Novel large-pore lightweight polypropylene mesh has better biocompatibility for rat model of hernia

Gelatin Multiwalled Carbon Nanotube Composite 3D Printed Semi Biological Mesh for Abdominal Hernia Treatment

Hernia is characterized by the protrusion of organs or tissue through weakened areas in the abdominal cavity wall. A common treatment for hernia involves the implantation of a mesh which promotes the growth of new tissue around or within the implanted material in the damaged area. The mesh is typically made from synthetic materials like polypropylene. However, such meshes have safety concerns like biofilm and scar tissue formation, foreign body reactions, and chronic pain. These concerns gave rise to the development of biological meshes. Owing to mechanical weakness, biological meshes fail due to migration and rapid degradation. This study is aimed to develop a mechanically viable biopolymer-based composite degradable mesh. A gelatin-MWCNT composite 3D printed mesh has been developed with different pore sizes and filament sizes. Adding MWCNTs improved the composite's ductility, printability, hydrophilicity, and modulus, and reduced its degradation rate. The 3D-printed mesh also showed signs of cell attachment and proliferation representing non-toxicity of MWCNTs within the composite materials. The data showed improved cell adherence due to the incorporation of MWCNTs within the composite materials. Among the various material compositions tested, the composite material with gelatin with 0.01 g MWCNTs gave the optimum mechanical strength and biocompatibility results.

Safety and Effectiveness of G-Mesh® Gynecological Meshes Intended for Surgical Treatment of Pelvic Organ Prolapse-A Retrospective Analysis

Background: The prevalence of POP in women ranges from 30-40%, with 10-20% requiring surgical intervention. Annually, over 225,000 surgical procedures for POP are performed in the United States. The severity of prolapse is assessed using the four-stage POP-Q system, which facilitates clinical research by providing a standardized measure of defect severity. Surgical intervention is indicated for more severe cases, with various techniques available through vaginal or abdominal access. Synthetic meshes, primarily made of polypropylene (PP), are commonly used in POP surgeries due to their biocompatibility and mechanical support. This research aims to evaluate the effectiveness and safety of a non-resorbable, light polypropylene gynecological mesh (G-Mesh®, Tricomed S.A., Łódź, Poland) in the surgical treatment of pelvic floor prolapse in women. Methods: The meshes were implanted via laparoscopy (Dubuisson method) and laparotomy or transvaginally. A multicenter, retrospective study was conducted involving 81 patients aged 28-83. Results: The results collected at three follow-up visits indicated a high level of patient satisfaction, minimal discomfort, and no significant pain. Many patients emphasized significant improvement in quality of life and the lack of any adverse events associated with the presence of the implant. Conclusions: The G-Mesh® gynecological mesh has emerged as an effective and safe intervention for treating pelvic floor dysfunction in women, addressing conditions such as cystocele, rectocele, uterine prolapse, and ureterocele.

Effect of Compressive Modulus of Porous PVA Hydrogel Coating on the Preventing Adhesion of Polypropylene Mesh

PP mesh is a widely used prosthetic material in hernia repair. However, visceral adhesion is one of the worst complications of this operation. Hence, an anti-adhesive PP mesh is developed by coating porous polyvinyl alcohol (PVA) hydrogel on PP surface via freezing-thawing process method. The compressive modulus of porous PVA hydrogel coating is first regulated by the addition of porogen sodium bicarbonate (NaHCO3) at various quality ratios with PVA. As expected, the porous hydrogel coating displayed modulus more closely resembling that of native abdominal wall tissue. In vitro tests demonstrate the modified PP mesh show superior coating stability, excellent hemocompatibility, and good cytocompatibility. In vivo experiments illustrate that PP mesh coated by the PVA4 hydrogel that mimicked the modulus of native abdominal wall could prevent adhesion effectively. Based on this, the rapamycin (RPM) is loaded into the porous PVA4 hydrogel coating to further improve anti-adhesive property of PP mesh. The Hematoxylin and eosin (H&E) and Masson trichrome (MT) staining results verified that the resulting mesh could alleviate the inflammation response and reduce the deposition of collagen around the implantation zone. The biomimetic mechanical property and anti-adhesive property of modified PP mesh make it a valuable candidate for application in hernioplasty.

A novel electrospun polylactic acid silkworm fibroin mesh for abdominal wall hernia repair

Objective

Abdominal wall hernias are common abdominal diseases, and effective hernia repair is challenging. In clinical practice, synthetic meshes are widely applied for repairing abdominal wall hernias. However, postoperative complications, such as inflammation and adhesion, are prevalent. Although biological meshes can solve this problem to a certain extent, they face the problems of heterogeneity, rapid degradation rate, ordinary mechanical properties, and high-cost. Here, a novel electrospinning mesh composed of polylactic acid and silk fibroin (PLA-SF) for repairing abdominal wall hernias was manufactured with good physical properties, biocompatibility and low production cost.

Materials and methods

FTIR and EDS were used to demonstrate that the PLA-SF mesh was successfully synthesized. The physicochemical properties of PLA-SF were detected by swelling experiments and in vitro degradation experiments. The water contact angle reflected the hydrophilicity, and the stress‒strain curve reflected the mechanical properties. A rat abdominal wall hernia model was established to observe degradation, adhesion, and inflammation in vivo. In vitro cell mesh culture experiments were used to detect cytocompatibility and search for affected biochemical pathways.

Results

The PLA-SF mesh was successfully synthesized and did not swell or degrade over time in vitro. It had a high hydrophilicity and strength. The PLA-SF mesh significantly reduced abdominal inflammation and inhibited adhesion formation in rat models. The in vitro degradation rate of the PLA-SF mesh was slower than that of tissue remodeling. Coculture experiments suggested that the PLA-SF mesh reduced the expression of inflammatory factors secreted by fibroblasts and promoted fibroblast proliferation through the TGF-β1/Smad pathway.

Conclusion

The PLA-SF mesh had excellent physicochemical properties and biocompatibility, promoted hernia repair of the rat abdominal wall, and reduced postoperative inflammation and adhesion. It is a promising mesh and has potential for clinical application.

Latest Trends on the Attenuation of Systemic Foreign Body Response and Infectious Complications of Synthetic Hernia Meshes

Throughout the past few years, hernia incidence has remained at a high level worldwide, with more than 20 million people requiring hernia surgery each year. Synthetic hernia meshes play an important role, providing a microenvironment that attracts and harbors host cells and acting as a permanent roadmap for intact abdominal wall reconstruction. Nevertheless, it is still inevitable to cause not-so-trivial complications, especially chronic pain and adhesion. In long-term studies, it was found that the complications are mainly caused by excessive fibrosis from the foreign body reaction (FBR) and infection resulting from bacterial colonization. For a thorough understanding of their complex mechanism and providing a richer background for mesh development, herein, we discuss different clinical mesh products and explore the interactions between their structure and complications. We further explored progress in reducing mesh complications to provide varied strategies that are informative and instructive for mesh modification in different research directions. We hope that this work will spur hernia mesh designers to step up their efforts to develop more practical and accessible meshes by improving the physical structure and chemical properties of meshes to combat the increasing risk of adhesions, infections, and inflammatory reactions. We conclude that further work is needed to solve this pressing problem, especially in the analysis and functionalization of mesh materials, provided of course that the initial performance of the mesh is guaranteed.

Mesh OR Patch for Hernia on Epigastric and Umbilical Sites (MORPHEUS-Trial): The Complete Two-year Follow-up

OBJECTIVE

The objective of this trial was to identify a superior method for umbilical and epigastric hernia repair in terms of complications. Complications such as an extended operation duration, additional use of painkillers, reoperation, infection, seroma, extended wound care, extended hospitalization, and early recurrence were reported according to the Clavien-Dindo grading system.

SUMMARY BACKGROUND DATA

Over the years mesh repair is proven the gold standard for umbilical and epigastric hernias. The question remains, which mesh should be used?

METHODS

In this randomized controlled, multicenter trial, all patients ≥ 18 years with a single, symptomatic, and primary small umbilical or epigastric hernia qualified for inclusion. Flat preperitoneal polypropylene mesh repair was compared with patch repair (PROCEED Ventral Patch) (PVP).

RESULTS

A total of 352 patients were randomized; 348 patients received the intervention (n = 177 PVP vs n = 171 mesh). One out of 4 suffered from any kind of complication within 2 years postoperative (27.6%). A significant difference in complications was seen, in favor of polypropylene mesh repair (P = 0.044, 22.1% mesh vs 32.5% PVP). Reoperation was performed in 19 PVP operated patients (10.7%) versus 7 patients with polypropylene mesh repair (4.0%, P = 0.021).No significant differences were seen in recurrences (n = 13, 8.4% PVP vs n = 6, 4.1% mesh, P = 0.127).

CONCLUSIONS

In small epigastric and small umbilical hernia repair a flat polypropylene mesh repair was associated with a lower complication rate than PVP repair. No differences in recurrence rates were seen. Combining all complications, the preperitoneal positioned flat polypropylene mesh performed better.

Methacrylic Acid Copolymer Coating Enhances Constructive Remodeling of Polypropylene Mesh by Increasing the Vascular Response

This study reports that a methacrylic acid (MAA)-based copolymer coating generates constructive remodeling of polypropylene (PP) surgical mesh in a subcutaneous model. This coating is non-bioresorbable and follows the architecture of the mesh without impeding connective tissue integration. Following implantation, the tissue response is biased toward vascularization instead of fibrosis. The vessel density around the MAA mesh is double that of the uncoated mesh two weeks after implantation. This initial vasculature regresses after two weeks while mature vessels remain, suggesting an enhanced healing response. Concurrently, the MAA coating alters the foreign body response to the mesh. Fewer infiltrating cells, macrophages, and foreign body giant cells are found at the tissue-material interface three weeks after implantation. The coating also dampens inflammation, with lower expression levels of pro-inflammatory and fibrogenic signals (e.g., Tgf-β1, Tnf-α, and Il1-β) and similar expression levels of anti-inflammatory cytokines (e.g., Il10 and Il6) compared to the uncoated mesh. Contrary to other coatings that aim to mitigate the foreign body response to PP mesh, a MAA coating does not require the addition of any biological agents to have an effect, making the coated mesh an attractive candidate for soft tissue repair.

Proof of concept, design, and manufacture via 3-D printing of a mesh with bactericidal capacity: Behaviour in vitro and in vivo

Currently, hernia treatment involves implantation of a mesh prosthesis, usually made of polypropylene, and the primary complication is infection of the device, which leads to an exponential increase in morbidity. Three-dimensional printing offers a method of dealing with complications of this magnitude. Therefore, in this study, the bactericidal properties and effectiveness of three-dimensional-printed meshes with polycaprolactone (PCL) and gentamicin were evaluated in vitro in Escherichia coli cultures, and their histological behaviour was examined in vivo. Different PCL meshes were implanted into four groups of rats, with 10 rats in each group: PCL meshes, PCL meshes with alginate and calcium chloride, PCL meshes with gentamicin, and PCL meshes with alginate and gentamicin. Thirty-six microporous meshes were manufactured, and their bactericidal properties were assessed. When the meshes did not include an antibiotic, an inhibition halo was not observed; when the gentamicin was free, an asymmetric inhibition area of 5.65 ± 0.46 cm² was present; when the gentamicin was encapsulated, a rectangular area of 5.40 ± 0.38 cm² was observed. In the rats, macroporous and microporous mesh implants produced mild inflammation and substantial fibrosis with collagen and neovascular foci. A significant difference was observed in fibroblastic activity between the PCL with alginate group and the PCL with alginate and gentamicin group microporous meshes (p = .013) and in collagen deposits between the macroporous and microporous meshes in the PCL mesh group (p = .033). The feasibility of manufacturing drug-doped printed PCL meshes containing alginate and gentamicin was verified, and the meshes exhibited bactericidal effects and good histopathological behaviour.

Ventral hernia repair in rat using nanofibrous polylactic acid/polypropylene meshes

Aim: In the present study, we combined a nanofibrous polylactic acid (PLA) scaffold fabricated by electrospinning with a polypropylene (PP) material to generate a new type of mesh for hernia repair. Materials & methods: The PLA/PP mesh was tested with tensile testing, in vitro cytocompatibility and degradation. A total of 90 rats were randomly allocated to PLA/PP, PP and polyester (PE) mesh groups for the in vivo study to evaluate the properties of PLA/PP mesh. Results: PLA/PP mesh had superior mechanical properties. It also resulted in less inflammation adhesion formation (p < 0.05), which was related to the TGF-β1/Smad pathway. The distribution of collagen I and III in PLA/PP mesh was also superior to those in the other two groups (p < 0.05). Conclusion: The PLA/PP mesh would be suitable for ventral hernia repair in the future.