Versatile Agent Research Articles

SYNTHESIS OF VANADIUM GRAPHITIC-CARBON NITRIDE(V/g-C₃N₄) COMPOSITE FOR BIOLOGICAL APPLICATION

The synthesis of vanadium carbon nitride (V/g-C₃N₄) composites has been explored for their potential as antimicrobial and antioxidant agents. These materials were evaluated against Escherichia coli and Staphylococcus aureus using a combination of disc diffusion, well diffusion, and biofilm inhibition assays. Antioxidant properties were assessed through DPPH free radical scavenging analysis. V/g-C₃N₄ composites demonstrated notable antimicrobial activity, exhibiting inhibition zones comparable to ciprofloxacin, the standard antibiotic. In disc and well diffusion assays, the composites significantly inhibited the growth of both bacterial strains, with Staphylococcus aureus exhibiting marginally higher sensitivity. Biofilm inhibition assays revealed effective suppression of bacterial adhesion and biofilm formation, achieving biofilm inhibition percentages of approximately 17% for E. coli and 22.6% for S. aureus. These results underscore the potential of V/g-C₃N₄ in curbing biofilm-associated infections. Antioxidant activity was quantitatively measured using the DPPH assay, with radical scavenging efficiency consistently exceeding 52%. This performance highlights the dual functionality of V/g-C₃N₄ composites as both antimicrobial and antioxidant agents. Comparatively, ciprofloxacin demonstrated superior antibacterial activity but lacked antioxidant properties, emphasizing the multifaceted advantage of V/g-C₃N₄ composites in biomedical applications. The shake-flask method further validated the biocompatibility and antimicrobial effectiveness of V/g-C₃N₄. This study indicates that vanadium carbon nitride composites hold promise as versatile agents in combating oxidative stress and bacterial infections, particularly in environments where biofilm formation exacerbates antimicrobial resistance. Future studies will focus on optimizing the composite synthesis and exploring its efficacy against a broader range of pathogens.

Modeling and optimization of surface modification process of ultrafiltration membranes by guanidine-based deep eutectic solvent.

Low performance and the high fouling tendency of Polyetherimide (PEI) membranes prevent their widespread commercial utility. In this study, we utilized a deep eutectic solvent (DES) as a versatile agent for surface modification of the PEI membrane using a simple and sustainable method. To attain an efficient PEI membrane, modeling and optimization of the modification condition were conducted via response surface methodology (RSM). The effects of two effective variables, including the choline/guanidine (Ch/Gu) ratio (0.5-2) and modification time (12-48h), were evaluated on four responses, i.e., pure water flux (PWF), flux recovery ratio (FRR), irreversible fouling ratio (Rir), and total resistance (Rt). The structural and chemical characteristics and filtration performance of the fabricated membranes were evaluated. The optimum condition was obtained at a 0.8 Ch/Gu ratio and 30h of modification time to reach the best performance of the DES-PEI membrane. The industrial application of optimally modified DES/PEI membrane was investigated by filtering penicillin and cephalexin antibiotics. The rejection data showed higher performance of the modified membrane (>95%) compared to the bare membrane (∼63%). Furthermore, the long-term filtration evaluation in dead-end and cross-flow setups indicated stable flux and rejection of the DES/PEI-modified membrane. The DES, including Ch/Gu, can be viewed as an agent to enhance both PWF and antifouling properties while broadening membrane applications in separating antibiotics for PEI membranes through an eco-friendly and cost-effective method.

Synthesis and Characterization of Metal Particles Using Malic Acid-Derived Polyamides, Polyhydrazides, and Hydrazides.

Malic acid-derived polyamides, polyhydrazides, and hydrazides exhibit strong potential for a variety of biological applications. This study demonstrates the synthesis of cobalt, silver, copper, zinc, and iron particles by a facile chemical reduction approach utilizing malic acid-derived polyamides, polyhydrazides, and hydrazides as stabilizing and reducing agents. Comprehensive characterization of the particles was performed using UV-Vis spectroscopy, FTIR, XRD, SEM, and EDX analysis. The synthesized particles included both zero-valent metals and oxides exhibiting mixed-phase compositions that may influence their functional properties. UV-vis analysis confirmed the formation of particles represented by the surface plasmon resonance (SPR) peaks specific to each metal particle. FTIR spectroscopy revealed the interaction of the metal particles with the polymer matrix owing to the significant contribution of functional groups in the processes of reduction and stabilization. Further structural insights were obtained via X-ray diffraction (XRD), which identified crystalline phases, and scanning electron microscopy (SEM), which demonstrated uniform morphologies. Additionally, energy-dispersive X-ray (EDX) analysis provided compositional details, affirming the purity and distribution of metallic elements. These findings highlight the potential of malic acid-derived polymers as versatile agents for nanoparticle synthesis with applications in catalysis, sensing, and biomedical technologies.

Applications of Au25 Nanoclusters in Photon-Based Cancer Therapies.

Atomically precise gold nanoclusters (AuNCs) exhibit unique physical and optical properties, making them highly promising for targeted cancer therapy. Their small size enhances cellular uptake, facilitates rapid distribution to tumor tissues, and minimizes accumulation in non-target organs compared to larger gold nanoparticles. AuNCs, particularly Au25, show significant potential in phototherapy, including photothermal (PTT), photodynamic (PDT), and radiation therapies. These therapies benefit with minimal damage to surrounding healthy tissue. AuNCs also demonstrate excellent stability and biocompatibility, crucial for their effective use in clinical applications. Recent advances in the synthesis and functionalization of AuNCs have further improved their therapeutic efficacy, making them versatile agents for enhancing cancer treatment outcomes. Ongoing research aims to better understand their pharmacokinetics, biodistribution, and long-term safety, paving the way for their broader application in advanced cancer therapies.

Chemical and Biotechnological Processes Employed as Emerging Technologies for the Production and Stability of Bacteriocins

Bacteriocins are antimicrobial peptides produced by bacteria with promising potential for controlling pathogens in various fields. This study highlights recent advances in the research on bacteriocins, providing a comprehensive overview of emerging technologies applied to the production and stability of these compounds, as the use of alternative substrates and encapsulation techniques. In recent decades, significant efforts have focused on discovering novel molecules with broad-spectrum activity capable of combating both Gram-positive and Gram-negative microorganisms, including clinically and industrially relevant pathogens. Recent studies explore strategies to optimize bacteriocin production, such as modifications in cultivation parameters aimed at reducing costs and increasing yield. Additionally, microencapsulation techniques have been widely discussed, emphasizing their role in enhancing the stability and efficacy of bacteriocins under adverse conditions. Finally, this article examines the potential applications of bacteriocins, highlighting their use as natural food preservatives, therapeutic alternatives for infection control, and bioactive agents in sustainable agriculture. These advancements establish bacteriocins as versatile agents with significant technological and economic impacts.

Ecological Niches of Bacillus Species and their Multifaceted Mechanisms in Combatting Plant Pathogens

The Bacillus genus, an integral member of the Firmicutes phylum, is characterized by its rod-shaped structure and widespread presence in diverse ecosystems. Known for its resilience, Bacillus thrives in various environments, making it a versatile agent in agriculture. Several Bacillus species serve as biocontrol agents, effectively managing fungal and bacterial plant diseases. Their efficacy stems from a range of biochemical and metabolic actions, including the production of siderophores that suppress phytopathogens and promote plant growth. Bacillus spp. produce hydrolytic enzymes such as chitinases, glucanases, proteases, and cellulases, which degrade pathogen cell components, leading to cellular collapse. Additionally, Bacillus secretes antimicrobial compounds like bacillomycin, fengycin, iturin, surfactin, and difficidin, targeting multiple plant pathogens. The production of volatile antimicrobial compounds further enhances their biocontrol potential by inhibiting microbial growth and reproduction. Moreover, Bacillus plays a vital role in activating plant defense mechanisms, including Induced Systemic Resistance (ISR). Through the production of elicitor compounds, Bacillus triggers the jasmonic acid signaling pathway on host plant, fortifying the plant's biochemical and physical barriers against pathogen invasion. These multifaceted attributes position Bacillus as a promising tool for sustainable plant disease management and enhanced crop health.

Lactoferrin as a Versatile Agent in Nanoparticle Applications: From Therapeutics to Agriculture.

Nanoparticles (NPs) have emerged as a potent choice for various applications, from drug delivery to agricultural studies, serving as an alternative and promising methodology for future advancements. They have been widely explored in delivery systems, demonstrating immense promise and high efficiency for the delivery of numerous biomolecules such as proteins and anticancer agents, either solely or modified with other compounds to enhance their capabilities. In addition, the utilization of NPs extends to antimicrobial studies, where they are used to develop novel antibacterial, antifungal, and antiviral formulations with advanced characteristics. Lactoferrin (Lf) is a glycoprotein recognized for its significant multifunctional properties, such as antimicrobial, antioxidant, anti-inflammatory, anticancer, and neuroprotective effects. Its activity has a broad distribution in the human body, with Lf receptors present in multiple regions. Current research shows that Lf is utilized in NP technology as a surface material, encapsulated biomolecule, and even as an NP itself. Due to the abundance of Lf receptors in various regions, Lf can be employed as a surface material in NPs for targeted delivery strategies, particularly in crossing the BBB and targeting specific cancers. Furthermore, Lf can be synthesized in an NP structure, positioning it as a strong candidate in future NP-related applications. In this article, we explore the highlighted and underexplored areas of Lf applications in NPs research.

Natural killer cells as promising candidates in Cancer therapeutics and related immune resistance in tumor microenvironment

Natural killer (NK) cells, as critical components of the innate immune system, have emerged as promising candidates in cancer therapy due to their ability to recognize and destroy tumor cells without prior sensitization. Their mechanisms of action, including perforin-granzyme release and antibody-dependent cellular cytotoxicity (ADCC), position them as versatile agents in cancer immunotherapy. Recent advancements, such as chimeric antigen receptor (CAR)-NK cells and cytokine-based stimulation, have demonstrated enhanced efficacy and reduced side effects compared to conventional immunotherapies. However, the immunosuppressive tumor microenvironment (TME) remains a significant obstacle, imposing challenges like immune checkpoint activation, cytokine suppression, and metabolic constraints that impair NK cell activity. This paper explores the therapeutic potential of NK cells, the challenges of immune resistance in the TME, and emerging strategies to enhance NK cell efficacy. Addressing these challenges is crucial for optimizing NK cell-based treatments and achieving durable responses in cancer patients.

Repurposing Historic Drugs for Neutrophil-Mediated Inflammation in Skin Disorders.

Neutrophil-mediated inflammation is a key feature of immune-mediated chronic skin disorders, but the mechanistic understanding of neutrophil involvement in these conditions remains incomplete. Dapsone, colchicine, and tetracyclines are established drugs within the dermatologist's therapeutic armamentarium that are credited with potent anti-neutrophilic effects. Anti-neutrophilic drugs have established themselves as versatile agents in the treatment of a wide range of dermatological conditions. Some of these agents are approved for the management of specific dermatologic conditions, but most of their current uses are off-label and only supported by isolated reports or case series. Their anti-inflammatory and immunomodulatory properties make them particularly valuable in managing auto-immune bullous diseases, neutrophilic dermatoses, eosinophilic dermatoses, interface dermatitis, and granulomatous diseases that are the focus of this review. By inhibiting inflammatory pathways, reducing cytokine production, and modulating immune responses, they contribute significantly to the treatment and management of these complex skin conditions. Their use continues to evolve as our understanding of these diseases deepens, and they remain a cornerstone of dermatological therapy.

Peptide-Based Biomaterials for Combatting Infections and Improving Drug Delivery.

This review explores the potential of peptide-based biomaterials to enhance biomedical applications through self-assembly, biological responsiveness, and selective targeting. Peptides are presented as versatile agents for antimicrobial activity and drug delivery, with recent approaches incorporating antimicrobial peptides into self-assembling systems to improve effectiveness and reduce resistance. The review also covers peptide-based nanocarriers for cancer drug delivery, highlighting their improved stability, targeted delivery, and reduced side effects. The focus of this work is on the bioactive properties of peptides, particularly in infection control and drug delivery, rather than on their structural design or material characteristics. Additionally, it examines the role of peptidomimetics in broadening biomaterial applications and enhancing resistance to enzymatic degradation. Finally, the review discusses the commercial prospects and challenges of translating peptide biomaterials into clinical applications.

Therapeutic potential and agricultural benefits of curcumin: a comprehensive review of health and sustainability applications

AbstractTurmeric (Curcuma longa L.), the plant from which curcumin is derived, is renowned for its wide range of therapeutic and agricultural benefits. Curcumin, the key bioactive compound, is highly valued for its potent anti-provocative, antioxidant, and antimicrobial properties, which contribute to its effectiveness in treating various human diseases and improving plant resilience to environmental stresses. The therapeutics potential of curcumin is notable owing its abilities to combat microbes act as an oxidant and reduce inflammation. Its effectiveness in treating a range of human disease such as tumor, cardiac problems, and brain degenerative ailments stems from its ability to modulate various cellular process and signaling pathways. Despite its low bioavailability, innovations in delivery system such as nanoparticles and liposomal formulations, have enhanced its therapeutic efficacy by improving solubility and systemic absorption. In agriculture, curcumin's antimicrobial properties provide a natural alternative to chemical pesticides, offering protection against pathogens and enhancing plant resilience to specific environmental stresses such as drought, salinity, and oxidative stress. Nanotechnology applications have furthered these benefits by facilitating the efficient uptake and distribution of curcumin within plant tissues, promoting growth and stress tolerance. This review also highlights curcumin's nutritional benefits, including its impact on gut health and metabolic syndrome. Synergistic interactions with dietary nutrients can amplify its health benefits, making it a valuable dietary supplement. However, ongoing research is needed to fully understand curcumin's mechanisms of action and long-term safety. Overall, curcumin holds promise as a versatile agent in both medical and agricultural fields, supporting sustainable practices and advancing health outcomes. Future research should focus on optimizing curcumin formulations and translating preclinical findings into clinical successes. Graphical abstract

Biomedical applications of terbium oxide nanoparticles by Couroupita guianensis aubl leaves extract: A greener approach

Couroupita guianensis aubl (CGA) is a plant known for its therapeutic characteristics and extensively used in biomedicine. This paper presents a method for synthesizing terbium oxide (Tb2O3) nanoparticles (NPs) utilizing the leaves extract of CGA which is sustainable and environmentally friendly. The practical synthesis of Tb2O3 NPs was validated using UV–vis analysis, revealing a prominent peak at 246 nm and the calculated band gap value of 3.02 eV. The existence of numerous functional groups and molecular bonding interactions in the Tb2O3 NPs was confirmed using FTIR spectrum analysis. In addition, the XRD examination confirmed that the nanoparticles had a crystalline structure with dimensions of 27.3 nm. The TEM imaging revealed the particle size of around 5.63 nm. The manufactured Tb2O3 NPs were analysed for anticancer capabilities against human MCF-7 cancer cell lines. Overall, our study emphasizes the ability of green-produced Tb2O3 NPs to be versatile agents with antidiabetic, antioxidant, and anticancer effects. These nanoparticles are potentially used in biomedical applications, providing long-lasting solutions to various health-related problems.

Alginate-functionalized and 4T1 cell membrane-coated multi-tasking nanoparticulate system for near-infrared-triggered photodynamic therapy on breast cancer: In vitro cellular and in vivo mice models

Recently, combination treatment of chemo-dynamic therapy (CDT) and photodynamic therapies (PDT) is well-known and prominent therapeutic strategy for breast tumor. Importantly, tailored nanomedicines with unique personalized properties including nanocarrier suitability and effective targeting ability that requires the exhaustive understanding of tumor microenvironment. Recently, researchers have designed a smart upconversion nanoparticles (UCNPs) that have unique characteristics to achieve targeting for respond tumor microenvironment. In the present study, we first time fabricated a novel combination of oxidized sodium alginate-enveloped and 4T1 cancer cell membrane-coated up-conversion nanoparticles (4TUCNP@SMZ) were engineered for breast cancer-targeted therapy. The nanoparticles could be formed via electrostatic interaction, which showed excellent biocompatibility, increased cellular uptake with normal and cancer cells. The fabricated Alginate and 4T1-membrane functionalized up-conversion nanoparticles significantly benefitted to targeted delivery system for local breast cancer and prominently inhibit tumor development via chemo-dynamic therapy (CDT) and PDT. The greater susceptibility of tumor cells to oxidative stress may also result from the depletion of intracellular GSH by the 4TUCNP@SMZ nanoparticles. The in vitro cell models (4T1 and MCF-7), in vivo tumor model and histological observation demonstrated that 4TUCNP@SMZ nanoparticles effectively targeted to breast tumor microenvironment and inhibit breast cancer cells. This report suggested that multifunctional Alginate-functionalized nanoparticles are a versatile agent for phototherapy for breast cancer treatment.

Carboxymethyl Chitosan-based Nanomaterials for Biomedical Applications: An Overview of Recent Advances and Prospects

Chitin is widely recognized as a highly abundant polymer found throughout the planet. This serves as a fundamental basis for the production of chitosan through deacetylation. Chitosan is non-toxic and biodegradable, making it highly suitable for applications as a biomaterial and in the development of drug delivery systems. However, the limited solubility of chitosan in neutral or alkaline environments has hindered its use in pharmacology and biology. Chitosan can undergo carboxymethylation, which enhances its water solubility while maintaining its biodegradability and compatibility with living organisms. Carboxymethyl chitosan (CMC) is a derivative of chitosan that is soluble in water and exhibits enhanced biological and physicochemical properties compared to chitosan. The CMC, or modified CMC, is a highly versatile agent with many applications. It has shown great promise in drug delivery, wound healing, bioimaging, biosensors, tissue engineering, and gene therapy. This study investigates the properties and potential applications of materials derived from carboxymethyl chitosan. These materials have attracted significant interest due to their versatility and fascinating possibilities in biomedical nanodevices and controlledrelease medication formulations.

Green engineered Mo-CeO2@C nanocomposites for visible light-assisted dye decomposition and microbial apoptosis

The profound contamination of reservoirs triggered by industrial dyes and the growing phenomenon of antibiotic-resistant bacteria present substantial risks to both the environment and human health. Conventional approaches to water treatment and microbiological disinfection can frequently become ineffective, expensive, and detrimental to the environment, and this issue underscores the need for novel materials that possess refined photocatalytic and antibacterial characteristics that thrive efficiently in a setting of visible light. An innovative nanostructured nanocomposite, Mo-CeO2@C, was synthesized using a green chemistry method coupled with Mo-CeO2 nanoparticles and pristine CeO2. The impact of Ce, Mo, and carbon-based nanocomposites has been validated by leveraging XRD, FTIR, UV–vis spectra, and FE-SEM/EDX. The sunlight-mediated photodegradation performance of carbon-based nanocomposite exhibited a superior photodegradation efficiency of 99.5 %, higher than others. The photocatalytic activity of M.B. dye concentration, catalyst dosage, scavenger test, and recyclability were also conducted, which confirm the optimal catalyst loading of 20 mg, dye concentration 40 ppm, and pH 8 with reusability up to sixth cycles. The carbon-coated doped nanocomposite displays superior antibacterial efficacy against gram-positive S. aureus, gram-negative E. coli, and P. vulgaris bacteria in comparison to CeO2 and Mo-doped CeO2. This may be attributed to the combined effects of the generation of reactive oxygen species (R.O.S.) and the intrinsic characteristics of the dopant and carbon matrix. The results of our research emphasize the potential of carbon-based nanoparticles as versatile agents in the realms of environmental rehabilitation and biomedical research. These nanoparticles provide a method to achieve more efficient and resilient solutions in these areas.

A multifunctional natural treasure based on a “one stone, many birds” strategy for designing health-promoting applications: Tordyliumapulum

Wild plants provide important bioactive compounds, and their analysis relies heavily on selecting the right extraction techniques and solvents. This study was conducted to determine the phenolic content and biopharmaceutical potential of four different extracts (ethyl acetate, ethanol, 70% ethanol, and water) from the aerial parts of wild plant Tordylium apulum L. The biochemical profile of the extract was screened using high performance liquid chromatography -mass spectrometry (HPLC-MS) analysis. The total phenolic and flavonoid content was examined using the Folin-Ciocalteu assay and the aluminium trichloride assay, respectively. The antioxidant activity was evaluated through several tests, including 2,2-Diphenyl-1-picrylhydrazyl (DPPH), 2,2′-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) (ABTS), cupric reducing antioxidant capacity (CUPRAC), ferric reducing antioxidant power (FRAP), phosphomolybdenum (PBD), and metal chelating activity (MCA). Five types of enzyme inhibition activity were tested against acetylcholinesterase (AChE), butrylcholinesterase (BChE), tyrosinase, α-amylase, and α-glucosidase. Additionally, For the first time, the inhibitory activity of T. apulum extract against human carbonic anhydrase isoenzymes I and II (hCA-I and hCA-II) was evaluated. Fifty-five compounds for negative ionization mode, and twenty-eight compounds for positive ionization mode were recorded in HPLC-MS analysis and they were polyphenolic, flavonoids, carbohydrates, sugar alcohol and amino acids. These results indicate that different solvents extract varying levels of antioxidants from T. apulum, with ethanol and water extracts generally exhibiting superior antioxidant activities. The ethanol extract of T. apulum exhibited the maximum contents of total phenolics measuring 33.71 mg gallic acid equivalent (GAE)/g. The ethanol extract exhibited the highest inhibition of AChE with 2.28 mg galanthamine equivalent (GALAE)/g. The ethyl acetate and ethanol extracts also showed the highest hCA-I and hCA-II inhibition potential, respectively. The ethanol-water and water extracts acted on the biofilm of E. coli (49.93% and 45.22%, respectively), and the biofilm of P. aeruginosa (50.68% and 44.46%, respectively). The extracts were tested on different cell lines for cytotoxic potentials and in particular the water extract induced the apoptotic pathways in cervical cancer (HELA) cell lines. In conclusion, T. apulum exhibit multidirectional biological properties and it could be considered as a versatile agent for the development of health-promoting applications.

Versatile Approaches of Quantum Dots in Biosensing and Imaging.

Cancer is considered a formidable global health threat, despite substantial strides in diagnosis, detection, and therapeutic strategies. Remarkable progress has been achieved in these realms, yet the survival rates for cancer patients have persisted at suboptimal levels over decades. Acknowledging the need to address the ongoing challenges in cancer survival rates, research efforts are being made to push the boundaries of innovation in diagnostic techniques, bioimaging, and drug delivery technologies. Over the past few years, nano(bio)technology-based approaches have been applied for biosensing and imaging applications to detect biochemical substances in various matrices. Among various nanoengineered particulates, quantum dots (QDs) have been recognized as versatile agents for these applications. QDs, often called artificial atoms, are characterized by the remarkable optical and electrical features which are essential for cytosensing, localized bioimaging and therapeutics. Here in this review, we have discussed various QDs as sensitive and selective agents for precise sensing and imaging of cancer cells. Both electrochemical and optical approaches have been used to describe the cytosensing detection methods. Furthermore, the bioimaging of malignant tumor cells and the drug delivery with therapeutic responses of QDs have also been highlighted. This review also lists the several kinds of QDs that are frequently used for such kinds of applications, such as carbon, graphene, zinc, and other types of hybrid-based QDs. Finally, to shed insight on prospective research, the advantages and potential of QDs are also highlighted. In this article, we also emphasize the limitations and address the difficulties associated with QDs in clinical applications in order to provide insights for potential solutions.

Parametric optimization of Cement-based solidification combined with vacuum-assisted filtration

This study delves into the parametric optimalization of cement-based stabilized soft clays (CBSC) combined vacuum-assisted filtration (VAF) technique on for engineering applications, focusing on the influence of the retarder, calcium source and intermittent time etc. Key findings include VAF benefiting CBSC’s strength for water discharge from the paste, where the UCS of CBSC treated with VAF can increase more than ten times higher than the untreated samples (e.g., 767 kPa versus 60 kPa). The added retarders extend the initial setting time, thus facilitating the removal of excessive water, that the 0.2 % addition of calcium lignosulfonate causes 6.5 % increment of dewatering mass. Especially, calcium lignosulfonate, working as a versatile agent of imparting significant improvements in the rheological properties of cement mixtures and augmenting the structural integrity of clayey soils, was found to significantly enhance the VAF efficiency and the UCS, of which 28-day’s UCS further increases comparing to referential group after VAF. The study also reveals that calcium sources, such as desulfurized ash and lime, are also vital in replenishing calcium ions lost during VAF and maintaining a strong alkaline environment, significantly contributing to the strength enhancement. Additionally, the intermittent timing is also critical to the filtration efficiency, where the intermittent time was recommended within two hours post-mixing. These findings offer valuable insights for the practical application of CBSC by the VAF assistance, particularly involving soft clays with high water content.

Liposomes as versatile agents for the management of traumatic and nontraumatic central nervous system disorders: drug stability, targeting efficiency, and safety.

Various nanoparticle-based drug delivery systems for the treatment of neurological disorders have been widely studied. However, their inability to cross the blood-brain barrier hampers the clinical translation of these therapeutic strategies. Liposomes are nanoparticles composed of lipid bilayers, which can effectively encapsulate drugs and improve drug delivery across the blood-brain barrier and into brain tissue through their targeting and permeability. Therefore, they can potentially treat traumatic and nontraumatic central nervous system diseases. In this review, we outlined the common properties and preparation methods of liposomes, including thin-film hydration, reverse-phase evaporation, solvent injection techniques, detergent removal methods, and microfluidics techniques. Afterwards, we comprehensively discussed the current applications of liposomes in central nervous system diseases, such as Alzheimer's disease, Parkinson's disease, Huntington's disease, amyotrophic lateral sclerosis, traumatic brain injury, spinal cord injury, and brain tumors. Most studies related to liposomes are still in the laboratory stage and have not yet entered clinical trials. Additionally, their application as drug delivery systems in clinical practice faces challenges such as drug stability, targeting efficiency, and safety. Therefore, we proposed development strategies related to liposomes to further promote their development in neurological disease research.

Hollow magnetic vortex nanorings loaded with quercetin encapsulated in polydopamine: A high-performance, intelligent nanotheranostic platform for enhanced tumor imaging and dual thermal treatment

Nanoparticle-mediated thermotherapeutic research strives innovative, multifunctional, efficient, and safe treatments. Our study introduces a novel nanoplatform: the hollow magnetic vortex nanorings within a polydopamine layer (HMVNp), which exhibit dual functionality as magnetic and photothermal agents. Utilizing a “Dual-mode” approach, combining an alternating magnetic field (AMF) with near-infrared (NIR) laser irradiation, HMVNp demonstrated a significant enhancement in heating efficacy (58 ± 8 %, SAR = 1441 vs 1032 W/g) over traditional solid magnetite nanoparticles coated with polydopamine (SMNp). The unique geometry larger surface area to volume ratio facilitates efficient magnetic vortex dynamics and enhanced heat transfer. Addressing the challenge of heat resistant heat shock protein (Hsp) expression, encapsulated quercetin (Q) within HMVNp leverages tumor acidity and dual-mode thermal therapy to enhance release, showing a 28.8 ± 6.81 % increase in Q loading capacity compared to traditional SMNp. Moreover, HMVNp significantly improves contrast for both magnetic resonance imaging (MRI) and photoacoustic imaging (PAI), with an approximately 62 % transverse relaxation (R2 = 81.5 vs 31.6 mM-1s−1 [Fe]). In vivo studies showed that while single treatments slowed tumor growth, dual-mode therapy with quercetin significantly reduced tumors and effectively prevented metastases. Our study highlights the potential of HMVNp/Q as a versatile agent in thermotherapeutic interventions, offering improved diagnostic imaging capabilities.