Nearly 90% of thermosets are produced from petroleum resources, they have remarkable mechanical characteristics, are chemically durable, and dimensionally stable. However, they can contribute to global warming, depletion of petroleum reserves, and environmental contamination during manufacture, use, and disposal. Using renewable resources to form thermosetting materials is one of the most crucial aspects of addressing the aforementioned issues. Vanillin-based raw materials have been used in the industrial manufacturing of polymer materials because they are simple to modify structurally. Conversely, traditional thermosetting materials as a broad class of high-molecular-weight molecules are challenging to heal, decompose and recover owing to their permanent 3-D crosslinking network. Once the products are damaged, recycling issues could arise, causing resource loss and environmental impact. It could be solved by inserting dynamic covalent adaptable networks (DCANs) into the polymer chains, increasing product longevity, and minimizing waste. It also improves the attractiveness of these products in the prospective field. Moreover, it is essential to underline that increasing product lifespan and reducing waste is equivalent to reducing the expense of consuming resources. The detailed synthesis, reprocessing, thermal, and mechanical characteristics of partly and entirely biomass thermosetting polymers made from vanillin-modified monomers are covered in the current work. Finally, the review highlights the benefits, difficulties, and application of these emerging vanillin-modified vitrimers as a potential replacement for conventional non-recyclable thermosets.
In the recent years, the medical sector is getting increasingly interested in the wound dressing materials that contain medicinal herb instead of metal nanoparticles to impart antibacterial or other desirable properties. Herein, a novel multicomponent nanofibrous mat has been successfully prepared by electrospinning technique from a blended solution of polyvinyl alcohol, honey and Curcumin longa (turmeric) extract for potential application as the wound dressing material. Ethyl acetate extraction was followed to obtain the restorative components of turmeric. The fabricated nanofibrous materials were characterized by scanning electron microscope, moisture management tester, bacterial assay and Fourier-transform infrared spectroscopy (FTIR) to evaluate their morphological, moisture, antibacterial and chemical behavior, respectively. Nanofibers of fabricated mat show an average diameter of 340 nm with better moisture management properties compared to polyvinyl alcohol nanomat alone. The agar diffusion method has been used to evaluate the antibacterial activity against Staphylococcus aureus bacteria showing the formation of inhibition zone with a value of 29 mm and 38 mm. The presence of characteristic peaks in Fourier-transform infrared spectra reveals that all the desired components are present in the developed nanofibrous mats.
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