Essential oils (EOs) are the volatile lipophilic components extracted from plants. Many EOs have demonstrated strong antimicrobial properties when tested in in vitro experiments. The commercial applications of these EOs require a suitable formulation constituted by biodegradable compounds that protect them from degradation and evaporation at the same time that allows for a sustained release. The objective of this study was therefore to reduce the rate of evaporation of the oil via microencapsulation. Alginate microspheres (AMSs) were prepared using emulsion extrusion method. The AMSs were hardened with a cross-linking agent, calcium chloride. The effects of the three variables: alginate concentration (0.5%-8%), the amount of cross-linking agent (0.125%-2%) and time of cross-linking (5-30 min.) on loading capacity and encapsulation efficiency (EE, %) were studied. The effect of the amount of cross-linker was significant on loading capacity (%) and EE (%). The AMSs under the optimized conditions provided loading capacity of 22%-24% and EE of 90%-94% based on type of EO. The antifungal activity of vapors of microencapsulated and non-microencapsulated oils were evaluated against two of pathogenic fungi species for stored grains: Aspergillus niger and Fusarium verticillioides. The optimized MSs were observed to have a sustained in vitro release profile (50% of the antifungal activity was maintained at the 8th day of the study). In conclusion, encapsulation in Ca-alginate microspheres may effectively reduce the evaporation rate of essential oils, thus increase the potential antifungal activity.
Cotton fabrics with durable and reusable daylight-induced antibacterial/antiviral functions were developed by using a novel fabrication process, which employs strong electrostatic interaction between cationic cotton fibers and anionic photosensitizers. The cationic cotton contains polycationic short chains produced by a self-propagation of 2-diehtylaminoehtyl chloride (DEAE-Cl) on the surface of cotton fibers. Then, the fabric (i.e., polyDEAE@cotton) can be readily functionalized with anionic photosensitizers like rose Bengal and sodium 2-anthraquinone sulfate to produce biocidal reactive oxygen species (ROS) under light exposure and consequently provide the photo-induced biocidal functions. The biocidal properties of the photo-induced fabrics (PIFs) were demonstrated by ROS production measurements, bactericidal performance against bacteria (e.g., E coli and L. innocua), and antiviral results against T7 bacteriophage. The PIFs achieved 99.9999% (6 log) reductions against bacteria and the bacteriophage within 60 min of daylight exposure. Moreover, the PIFs showcase excellent washability and photostability, making them ideal materials for reusable face masks and protective suits with improved biological protections compared with traditional PPE. This work demonstrated that the cationized cotton could serve as a platform for different functionalization applications, and the resulting fiber materials could inspire the development of reusable and sustainable PPE with significant bioprotective properties to fight the COVID-19 pandemic as well as the spread of other contagious diseases.
During the development of antibacterial
and antiviral materials
for personal protective equipment (PPE), daylight active functional
polymeric materials containing vitamin K compounds (VKs) and impacts
of polymer structures to the functions were investigated. As examples,
hydrophobic polyacrylonitrile (PAN) and hydrophilic poly(vinyl alcohol-co-ethylene) (PVA-co-PE) polymers were
directly blended with three VK compounds and electrospun into VK-containing
nanofibrous membranes (VNFMs). The prepared VNFMs exhibited robust
photoactivity in generating reactive oxygen species (ROS) under both
daylight (D65, 300–800 nm) and ultraviolet A (UVA, 365 nm)
irradiation, resulting in high antimicrobial and antiviral efficiency
(>99.9%) within a short exposure time (<90 min). Interestingly,
the PVA-co-PE/VK3 VNFM showed higher ROS
production rates and better biocidal functions than those of the PAN/VK3 VNFM under the same photoirradiation conditions, indicating
that PVA-co-PE is a better matrix polymer material
for these functions. Moreover, the prepared PVA-co-PE/VK3 VNFM maintains its powerful microbicidal function
even after five times of repeated exposures to bacteria and viruses,
showing the stability and reusability of the antimicrobial materials.
The fabrication of photoinduced antimicrobial VNFMs may provide new
insights into the development of non-toxic and reusable photoinduced
antimicrobial materials that could be applied in personal protective
equipment with improved biological protections.
A novel
ultrasensitive nanobody-based electrochemical immunoassay
was prepared for assessing human exposure to pyrethroid insecticides.
3-Phenoxybenzoic acid (3-PBA) is a common human urinary metabolite
for numerous pyrethroids, which broadly served as a biomarker for
following the human exposure to this pesticide group. The 3-PBA detection
was via a direct competition for binding to alkaline phosphatase-embedded
nanobodies between free 3-PBA and a 3-PBA-bovine serum albumin conjugate
covalently immobilized onto citric acid-decorated nylon nanofibers,
which were incorporated on a screen-printed electrode (SPE). Electrochemical
impedance spectroscopy (EIS) was utilized to support the advantage
of the employment of nanofibrous membranes and the success of the
immunosensor assembly. The coupling between the nanofiber and nanobody
technologies provided an ultrasensitive and selective immunosensor
for 3-PBA detection in the range of 0.8 to 1000 pg mL–1 with a detection limit of 0.64 pg mL–1. Moreover,
when the test for 3-PBA was applied to real samples, the established
immunosensor proved to be a viable alternative to the conventional
methods for 3-PBA detection in human urine even without sample cleanup.
It showed excellent properties and stability over time.
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