Current strategies to treat pelvic organ prolapse (POP) or stress urinary incontinence (SUI), include the surgical implantation of vaginal meshes. Recently, there have been multiple reports of issues generated by these meshes conventionally made of poly(propylene). This material is not the ideal candidate, due to its mechanical properties leading to complications such as chronic pain and infection. In the present manuscript, we propose the use of an alternative material, thermoplastic polyurethane (TPU), loaded with an antibiotic in combination with fused deposition modelling (FDM) to prepare safer vaginal meshes. For this purpose, TPU filaments containing levofloxacin (LFX) in various concentrations (e.g., 0.25%, 0.5%, and 1%) were produced by extrusion. These filaments were used to 3D print vaginal meshes. The printed meshes were fully characterized through different tests/analyses such as fracture force studies, attenuated total reflection-Fourier transform infrared, thermal analysis, scanning electron microscopy, X-ray microcomputed tomography (μCT), release studies and microbiology testing. The results showed that LFX was uniformly distributed within the TPU matrix, regardless the concentration loaded. The mechanical properties showed that poly(propylene) (PP) is a tougher material with a lower elasticity than TPU, which seemed to be a more suitable material due to its elasticity. In addition, the printed meshes showed a significant bacteriostatic activity on both Staphylococcus aureus and Escherichia coli cultures, minimising the risk of infection after implanting them. Therefore, the incorporation of LFX to the TPU matrix can be used to prepare anti-infective vaginal meshes with enhanced mechanical properties compared with current PP vaginal meshes.
Implantable drug delivery devices offer many advantages over other routes of drug delivery. Most significantly, the delivery of lower doses of drug, thus, potentially reducing side-effects and improving patient compliance. Three dimensional (3D) printing is a flexible technique, which has been subject to increasing interest in the past few years, especially in the area of medical devices. The present work focussed on the use of 3D printing as a tool to manufacture implantable drug delivery devices to deliver a range of model compounds (methylene blue, ibuprofen sodium and ibuprofen acid) in two in vitro models. Five implant designs were produced, and the release rate varied, depending on the implant design and the drug properties. Additionally, a rate controlling membrane was produced, which further prolonged the release from the produced implants, signalling the potential use of these devices for chronic conditions.
Catheter associated infections are a common complication that occurs in dialysis patients. Current strategies to prevent infection include catheter coatings containing heparin, pyrogallol or silver nanoparticles, which all have an increased risk of causing resistance in bacteria. Therefore, a novel approach for manufacture, such as the use of additive manufacturing (AM), also known as 3D-printing, is required. Filaments were produced by extrusion using thermoplastic polyurethane (TPU) and Tetracycline Hydrochloride (TC) in various concentrations (e.g. 0%, 0.25%, 0.5% and 1%). The extruded filaments were used in a fused deposition modelling (FDM) 3D-printer to print catheter constructs at varying concentrations. Release studies in phosphate buffered saline (PBS), microbiology studies, thermal analysis, contact angle, ATR-FTIR, scanning electron microscopy (SEM) and X-ray Micro Computer Tomography (μCT) analysis were conducted on the printed catheters. The results suggested that TC was uniformly distributed within the TPU matrix. The microbiology testing of the catheters showed that devices containing TC had an inhibitory effect on the growth of Staphylococcus aureus NCTC 10788 bacteria. Catheters containing 1% TC maintained inhibitory effect after 10day release studies. After an initial burst release in the first 24 h, there was a steady release of TC in all concentrations of catheters. 3D-printed antibiotic catheters were successfully printed with inhibitory effect on S. aureus bacteria. Finally, TC containing catheters showed resistance to S. aureus adherence to their surfaces when compared with catheters containing no TC. Catheters containing 1% of TC showed a bacterial adherence reduction of up to 99.97%. Accordingly, the incorporation of TC to TPU materials can be effectively used to prepare antiinfective catheters using FDM. This study highlights the potential for drug impregnated medical devices to be created through AM.
Implantable
devices are versatile and promising drug delivery systems,
and their advantages are well established. Of these advantages, long-acting
drug delivery is perhaps the most valuable. Hydrophilic compounds
are particularly difficult to deliver for prolonged times. This work
investigates the use of poly(caprolactone) (PCL)-based implant
coatings as a novel strategy to prolong the delivery of hydrophilic
compounds from implantable devices that have been prepared by additive
manufacturing (AM). Hollow implants were prepared from poly(lactic
acid) (PLA) and poly(vinyl alcohol) (PVA) using fused filament fabrication
(FFF) AM and subsequently coated in a PCL-based coating. Coatings
were prepared by solution-casting mixtures of differing molecular
weights of PCL and poly(ethylene glycol) (PEG). Increasing the proportion
of low-molecular-weight PCL up to 60% in the formulations decreased
the crystallinity by over 20%, melting temperature by over 4 °C,
and water contact angle by over 40°, resulting in an increased
degradation rate when compared to pure high-molecular-weight PCL.
Addition of 30% PEG to the formulation increased the porosity of the
formulation by over 50% when compared to an equivalent PCL-only formulation.
These implants demonstrated
in vitro
release rates
for hydrophilic model compounds (methylene blue and ibuprofen sodium)
ranging from 0.01 to 34.09 mg/day, depending on the drug used. The
versatility of the devices produced in this work and the range of
release rates achievable show great potential. Implants could be specifically
developed in order to match the specific release rate required for
a number of drugs for a wide range of conditions.
Pelvic organ prolapse (POP) is one of the most common chronic disorders in women, impacting the quality of life of millions of them worldwide. More than 100 surgical procedures have been developed over the decades to treat POP. However, the failure of conservative strategies and the number of patients with recurrence risk have increased the need for further adjuvant treatments. Since their introduction, surgical synthetic meshes have dramatically transformed POP repair showing superior anatomic outcomes in comparison to traditional approaches. Although significant progress has been attained, among the meshes in clinical use, there is no single mesh appropriate for every surgery. Furthermore, due to the risk of complications including acute and chronic infection, mesh shrinkage, and erosion of the tissue, the benefits of the use of meshes have recently been questioned. The aim of this work is to review the evolution of POP surgery, analyzing the current challenges, and detailing the key factors pertinent to the design of new mesh systems. Starting with a description of the pelvic floor anatomy, the article then presents the traditional treatments used in pelvic organ disorders. Next, the development of synthetic meshes is described with an insight into how their function is dependent on both mesh design variables (i.e., material, structure, and functional treatment) and surgical applications. These are then linked to common mesh‐related complications, and an indication of current research aiming to address these issues.
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