Lignin (LIG) is a natural biopolymer with well-known antioxidant capabilities. Accordingly, in the present work, a method to combine LIG with poly(lactic acid) (PLA) for fused filament fabrication applications (FFF) is proposed. For this purpose, PLA pellets were successfully coated with LIG powder and a biocompatible oil (castor oil). The resulting pellets were placed into an extruder at 200 °C. The resulting PLA filaments contained LIG loadings ranging from 0% to 3% (w/w). The obtained filaments were successfully used for FFF applications. The LIG content affected the mechanical and surface properties of the overall material. The inclusion of LIG yielded materials with lower resistance to fracture and higher wettabilities. Moreover, the resulting 3D printed materials showed antioxidant capabilities. By using the 2,2-diphenyl-1-picrylhydrazyl (DPPH) method, the materials were capable of reducing the concentration of this compound up to ca. 80% in 5 h. This radical scavenging activity could be potentially beneficial for healthcare applications, especially for wound care. Accordingly, PLA/LIG were used to design meshes with different designs for wound dressing purposes. A wound healing model compound, curcumin (CUR), was applied in the surface of the mesh and its diffusion was studied. It was observed that the dimensions of the meshes affected the permeation rate of CUR. Accordingly, the design of the mesh could be modified according to the patient’s needs.
Lignin is the second most abundant
biopolymer on the planet. It
is a biocompatible, cheap, environmentally friendly and readily accessible
material. It has been reported that these biomacromolecules have antimicrobial
activities. Consequently, lignin (LIG) has the potential to be used
for biomedical applications. In the present work, a simple method
to prepare lignin-based hydrogels is described. The hydrogels were
prepared by combining LIG with poly(ethylene glycol) and poly(methyl
vinyl ether-co-maleic acid) through an esterification
reaction. The synthesis took place in the solid state and can be accelerated
significantly (24 vs 1 h) by the use of microwave (MW) radiation.
The prepared hydrogels were characterized by evaluation of their swelling
capacities and with the use of infrared spectroscopy/solid-state nuclear
magnetic resonance. The prepared hydrogels showed LIG contents ranging
between 40% and 24% and water uptake capabilities up to 500%. Furthermore,
the hydrophobic nature of LIG facilitated loading of a model hydrophobic
drug (curcumin). The hydrogels were capable of sustaining the delivery
of this compound for up to 4 days. Finally, the materials demonstrated
logarithmic reductions in adherence of Staphylococcus
aureus and Proteus mirabilis of up to 5.0 relative to the commonly employed medical material
poly(vinyl chloride) (PVC).
We describe, for the first time, stimulus-responsive hydrogel-forming microneedle (MN) arrays that enable delivery of a clinically relevant model drug (ibuprofen) upon application of light. MN arrays were prepared using a polymer prepared from 2-hydroxyethyl methacrylate (HEMA) and ethylene glycol dimethacrylate (EGDMA) by micromolding. The obtained MN arrays showed good mechanical properties. The system was loaded with up to 5% (w/w) ibuprofen included in a light-responsive 3,5-dimethoxybenzoin conjugate. Raman spectroscopy confirmed the presence of the conjugate inside the polymeric MN matrix. In vitro, this system was able to deliver up to three doses of 50 mg of ibuprofen upon application of an optical trigger over a prolonged period of time (up to 160 h). This makes the system appealing as a controlled release device for prolonged periods of time. We believe that this technology has potential for use in "on-demand" delivery of a wide range of drugs in a variety of applications relevant to enhanced patient care.
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