Valuable Compounds Research Articles

Waste marble sludge and calcined clay brick powders in conventional cement farina production for cleaner built environment

In the manufacturing of some sectors, such as marble and brick, certain byproducts, such as sludge, powder, and pieces containing valuable chemical compounds, emerge. Some concrete plants utilize these byproducts as mineralogical additives in Turkey. The objective of the experimental study is to ascertain whether the incorporation of waste from the marble and brick industries, in powder form, into cement manufacturing as a mineralogical additive or substitute is a viable option. The materials used in this study were marble and brick wastes, CEM I 42.5 N cement, CEM I 42.5 clinker, water and CEN standard sand. as a replacement for the cement and a substitution for the clinker, the waste marble sludge powder and calcined clay brick powder was separately replaced with either CEM I 42.5 N cement or CEM I 42.5 clinker To determine the usability of marble and brick wastes in conventional cement and clinker production. To this end, there were prepared twenty-four different binder constituents at 0, 6, 10, 20, 21, and 35%. Then the hardened mortar samples were prepared with the new twenty-four different binders, standard drinkable water, and standard mortar sand. Besides, to evaluate pozzolanic activity, the construction lime was mixed with the marble and brick wastes. The microstructure of the marble and brick waste was analyzed using X-ray fluorescence, scanning electron microscopy and energy dispersive spectroscopy. In addition to the microstructure analyses, the chemical features of the marble and brick wastes, including oxides, loss on ignition, pH, total organic content and clay content, were determined in accordance with current standards. The physical and pozzolanic features of the wastes, such as their fineness, density, specific surface area, water permeability, and flexural and compressive strengths, were also evaluated using up-to-date standards. The results of the chemical experiments indicate that the total oxides of calcium, silica, alumina, and ferrite in marble powder and brick powder are more than 54% and 82%, respectively. Marble powder and brick powder are more finely ground than a few mineralogical materials, such as fly ash and silica fume, according to the residue amounts on sieves. Consequently, marble and brick powders can be used as water reducers in mortar, grout, and concrete. Moreover, marble and brick powder have a higher density than many mineralogical materials, making them suitable for applications requiring a higher binder feature of cement, higher strength, and improved durability of mortar and concrete. The specific surface area and water permeability of the marble and brick powders provide compelling evidence to support the inferences previously made about the fineness and density of these materials. Additionally, the pozzolanic properties of the brick powder were three and fourteen times greater than those of the marble powder, as evidenced by its compressive and flexural strengths, respectively. It can be reasonably deduced from the experimental results that marble powder is a latent hydraulic mineralogical natural additive or substitute, while brick powder is an unnatural mineralogical pozzolanic additive or substitute for cement-making processes.

Metabolic engineering of Escherichia coli for the biosynthesis of O-acetyl-L-homoserine

O-acetyl-L-homoserine (OAH) is a promising platform compound for the production of L-methionine and other valuable compounds, while its low yield and low conversion rate limit the industrial application. To solve these problems, we constructed a strain for high OAH production with the previously constructed L-homoserine producer Escherichia coli HS33 as the chassis by systematic metabolic engineering. Firstly, PEP accumulation, pyruvate utilization, and OAH synthesis pathway (overexpressing aspB, aspA, and thrAC1034T) were enhanced to obtain an initial strain accumulating 13.37 g/L OAH. Subsequently, the co-factor synthesis genes were integrated to supply reducing power and energy, which increased the yield to 15.79 g/L. The OAH yield of the engineered strain OAH28 was further increased to 17.49 g/L by strengthening the acetic acid reuse pathway, improving the supply of acetyl-CoA, and regulating the expression of MetX from different sources. Finally, in a 5 L fermenter, OAH28 achieved an OAH titer of 47.12 g/L, with a glucose conversion rate of 32% and productivity of 0.59 g/(L·h). The results lay a foundation for increasing the OAH production by metabolic engineering and give insights into the industrial production of OAH.

Electrochemical Deconstruction of Waste Polyvinylidene Chloride (PVDC) to Value-Added Products in Batch and Flow.

Chlorinated polymers have made enormous contributions to materials science and are commercially produced on a large scale. These chlorinated polymers could be recycled as chlorine sources to efficiently produce valuable chlorinated compounds owing to their facile release of HCl. Although the thermal stability of PVDC is low compared to PVC, this can be advantageous in terms of easy and fast dehydrochlorination. Herein, we report an efficient electrochemical chlorination using poly(vinylidene chloride) (PVDC) as a chlorine source that works in an undivided cell and applies to a good number of examples. This method works on commodity polymers such as waste PVDC-PVC pharma blister film, PVDC-PO multilayer food packaging, and compression molded sheets of Ixan PVDC (with heat stabilizer) with similar efficiency. Furthermore, this method also provides the dechlorination of PVDC up to 98 %, leading to unsaturated dechlorinated material. Converting PVDC into more stable unsaturated compounds, the release of harmful chlorine-containing gases during incineration can be minimized. Additionally, this method is not only restricted to batch processes but an electroflow process for PVDC dechlorination and electrosynthesis has also been demonstrated.

High-Pressure Extraction Techniques for Efficient Recovery of Flavonoids and Coumarins from Flower Seeds

The extraction of bioactive compounds, such as flavonoids and coumarins, from natural sources has gained significant attention due to their potential health benefits. This review aims to explore the application of high-pressure extraction processes, particularly supercritical fluid extraction (SFE) and pressurized liquid extraction (PLE), for obtaining flavonoids and coumarins from flower seeds. These techniques offer a greener, more efficient alternative to conventional extraction methods, minimizing the use of harmful solvents and improving the yield and purity of the target compounds. Flower seeds, a rich source of bioactive molecules, are an underutilized reservoir for these valuable compounds. For example, seeds from plants such as Calendula officinalis (calendula) and Helianthus annuus (sunflower) are rich in flavonoids and coumarins. The proposed review will examine the influence of extraction parameters—such as temperature, pressure, solvent choice, and extraction time—on the yield and quality of flavonoids and coumarins. This review aims to provide a comprehensive understanding of high-pressure extraction methods and optimize protocols for the efficient, sustainable extraction of flavonoids and coumarins from flower seeds.

Sustainable Extraction Technology of Fruit and Vegetable Residues as Novel Food Ingredients.

Fruit and vegetable waste (FVW) is a global waste issue with environmental impacts. It contains valuable compounds such as polysaccharides, polyphenols, proteins, vitamins, pigments, and fatty acids, which can be extracted for food applications. This study aims to review sustainable extraction methods for FVW and its potential in the food industry. This paper provides an overview of the sources and sustainable methods of high value-added compounds extracted from FVW. Sustainable techniques, including supercritical fluid extraction and ultrasound-assisted extraction, are compared with traditional methods, for their efficiency in extracting high-value compounds from FVW while minimizing environmental impact. Sustainable extraction of FVW compounds is sustainable and beneficial for novel food ingredients. However, challenges in scalability and cost need to be addressed for wider adoption in the food sector. Sustainable extraction techniques effectively extract phytochemicals from FVW, preserving bioactivity and reducing environmental load. These methods show promise for sustainable food ingredient development.

Seed bacterization with siderophore-producing bacteria: a strategy to enhance growth and alkaloid content in Catharanthus roseus.

Catharanthus roseus is a medicinal plant widely known for producing monoterpenoid indole alkaloids (MIAs), including therapeutic compounds such as vinblastine and vincristine, which are crucial for cancer treatment. However, the naturally low concentration of these alkaloids in plant tissues poses a significant challenge for large-scale production. This study explores the application of siderophore-producing bacteria for seed bacterization of Catharanthus roseus to enhance the production of MIAs, including vindoline, catharanthine, and vinblastine. Utilizing High-Performance Liquid Chromatography (HPLC), we observed a significant increase in the concentration of these alkaloids in bacterized plants compared to controls. FTIR spectra of treated plants showed strong correlations with standard alkaloid mixtures, confirming higher alkaloid accumulation. Our findings demonstrate that bacterial siderophores play a vital role in optimizing iron uptake, which is crucial for secondary metabolite biosynthesis. This research highlights the potential of using microbial biotechnology to improve the yield of valuable pharmaceutical compounds in medicinal plants. Enhancing the biosynthetic pathways of MIAs offers a sustainable and efficient strategy for boosting the production of key therapeutic alkaloids in Catharanthus roseus, paving the way for advanced biotechnological applications in plant-based drug production.

Codeine 3-O-demethylase catalyzed biotransformation of morphinan alkaloids in Escherichia coli: site directed mutagenesis of terminal residues improves enzyme expression, stability and biotransformation yield

The cultivation of opium poppy is the only commercially viable source of most morphinan alkaloids. Bioproduction of morphinan alkaloids in recombinant whole-cell systems provides a promising alternate source of these valuable compounds. The enzyme codeine 3-O-demethylase can transform morphinan alkaloids by O-demethylation and has been applied in single step biotransformation reactions or as part of larger biosynthetic cascade, however, the productivity for these reactions remains low and suboptimal enzyme properties could be improved. This mutagenesis study targeted non-conserved N-and C-terminal residues, which were replaced with the equivalent residues from enzyme thebaine 6-O-demethylase. Whole cell biotransformation performance was significantly improved in Escherichia coli expressing codeine 3-O-demethylase mutants, with a ~ 2.8-fold increase in the production of oripavine from thebaine and ~ 1.3-fold increase in the production of morphine from codeine. Statistical analysis of biotransformation yield, enzyme expression and stability, predicted using changes in Gibbs free energy (ΔΔG) with deep-learning-based model DDmut, suggested that altered enzyme stability and/or expression of soluble protein may contribute to the observed improvements in biotransformation. This approach could be beneficial for screening future codeine 3-O-demethylase mutations and for other enzymes.

Homo-Mannich Reaction of Cyclopropanols: A Versatile Tool for Natural Product Synthesis.

ConspectusThe Mannich reaction, involving the nucleophilic addition of an enol(ate) intermediate to an imine or iminium ion, is one of the most widely used synthetic methods for the synthesis of β-amino carbonyl compounds. Nevertheless, the homo-Mannich reaction, which utilizes a homoenolate intermediate as the nucleophilic partner and provides straightforward access to the valuable γ-amino carbonyl compounds, remains underexplored. This can be largely attributed to the difficulties in generation and manipulation of the homoenolate species, despite various homoenolate equivalents that have been developed. Among the homoenolate equivalents developed, cyclopropanol stands out due to its intriguing reactivities endowed by the highly strained cyclopropane. Upon activation by a metal, cyclopropyl alcohol is prone to undergo an endocyclic C(sp3)-C(sp3) bond cleavage to give a homoenolate intermediate or a β-keto radical intermediate, which sets the stage for a diverse range of transformations. This account outlines our recent progress in the development of homo-Mannich reaction of cyclopropanol and its applications in natural product total synthesis. This new methodology can be classified into two subtypes: 1) the homo-Mannich reaction of cyclopropanol with imines or iminium ions and 2) the homo-Mannich-type reaction of cyclopropanol with heteroarenes. Through different ways to generate imines or iminium ions, tandem or sequential reactions of C-H oxidation/homo-Mannich, Bischler-Napieralski/homo-Mannich, and asymmetric allylation/homo-Mannich have been developed, leading to the rapid assembly of core scaffolds of sarpagine, koumine, ibophyllidine, Aspidosperma, Melodinus, and Kopsia alkaloids. Besides the reactions with imines or iminium ions, cyclopropyl alcohol can undergo ring-opening addition to indole and pyrrole rings to deliver core scaffolds of schizozygane and indolizidine alkaloids. Based on these methodology advancements, we have accomplished the asymmetric synthesis of 29 alkaloids belonging to 8 families. In this Account, we present a complete picture of our works concerning synthetic design, method development, and applications in natural product total synthesis. It is anticipated that the development of new methodologies of cyclopropyl alcohol will find broad applications in the realm of natural product synthesis.

Discovery of Novel RNA Demethylase FTO Inhibitors Featuring an Acylhydrazone Scaffold with Potent Antileukemia Activity.

Fat mass obesity-associated protein (FTO) has been emerging as a potential therapeutic target for drug discovery in RNA epigenetics. In this work, a series of novel FTO inhibitors featuring an acylhydrazone scaffold were identified, and the optimized compounds 8t-v showed potent FTO inhibitory activities with IC50 values ranging from 7.1 to 9.4 μM. FTO inhibitor 8t, as the lead compound, exhibited potent antiproliferative capacities against MOLM13, NB4, and THP-1 with IC50 values of 0.35, 0.59, and 0.70 μM, respectively, and remarkably induced NB4 cell apoptosis. Compound 8t also inhibited the FTO demethylation, enhanced the abundance of m6A, stabilized FTO protein folding, and regulated the oncogenic FTO signaling pathway. Importantly, compound 8t significantly caused a tumor volume reduction and tumor weight loss with a tumor growth inhibition (TGI) value of 51% in NB4 xenograft mice. Overall, our work provided valuable lead compounds for FTO inhibitors featuring an acylhydrazone scaffold with potent antileukemia activity both in vitro and in vivo.

Methyl Derivatives of Flavone as Potential Anti-Inflammatory Compounds.

Flavones are natural compounds that are broadly distributed in our diet. Their unique properties provide the possibility to control the immune system and the process of inflammation. A high intake of flavonoids, including flavones, may offer protection against reactive oxygen species, inflammation, and chronic diseases. In this research, we evaluated the anti-inflammatory effect of five methylflavones, 2'-methylflavone (5C), 3'-methylflavone (6C), 4'-methylflavone (7C), 6-methylflavone (8C), and 6-methyl-8-nitroflavone (12C), in lipopolysaccharide (LPS) stimulated RAW 264.7 cells (murine macrophage cell line). We estimated the nitrite concentration and detected reactive oxygen species using the chemiluminescence method. Moreover, we measured the production of pro-inflammatory cytokines using the Bio-Plex Magnetic Luminex Assay. As a result of our findings, we have established that some of the methyl derivatives of flavone inhibit nitric oxide (NO) production and chemiluminescence generated by LPS-stimulated macrophages, but they also have an influence on pro-inflammatory cytokines production. This study showed that 2'-methylflavone (5C) and 3'-methylflavone (6C) possess the strongest anti-inflammatory activity among all tested derivatives of flavone. In conclusion, our study demonstrated that methylflavones may be potentially valuable compounds for the alleviation of inflammatory reactions.

Rational Design of Porous Organic Framework (POF) for Efficient Conversion of CO2 to Cyclic Carbonates and 2-Oxazolidinones at Atmospheric Pressure Conditions.

Carbon dioxide (CO2) capture and its subsequent catalytic fixation into usable compounds represent a potential approach for addressing the energy problem and the implications of global warming. Hence, it is necessary to develop effective catalytic systems required for the transformation of CO2 into valuable chemicals/fuels. Herein, we rationally designed a hydroxyl-functionalized porous organic framework (OH-POF) consisting of both acidic (OH) as well as basic N sites for the transformation of CO2 using epoxides for the production of cyclic carbonates (CCs), a useful commodity chemical under environmental-friendly, metal/solvent/co-catalyst-free conditions. Moreover, OH-POF was post-synthetically modified to anchor non-noble metal, Zn(II) to generate Zn-POF and further explored it for the efficient functionalization of CO2 with propargylic amines to generate valuable bioactive 2-oxazolidinones. Significantly, both OH-POF and Zn-POF demonstrated exceptional reusability with catalytic efficacy retained across numerous cycles of use. Notably, this study showcases a green and sustainable process for utilization of CO2 under environmentally favorable ambient conditions into two highly valuable compounds, viz cyclic carbonates and 2-oxazolidinones.

Biotechnological techniques in the production of plant-made pharmaceuticals

Plants produce a wide variety of secondary metabolites, many of which have complex structures. Wild and cultivated plants currently remain the primary sources of most pharmaceutically significant secondary metabolites. However, the production of these compounds in plants is limited by the capacity of their biosynthetic pathways. This limitation has prompted efforts to develop methods to increase the yield of desired secondary metabolites. Advances in "omic" techniques have accelerated the development of approaches that utilize plants as bio-factories to produce these valuable compounds. This review provides an overview of strategies for producing high-value plant products and using plants as heterologous hosts to produce foreign recombinant proteins for medical applications.

Effects of banana peel flour (Musa paradisiaca AAB (sub-group Pisang Nangka)) substitution on physicochemical and sensory properties of bun

This study focused on the utilisation of banana peel flour (BPF) as a potential substitute for wheat flour in buns, addressing both agriculture waste reduction and enhanced bun nutritional value. The widespread cultivation of bananas results in surplus by-products, particularly discarded peels, contributing to organic waste accumulation. Given the recognition of valuable compounds within banana peels and concerns surrounding wheat consumption, investigating BPF's feasibility as an alternative flour is paramount. The specific aims encompass assessing BPF's physicochemical attributes relative to wheat flour and evaluating sensory and physicochemical characteristics of BPF-incorporated buns compared to conventional wheat flour buns. Analysis of BPF revealed reduced moisture and water activity, and increased ash, minerals, crude fibre, and total soluble solids compared to wheat flour. The intensified red-yellow hues in BPF, attributed to the Maillard browning reaction, signify potential sensorial alterations. Upon substitution, bun hardness, gumminess, chewiness, mineral content, and crude fibre increased, while L* and b* values declined in both crumb and crust. The incorporation of 5% BPF had a milder impact on overall bun acceptance than a 10% substitution level. This gradual integration of BPF suggests a plausible way to replace wheat flour, effectively addressing waste reduction, enhancing environmental sustainability, and bolstering nutritional composition. Future research could delve into exploring the antioxidant and antimicrobial properties of BPF, unlocking innovative possibilities for utilising agricultural by-products, thereby advancing sustainable and nutritionally enriched food production.

Microwave Synthesis of Butyl Levulinate Using a Keggin Heteropolyacid from Eichhornia crassipes Cellulose Obtained by Pretreatment with Bacillus sp.

Underutilized lignocellulosic biomass, such as aquatic plants, faces sustainability challenges due to energy-intensive treatments. This study investigates the use of Bacillus sp. for the biological pretreatment of water hyacinth (Eichhornia crassipes) aiming to improve the efficiency of alkyl levulinate (AL) production, which are valuable compounds used as fuel additives, solvents, and plasticizers. The pretreatment with Bacillus sp. resulted in stable bacterial growth and a significant increase in cellulose content (up to 27%) compared to untreated samples. X-ray diffraction revealed a higher crystallinity index (63%) in the treated cellulose, while morphological analysis confirmed microbial degradation. Thermogravimetric analysis showed improved thermal stability, consistent with the higher crystallinity, and FTIR spectra indicated successful delignification. The microwave-assisted synthesis of butyl levulinate yielded 30% from Bacillus sp.-treated cellulose, compared to 11% from untreated cellulose, highlighting the potential for biomass valorization through biological pretreatment.

Leveraging CRISPR/Cas9 in notable bacteria for the production of industrially valuable compounds

Leveraging CRISPR/Cas9 in notable bacteria for the production of industrially valuable compounds

Recent Advances in the Chemistry of Thienopyranone Heterocycles: Synthesis, Reactivity, and Application

Abstract: Thiophene and pyranone are valuable heterocyclic compounds that play a crucial role in the development of new drug molecules. The combination of thiophene and pyranone moieties in hybrid structures has opened exciting possibilities for various applications, leading to the discovery of thienopyranones (Thpyns), such as 5H-thieno[3,2-b]pyran-5-one, 2H-thieno[2,3-b]pyran-2-one, 4H-thieno[3,2-c]pyran-4-one, 7H-thieno[2,3-c]pyran-7-one, all of which exhibit intriguing properties. This review offers an in-depth analysis of the preparation methods and chemical reactivity of thienopyranones

Characterisation of Cannabis glandular trichome development reveals distinct features of cannabinoid biosynthesis.

Cannabis trichome development progresses in distinct phases that underpin the dynamic biosynthesis of cannabinoids and terpenes. This study investigates the molecular mechanisms underlying cannabinoid and terpenoid biosynthesis in glandular trichomes of Cannabis sativa (CsGTs) throughout their development. Female Cannabis sativa c. Hindu Kush were cultivated under controlled conditions, and trichome development was analysed from week 3 to week 8 of the flowering period. We employed light microscopy, quantitative metabolomics and proteomics to analyse morphological changes in trichome secretory cell development, and temporal changes in metabolite accumulation and protein abundance. Our findings identified three distinct developmental phases: pre-secretory (T3), secretory (T6), and post-secretory (T8), the first time the three phases of trichome development have been identified and investigated in CsGTs. The pre-secretory phase was characterized by smaller secretory cells, limited metabolite accumulation and elevated levels of proteins involved in protein biosynthesis and cellular development. The secretory phase exhibited the highest biosynthetic activity, marked by larger secretory cells, increased plastidal activity, central carbon metabolism, and significant accumulation of cannabinoids and terpenoids. The post-secretory phase showed a decrease in secretory cell size, reduced metabolic activity, and a decrease in the abundance of primary and secondary metabolism enzymes, although THCA continued to accumulate. Key enzymes showed dynamic changes correlating with the stages of trichome development. This study provides a comprehensive understanding of the molecular mechanisms regulating cannabinoid and terpenoid biosynthesis in CsGTs, offering insights for enhancing the production of these valuable compounds through targeted breeding and biotechnological approaches.

Green and Innovative Extraction: Phenolic Profiles and Biological Activities of Underutilized Plant Extracts Using Pulsed Electric Fields and Maceration.

Underutilized plant species such as Asteriscus graveolens (Forssk.) Less., Haloxylon scoparium Pomel, and Ruta chalepensis L. have been historically valued in traditional medicine for their potential health benefits. These species present an untapped source of bioactive compounds with significant applications in the food and pharmaceutical industries, including the development of functional foods and additives. Recent advances in food processing have introduced innovative methods, such as pulsed electric fields (PEFs), to enhance the extraction of valuable compounds without compromising their integrity or quality. This study investigates the impact of PEF technology on the recovery of bioactive compounds from these plants, comparing it with conventional maceration (MAC) techniques. Phenolic compound profiles and biological activities, including antioxidant, antimicrobial, anti-inflammatory, and cytotoxic effects, were evaluated. The results demonstrated that for R. chalepensis, PEF extraction achieved comparable phenolic content (58 mg/g) to MAC (72 mg/g). However, MAC generally provided higher phenolic yields for other plants. A. graveolens extracts exhibited significant antitumoral and anti-inflammatory potentials. The antimicrobial results indicated that MAC extracts were more effective against bacterial growth, while PEF extracts outperformed MAC against A. brasiliensis (MIC: 10 mg/mL). Antioxidant potential was observed in both methods, with TBARS IC50 values ranging from 17 to 79.5 µg/mL. While MAC generally yielded superior results, PEF extraction showed great promise as an environmentally sustainable alternative, eliminating the need for organic solvents and aligning with green extraction principles.

Valorisation of Refosco grape pomace: exploring its antioxidant, antimicrobial, and antiadhesive properties

Abstract Agricultural by-products, including winery waste, represent both an environmental challenge and a valuable source of bioactive compounds. This study investigated the antioxidative, antimicrobial, and antiadhesive properties of grape seed and peel extracts derived from the red wine variety Refosco. Water and methanol extracts were prepared from dried, ground seeds and peels, both before and after supercritical extraction (SFE). The total antioxidant capacity (TAC) of water- and lipid-soluble compounds was measured. Minimal inhibitory concentrations (MICs) and antiadhesion effects of water extracts were then determined for Campylobacter jejuni, Escherichia coli, Staphylococcus aureus, and Pseudomonas aeruginosa. The antimicrobial effects were further evaluated in pasta dough as a model food matrix. Our results showed that some methanol extracts exhibited significantly higher TAC values compared to water extracts. However, the TAC of water-soluble compounds was significantly higher than that of lipid-soluble compounds, regardless of the solvent used. Although the TAC of dried seed and peel samples (SDRY; PDRY) was higher than that of SFE residues, the difference was not statistically significant. The most potent antimicrobial effect was observed for SDRY extracts, with MICs as low as 0.625 mg/mL. Additionally, both SDRY and PDRY water extracts, at 1/8 of the MIC, exhibited antiadhesion activity. In conclusion, red grape pomace from the Refosco variety proves to be a cost-effective source of valuable water-soluble compounds with antioxidative, antimicrobial, and antiadhesive properties. Importantly, results showed that the SFE residue retained some bioactive properties, further highlighting the potential of this by-product.

Is Membrane Filtration Applicable for the Recovery of Biologically Active Substances from Spent Lavender?

This study explored the batch membrane filtration of 40% ethanol extracts from spent lavender, containing valuable compounds like rosmarinic acid, caffeic acid, and luteolin, using a polyamide-urea thin film composite X201 membrane. Conducted at room temperature and 20 bar transmembrane pressure, the process demonstrated high efficiency, with rejection rates exceeding 98% for global antioxidant activity and 93-100% for absolute concentrations of the target components. During concentration, the permeate flux declined from 2.43 to 1.24 L·m-2·h-1 as the permeate-to-retentate-volume ratio increased from 0 to 1. The process resistance, driven by osmotic pressure and concentration polarization, followed a power-law relationship with a power value of 1.20, consistent with prior nanofiltration studies of rosmarinic acid solutions. Notably, no membrane fouling occurred, confirming the method's scalability without compromising biological activity. The antioxidant activity, assessed via the DPPH method, revealed that the retentate exhibited double the activity of the feed. Antibacterial assays using broth microdilution showed that the retentate inhibited Escherichia coli by 73-96% and Bacillus subtilis by 97-98%, making it the most active fraction. These findings validate the effectiveness of the X201 membrane for concentrating natural antioxidants and antibacterial agents from lavender extract under sustainable operating conditions.