Biocompatibility versus peritoneal mesothelial cells of polypropylene prostheses for hernia repair, coated with a thin silica/silver layer

Muzio, Giuliana; Perero, Sergio; Miola, Marta; Oraldi, Manuela; Ferraris, Sara; Verné, Enrica; Festa, Federico; Canuto, Rosa Angela; Festa, Valentino; Ferraris, Monica

doi:10.1002/jbm.b.33697

Cited by 28 publications

(23 citation statements)

References 56 publications

(147 reference statements)

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“…Very recently, Muzio et al [98] deposited a silver nanocluster/SiO 2 glass composite coating on a polypropylene prosthesis comprising a porous mesh in contact with the parietal side and a 70-µm thick smooth layer that prevented adhesion with intestine and viscera (Fig. 4d).…”

Section: Prostheses For Hernia Repairmentioning

confidence: 99%

Glass-based coatings on biomedical implants: a state-of-the-art review

Baino¹,

Verné²

2017

Biomedical Glasses

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Bioactive glasses, invented by Prof. Larry L. Hench in the late 1960s, have revolutionized the field of biomaterials as they were shown to tightly bond to both hard and soft living tissues and to stimulate cells towards a path of regeneration and self-repair. However, due to their relatively poor mechanical properties (brittleness, low bending strength and fracture toughness), they are generally unsuitable for load-bearing applications. On the other hand, bioactive glasses have been successfully applied as coatings on the surface of stronger/tougher substrates to combine adequate mechanical properties with high bioactivity and, in some cases, additional extrafunctionalities (e.g. antibacterial properties, drug release). After giving a short overview of the main issues concerning the fabrication of glass coatings, this review provides a state-of-the-art picture in the field and specifically discusses the development of bioactive and hierarchical coatings on 3D porous scaffolds, joint prostheses, metallic substrates (e.g. wires or nails) for orthopedic fixation, polymeric meshes and sutures for wound healing, ocular implants and percutaneous devices.

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Section: Prostheses For Hernia Repairmentioning

confidence: 99%

Glass-based coatings on biomedical implants: a state-of-the-art review

Baino¹,

Verné²

2017

Biomedical Glasses

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“…However, the RF sputtering of silversilica nanocluster at the same parameters with 15 min of sputtering time, yields atomic ratio of 0.37 ± 0.015 for (Ag/(Ag ? Si)) [32]. However, in the current work, the composition of silver in the top layer could not be measured because of the complex multilayer composite coating's structure and high roughness of the bottom EPD layer.…”

Section: Sputtering Condition 1 (Epd/rf-20)mentioning

confidence: 84%

“…The Ag/SiO 2 ratio was tailored to avoid an excess of Ag (higher concentration of Ag may lead to toxicity). The Ag/ SiO 2 ratio was adjusted by applying a duty cycle to the Ag target; the plasma on the Ag target was turned-on for 1 s after every 24 s through the whole deposition process of 20 and 40 min [32]. Pure Argon atmosphere was used with a deposition pressure of 5.5 dPa, and the pressure before deposition was below 0.01 mPa.…”

Section: Rf Co-sputtering Of Silver Nanoclusters-silica Compositementioning

confidence: 99%

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Multifunctional stratified composite coatings by electrophoretic deposition and RF co-sputtering for orthopaedic implants

et al. 2021

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In this study, multifunctional stratified antibacterial and bioactive coatings were deposited and characterised. Initially, PEEK/bioactive glass (BG)/ mesoporous bioactive glass nanoparticle (MBGN) layers with a thickness of 110–120 μm were deposited on stainless steel substrates using electrophoretic deposition (EPD). Thin silver nanocluster-silica composite layers with a thickness of 70–155 nm were then deposited by radio frequency (RF) co-sputtering on the previously deposited EPD coatings. The deposition was carried for two different sputtering times (20 min and 40 min), which led to different layer thicknesses. PEEK/BG/MBGNs coatings were also deposited via single-step EPD. A comparison between the physicomechanical and biological characteristics of single layer PEEK/BG/MBGNs composite coating and bilayer Ag-PEEK/BG/MBGNs is presented. Scanning electron microscopy (SEM) and energy-dispersive x-ray spectroscopy (EDX) indicated that silver nanoclusters were homogeneously distributed in the multilayered EPD/RF coatings. An apatite-like structure was formed on the surface of the coatings upon immersion in simulated body fluid (SBF) after 1 day. Silver nanoclusters embedded in the silica matrix as a top layer provided controlled release of silver ions which led to a potent antibacterial effect against E. coli and S. carnosus. Single layer coatings exhibited a burst release of Ag ions, which led to antibacterial effects but were toxic to osteoblast cells. Finally, the results of WST-8 assays confirmed that the multi-structured coatings allow osteoblast-like cells to proliferate and attach strongly on the surface of the coatings.

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“…Polypropylene meshes with a silica/silver layer have been proposed for hernia repair and showed good biocompatibility in peritoneal mesothelial cells and tissue repair [244]. An antimicrobial mesh made of PP (Optilene Silver Mesh ® from Braun) with a coating of nano-crystalline silver showed significantly better bactericidal effect than the normal PP meshes [122].…”

Section: Meshes With Antimicrobial Metalsmentioning

confidence: 99%

Prosthetic Meshes for Hernia Repair: State of Art, Classification, Antimicrobial Approaches, and Fabrication Methods

Serrano‐Aroca¹,

Pous‐Serrano²

2021

Preprint

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Worldwide, hernia repair represents one of the most frequent surgical procedures encompassing a global market valued at several billion dollars. This type of surgery usually requires the implantation of a mesh that needs the appropriate chemical, physical and biological properties for the type of repair. This review thus presents a description of the types of hernias, current hernia repair methods, and the state of the art of prosthetic meshes for hernia repair providing the most important meshes used in clinical practice by surgeons working in this area classified according to their biological or chemical nature, morphology and whether bioabsorbable or not. We emphasise the importance of surgical site infection in herniatology, how to deal with this microbial problem, and we go further into the future research lines on the production of advanced antimicrobial meshes to improve hernia repair and prevent microbial infections, including multidrug-resistant strains. A great deal of progress has been made in this biomedical field in the last decade. However, we are still far from an ideal antimicrobial mesh that can also provide excellent integration to the abdominal wall, mechanical performance, low visceral adhesion and minimal inflammatory or foreign body reactions, among many other problems.

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Biocompatibility versus peritoneal mesothelial cells of polypropylene prostheses for hernia repair, coated with a thin silica/silver layer

Cited by 28 publications

References 56 publications

Glass-based coatings on biomedical implants: a state-of-the-art review

Glass-based coatings on biomedical implants: a state-of-the-art review

Multifunctional stratified composite coatings by electrophoretic deposition and RF co-sputtering for orthopaedic implants

Prosthetic Meshes for Hernia Repair: State of Art, Classification, Antimicrobial Approaches, and Fabrication Methods

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