Search Results (92)

Small-particle-produced goods, such as those used in industry, medicine, cosmetics, paints, abrasives, and plastic pellets or powders, are the main sources of microplastics. It is also possible to mention tire recycling granules here. Larger components break down in the environment to generate secondary microplastics. Microplastics, or particles smaller than 5 mm, and nanoplastics, or particles smaller than 1 μm, are the products of degradation and, in particular, disintegration processes that occur in nature as a result of several physical, chemical, and biological variables. Polypropylene, polyethylene, polyvinyl chloride (PVC), polystyrene, polyurethane, and polyethylene terephthalate (PET) are among the chemicals included in this contamination in decreasing order of quantity. Micro- and nanoplastics have been detected in the air, water, and soil, confirming their ubiquitous presence in natural environments. Their widespread distribution poses significant threats to human health, including oxidative stress, inflammation, cellular damage, and potential carcinogenic effects. The aim of this article is to review the current literature on the occurrence of micro- and nanoplastics in various environmental compartments and to analyze the associated health consequences. The article also discusses existing legal regulations and highlights the urgent need for intensified research into the toxicological mechanisms of microplastics and the development of more effective strategies for their mitigation. Full article

Salicornia species are halophytic plants that thrive in environments with moderate to high salinity. Owing to its high nutritional value and diverse bioactive constituents, Salicornia holds promise for applications in the food, feed, pharmaceutical, cosmetic, and bioenergy sectors. Understanding its salt tolerance mechanisms is important for developing crops suited to saline soils and water. Recent studies have revealed that Salicornia adapts to salinity through diverse physiological, biochemical, and molecular strategies. Despite these advances, a comprehensive synthesis of existing knowledge remains absent, hindering its effective application in crop improvement. In this review, recent advances in the understanding of Salicornia’s salinity tolerance are synthesized, with emphasis placed on key mechanisms: cell wall nano-mechanics, ion regulation and compartmentation, antioxidant defense, osmotic balance, phytohormonal control, signal transduction, transcriptional regulation, and the expression of salt-responsive proteins. The interactions among these mechanisms are also examined, along with their roles in conferring tolerance to additional abiotic stresses such as drought, submergence, and extreme temperatures. Finally, the potential applications of these findings in genetic engineering for improving salt tolerance in crops are discussed, along with proposed directions for future research to promote the use of halophytes in sustainable agriculture. Full article

Essential oils are complex mixtures of apolar components, mainly phenylpropanoids, monoterpenes, and sesquiterpenes. Vetiver (Vetiveria zizanioides (L.) Nash) is a non-endemic grass in several tropical regions, widely used for slope stabilization and erosion control because of its long and deep roots that help to bind the soil together, preventing landslides and soil loss. From these roots, vetiver essential oil is obtained, which is extracted and produced worldwide and highly valued for its diverse range of bioactive substances used by the cosmetics and perfume industries. These substances, present in a very complex mixture, are difficult to isolate. Zizanoic acid is a very rare substance in nature and also very interesting because of the biological properties already described. In the present study, zizanoic acid was selectively isolated with 84–87% purity from vetiver commercial essential oils, in which it was present at less than 10%, using KOH-impregnated silica gel column chromatography alone. The experiments were monitored using GC-MS and UHPLC-HRMS, and the isolated substances (zizanoic and valerenic acids) were further determined by NMR experiments. The whole methodology and analytical approach proved to be very efficient for natural product complex mixture analysis and also very selective, allowing for a distinct capacity to recover carboxylic acids from complex biological samples. Full article

Kutno is a picturesque city in central Poland, known for extensive rose breeding worldwide. Soil samples and rose petals were collected from 13 locations in the city and characterized by diverse environments. This allowed determining the response of plants to changing cultivation conditions. Rose petals have found a wide range of applications. They are used in the food, pharmaceutical and cosmetic industries. The aim of the research was to assess the contents of Cu, Zn, Cd, Ni, Pb and Cr in soils and their accumulation in rose petals. Samples were subjected to the microwave mineralization process using a mixture of concentrated HCl and HNO₃. The metal contents in the soil and roses were determined by HR-CS-AAS and ICP-OES, respectively. Roses are usually cultivated in soils with a limited mobile fraction of heavy metals. In these unfavorable conditions, flower petals can absorb heavy metals substantially. Petals of roses cultivated for cosmetic, pharmaceutical or food purposes should be tested for heavy metal content. This study indicates that toxic metals are blocked at the root zone, and their transport to the above-ground parts is severely hampered. Nevertheless, metals related to the photo-synthesis process (Zn, Cu) are more intensively taken up by roses, while the uptake of toxic metals is partially inhibited. Full article

Biochar can be regarded as a high-energy type of solid fuel produced via pyrolysis, which is the thermal modification of biomass of plant or animal origins. The biggest advantage of biomass relative to classic fossil fuels is the significant reduction in carbon dioxide emissions in the combustion process. Biochar is also considered a natural soil additive for improving soil parameters, increasing crop yields, remediating pollutants, and reducing emissions of methane, among other things. Over the past few years, the range of biochar applications has expanded significantly, as reflected in the number of scientific articles on the topic. Pyrolysates are used in the production of cosmetics, pharmaceuticals, building materials, animal feed, sorbents, and water filters, as well as in the field of modern energy storage and conversion, such as supercapacitors. The key importance of this material is attributed to its ability to sequestrate carbon and reduce greenhouse gas emissions. The relentless growth of the global economy and the high demand for energy generate large amounts of CO₂ in the atmosphere. Solving the carbon balance problem and the low-carbon energy transition toward carbon neutrality is very challenging. Biochar therefore appears to be an excellent tool for creating systems that can play an important role in mitigating climate change. The purpose of this review is to consolidate the existing knowledge and assess the potential of biochar in carbon neutrality based on the application sector. Full article

Cultural Heritage is a vital socioeconomic driver that must contend with works of art continuously exposed to degradation processes, which are further exacerbated by climate change. Aged coatings, varnishes, and soil can compromise the appearance of artworks, preventing their preservation and valorization. In response, soft matter and colloidal systems, such as nanostructured cleaning fluids (NCFs), have proved to be valuable solutions for safely and effectively cleaning works of art. Here, a novel cleaning system is proposed, for the first time employing microgels of poly(N-isopropylacrylamide) (PNIPAM) with surface chains of oligoethylene glycol methyl ether methacrylate (OEGMA) to favor shear deformation by lubrication. These microgels are loaded with NCFs featuring “green” solvents and different kinds of bio-derived or petroleum-based surfactants (non-ionic, zwitterionic). Rheological characterization of the combined systems highlighted a sharp transition from solid to liquid-like state in the 21–24 °C range when the zwitterionic surfactant dodecyldimethylamine oxide was used; the system displays a solid-like behavior at rest but flows easily at intermediate strains. At slightly higher temperature (>24 °C), an inversion of the G′, G″ values was observed, leading to a system that behaves as a liquid. Such control of rheological behavior is significant for feasible and complete removal of soiled polymer coatings from textured ceramic surfaces, which are difficult to clean with conventional gels, without leaving residues. These results position the PNIPAM-OEGMA microgels as promising cleaning materials for the conservation of Cultural Heritage, with possible applications also in fields where gelled systems are of interest (pharmaceutics, cosmetics, detergency, etc.). Full article

The feasibility of using a combination of organic fertilizer with a reduced rate of chemical nitrogen fertilizer as an alternative to conventional inorganic fertilization was tested on the growth and biomass accumulation of hemp plants and the phytochemical accumulation in their inflorescences. To achieve this goal, a field experiment was set up with the following nine treatments: F0, no fertilizer; NPK, mineral fertilizer with 100 kg ha⁻¹ nitrogen; C1, compost from solid digestate (50%) + cardoon-based spent mushroom substrate (50%); C2, compost from solid digestate (50%) + straw-based spent mushroom substrate (50%); C3, C4, C5, and C6, composts from solid digestate (50%, 67%, 75%, and 84%, respectively) and cardoon waste (50%, 33%, 25%, and 16%, respectively); SD, non-composted solid digestate. C1–C6 and SD were added to the soil, along with half the rate (50 kg ha⁻¹) of chemical nitrogen fertilizer. Taking F0 as a reference, all fertilized treatments, except C6 and SD, showed a notable increase in plant growth and biomass accumulation in the stem, inflorescence, and whole plant. Among the organic treatments, the best growth performances were detected in C1 and C5, which reached, or even exceeded, that of NPK. Compared to F0, all fertilized treatments had high phenolic acid and flavonoid yields, while high carotenoid, tocopherol, terpene, and cannabinoid (mainly CBD) yields were detected in all fertilized treatments except C6 and SD. Among the organic treatments, C1 and C5 stood out for their highest phenolic acid, flavonoid, carotenoid, and tocopherol yields, while C1, C2, and C3 stood out for their highest terpene and cannabinoid yields, which, in both cases, reached, or even exceeded, those of NPK. Overall, our findings show that 50% replacement of inorganic nitrogen fertilizer with C1 to C5 composts may represent a cost-effective and environmentally safe alternative to conventional inorganic fertilization that can sustain the growth of hemp plant and the phytochemical accumulation in its inflorescences, thus promoting the use of this crop for fiber and bioenergy production, as well as for applications in food, nutraceutical, agrochemical, and cosmetic sectors. Full article

In this study, a Bacillus velezensis SDU strain capable of producing poly-γ-glutamate (γ-PGA) was newly identified from the rhizosphere soil of Baimiao taro. The strain is a glutamate-independent strain and can produce polyglutamic acid in a culture medium completely free of glutamate. The hydrolyzed product of the polyglutamic acid produced is D-glutamic acid. The molecular weight of γ-PGA, estimated via the Mark–Houwink equation, was 1390 kDa. Furthermore, the molecular weight measured by Waters gel permeation chromatography with multi-angle laser light scattering (GPC–MALLS) was 1167 kDa. The production of γ-PGA and its antioxidant and tyrosine inhibition properties were investigated. The γ-PGA production reached 23.1 g/L, and the productivity was 0.77 g L⁻¹ h⁻¹. Specifically, γ-PGA exhibited superoxide anion (·O₂⁻) radical scavenging activity and tyrosinase inhibitory activity. This study introduces a promising strain and a highly efficient application method for γ-PGA, which can be broadly utilized in the pharmaceutical, food, and cosmetic industries. Full article

Unlike many biopolymers, α-1,3-glucan (α-1,3-GLU) is water-insoluble, making it a promising candidate for the production of moisture-resistant films with applications in biodegradable packaging, biomedicine, and cosmetics. This study aimed to characterize the structural, physicochemical (water affinity, optical, mechanical), and biodegradation properties of a film made from α-1,3-GLU extracted from Laetiporus sulphureus. The film was fabricated through alkaline dissolution, casting, drying, washing to remove residual NaOH, and re-plasticization with a glycerol solution. FTIR and Raman spectroscopy confirmed the polysaccharide nature of the film, with predominant α-glycosidic linkages. The film exhibited a semi-crystalline structure and high opacity due to surface roughness resulting from polymer coagulation. Owing to re-plasticization, the film showed a high moisture content (~47%), high water solubility (81.95% after 24 h), and weak mechanical properties (tensile strength = 1.28 MPa, elongation at break ≈ 10%). Its water vapor permeability (53.69 g mm m⁻² d⁻¹ kPa⁻¹) was comparable to other glycerol-plasticized polysaccharide films reported in the literature. The film supported the adhesion of soil microorganisms and target bacteria and was susceptible to degradation by Trichoderma harzianum and endo- and exo-α-1,3-glucanases, indicating its biodegradability. The limitations in its mechanical strength and excessive hydration indicate the need for improvements in the composition and methods of producing α-1,3-GLU films. Full article

Kaempferia larsenii Sirirugsa, a rare species in Thailand belonging to the Zingiberaceae family, is known for its effective pharmaceutical properties. However, its slow natural growth and threats from overharvesting and habitat encroachment pose significant challenges. This study investigated the effects of plant growth regulators (PGRs) on the plant regeneration, transplantation success, phytochemical profiling, and antioxidant properties of wild and in vitro-cultured plants. Plantlets (~1 cm long) were cultivated for 8 weeks in different types of MS media (solid, liquid, and liquid-over-solid) combined with various PGRs (BA, kinetin, TDZ, NAA, and IAA). Solid MS medium enriched with 2 mg/L BA, 3 mg/L TDZ, and 0.2 mg/L NAA produced the highest number of shoots (13.10 shoots/explant). By comparison, liquid MS medium containing 1 mg/L BA and 0.5 mg/L IAA also promoted high shoot production (4.70 shoots/explant). The strongest root induction (16.90 roots/explant) was achieved using a liquid MS medium supplemented with 2 mg/L BA, 2 mg/L kinetin, and 1 mg/L NAA. Sandy soil as a planting material yielded the highest survival rate (100%) during transplantation. The total phenolic content (TPC) and total flavonoid content (TFC) were higher in mother plants than in in vitro-cultured plants. The addition of PGRs significantly enhanced the production of secondary metabolites. The leaves of K. larsenii exhibited superior antioxidant properties compared to other organs under both growing conditions. Cinnamic acid was identified as abundant in in vitro-cultured plants via HPLC analysis. FTIR analysis revealed functional groups associated with phenolic acids and flavonoids, which are useful for phytochemical screening and antioxidant evaluation. This research highlighted the potential of biotechnology as a crucial strategy for conserving K. larsenii and demonstrated its sustainable application in the medical and cosmetics industries. Full article

Alpha-cembratriene-4,6-diol (α-CBT-diol) is a complex diterpenoid primarily found in Solanaceae (i.e., tobacco leaves), Pinaceae, and marine corals. Due to its intricate chemical structure, it serves as a precursor for several aroma compounds, including farnesal. Farnesal and its derivatives have applications across various fields, such as the fragrance and flavor industry, pharmaceuticals, agriculture, and cosmetics. In this study, Stenotrophomonas maltophilia H3-1, a strain capable of efficiently biodegrading α-CBT-diol into farnesal, was isolated from soil and identified through 16S rDNA sequence analysis. S. maltophilia H3-1 biodegraded 93.3% of α-CBT-diol (300 mg/L) within 36 h when grown under optimized culture conditions, including a temperature of 40 °C, pH of 8, 2 g/L maltose, and 2 g/L ammonium sulfate. Theoretically, this strain can produce 201 mg/L of farnesal during the biotransformation of α-CBT-diol. The putative α-CBT-diol bioconversion pathway expressed in S. maltophilia H3-1 is also proposed. This is the first study to report the bioconversion of α-CBT-diol into the high-value compound farnesal using a novel S. maltophilia H3-1 strain. It highlights that other compounds found in tobacco can also be bioconverted into valuable products. Full article

This article explores the ecological role of strawberry tree forests (Arbutus unedo L.) in the resilience of Portuguese forest ecosystems and their relationship with plant production as a source of food. It discusses the importance of the strawberry tree in fire combat and the improvement of agroforestry areas by mitigating erosion and augmenting soil organic matter. The multifunctionality of their fruits, emphasizing their utilization in food and beverage production, is also addressed. Moreover, the socio-economic and cultural significance of fruit production, emphasizing its role in sustainable development, is analyzed. The diversity of beverages (spirits, liquors, and gin) and food products (jams, jellies, etc.) effectively contribute to have a positive social and economic impact on the local populations and tradition maintenance. Moreover, the bioactive compounds in different parts of the plants and fruits have applications in pharmacology and cosmetics. Finally, the valorization of strawberry tree spirits mush waste as a source of natural dyes for textiles is discussed as a promising research topic to be explored in the future. Full article

Myrtle (Myrtus communis L.), an evergreen shrub belonging to the Myrtaceae family, is widely valued for its applications in the cosmetic, hygienic, and medicinal industries. This plant produces berries in two colors—white and black—with black berries receiving increasing attention due to their superior antioxidant properties. This study investigates black myrtle berries’ morphological and biochemical characteristics from eight prominent natural habitats in Fars Province, southwestern Iran. The results reveal significant variations in the morphological (such as fruit length and diameter, fruit length-to-diameter ratio, seed length and diameter, fruit weight, pulp weight, seed weight, pulp-to-seed ratio, and number of seeds) and biochemical attributes among the studied populations. The longest fruit was from the Kherqeh (KH) (8.29 mm) population, while the shortest was from the Baghnari (BN) (5.85 mm) population. The largest fruit diameter was also from KH (6.83 mm), which did not show a significant difference compared to the Zanjiran (ZF) population, while the smallest fruit diameter was from BN (5.12 mm), which did not differ significantly from the Kavar (KA), Simakan (SM), Kouhmareh Road (JK), or Atashkadeh (AT) populations. Notably, all populations exhibited high levels of phenolic compounds, ranging from 660 to 1846 mg per 100 g of fresh weight, and potent antioxidant activity, as indicated by low half-maximal inhibitory concentrations ranging from 0.018 to 0.187 mg per gram. Correlation analyses further demonstrated that altitude and specific soil properties influenced the biochemical traits of the berries to varying degrees. These findings offer valuable scientific insights for selecting and utilizing specific myrtle populations in horticulture, particularly for breeding programs to maximize antioxidant properties and phenolic content. Full article

The fruit of berry plants is primarily used for industrial purposes, while the leaves are often regarded as waste. However, these leaves, rich in valuable bioactive compounds, have the potential to serve as raw materials for various industries, including cosmetics. This study compared the content of micro- and macronutrients in the leaves of wild strawberry, blackberry, and blueberry plants. It revealed a high mineral content, particularly in the leaves of wild strawberry and blackberry plants. The plant leaves were also shown to contain vitamin C and exhibited antioxidant activity. The leaves of berry plants were used to obtain micellar extracts, which were then incorporated into the formulation of prototype bath washes. A cosmetic formulation without any extracts served as a reference. In the next step, the prototype cosmetics were evaluated for their chosen properties. The findings showed that incorporating micellar leaf extracts into cosmetic formulations reduced their viscosity and ability to generate long-lasting foam, even in the presence of model sebum. Furthermore, the cosmetics formulated with the extracts exhibited a reduced capacity to emulsify fatty soils compared to the reference formulation, which could present an advantageous option for individuals with sensitive skin. Full article

The presence of microplastics in the environment has increased due to anthropogenic activities; it is estimated that 15 million kilograms of plastic waste accumulate in the ocean annually. Pollution permeates every inch of the ocean from microplastics in the food chain to plastic water bottles floating on the surface. This monolith of ocean pollution is made up of all kinds of marine debris and contains 1.8 trillion pieces of plastic, covering an area twice the size of Texas. The objective of this review is to show advances in the study of emerging problems, specifically in the presence of microplastics in water and soil and their potential effects on health. In addition, microplastics have synergy with residual contaminants that exist in the water such as textile waste, organic matter, pathogens, etc. This causes damage to aquatic organisms as it makes nutrient transfer more complex in many of these species. There is a report that estimates that liabilities related to plastic pollution will cost the industry 100,000 million dollars due to lawsuits for damages and losses, of which 20,000 million will occur in the United States. The study of the presence of microplastics in the environment can generate indicators of the current effect to generate public policies that try to control the growth of this pollutant in the environment. It is important to discuss all the routes of generation of microplastics, distribution, and cosmetics involved in fast fashion with glitter and to evaluate the physical, chemical, biological, and toxicological effects on the environment, proposing the path and future to be followed regarding this research topic. Full article