Development of highly bacterial filtration efficient and antibacterial cellulose acetate/gum rosin composite nanofibers for facemask application.

Cellulose acetate (CA) is a non-toxic, renewable, and biodegradable polymeric material that can be effectively electrospuned into bacterial filtration efficient nanofiber membrane for face mask application. However, its fragile and non-antibacterial nature influenced its scalability. In this context, natural antibacterial gum rosin (GR) additive can be explored. Therefore, the present study aimed to produce a CA/GR composite nanofibers membrane for the finest bacterial filtration, excellent antibacterial moiety, and improved tensile properties for facemask application. Hence, in this work, we have studied the effect of GR concentrations (0-15 g) on the needleless electrospinning behavior and fibers' morphology through rheology, electrical conductivity, and SEM analysis. These analyses revealed that GR significantly affects the fibers' spinning behavior, morphology, and diameter of the produced fibers. Later, ATR-FTIR spectroscopy mapped the functional changes in the produced nanofibers that affirmed the integration of GR with CA polymer. This modification resulted in a 3-fold rise in tensile strength and an 11-fold decline in elongation% in 15 g CA/GR composite nanofibers membrane than the control sample. Furthermore, it has shown 98.79 ± 0.10% bacterial filtration efficiency and âˆ¼ 93 % reduction in Staphylococcus Aureus and Klebsiella Pneumoniae bacterial growth, elucidating a high-efficiency level for potential facemask application.

Vegan leather: a sustainable reality or a marketing gimmick?

The textile industry is the only one which has utilised all kinds of resources available in nature, and the evolution of textile materials has drastically hampered nature as well. Leather and fur are a few of the classic examples of materials derived from animals that have attracted dialogues about animal rights and ethical sourcing. To substitute animal-based leather, numerous materials have been manufactured synthetically and semi-synthetically. This review article discusses various types of leather, viz., bovine leather, poromerics, leatherette, plant-based vegan leather, and the sustainable alternatives available in the market as well as at the inductive research phase. The article is a comprehensive review of the leather and its commercially available alternatives along with their marketing strategy, and technical details. The article also compiles insight into the processing, and the components of vegan leather and the environmental issues related to them. The sustainability and circularity of processing in manufacturing vegan leather have also been discussed, with biodegradability as the focal point.

Antimicrobial Nanomaterials as Advanced Coatings for Self-Sanitizing of Textile Clothing and Personal Protective Equipment.

Controlling bioaerosols has become increasingly critical in affecting human health. Natural product treatment in the nano form is a potential method since it has lower toxicity than inorganic nanomaterials like silver nanoparticles. This research is important for the creation of a bioaerosol control system that is effective. Nanoparticles (NPs) are gradually being employed to use bacteria as a nonantibiotic substitute for treating bacterial infections. The present study looks at nanoparticles' antimicrobial properties, their method of action, their impact on drug-opposing bacteria, and the hazards connected with their operation as antimicrobial agents. The aspects that influence nanoparticle conduct in clinical settings, as well as their distinctive features and mode of action as antibacterial assistants, are thoroughly examined. Nanoparticles' action on bacterial cells is presently accepted by way of the introduction of oxidative stress induction, metal-ion release, and nonoxidative methods. Because many concurrent mechanisms of action against germs would necessitate multiple simultaneous gene modifications in the same bacterial cell for antibacterial protection to evolve, bacterial cells developing resistance to NPs is difficult. This review discusses the antimicrobial function of NPs against microbes and presents a comprehensive discussion of the bioaerosols: their origin, hazards, and their prevention. This state of the art method is dependent upon the use of personal protective gear against these bioaerosols. The benefit of the utmost significant categories of metal nanoparticles as antibacterial agents is given important consideration. The novelty of this review depends upon the antimicrobial properties of (a) silver (Ag), (b) zinc oxide (ZnO), and (c) copper oxide (CuO) nanoparticles. The value-added features of these nanoparticles are discussed, as well as their physicochemical characterization and pharmacokinetics, including the toxicological danger they pose to people. Lastly, the effective role of nanomaterials and their future in human wellness is discussed.

Development of multifunctional food packaging films based on waste Garlic peel extract and Chitosan.

A sustainable multifunctional food packaging composite film containing waste garlic peel extract (GPE) and Chitosan (CH) was prepared. This film exhibited antimicrobial potential towards Staphylococcus aureus and Klebsiella pneumoniae. GPE/CH films' morphological, physical, and functional properties were compared to those of CH film. Fourier transform infrared showed the interactions through hydrogen bonding between CH and GPE in the blends that improved the polymers' compatibility. Furthermore, X-ray diffraction analysis validated the compatibility between GPE and CH. GPE/CH films exhibited higher thickness and moisture content than the CH film. Remarkably, GPE/CH films showed lower water vapor barrier properties and higher ultra-violet protection and mechanical strength than CH film. Compact surfaces of the GPE infused CH films were unveiled through Scanning electron microscopy. GPE/CH film showed improved thermal stability after the addition of GPE. MTT method's cytotoxicity study manifested that the GPE/CH films are antioxidant and non-cytotoxic, implicating their biocompatibility and non-toxicity. The results suggest that GPE/CH films can find widespread commercial applications like food packaging materials, replacing the commonly used petrochemical plastics.

Cotton based composite fabric reinforced with waste polyester fibers for improved mechanical properties.

With the focus of industries shifting towards sustainable processing methods and the use of sustainable raw materials, reuse and recycling of polyester have gained a lot of momentum. In spite of considerable efforts, the utilization of polyester fiber waste has not yet found a strong foundation in textile processing. In this paper, waste polyester fibers obtained during the melt spinning process has been utilized by first dissolving it in an m-cresol solvent and later by chemical route polyester is regenerated on cotton leading to the preparation of cotton based composite fabric. The presence of polyester was confirmed using XRD, FTIR, and percent add on and SEM. Percent add on of 9.7% along with the doubling of tensile strength and enhanced thermal stability was observed. The results can make a way as one of the possibilities of utilizing polyester fiber waste.

Lemongrass (Cymbopogon Flexuosus Steud.) wats treated textile: A control measure against vector-borne diseases.

Mosquito-borne diseases are one of the major threats to human health. The long-term use of synthetic repellents has made mosquitoes resistant to them leading to search for novel methods of mosquito control. In the present study, we have developed a low cost, safe and effective formulation to impart mosquito larvicidal and antibacterial effect using essential oils. Oil in water nanoemulsion of three different oils: Lemongrass (cymbopogon flexuosus steud.) wats (CF) oil, Eucalyptus oil (EO) and Chrysnathemum Indicum were prepared using high shear homogenization of the organic with the aqueous phase in presence of surfactant. The oil biocomponents were studied using GCMS. An experimental study of oil in water nanoemulsion preparation, process optimization and stability based on the required size distribution and accelerated stability was performed with surfactant oil ratio (SOR), stirring time and speed as the variables for nanoemulsion preparation. The storage stability of the nanoemulsion was also studied in terms of particle size, pH, viscosity and zeta potential at room temperature and refrigeration temperature for a period of 6 months. The optimized emulsion was also tested for its mosquito larvicidal effect against both the susceptible and resistant species of mosquitoes. The antimicrobial efficacy of the emulsion was also assessed. In the present study, nylon net fabric was treated with Cymbopogon flexuosus (CF) oil nanoemulsion by depositing polyelectrolyte multilayers through the layer by layer (LBL) technique. The nanoemulsion was characterized for particle size, zeta potential, viscosity, pH and Poly Dispersity Index. Mosquito antennal response to pure CF oil and its nanoemulsion was noted. The application technique was optimized for the concentration of nanoemulsion used and the number of polymeric layers applied. The treated samples were tested against mosquito bioassays, microbial growth and fragrance retention. Wash durability of the treated samples was also analysed. GCMS and SEM analysis of the treated and washed samples was done to ensure the presence of active ingredient and finish on the fabric. The fabrics showed good mosquito repellency, fragrance retention and antimicrobial efficacy even after 25 washes, though the percentage mortality dropped. The repellent and anti-microbial fabrics developed may provide a safe, environment-friendly and effective alternative to the chemical-based repellents for achieving protection against mosquito bites.

Potential application of medical cotton waste for self-reinforced composite.

The present work mainly deals with the efficacy of the waste medical grade cotton (MGC) used for the sustainable self-reinforced composite (SRC). MGC waste was exposed in the autoclave for destroying all microorganisms including infected bacteria's and virus followed by scoured and bleached for removing blood stains and foreign materials. SRC film was prepared by selective dissolved fibre surface of waste MGC into a dissolved microcrystalline cellulose (DMCC) matrix solution prepared by lithium chloride/N,N-dimethylacetamide (LiCl/DMAc) solvent system. The tensile strength of SRC films was significantly improved up to 252 MPa, and it was higher than that of the DMCC film. In the FTIR study, no peak was found in 1620 cm-1 in SRC confirming that the LiCl/DMAc has been completely removed. SEM study also revealed the presence of partial dissolution of the surface of MGC which merged with DMCC matrix in the SRC. The XRD results displayed higher crystallinity SRC than DMCC film. The thermal stability of SRC as determined by TGA improved compared to the DMCC film from 225 °C for DMCC to 250-283 °C for SRC films. Therefore, these prominent results revealed the potential utilization of a sustainable resource, waste MGC in producing environmentally friendly SRC films with high-performance properties.

Preparation and characterization of biocomposite packaging film from poly(lactic acid) and acylated microcrystalline cellulose using rice bran oil.

Surface acylation of microcrystalline cellulose (MCC) was performed using rice bran oil (RBO). The resultant acylated MCC (RAMCC) exhibited reduced polarity as compared with MCC. Attenuated Total Reflection (ATR)- Fourier transform infrared (FTIR) spectroscopy confirmed hydrophobic MCC modification. RAMCC and MCC were incorporated into PLA matrix and their influence on morphological, mechanical, thermal and barrier properties of the PLA based biocomposite were analyzed. PLA/RAMCC biocomposite (with 2 wt% loading) exhibited lower water sorption compared to PLA film and PLA/MCC. X-ray Diffraction (XRD) analysis result showed an increase in crystallinity of PLA/RAMCC and reduction in water vapour permeability as compared to PLA film and PLA/MCC composite. PLA/RAMCC exhibited the best mechanical, thermal and UV barrier properties. The fractured surfaces of the composites showed an even distribution of RAMCC throughout PLA matrix. Biodegradability of samples was characterized using soil buried method. The cytotoxicity of the developed PLA-based films was evaluated on human dermal fibroblast (HDF) monolayer culture by the MTT method and it has shown that the films were non-cytotoxic thus indicating their biocompatibility and non-toxicity. These biodegradable composite films can be a sustainable utilization of RBO and MCC in the packaging application.