1. 五邑大学 纺织科学与工程学院, 广东 江门 529020
  • 收稿日期:2025-10-21 修回日期:2026-02-06 出版日期:2026-03-15 发布日期:2026-03-15
  • 通讯作者: 郭昌盛(1988—),男,讲师,博士。主要研究方向为功能纺织材料。E-mail:gcswy9@163.com
  • 作者简介:刘鹏碧(1990—),女,讲师,博士。主要研究方向为医用纺织品。
  • 基金资助:
    江门市基础与应用基础研究重点项目(2520002000054);五邑大学高层次人才科研启动基金(2020AL009);五邑大学高层次人才科研启动基金(AL2021003)

Preparation and antibacterial properties of coated polypropylenemeshes by one-step co-deposition of phytic acid and benzalkonium chloride

LIU Pengbi, REN Jinggang, ZHANG Kuanxiang, CAO Dongyang, LIU Xi, GUO Changsheng()   

  1. College of Textile Science and Engineering, Wuyi University, Jiangmen, Guangdong 529020, China
  • Received:2025-10-21 Revised:2026-02-06 Published:2026-03-15 Online:2026-03-15

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摘要:

针对在疝修补手术中,传统聚丙烯补片植入后易出现细菌感染、术后粘连等并发症的问题,采用低温等离子体技术与一步共沉积工艺,在聚丙烯补片表面构建植酸(PA)/苯扎氯铵(BAC)抗菌涂层,制备过程仅需4 h。借助场发射扫描电子显微镜、X射线衍射仪、傅里叶变换红外光谱仪、X射线光电子能谱仪、水接触角分析仪等对涂层补片的结构与性能进行表征,并测试其蛋白质吸附量、抗菌性能及细胞毒性。结果表明:补片表面功能化修饰成功,亲水性得到极大改善;与原始聚丙烯补片相比,涂层补片的蛋白质吸附量显著减少;对大肠埃希菌和金黄色葡萄球菌的抑菌率均达99.99%~100%,抑菌圈直径分别为22.5、40 mm;同时,涂层补片还表现出优异的顺应性及较低的细胞毒性。本研究为抗菌疝修补片的开发提供了一种操作简便且具有潜在应用前景的解决方案。

关键词: 疝修补片, 聚丙烯补片, 低温等离子体处理, 一步共沉积, 植酸, 苯扎氯铵, 抗菌性能, 医用纺织品

Abstract:

Objective Hernia repair patches are crucial medical implants, but the popularly used polypropylene meshes (PPM) are found to encounter complications such as bacterial infection, postoperative adhesion, and foreign body reaction in clinical practice. This study aims to develop functionally coated patch with required antibacterial properties, hydrophilicity and biocompatibility, thereby providing a novel approach for the research of antibacterial and anti-adhesion composite patches.

Method A phytic acid / benzalkonium chloride (PA/BAC) coating was constructed on polypropylene patch by low-temperature plasma pre-treatment combined with one-step co-deposition, mildly fabricable within 4 h. The coating was characterized by field-emission scanning electron microscopy (FE-SEM), X-ray diffractometry (XRD), X-ray photoelectron spectroscopy (XPS), Fourier transform infrared spectroscopy (FT-IR), and water contact angle (WCA) analysis. The in vitro antibacterial efficacy of the coated patch against E. coli and S. aureus was evaluated using the agar diffusion method and colony-forming unit (CFU) counting method.

Results Comprehensive characterizations and in vitro experiments confirmed that phytic acid/benzalkonium chloride (PA/BAC)-coated polypropylene patches were successfully prepared with satisfactory multifunctional properties. FE-SEM observations revealed BAC concentration-dependent coating deposition. The PA/BAC (0.08%) group showed sparse large-sized deposits, the 0.1% group exhibited smaller and denser particles, and the 0.15% group formed a continuous dense full-coverage coating, attributing to enhanced electrostatic interactions between PA and BAC. FT-IR, XRD, and XPS verified successful PA/BAC deposition on polypropylene patches. Water contact angle (WCA) measurements indicated the original PP patch had a WCA of 110.5°, while PA/BAC-coated patches achieved rapid liquid wetting within 1.61-4.41 s, reflecting significantly improved hydrophilicity. Consistently, the bovine serum albumin (BSA) adsorption capacity of coated patches( (39.4±3.04)-(44.5±2.72) mg/g) was remarkably lower than that of the original PP patch( (67.2±3.87 ) mg/g), demonstrating good hydrophilicity and biocompatibility that supports anti-tissue adhesion potential. The compliance test results of the coated patch confirmed that the patch retained its compliance, with its intrinsic flexibility effectively preserved. In vitro antibacterial tests showed PA-coated patches had no obvious inhibition zones, whereas PA/BAC coatings exhibited BAC concentration-dependent activity, where inhibition zone diameters were 14.6-22.5 mm against E. coli and 21-40 mm against S. aureus, with antibacterial rates of 99.99%-100% for both strains. The results indicated satisfactory antibacterial activity of all PA/BAC coatings against E. coli and S. aureus, with the antibacterial rate increasing with rising BAC concentration. The outstanding antibacterial performance constitutes a key innovation of this study. Cytotoxicity assays revealed that the low BAC concentration (0.05%, 0.08%) groups maintained 76%-82% cell viability, with cells adhering well and retaining normal morphology, indicating acceptable coating biocompatibility.

Conclusion In order to address bacterial infection and postoperative adhesion of polypropylene hernia meshes in clinical use, this study proposes a surface functionalization strategy with PA and BAC. A PA/BAC coating was constructed on PP patches via low-temperature plasma pretreatment combined with one-step co-deposition, gently fabricated in 4 h. This mild, simple process enables PP mesh functionalization, relying on PA's surface affinity and electrostatic interactions between PA and BAC. Static water contact angle tests showed full droplet wetting on coated patches, indicating significantly enhanced hydrophilicity. Protein adsorption assays revealed a marked reduction vs. original PP patch, supporting anti-adhesion capacity. In vitro antibacterial tests demonstrated excellent efficacy against E. coli and S. aureus, with inhibition zones expanding with BAC concentration and a 100% antibacterial rate. Cell experiments showed normal morphology and adherent growth on patches coated with 0.05%, 0.08%, and 0.1% PA/BAC. Future work will focus on optimizing BAC's concentration range and its low-toxicity modification. In summary, this one-step co-deposition strategy synergistically enhances PP patches' antibacterial and anti-adhesion functions, with simple, mild conditions suitable for industrialization, offering an innovative pathway for functionalizing hernia repair materials.

Key words: hernia repair patch, polypropylene patch, low-temperature plasma treatment, one-step co-deposition, phytic acid, benzalkonium chloride, antibacterial property, medical textiles

中图分类号: 

  • TQ 342

图1

一步共沉积法生成PA/BAC涂层补片的示意图"

图2

原PP补片和涂层PP补片的SEM 照片"

图3

原PP补片和涂层PP补片傅里叶红外光谱图"

图4

原PP补片和涂层PP补片XRD谱图"

图5

原PP补片及涂层补片表面化学成分分析"

图6

原PP补片和涂层PP补片水接触角图"

图7

涂层补片的直观顺应性表征图"

图8

涂层补片对大肠埃希菌和金黄色葡萄球菌的抑制效果"

图9

涂层补片对大肠埃希菌和金黄色葡萄球菌的杀菌效果照片"

表1

涂层补片对大肠埃希菌和金黄色葡萄球菌的抑菌率"

补片 抑菌率/%
E. coli S. aureus
PA 0 0
PA/BAC(0.05%) ≥99.99 100
PA/BAC(0.08%) 100 100
PA/BAC(0.1%) 100 100
PA/BAC(0.15%) 100 100

图10

BSA蛋白吸附量 注:***表示p≤ 0.001,结果具有统计学意义。"

图11

培养1 d和3 d的细胞形态图"

[1] 刘延圈. 一文了解疝气以及护理[J]. 健康必读, 2025(15): 128-129.
LIU Yanquan. Understanding hernia and nursing care[J]. Gems of Health, 2025(15): 128-129.
[2] SETHI V, VERMA C, GUPTA A, et al. Infection-resistant polypropylene hernia mesh: vision & innovations[J]. ACS Applied Bio Materials, 2025, 8(3): 1797-1819.
doi: 10.1021/acsabm.4c01751
[3] 王小飞. 聚氨酯凝胶改性聚丙烯补片的制备及性能研究[D]. 成都: 四川大学, 2023: 3-10.
WANG Xiaofei. Preparation and properties of polyurethane gel modified polypropylene patch[D]. Chengdu: Sichuan University, 2023: 3-10.
[4] 刘沁欣. PP/PCL复合疝修补片的开发与性能评价[D]. 上海: 东华大学, 2020: 2-8.
LIU Qinxin. Development and performance evaluation of PP/PCL composite hernia repair patch[D]. Shanghai: Donghua University, 2020: 2-8.
[5] WEI D D, JIAO G H, TAO Y H, et al. Polypropylene mesh coated with dual cross-linked hyaluronic acid/polyvinyl alcohol composite hydrogel with antiadhesion and angiogenesis properties for abdominal wall repair[J]. Advanced Materials Technologies, 2025, 10(9): 2401786.
doi: 10.1002/admt.v10.9
[6] 方琴, 周棣华, 蔺虹宾, 等. 植酸添加对铝合金微弧氧化膜组织结构及性能的影响[J]. 兵器材料科学与工程, 2026, 49(1): 111-118.
FANG Qin, ZHOU Dihua, LIN Hongbin, et al. Effect of phytic acid addition on microstructure and properties of micro arc oxidation film on aluminum alloy[J]. Ordnance Material Science and Engineering, 2026, 49(1): 111-118.
[7] 刘强, 程鑫, 游波. 植酸-硅烷改性氧化石墨烯/聚天门冬氨酸酯复合涂层的构筑及其防腐蚀机理[J]. 腐蚀与防护, 2025, 46(5): 15-23.
LIU Qiang, CHENG Xin, YOU Bo. Preparation of phytic acid and silane modified graphene oxide polyaspartic acid ester composite coating and its anti-corrosion mechanism[J]. Corrosion & Protection, 2025, 46(5): 15-23.
[8] GENG Z J, GUO C P, LU D H, et al. Natural polysaccharide-based injectable hydrogels with tunable mechanical and electrical properties enabled by phytic acid[J]. Carbohydrate Research, 2025, 554: 109555.
doi: 10.1016/j.carres.2025.109555
[9] 李文秋, 李瑞涛, 杨宗山, 等. 一种新型复合抗菌剂的制备及其抗菌性能研究[J]. 应用化工, 2021, 50(S1): 150-153, 160.
LI Wenqiu, LI Ruitao, YANG Zongshan, et al. Preparation and antibacterial properties of benzalkonium chloride-Fe3+-montmorillonite antibacterial agent[J]. Applied Chemical Industry, 2021, 50(S1): 150-153, 160.
[10] 马珂珂. 非诺贝特对大鼠结膜下组织纤维化的下调作用及其机制研究[D]. 厦门: 厦门大学, 2020: 3-5.
MA Keke. Down-regulation of fenofibrate on subconjunctival fibrosis in rats and its mechanism[D]. Xiamen: Xiamen University, 2020: 3-5.
[11] 王晓燕, 吴晓慧, 蔡碧梅. 苯扎氯铵溶液联合盐酸环丙沙星栓对细菌性阴道炎疗效研究[J]. 中华灾害救援医学, 2024, 11(10): 1159-1162, 1169.
WANG Xiaoyan, WU Xiaohui, CAI Bimei. Study on the efficacy of benzalkonium chloride solution combined with ciprofloxacin hydrochloride suppositories in the treatment of bacterial vaginosis[J]. Chinese Journal of Disaster Medicine, 2024, 11(10): 1159-1162, 1169.
[12] RAJ R, SHENOY S J, MONY M P, et al. Surface modification of polypropylene mesh with a porcine cholecystic extracellular matrix hydrogel for mitigating host tissue reaction[J]. ACS Applied Bio Materials, 2021, 4(4): 3304-3319.
doi: 10.1021/acsabm.0c01627 pmid: 35014417
[13] BREDIKHIN M, GIL D, REX J, et al. Anti-inflammatory coating of hernia repair meshes: a 5-rabbit study[J]. Hernia, 2020, 24(6): 1191-1199.
doi: 10.1007/s10029-020-02122-9
[14] YU S, SHI W T, HOUSHYAR S, et al. Preparation and performances of coated polypropylene hernia mesh with natural biomaterials[J]. Colloid and Interface Science Communications, 2021, 45: 100535.
doi: 10.1016/j.colcom.2021.100535
[15] QIAO Y S, LI Y, ZHANG Q, et al. Dopamine-mediated zwitterionic polyelectrolyte-coated polypropylene hernia mesh with synergistic anti-inflammation effects[J]. Langmuir, 2020, 36(19): 5251-5261.
doi: 10.1021/acs.langmuir.0c00602 pmid: 32336102
[16] HE X D, ZHANG J Y, XIE L W, et al. Phytic acid-promoted rapid fabrication of natural polypeptide coatings for multifunctional applications[J]. Chemical Engineering Journal, 2022, 440: 135917.
doi: 10.1016/j.cej.2022.135917
[17] DING R, YU L F, PENG P D, et al. Durable and robust antibacterial polypropylene hernia mesh for abdominal wall defect repair[J]. ACS Applied Materials & Interfaces, 2024, 16(20): 25686-25697.
[18] WEI D D, HUANG Y L, LIANG M, et al. Polypropylene mesh coated with hyaluronic acid/polyvinyl alcohol composite hydrogel for preventing bowel adhesion[J]. International Journal of Biological Macromolecules, 2024, 270: 132061.
doi: 10.1016/j.ijbiomac.2024.132061
[19] 庄金秋, 梅建国, 张颖, 等. 猪圆环病毒2型Cap蛋白琼脂扩散试验检测方法的建立[J]. 中国动物检疫, 2020, 37(9): 113-117.
ZHUANG Jinqiu, MEI Jianguo, ZHANG Ying, et al. Establishment of an agar-gel precipitation test for PCV2 cap protein[J]. China Animal Health Inspection, 2020, 37(9): 113-117.
[20] 牛世全, 李静, 张雪莹, 等. 一株抗黄芪根腐病芽孢杆菌的筛选、鉴定及抑菌物质的初步研究[J]. 西北师范大学学报(自然科学版), 2021, 57(2): 79-86.
NIU Shiquan, LI Jing, ZHANG Xueying, et al. Screening and identification of Bacillus subtilis against root rot disease of Astragalus membranaceus and preliminary study on the antibacterial substance[J]. Journal of Northwest Normal University (Natural Science), 2021, 57(2): 79-86.
[21] LI Y, XU Z H, TANG L Q, et al. Nanofibers fortified with synergistic defense route: a potent wound dressing against drug-resistant bacterial infections[J]. Chemical Engineering Journal, 2023, 475: 146492.
doi: 10.1016/j.cej.2023.146492
[22] YE S J, WEI D F, XU X, et al. Surface antimicrobial modification of polyamide by poly(hexamethylene guanidine) hydrochloride[J]. Polymers for Advanced Technologies, 2020, 31(8): 1847-1856.
doi: 10.1002/pat.v31.8
[23] PANZARASA G, OSYPOVA A, TONCELLI C, et al. The pyranine-benzalkonium ion pair: a promising fluorescent system for the ratiometric detection of wound pH[J]. Sensors and Actuators B: Chemical, 2017, 249: 156-160.
doi: 10.1016/j.snb.2017.04.045
[24] 乔燕莎, 毛迎, 徐丹瑶, 等. 用于应对疝修补术后并发症的经编补片研究进展[J]. 纺织学报, 2022, 43(3): 1-7.
QIAO Yansha, MAO Ying, XU Danyao, et al. Research progress in warp-knitted meshes for tackling complications after hernia repair[J]. Journal of Textile Research, 2022, 43(3): 1-7.
doi: 10.1177/004051757304300101
[25] WANG Z Y, HAMEDI H, ZHANG F, et al. Plasma-induced diallyldimethylammonium chloride antibacterial hernia mesh[J]. ACS Applied Bio Materials, 2022, 5(12): 5645-5656.
doi: 10.1021/acsabm.2c00695 pmid: 36446396
[26] YAO X, HU W H, LI Y H, et al. Dual dynamic crosslinked hydrogel patch embodied with anti-bacterial and macrophage regulatory properties for synergistic prevention of peritendinous adhesion[J]. Advanced Functional Materials, 2024, 34(34): 2400660.
doi: 10.1002/adfm.v34.34
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