Optimization of the Hemolysis Assay for the Assessment of Cytotoxicity

Protein to biomaterials: Unraveling the antiviral and proangiogenic activities of Ac-Tβ1-17 peptide, a thymosin β4 metabolite, and its implications in peptide-scaffold preparation

Peptide metabolites are emerging biomolecules with numerous possibilities in biomaterial-based regenerative medicine due to their inherent bioactivities. These small, naturally occurring compounds are intermediates or byproducts of larger proteins and peptides, and they can have profound effects, such as antiviral therapeutics, proangiogenic agents, and regenerative medicinal applications. This study is among the first to focus on using thymosin β4 protein-derived metabolites to pioneer novel applications for peptide metabolites in biomaterials. This study found that the novel peptide metabolite acetyl-thymosin β4 (amino acid 1-17) (Ac-Tβ1-17) exhibited significant protease inhibition activity against SARS-CoV-2, surpassing its precursor protein. Additionally, Ac-Tβ1-17 demonstrated beneficial effects, such as cell proliferation, wound healing, and scavenging of reactive oxygen species (ROS) in human umbilical vein endothelial cells (HUVEC). Integrating Ac-Tβ1-17 into a peptide-based scaffold facilitated cell growth and angiogenesis inside the scaffold and through gradual release into the surrounding environment. The Ac-Tβ1-17 peptide treatment induced significant biochemical responses in HUVEC, increasing Akt, ERK, PI3K, MEK, and Bcl-2 gene expression and proangiogenic proteins. Ac-Tβ1-17 peptide treatment showed similar results in ex vivo by enhancing mouse fetal metatarsal growth and angiogenesis. These findings highlight the potential of natural protein metabolites to generate biologically active peptides, offering a novel strategy for enhancing biomaterial compatibility. This approach holds promise for developing therapeutic biomaterials using peptide metabolites, presenting exciting prospects for future research and applications.

On-demand dual-stimuli-responsive hydrogels for localized and sustained delivery of MP-L [I5R8] to treat bacterial wound infections

This study presents the development of two novel injectable dual-responsive polyanionic hydrogels (DRPHs) based on N-isopropylacrylamide (NIPAM), incorporating carboxylic acid comonomers for temperature- and pH-responsive drug release. These hydrogels were designed for the sustained and localized delivery of the antimicrobial peptide MP-L [I5R8], targeting multidrug-resistant bacteria (MDRB) in wound infections. The physicochemical characterization confirmed polymer formation and comonomer integration through Fourier-transform infrared spectroscopy (FTIR) and nuclear magnetic resonance (NMR). Rheological analysis demonstrated a temperature-dependent sol-gel transition at ∼35°C, making the hydrogels suitable for in situ gelation at physiological conditions. The hydrogels exhibited tunable swelling behavior and a controlled dual-phase release profile of MP-L [I5R8], ensuring both immediate bactericidal activity and prolonged antimicrobial effect. In vitro assays confirmed sustained antimicrobial efficacy against Staphylococcus aureus and Pseudomonas aeruginosa, while biocompatibility tests validated their safety for biomedical applications. An in vivo diabetic wound infection model demonstrated rapid infection clearance, enhanced wound healing, and organized tissue regeneration following treatment with MP-L [I5R8]-loaded DRPHs. These results highlight the potential of dual-stimuli-responsive hydrogels as a next-generation antimicrobial delivery platform for the treatment of chronic infected wounds, such as diabetic foot ulcers.

Imaging oligomers of alpha-toxin (Hla) variants using high-speed AFM and neutralizing Hla hemolytic activity with their antisera

Alpha-toxin (Hla) variants, such as the toxoids HlaH35A, HlaH35L, and HlaH35LH48L, have been shown to lack hemolytic activity and present promising antigen sources for vaccine development against S. aureus. The His35 site is critical in the oligomerization process of Hla during transmembrane pore formation, leading to cell lysis. This study employed high-speed atomic force microscopy (HS-AFM) to image the structures of HlaH35A, HlaH35L, and HlaH35LH48L proteins on POPC/Chol lipid membranes. Single-site His35 mutations (HlaH35A, HlaH35L) could form oligomer structures, whereas the double-site HlaH35LH48L mutation resulted in the monomer state. These HS-AFM findings confirm that the region between His35 and His48 is crucial for protomer-protomer interactions essential for oligomerization and pore formation. Hemolytic activity of wild-type Hla on red blood cells (RBCs) was significantly reduced when mixed with HlaH35A, HlaH35L, or HlaH35LH48L at weight ratios 1:5 (HlaWT:toxoid) or higher. However, these toxoids exhibited weak neutralization activities at lower mixing ratios with HlaWT. The increased anti-Hla antibodies (IgG) in mice treated with these Hla toxoids have emerged as a potential treatment avenue to neutralize the hemolytic activity of the HlaWT toxin on RBCs. Serum analysis from mice injected with HlaH35A, HlaH35L, and HlaH35LH48L toxoids showed that these sera could neutralize the hemolytic activity of the HlaWT toxin. Thus, these Hla variants are promising candidates for developing supportive treatments for S. aureus infections.

KNR50: a moonlighting bioactive peptide hidden in the C-terminus of bovine casein αS2 with powerful antimicrobial, antibiofilm, antiviral and immunomodulatory activities

Milk is a primary nutrition source for newborns and adults and, in addition, is also a valuable reservoir of bioactive peptides. Many of these peptides are hidden as "cryptic" sequences in milk proteins and released in the bioactive form through protease digestions. Caseins, the most abundant proteins in bovine milk, host several cryptic bioactive peptides including those antimicrobials. In this study we report in-silico identification, production in recombinant form and extensive characterization of KNR50, a novel cationic antimicrobial peptide (CAMP) located at the C-terminus of bovine casein αS2. KNR50 shows antimicrobial activity against a large panel of bacteria and does not induce resistance development. In addition, KNR50 shows a remarkably wide spectrum of functional properties, as antibiofilm and antiviral activities, immunomodulatory and antioxidant properties as well as promising in-vivo anti-infective properties in a Caenorhabditis elegans model. These findings suggest that KNR50 could serve as a promising multifunctional agent with potential applications not only in combating infectious diseases and enhancing immune responses but also in non-clinical settings such as food preservation, where its antimicrobial properties could be exploited to extend shelf-life and improve food safety.

Surfactant-based drug delivery systems for cancer therapy: Advances, challenges, and future perspectives

Cancer is one of the most formidable global health challenges, needing ongoing progress in therapeutic approaches. Conventional cancer treatments, such as chemotherapy, frequently suffer from low solubility, systemic toxicity, and a lack of tailored drug delivery, resulting in unwanted side effects and limited efficacy. Surfactant-based drug delivery systems have emerged as a viable method for increasing drug solubility, stability, and tailored transport to tumor locations. Surfactants, due to their amphiphilic character, play an important role in the development of various drug delivery systems, such as micelles, liposomes, nanoemulsions, and lipid-based nanoparticles, which improve drug bioavailability and therapeutic index. This article looks at the fundamental role of surfactants in drug administration, including their classification (ionic, nonionic, amphoteric, and zwitterionic) and self-assembly behavior in the formation of micellar, vesicular, and emulsified nanocarriers. Various surfactant-based drug delivery platforms in oncology are explored, including polymeric and surfactant-stabilized micelles, liposomes (e.g., Doxil), nanoemulsions, solid lipid nanoparticles (SLNs), and nanostructured lipid carriers (NLCs). Furthermore, the use of surfactant-metal complexes in cancer therapy is emphasized because of their potential to improve therapeutic activity and selectivity. The review also looks at surfactant-enhanced drug targeting strategies, such as passive targeting using the enhanced permeability and retention (EPR) effect, active targeting with ligand-functionalized surfactant-based carriers, and stimuli-responsive systems designed for controlled drug release in the tumor microenvironment. Surfactant-based drug delivery advancements are explored, with an emphasis on current advances such as biodegradable and bio-inspired surfactants, combination therapies using surfactant-stabilized carriers, and AI-driven drug formulation techniques. Despite its potential, surfactant-based drug delivery systems confront several hurdles, including biocompatibility concerns, synthetic surfactant toxicity, stability issues, and scaling restrictions in pharmaceutical manufacture. Furthermore, regulatory barriers in clinical translation remain severe. Addressing these problems with innovative surfactant formulations, green chemical techniques, and sophisticated nanotechnological alterations will be critical to optimizing these systems for clinical use. This review provides a comprehensive analysis of the progress, challenges, and future perspectives of surfactant-based drug delivery systems in cancer therapy, highlighting their potential to revolutionize oncology treatments by improving drug efficacy, reducing systemic toxicity, and enabling precision medicine.

In vitro and in vivo antibacterial activity, resistance analysis and molecular docking study of pleuromutilin derivatives against Streptococcus suis

OBJECTIVES

To evaluate the in vitro and in vivo antimicrobial activity of pleuromutilin derivatives modified with C14 side-chain against Streptococcus suis.

METHODS

To determine the minimum inhibitory concentrations (MICs) of 268 pleuromutilin derivatives with C14 side-chain modifications against S. suis ATCC 43 765 using the broth dilution method. Derivative B43, B49, B52, B53 and B54, which exhibited better antimicrobial activity, were selected for further investigation of their in vitro antibacterial effect, cytotoxicity, and in vivo antibacterial effect.

RESULTS

Determination activity of five derivatives against clinical strains (n = 37), as well as growth and time-killing curves. Those experiments showed that all the five derivatives had good activity against S. suis in vitro. Resistance-inducing assays demonstrated that, except for B43, the derivatives had similar abilities to induce resistance to tiamulin. In addition, the five derivatives did not have erythrocyte haemolytic toxicity (0.25-16 mg/L) and cytotoxicity (1.25-80 mg/L). In the mouse thigh infection model, the derivative of B49 exhibited superior antibacterial efficacy. About 40 mg/kg B49 had good activity and improved the survival rate of mice by 33.3% in the S. suis mouse peritonitis model. Molecular docking study and scanning electron microscopy revealed that B49 can effectively bind to the active site of the 50S ribosome and disrupt cell membranes.

CONCLUSIONS

A total of 68.66% of the 268 C14 side-chain modified pleuromutilin derivatives showed potent activity against S. suis. Among them, B49 showed good in vitro and in vivo antimicrobial effects against S. suis, indicating that B49 can be intensively studied as an antimicrobial candidate compound.

Pneumolysin-responsive liposomal platform for selective treatment of Streptococcus pneumoniae

The bacterium Streptococcus pneumoniae has become a leading cause of meningitis, sepsis, and bacterial pneumonia worldwide, with increased prevalence of antibiotic-resistant serotypes serving to exacerbate the issue. The main factor responsible for colonization and immune response escape in pneumococcal infections is the secreted molecule pneumolysin, which is a subset within a family of related toxins that form transmembrane pores in biological membranes through cholesterol recognition and binding. The conserved activity and structure of pneumolysin between all observed S. pneumoniae serotypes, along with its requirement for pathogenicity, has made this molecule an attractive target for vaccination, diagnostic, and sequestration platforms, but not yet as a facilitative agent for therapeutic treatment. Consequently, the present work aimed to examine the impact of liposomal cholesterol content for pneumolysin-induced release of the encapsulated antimicrobial peptide nisin. It was determined that a cholesterol content above 45 mol% was necessary to facilitate interactions with both purified pneumolysin toxin and S. pneumoniae culture, demonstrated through enhanced nisin release and a reduction in hemolytic rates upon exposure of the toxin with cholesterol-rich vesicles. Antibacterial testing highlighted the ability of the developed platform to elicit a potent and specific bactericidal response in vitro against cultured S. pneumoniae when compared to a control strain, Staphylococcus epidermidis. It further improved viability of a fibroblast cell line upon S. pneumoniae challenge, outperforming free nisin via the synergistic impact of simultaneous bacterial clearance and pneumolysin neutralization. These findings collectively indicate that cholesterol-rich liposomes hold promise as a selective treatment platform against pneumococcal infections.

Advances in the study of extracellular vesicles of Naegleria fowleri and their role in contact-independent pathogenic mechanisms

BACKGROUND

Extracellular vesicles (EVs) are spherical membrane particles released by prokaryotic and eukaryotic cells. EVs produced by pathogenic organisms are known to play a role in host-pathogen interactions; however, despite some reports on Naegleria fowleri EVs, their potential role in inducing cytopathic effects remains poorly understood. In this study, we evaluated the role of N. fowleri EVs in contact-independent pathogenic mechanisms.

METHODS

Extracellular vesicles were characterized via transmission electron microscopy, nanoparticle tracking analysis, SDS-PAGE, mass spectrometry, Western blotting, and zymography. EVs internalization by trophozoites and MDCK epithelial cells was also determined. Finally, mammalian cells were coincubated with EVs to evaluate haemolytic activity, epithelial paracellular ionic permeability alterations, and necrosis.

RESULTS

Naegleria fowleri extracellular vesicles, ranging from 82.5 to 576.5 nm in size, were isolated, with a mean of 216.8 nm and a mode of 165.3 nm. Proteomic analysis identified 1006 proteins in the EVs, including leishmanolysin, a protein associated with pathogenic mechanisms such as adhesion and enzymatic processes. The proteolytic activity of EVs was found to be primarily due to serine protease. Furthermore, EVs were internalized by both trophozoites and MDCK cells. Additionally, EVs exhibited haemolytic activity in erythrocytes as well as increased ionic permeability and necrosis in MDCK cells 24 h postinteraction.

CONCLUSIONS

Naegleria fowleri EVs exhibit proteolytic and haemolytic activity and are internalized by trophozoites and MDCK epithelial cell monolayers, increasing the ionic permeability of the monolayer and inducing necrosis. Furthermore, these vesicles contain molecules associated with pathogenic processes such as leishmanolysin. Our results suggest that EVs facilitate paracellular invasion, migration, and damage caused by trophozoites and play a significant role in pathogenic processes as part of a contact-independent mechanism, which, in conjunction with a contact-dependent mechanism, enhances our understanding of the pathogenicity exhibited by this amphizoic amoeba during its invasion of target tissues.

Picolinic acid, a tryptophan metabolite, triggers cellular senescence by targeting NOS/p38 MAPK/CK1α/MLKL signaling and metabolic exhaustion in red blood cells

Anemia is among the most commonly reported adverse events of anticancer therapy. Picolinic acid (PA), an endogenous metabolite of tryptophan degradation in the kynurenine pathway, is a metal chelator with an anticancer activity. The objective of the current study is to investigate the modulation of red blood cell (RBC) lifespan by PA. Hemolytic and eryptotic markers were evaluated in the presence and absence of PA by photometric and flow cytometric methods. PA demonstrated a dual effect on hemolysis in which it was pro-hemolytic in isotonic media but anti-hemolytic under hypotonic challenge. PA also induced RBC senescence with reduced AChE activity. In addition, treated cells tested positive for annexin-V and Fluo4 and had a significantly lower forward scatter signal. Notably, ATP-replenished cells showed significantly enhanced chemoresistance against PA toxicity, which was also alleviated by ascorbic acid, L-NAME, SB203580, D4476, and necrosulfonamide. Furthermore, an inhibitory effect on PA was observed in incubation media supplemented with isosmotic sucrose but not urea. These data suggest that PA accelerates RBC aging through anticholinesterase activity and exhibits hemolytic and eryptotic properties characterized by phosphatidylserine externalization, Ca2+ mobilization, cell shrinkage, metabolic shutdown, and stimulation of the NOS/p38 MAPK/CK1α/MLKL pathway.

Supplementary Information

The online version contains supplementary material available at 10.1007/s43188-025-00280-5.

Harnessing curcumin in a multifunctional biodegradable metal-organic framework (bio-MOF) for targeted colorectal cancer theranostics

Despite significant advancements in managing colorectal cancer (CRC), the issues of efficient diagnosis and targeted therapy remain demanding. To address these challenges and improve treatment outcomes while reducing the cost and side effects, there is a need for more effective theranostic systems that combine diagnostic techniques with therapeutic modalities. This study introduces a pioneering approach for the synthesis of a porous bio-MOF (biodegradable metal-organic framework) using iron as the metal component and curcumin as the pharmaceutical ingredient. Subsequently, the developed drug delivery system was equipped with the anticancer drug doxorubicin (DOX), coated with biocompatible polyethylene glycol (PEG), and targeted with a CRC-specific aptamer (EpCAM). The physicochemical characterization confirmed the successful synthesis of the bio-MOF, demonstrating high encapsulation efficiency and pH-dependent release of DOX. In vitro studies for anticancer activity, cellular uptake, and mechanism of cell death demonstrated that in the case of positive EpCAM HT-29 cells, Apt-PEG-MOF@DOX had enhanced internalization that resulted in massive apoptosis. In vivo studies of the nanoparticles were then conducted in immunocompromised C57BL/6 mice bearing HT-29 tumors. These studies showed that the targeted platform could induce efficient tumor regression with reduced systemic toxicity. The targeted bio-MOF also exhibited MRI imaging properties useful for monitoring tumors. Significantly, the biocompatibility of the introduced bio-MOF was enhanced by pursuing the green synthesis method, which does not engage toxic solvents and strong acids. Overall, this multimodal system acts diversely as a tumor imaging agent and a therapeutic delivery platform suitable for CRC theranostics.

Bacteria-triggered on-demand thymol release for salmon preservation: A self-destructive antibacterial strategy

To prevent foodborne pathogen invasion in fresh meat during storage, this study develops an enzyme/redox dual-responsive nanomaterial (Thy@MSN-S-S-Casein). Upon encountering bacteria, the casein shell is degraded by bacterial proteases, and glutathione (GSH) cleaves the disulfide bonds on the mesoporous silica nanoparticle (MSN) surface, releasing thymol to combat the bacteria. Trypsin and GSH triggered a cumulative release of 68.37 % thymol from Thy@MSN-S-S-Casein within 48 h, which was significantly higher than the release by trypsin alone (49.93 %) or without any activation (17.33 %). The antibacterial activities of Thy@MSN-S-S-Casein can be triggered by both artificially inoculated bacteria and naturally-infected bacteria on the salmon surfaces, leading to a reduction in the total viable count (TVC) in both experiments. Additionally, it inhibited the deterioration of the salmon fillets' quality indicators and extended their shelf life by about 3 days. This bacteria-triggered release strategy offers a promising self-destructive antibacterial approach for mitigating pathogen outbreaks in food preservation.

Exploring the correlation of linker structure and antimicrobial activities of pyridinium-based cationic biocides: Aromatic versus aliphatic architectures

Cationic biocides, particularly quaternary ammonium compounds (QACs), play a vital role in controlling microbial infections across various industries, healthcare facilities and households. As their widespread use increased drastically in the last few years due to COVID-19, there is growing concern about the development of resistance among microorganisms exposed to cationic biocides. It is crucial to recognize this threat in advance and respond by modifying and replacing the old generation of commercial biocides. Reported here is the pyridinium-based bis-QACs tuning via combination of two simple synthesis approaches to achieve novel biocide's architectures with mixed linkers. The obtained compounds were subjected to a broad bioactivity assay against a panel of 26 microbial pathogens, including multi-resistant bacterial ESKAPEE strains, fungi and biofilms. Novel hit-compounds showed improved antibacterial and antibiofilm action, rapid bacterial eradication within 15-30 min of exposure and 4.5-fold lower hemotoxicity, as well as lower potential for the development of bacterial resistance compared to commercial lead antiseptic octenidine. Highlighted findings and insights will serve as a good basis for further studies of bis-QACs as highly effective biocides.

Cationic antimicrobial peptides: potential templates for anticancer agents

Cancer is a major global health concern and one of the leading causes of death worldwide. According to the World Health Organization (WHO), there is an urgent need for novel therapeutic agents to treat this disease. Some antimicrobial peptides (AMPs) have demonstrated activity against both microbial pathogens and cancer cells. Among these, cationic AMPs (CAMPs) have garnered significant attention because of their ability to selectively interact with the negatively charged surfaces of cancer cell membranes. CAMPs present several advantages such as high specificity for targeting cancer cells, minimal toxicity to normal cells, reduced probability of inducing resistance, stability under physiological conditions, ease of chemical modification, and low production costs. This review focuses on CAMPs with anticancer properties such as KLA, bovine lactoferricin derivatives, and LTX-315, and briefly explores common bioinformatics tools for Anticancer Peptides (ACPs) selection pipeline from AMPs.

Rational design of synthetic antimicrobial peptides based on the Escherichia coli ShoB toxin

Antibiotic resistance is an escalating global concern, necessitating the development of novel antibiotics with unique mechanisms of action, and preferably also with a lowered propensity for resistance development. Type-I Toxin-Antitoxin (TA) systems that are ubiquitous in bacterial genomes consist of a genetic toxin element encoding a hydrophobic peptide and an antitoxin element producing an sRNA that inhibits the toxin translation. Although the biological roles of these membrane-associated toxins remain incompletely understood, their inherent lethality upon overexpression suggests a potential as antimicrobial agents. In this study, we explore the ShoB toxin from the shoB-ohsC TA system in Escherichia coli (E. coli) as a basis for designing synthetic antimicrobial peptides for exogenous delivery. We demonstrate that ShoB-derived peptides can retain antimicrobial efficacy when modified into shorter, cationic analogs with enhanced solubility. Our most promising hits exhibit rapid bactericidal action and frequency of resistance within E. coli cultures indicate a limited tendency for resistance development. These findings highlight that type-I TA systems constitute a novel source of potential peptide-based antibiotics, thereby offering an alternative largely unexplored strategy to combat antibiotic-resistant bacterial infections.

Evaluation of the antiproliferative, cytotoxic and phytochemical properties of Zimbabwean medicinal plants used in cancer treatment

BACKGROUND

Cancer cases have been on the rise globally and several treatment strategies have been developed but mortality rates remain high. Zimbabwe, like many other countries, has also experienced a surge in cancer cases. In Zimbabwe, medicinal plants have been widely used to treat cancer for centuries. However, there has been limited research on the effectiveness, safety, and chemical composition of these plants. The current study assessed antiproliferative, cytotoxic and phytochemical properties of selected Zimbabwean medicinal plants.

METHOD

Cytotoxic activity of Agelenthus pungu, Carissa edulis, Dombeya rotundifolia, Flacourtia indica, Lannea discolor, Leonotis ocymifolia, Leucas martinicensis, Plicosepalus kalachariensis, Pseudolachnostylis maproneifolia, Solanum incanum, Strychnos cocculoides, Strychnos spinosa and Viscum verrucosum extracts were evaluated on normal murine peritoneal cells and sheep erythrocytes while antiproliferative activity was assessed on Jurkat T and HL60 cell lines. Cell viability was determined using the trypan blue exclusion and sulforhodamine B assay. Additionally, the effect of reduced glutathione on cytotoxic extracts was examined. The phytochemicals of the methanolic extracts were qualitatively determined using standard methods.

RESULTS

Agelenthus pungu, Carissa edulis, Flacourtia indica, Strychnos cocculoides, Strychnos spinosa and Viscum verrucosum were cytotoxic to normal murine peritoneal cells. Flacourtia indica and Viscum verruscosum caused haemolysis of sheep erythrocytes at a concentration of 250 µg/mL for both plant extracts and 125 µg/mL for Viscum verrucosum. Cell viability increased on addition of 25 µg/mL of reduced glutathione to the extracts considered the most cytotoxic extracts, Agelenthus pungu and Viscum verrucosum. Agelenthus pungu, Carissa edulis, Leonotis ocymifolia, Leucas martinicensis and Viscum verrucosum significantly inhibited Jurkat T and HL60 cell proliferation. Viscum verrucosum was the most potent with the lowest half-maximum inhibitory concentration (IC50) values of 33 and 34 µg/mL on Jurkat T and HL60 cell lines respectively. The most dominant phytochemical classes were alkaloids, flavonoids and saponins.

CONCLUSION

This study demonstrates that Agelenthus pungu, Carissa edulis, Leonotis ocymifolia, Leucas martinicensis and Viscum verrucosum have antiproliferative activity against Jurkat T and HL60 cell lines. Viscum verrucosum was the most potent. These findings emphasise the importance of medicinal plants as well as their potential use as sources of novel compounds in anticancer drug discovery.

Formononetin exerts synergistic action with artesunate against multi-drug-resistant P. falciparum arresting ring-to-schizont transition by inducing reactive oxygen species

Malaria, caused by Plasmodium falciparum, presents significant challenges for treatment due to the parasite's complex life cycle and increasing multi-drug resistance. Artemisinin-based combination therapies (ACTs) are the current standard treatment, resistance development necessitates the exploration of new therapeutic targets. Recent evidence suggests that targeting oxidative stress to arrest blood stage ring to schizont growth progression in Plasmodium could offer a novel approach to combat drug-resistant malaria. Phytomolecules have been recognized for their potential to modulate oxidative stress with artemisinin derivatives. In the present study, we aimed to evaluate the effectiveness of formononetin (FMT), a natural isoflavonoid, alone and in combination with artesunate (ART) against multidrug-resistant P. falciparum (K1) strain and to decipher the underlying mechanism of action. The study presents compelling evidence demonstrating the anti-plasmodial action of FMT alone (IC50 value 212µM) and synergistic interaction (FICI 0.13) with ART at a 1:1 ratio against the K1 strain of P. falciparum. The combination treatment affected the progression of P. falciparum from the ring stage to the schizont and showed the effect at asexual erythrocytic stages. Moreover, the combination resulted in a notable increase in reactive oxygen species (ROS) levels, both independently and in combination with ART. In combination with ART, FMT effectively modulated the total glutathione (GSH) level. Moreover, FMT and ART demonstrated the ability to induce apoptosis-like death of parasites, as evidenced by the Lipid peroxidation (malondialdehyde-MDA) and DNA fragmentation (TUNEL) levels. These results indicate that FMT could potentially ameliorate the growth of multidrug-resistant malaria parasites, enhance the effects of ART, and be suitable for developing anti-plasmodial agents from a cheap and sustainable source.

Assessing the Toxicity of Terpene- and Amino Acid-Based Natural Deep Eutectic Solvents

Over the past decade, there has been a significant increase in the discovery of greener solvents for industrial applications. In this context, deep eutectic solvents (DESs) have emerged as promising candidates across various sectors, including biomass conversion, paper and pulp, pharmaceuticals, and textiles. A new class of DESs, known as natural deep eutectic solvents (NADESs), is derived from natural chemicals and is expected to be more environmentally friendly. However, research into the environmental impact and toxicity of NADESs is still limited. Given the broad applications of DESs and the urgent need for sustainable alternatives, studying their toxicity is crucial. In our current study, we focused on NADESs formulated from menthol, thymol, and amino acid. We assessed their toxicity on different cell lines using standard biochemical assays. Remarkably, our findings also indicate that these NADESs exhibit low toxicity in the HaCaT cell line and a mice blood sample. We also found that all of the tested NADESs have shown better antimicrobial property values compared to the individual components of NADESs, indicating the importance of NADES formulation for applications. Among the tested NADESs, menthol:thymol (1:1) showed the best antibacterial properties. These results hold significant implications for the development of NADESs in industrial applications, suggesting a path forward for the adoption of greener and safer solvents.

Cell death signaling in human erythron: erythrocytes lose the complexity of cell death machinery upon maturation

Over the recent years, our understanding of the cell death machinery of mature erythrocytes has been greatly expanded. It resulted in the discovery of several regulated cell death (RCD) pathways in red blood cells. Apoptosis (eryptosis) and necroptosis of erythrocytes share certain features with their counterparts in nucleated cells, but they are also critically different in particular details. In this review article, we summarize the cell death subroutines in the erythroid precursors (apoptosis, necroptosis, and ferroptosis) in comparison to mature erythrocytes (eryptosis and erythronecroptosis) to highlight the consequences of organelle clearance and associated loss of multiple components of the cell death machinery upon erythrocyte maturation. Recent advances in understanding the role of erythrocyte RCDs in health and disease have expanded potential clinical applications of these lethal subroutines, emphasizing their contribution to the development of anemia, microthrombosis, and endothelial dysfunction, as well as their role as diagnostic biomarkers and markers of erythrocyte storage-induced lesions. Fas signaling and the functional caspase-8/caspase-3 system are not indispensable for eryptosis, but might be retained in mature erythrocytes to mediate the crosstalk between both erythrocyte-associated RCDs. The ability of erythrocytes to switch between eryptosis and necroptosis suggests that their cell death is not a simple unregulated mechanical disintegration, but a tightly controlled process. This allows investigation of eventual pharmacological interventions aimed at individual cell death subroutines of erythrocytes.

DNA nanovaccines derived from ferritin-modified glycogens for targeted delivery to immature dendritic cells and for promotion of Th1 cell differentiation

DNA vaccines have emerged as a powerful approach for advanced cancer therapy. Despite the development of various delivery systems to enhance the immunogenicity of DNA vaccines, many still face challenges such as limited DNA condensation, rapid degradation in vivo and insufficient targeting to lymph nodes (LNs). Synthetic dendrimers with modifiable surfaces exhibit high efficiency in DNA condensation, but their synthesis is extremely complex. This study utilizes cationic glycogen, a natural branched dendrimer-like polymer, as the core structure for efficient DNA condensation and delivery, ensuring good biocompatibility. By connecting ferritin light chain to the glycogen surfaces, active targeting of LNs can be achieved due to its affinity for the SCARA5 receptor on immature dendritic cells (DCs), facilitating vaccine migration to the LNs. In addition, a seperate plasmid encoding adjuvant IL-12 was co-delivered to further boost the immunogenicity of the DNA nanovaccine. In vivo and in vitro experiments confirmed the effective transfection capability of this DNA vaccine, demonstrating promoted DC maturation, increased antigen presentation, and Th1 cell differentiation, resulting in improved anti-tumor efficiency in vivo. This innovative multi-gene co-loaded DNA vaccine offers valuable insights into combined gene therapy and broadens the research horizon on non-viral gene carriers. STATEMENT OF SIGNIFICANCE: The DNA vaccine encounters challenges such as limited DNA condensation, rapid degradation and insufficient targeting to lymph nodes (LNs), resulting in generally weak immunogenicity. In the current study, a novel nanovaccine is developed by connecting ferritin light chain to natural dendrimer glycogen, for simultaneous delivery of dual plasmids. The cationized glycogen provides strong DNA condensation ability, while ensuring excellent stability of the nanovaccine. The presence of ferritin light chain leads to effective targeting of dendritic cells (DCs), facilitating its migration to LNs. Moreover, the plasmid encoding the adjuvant IL-12 is co-incorporated with the antigen plasmid to mitigate the immunosuppression environment. This strategy significantly improves the immunogenicity of DNA vaccines, demonstrating high efficiency in cancer immunotherapy.

Antibacterial collagen-guar gum hydrogels with zeolitic imidazolate framework-67 (ZIF-67): an innovative platform for advanced wound healing

The current challenge in developing wound healing dressings lies in achieving antibacterial effects while avoiding cytotoxicity to cells that are crucial for the healing process. Addressing this challenge, Zeolitic Imidazolate Framework-67 (ZIF-67), a cobalt-containing metal-organic framework (MOF), has emerged as a promising additive due to cobalt's broad-spectrum antimicrobial effects. This study developed semi-interpenetrating polymer network (semi-IPN) hydrogels by incorporating 1-3 wt.% ZIF-67 into collagen-guar gum matrices, resulting in biocomposites with tunable structural and functional properties. These biocomposites exhibit a fibrillar-granular morphology, uniform cobalt ion distribution on a semi-crystalline surface, and strong antibacterial activity against Escherichia coli (E. coli). At 3 wt.%, ZIF-67 accelerates gelation, strengthens crosslinking interactions, and enhances the storage modulus, thermal stability, and hydrolytic resistance of the hydrogels. Furthermore, biocomposites with 1 wt.% ZIF-67 also function as in-situ curcumin delivery systems, offering controlled release under physiological conditions and significant biodegradation in the presence of collagenase. In vitro tests demonstrate that the chemical composition of these hydrogels, regardless of ZIF-67 content, effectively supports monocyte and fibroblast metabolic activity, promotes cell proliferation, and increases interleukin-10 (IL-10) secretion by human monocytes. Additionally, the absence of hemolytic effects in human blood further underscores the safety and suitability of these hydrogel biocomposites for advanced wound treatment applications.

Harnessing Silver Nanoclusters to Combat Staphylococcus aureus in the Era of Antibiotic Resistance

Background/Objectives: In the race to develop new antibiotics to combat multidrug-resistant bacteria, particularly the ESKAPE pathogens which pose a significant threat to public health, silver nanoclusters (AgNCs) have emerged as a promising alternative. This article focuses on the potential of novel silver nanoclusters as an antimicrobial agent against Staphylococcus aureus, a high-priority pathogen known for its ability to cause persistent nosocomial infections and develop protective biofilms. Methods: In this study, we successfully synthesized AgNCs at pH 7 using an eco-friendly photoreduction method with poly acrylic acid (PAA) and poly methacrylic acid (PMAA) as stabilizers. This methodology produced fluorescent AgNCs, demonstrating their stability in aqueous solutions for at least three months and highlighting the effectiveness of PAA and PMAA as stabilizing agents. The AgNCs were incubated with S. aureus suspension, and the antimicrobial capability at different concentrations and times of incubation were determined. Also, the AgNCs hemocompatibility was studied by exposing the clusters to rat blood cells. Results: The in vitro assays revealed that AgNCs capping with PAA or PMAA has antimicrobial activity in low doses (the determination of minimum inhibitory concentration (MIC): 0.2 µg/mL, and the determination of minimum bactericidal concentration (MBC): 2 µg/mL) and without cytotoxicity (hemolysis less than 10%) to rat blood cells until 1 µg/mL. In the presence of both AgNCs (5 µg/mL), bacterial growth was completely inhibited within just 3 h. Conclusions: The findings of this study highlight the potential of silver nanoclusters as effective antimicrobial agents against S. aureus. Their stability, low toxicity, and rapid bactericidal activity make them promising candidates for further development in antimicrobial applications.

Assessing the impact of CD73 inhibition on overcoming anti-EGFR resistance in glioma cells

Objectives

Glioblastoma (GB) is a grade IV glial tumor characterized by high malignancy and dismal prognosis, primarily due to high recurrence rates and therapeutic resistance. The epidermal growth factor receptor (EGFR), a receptor tyrosine kinase (RTK), regulates signaling pathways, including cell growth, proliferation, survival, migration, and cell death. Many cancers utilize immune checkpoints (ICs) to attenuate immune responses. CD73 is an enzyme that functions as an IC by hydrolyzing AMP to adenosine, suppressing immune cells in the tumor microenvironment. However, the role of CD73 in resistance to EGFR inhibitors is poorly understood. This study aims to elucidate the resistance mechanisms induced by anti-EGFR treatment and to evaluate an anti-CD73 approach to overcome resistance mediated by anti-EGFR monotherapy.

Methods

The U251 GB cell line was treated with AG1478, an EGFR inhibitor, and the resistance markers MRP-1, PD-L1, and CD73 were evaluated using flow cytometry. Additionally, we assessed the combination effects of AG1478 and APCP (an EGFR and a CD73 inhibitor, respectively) on cell cycle progression, proliferation, apoptosis, and migration in vitro.

Results

We observed high EGFR, PD-L1, and CD73 expression in human GB cells. The treatment with AG1478 increased the expression of resistance markers MRP-1, PD-L1, and CD73, whereas it decreased CTLA-4. The combination of AG1478 and APCP did not alter proliferation or apoptosis but interfered with cell cycling, arresting the cells in the G1 phase, decreasing cell motility and partially reversing MRP-1 overexpression.

Conclusion

In summary, our findings indicate that CD73 inhibition has a modest effect in overcoming resistance to EGFR monotherapy in vitro. Thus, further in vivo studies are needed, as the inhibition of both EGFR and CD73 affects cells in the tumor microenvironment and could potentially enhance anti-tumor immunity.

ERLNs augment simultaneous delivery of GFSV into PC-3 cells: Influence of drug combination on SDH, GPX-4, 5α-RD, and cytotoxicity

Objective

Prostate cancer (PCA) is the second most widespread cancer among men globally, with a rising mortality rate. Enzyme-responsive lipid nanoparticles (ERLNs) are promising vectors for the selective delivery of anticancer agents to tumor cells. The goal of this study is to fabricate ERLNs for dual delivery of gefitinib (GF) and simvastatin (SV) to PCA cells.

Methods

ERLNs loaded with GF and SV (ERLNGFSV) were assembled using bottom-up and top-down techniques. Subsequently, these ERLN cargoes were coated with triacylglycerol, and phospholipids and capped with chitosan (CS). The ERLNGFSV, and CS engineered ERLNGFSV (CERLNGFSV) formulations were characterized for particle size (PS), zeta potential (ZP), and polydispersity index (PDI). The biocompatibility, and cytotoxicity of the plain and GF plus SV-loaded ERLN cargoes were assessed using erythrocytes and PC-3 cell line. Additionally, molecular docking simulations (MDS) were conducted to examine the influence of GF and SV on succinate dehydrogenase (SDH), glutathione peroxidase-4 (GPX-4), and 5α-reductase (5α-RD).

Results

These results showed that plain, ERLNGFSV, and CERLNGFSV cargoes have a nanoscale size and homogeneous appearance. Moreover, ERLNGFSV and CERLNGFSV were biocompatible, with no detrimental effects on erythrocytes. Treatment with GF, SV, GF plus SV, ERLNGFSV, and CERLNGFSV significantly reduced the viability of PC-3 cells compared to control cells. Particularly, the blend of GF and SV, as well as ERLNGFSV and CERLNGFSV augmented PC-3 cell death. Also, treating PC-3 cells with free drugs, their combination, ERLNGFSV, and CERLNGFSV formulations elevated the percentage of apoptotic cells. MDS studies demonstrated that GF and SV interact with the active sites of SDH, GPX-4, and 5α-reductase.

Conclusions

This study concludes that SVGF combination and ERLNs loading induce particular delivery, and synergism on PC-3 death through action on multiple pathways involved in cell proliferation, and apoptosis, besides the interaction with SDH, GPX-4, and 5α-RD. Therefore, GFSV-loaded ERLN cargoes are a promising strategy for PCA treatment. In vivo studies are necessary to confirm these findings for clinical applications.

Viability and Surface Morphology of Human Erythrocytes upon Interaction with Chitosan Derivatives

The viability and surface morphology of human erythrocytes upon interaction with oligochitosan (OCH), having a molecular weight (MW) of 6.2-15.4 kDa and a degree of acetylation (DA) of 1-2%, and interaction with N-reacetylated OCH (ROCH) with a 6.4-14.3 kDa MW and 24-30% DA were studied in isotonic saline phosphate buffer with pH 7.4. It was shown that the use of OCH caused high hemolysis and irreversible transformation of the erythrocytes. Thus, OCH having a 6.2 kDa MW and 1% DA, used at a 0.01% concentration, induced high hemolysis of erythrocytes, and their viability did not exceed the maximal value of 60%. Among the nonhemolyzed erythrocytes, about 20% reversibly transformed erythrocytes and about 20% irreversibly transformed erythrocytes were observed in comparison with the control experiments. For the first time, it was shown that ROCHs had a much lower impact on the cells. Thus, about 82% of the erythrocytes had a discoid form, while 12% and ∼6% of the cells underwent reversible and irreversible transformations, respectively, in the presence of ROCH (MW 6.4, DA 24%), used at a 0.01% concentration. It was observed that an increase in the MW and concentration of chitosan derivatives led to a decrease in the cell viability. It was supposed that the complexation of chitosan derivatives with phosphate counterions in the buffer might reduce the impact of chitosan derivatives on the viability and surface morphology of erythrocytes due to a reduction in the average zeta-potential of chitosan derivative/phosphate complexes from positive to negative values. These results supported the suggestion that reacetylation and reduction of the overall charge of chitosan molecules could improve the compatibility of chitosan derivatives with erythrocytes. This finding opens an opportunity for the construction of chitosan derivatives and their complexes that are compatible with other blood forming elements.

Antibody-Targeted Bismuth Gadolinium Nanoconjugate for Image-Guided Radiotherapy of Hepatocellular Carcinoma

Hepatocellular carcinoma (HCC), one of the most lethal cancers of the liver, has limited treatment options at advanced stages. Here, bismuth gadolinium (BiGd) nanoparticles (NPs) conjugated with anti-vascular endothelial growth factor antibody (aVEGF) are designed and tested for targeted image-guided radiation therapy against HCC. The BiGd NPs are synthesized using the sol-gel technique, functionalized with silica NPs, and labeled with fluorescent protamine-rhodamine B. For tumor targeting, the NPs are conjugated with aVEGF, and an in vitro study confirms the binding of the aVEGF-BiGd nanoconjugate to McA-RH7777 hepatoma cells. Biocompatibility of the aVEGF-BiGd nanoconjugate is evaluated using McA-RH7777 cells, with no cytotoxicity observed even at 250 μg/mL. Also, aVEGF-BiGd demonstrates in vivo microcomputed tomography contrast enhancement. NPs and/or radiation therapy (RT) is conducted in female BALB/c nude mice with subcutaneously implanted McA-RH7777 cells, and a significant reduction in tumor size is observed in the mice treated with the aVEGF-BiGd nanoconjugate and RT compared to other groups (p < 0.01). The combined effect of nanoconjugate and RT exhibits decreased vascularity, cell proliferation, and increased apoptosis. This study demonstrates the potential of the developed hybrid BiGd nanoconjugate for targeted and image-guided radiotherapy of HCC.

pH-Responsive Conformational-Switching Cationic Fusion Protein for Promoted Plasmid DNA Delivery and Transfection

Gene therapy holds great promise for treating various diseases, but challenges such as delivery efficiency, immune response, and long-term effects still remain. Protamine is a frequently used gene delivery vector for its strong nucleic acid binding capacity, but its application is constrained by inadequate nucleic acid release, resulting in low transfection efficiency. Here, we introduce a fusion protein by integrating LAH4 peptides on both ends of protamine's DNA-binding motif. This fusion protein exhibits lower cytotoxicity compared to protamine. At pH 7.4, its uniform charge distribution and α-helical structure enable robust DNA condensation and DNase resistance. Under acidic conditions (pH 5.8), the conformational change of the protein weakens its DNA binding, facilitating controlled release in endosomes/lysosomes. Simultaneously, it interacts with the endosomal membrane to form pores, aiding in the endosomal escape of the nucleic acids, thereby significantly improving transfection efficiency. This fusion protein offers the potential for efficient and safe nucleic acid delivery.

Optimizing Andrographolide from Sambiloto Leaves (Andrographis paniculata) Using Cyclodextrin Metal-Organic Frameworks for Targeted Pulmonary Delivery via a Metered Dose Inhaler: A Proof-Of-Concept Study

Andrographis paniculata is recognized for its numerous applications in the pharmaceutical industry. The primary compound of this plant, andrographolide (AG), has demonstrated potent antibacterial properties, including against K. pneumoniae. However, its poor solubility limits its bioavailability. To address this, the creation of an inclusion complex (IC) using cyclodextrin (CD) and Metal-Organic Frameworks (MOFs) offers a promising solution for improving AG's solubility and bioavailability. The AG-CD-MOFs are intended to be delivered via a metered dose inhaler (MDI), allowing for direct targeting of lung tissue. This research focuses on designing AG encapsulated within CD-MOFs to boost solubility and enhance drug efficacy when delivered directly to the lungs via an MDI. Computational molecular modeling indicated that γ-CD is the most suitable host molecule for forming an inclusion complex (IC) with AG, surpassing α-CD and β-CD. The optimal AG to γ-CD ratio for the IC is 1:2 (w/w), with a particle size of 534.53 ± 49.11 nm, a PDI of 0.121 ± 0.01, an encapsulation efficiency (EE) of 89.45 ± 7.03%, and a drug loading (DL) of 26.09 ± 2.87%. The IC exhibits strong antibacterial activity comparable to AG crystal-DMSO, highlighting the importance of solubility in AG's antibacterial efficacy. Additionally, drug release studies revealed that the IC's release profile is nearly nine times greater than that of the AG crystal. In vivo studies further demonstrated the high selectivity of the MDI for lung tissue delivery compared to injection and oral administration, with drug concentrations of 7.44 ± 0.57 μg/mL, 1.52 ± 0.23 μg/mL, and 1.5 ± 0.16 μg/mL, respectively. Moreover, the MDI AG-CD-MOFs exhibited sustained-release properties, maintaining a drug concentration of 5.27 ± 0.75 μg/mL in lung tissue for up to 48 h, significantly higher than injection and oral administration, which only maintained concentrations of 1.52 ± 0.23 μg/mL and 1.50 ± 0.16 μg/mL at 8 h, respectively. The developed formulation shows high selectivity to lung tissue and shows sustained-release behavior. The formula was deemed safe based on in vitro hemolysis and irritation risk tests and did not cause inflammation in lung tissue, as confirmed by histopathology studies. Furthermore, in vivo studies are strongly recommended to validate this therapy and improve pneumonia treatment options.

Specific Rosetta-based protein-peptide prediction protocol allows the design of novel cholinesterase inhibitor peptides

The search for novel cholinesterase inhibitors is essential for advancing treatments for neurodegenerative disorders such as Alzheimer's disease (AD). In this study, we employed the Rosetta pepspec module, originally developed for designing peptides targeting protein-protein interactions, to design de novo peptides targeting the peripheral aromatic site (PAS) of acetylcholinesterase (AChE) and butyrylcholinesterase (BChE). A total of nine peptides were designed for human AChE (hAChE), T. californica AChE (TcAChE), and human BChE (hBChE). These peptides were synthesized using Fmoc-SPPS and tested in vitro using Ellman's reaction to evaluate their inhibitory potency. Peptide 11tA, designed for TcAChE, exhibited potent inhibition of hAChE (IC50 = 1.21 ± 0.25 µM) and demonstrated strong antioxidant activity against DPPH radicals and lipid peroxidation, making it a promising multitherapeutic candidate for AD. Peptide 11hB, designed for hBChE, showed the highest inhibitory activity against hBChE, with a Ki of 12.69 ± 1.27 µM, making it the most potent natural amino acid peptide reported against hBChE. The computational protocol effectively distinguished the specific characteristics of each enzyme target. Toxicity assessments, including hemolysis tests and A. salina lethality assays, revealed no toxic effects at low concentrations, further supporting the potential of these peptides for peptide-based drug development in AD. This study underscores the growing potential of peptides as alternatives to small-molecule drugs. It demonstrates that computational protocols for protein-protein interactions can be successfully adapted to design high-affinity peptide inhibitors.

Cadmium and ketoprofen accumulation influences aquatic ecosystem demonstrated using in-vivo zebrafish model

The growing concern about pollution and toxicity in aquatic as well as terrestrial organisms is predominantly caused due to waterborne exposure and poses a risk to environmental systems and human health. This study addresses the co-toxic effects of cadmium (Cd) and ketoprofen (KPF), representing heavy metal and pharmaceutical discharge pollutants, respectively, in aquatic ecosystems. A 96-h acute toxicity assessment was conducted using zebrafish embryos. The results indicated that high dosages of KPF (10, 15, and 100 µg/mL) and Cd (10 and 15 µg/mL) reduced survivability and caused concentration-dependent deformities such as scoliosis and yolk sac edema. These findings highlight the potential defects in development and metabolism, as evidenced by hemolysis tests demonstrating dose-dependent effects on blood cell integrity. Furthermore, this study employs adult zebrafish for a 42-day chronic exposure to Cd and KPF (10 and 100 µg/L) alone or combined (10 + 10 and 100 + 100 µg/L) to assess organ-specific Cd and KPF accumulation in tissue samples. Organ-specific accumulation patterns underscore complex interactions impacting respiratory, metabolic, and detoxification functions. Prolonged exposure induces reactive oxygen species formation, compromising antioxidant defense systems. Histological examinations reveal structural changes in gills, gastrointestinal, kidney, and liver tissues, suggesting impairments in respiratory, osmoregulatory, nutritional, and immune functions. This study emphasizes the importance of conducting extensive research on co-toxic effects to assist with environmental risk assessments and safeguard human health and aquatic ecosystems.

Blood compatibility evaluation of polydopamine nanoparticles

Introduction

Polydopamine nanoparticles (PDA NPs) exhibit numerous outstanding characteristics, including simple preparation, broad light absorption, drug binding ability, excellent biocompatibility and adhesive properties, making them suitable for biomedical application. However, the limited information on their hemocompatibility may hinder their progression from laboratory research to clinical application.

Methods

In this study, we investigated comprehensively the hemocompatibility of PDA NPs, assessed the effects of PDA NPs on red blood cells (RBCs) morphology and lysis, fibrinogen structure and conformation, blood coagulation, platelet activation, complement system activation, and organ toxicity.

Results

The results indicated that PDA NPs can induce morphological changes and hemolysis in RBCs in a concentration-dependent manner. Interactions with fibrinogen suggested a disturbance in the protein's microenvironment without significantly altering its secondary structure. This study also revealed that PDA NPs have a concentration-dependent effect on blood coagulation, platelet activation, and complement system activation. Additionally, PDA NPs showed no significant acute toxicity after intravenous injection.

Conclusion

The findings offer important insights into the hemocompatibility of PDA NPs, which is essential for their safe and effective clinical use. Understanding their interactions with blood components is key to ensuring their compatibility in biomedical applications. These results are vital for guiding the development of PDA NPs for medical use, particularly in blood-contacting applications.

Development of a curcumin-piperine nanoparticle system using dissolving microneedles for transdermal drug delivery in malaria treatment: In vitro evaluation

The combination of the active compounds curcumin and piperine (CP) is effective as an antimalarial; however, the solubility and bioavailability of CP are very low. This study aims to formulate CP in nanoparticles (NP), which are then fabricated into dissolving microneedles (DMN). The NPs were prepared with a concentration ratio of CP-Chitosan-So.TPP-So.Alginate (0.1:0.04:0.02:0.03). Subsequently, NPs-CP-DMN were formulated with NPs-CP concentrations (35:40:50 w/w) and a mixture of the polymers polyvinyl alcohol (PVA) and polyvinylpyrrolidone (PVP) in a ratio of (35:65, 40:60, 50:50). Characterization of the nanoparticles and microneedles was conducted, including dissolution time tests, permeation studies, hemolysis assessment, dermatokinetics, and in vitro antiplasmodial activity testing. The results showed that NPs-CP had an average size of 446.67 ± 40.27 nm and 367.6 ± 26.31 nm. On the formula NPs-CP-DMN the addition of PVA and PVP polymers (F2) resulted in DMNs with good mechanical strength and penetration ability, capable of penetrating five layers of Parafilm®. This formulation completely dissolved in 10 min without leaving any residue, with a curcumin flux value of 25.7 ± 0,51 µg/mL and piperine flux of 28.5 ± 0,51 µg/mL. The formulation showed no toxicity, with a hemolysis percentage of < 5 %, Tmax of 7 h, and Cmax values of 11.07 ± 0.31 µg/cm3 for curcumin and 17.40 ± 3.3 µg/cm3 for piperine. Moreover, this formulation effectively inhibited the P.falciparum FCR3 strain parasite, with an IC50 value of 35.9 μg/mL. Therefore, this study holds promise as a new strategy for malaria treatment.

Integrative computational and experimental study of propolis, polyvinyl alcohol, and alhagi maurorum complex as anticancer and antibacterial agents

The study examined the potential applications of propolis, polyvinyl alcohol (PVA), and Alhagi maurorum extracts in drug delivery systems, utilizing both computer and lab methods. The study uses molecular docking probes along with DFT (density functional theory) to investigate molecular interactions and examine the binding of drugs to carrier materials. The HOMO (Highest Occupied Molecular Orbital)-LUMO (Lowest Occupied Molecular Orbital) gap for the mix of PVA, galangin, and triterpene glycoside is -0.07621 eV, which matches the experiment results. This small gap enhances responsiveness in drug delivery applications, which is crucial for successful interactions with biological targets. It's possible that a delivery system that combines galangin and triterpene glycosides would work better and be more compatible with living things.The experimental results of the Methyl Thiazole Tetrazolium (MTT) show consistent findings: The viability of MCF7, a human breast cancer cell line, significantly decreased at all concentrations of propolis and polyvinyl alcohol compared to WRL68, a fetal liver cell line. Within-group comparisons showed less viability in both groups at 400 µg/ml. Mean ± SD: 42.05267 ± 1.951655; 67.12533 ± 7.401263.In the positive control group, the average number of malignant cells was 47.06, but the average number of cells in the fourth treatment (Propolis + PVA) and the third combination (Propolis + Alhagi maurorum + PVA) were 42.05267 and 42.97800, respectively. The Sustainable Development Goals in Industry and Innovation are focusing on developing a new combination of alhagi and propolis using PVA as a polymer carrier.

Enhancing the antimycobacterial efficacy of pyridine-4-carbohydrazide: linkage to additional antimicrobial agents via oxocarboxylic acids

This study evaluates the antimycobacterial potential of novel "mutual" bioactive amides, combining pyridine-4-carbohydrazide (isoniazid, INH) with various antimicrobial agents (sulphonamides, 4-aminosalicylic acid, thiosemicarbazide, diphenyl (thio)ethers) via oxocarboxylic acids. The aim was to enhance activity against both drug-susceptible and multidrug-resistant (MDR) Mycobacterium tuberculosis and non-tuberculous strains, while overcoming drug resistance through dual-action mechanisms. Many derivatives exhibited potent antimycobacterial activity, with minimum inhibitory concentrations (MICs) as low as ≤0.25 μM, outperforming INH, especially diphenyl (thio)ethers and biphenyl analogues. Additionally, the compounds were effective against M. kansasii (MICs ≤1 μM) and inhibited MDR strains at higher concentrations (≥8 μM). The cytotoxicity assay indicated a favourable safety profile, with no significant haemolysis at 125 μM, and some compounds were even protective. Selectivity for mycobacteria was confirmed by low inhibition of Gram-positive bacteria and inactivity against Gram-negative bacteria or fungi, highlighting the potential for further development as antimycobacterial agents.

A mechanistic overview on green assisted formulation of nanocomposites and their multifunctional role in biomedical applications

The importance of nanocomposites constantly attains attention because of their unique properties all across the fields especially in medical perspectives. The study of green-synthesized nanocomposites has grown to be extremely fascinating in the field of research. Nanocomposites are more promising than mono-metallic nanoparticles because they exhibit synergistic effects. This review encapsulates the current development in the formulation of plant-mediated nanocomposites by using several plant species and the impact of secondary metabolites on their biocompatible functioning. Phyto-synthesis produces diverse nanomaterials with biocompatibility, environment-friendliness, and in vivo actions, characterized by varying sizes, shapes, and biochemical nature. This process is advantageous to conventional physical and chemical procedures. New studies have been conducted to determine the biomedical efficacy of nanocomposites against various diseases. Unfortunately, there has been inadequate investigation into green-assisted nanocomposites. Incorporating phytosynthesized nanocomposites in therapeutic interventions not only enhances healing processes but also augments the host's immune defenses against infections. This review highlights the phytosynthesis of nanocomposites and their various biomedical applications, including antibacterial, antidiabetic, antiviral, antioxidant, antifungal, anti-cancer, and other applications, as well as their toxicity. This review also explores the mechanistic action of nanocomposites to achieve their designated tasks. Biogenic nanocomposites for multimodal imaging have the potential to exchange the conventional methods and materials in biomedical research. Well-designed nanocomposites have the potential to be utilized in various biomedical fields as innovative theranostic agents with the subsequent objective of efficiently diagnosing and treating a variety of human disorders.

Enhanced and Sustained Transdermal Delivery of Oxypurinol Using Thermosensitive Gel Combined with Polymeric Solid Microneedles

Gout is a pathological condition caused by monosodium urate crystal deposition in tissues. Allopurinol, the first-line therapy, inhibits xanthine oxidase but may be ineffective due to reduced conversion to oxypurinol (OXY). Current delivery routes for OXY, including oral and intravenous routes, have drawbacks such as poor solubility and patient discomfort. This study developed a delivery system integrating thermosensitive gel (TRG) containing OXY with polymeric solid microneedles (PSMNs). Molecular docking demonstrated high-affinity binding interactions between OXY and Pluronic (-2.5). The TRG, formulated with Pluronic F127 and F68, was assessed for gelation temperature, pH, spreadability, and bioadhesive strength. PSMN, made from poly(vinyl alcohol) and polyvinylpyrrolidone K-30 with citric acid, was evaluated for mechanical strength and skin penetration. In vitro hemolysis activity, drug release, and ex vivo permeation studies were conducted. Molecular docking results showed stable binding with an affinity of -2.5 between the ligands of OXY and Pluronic. The TRG formulation exhibited promising characteristics for transdermal drug delivery. PSMN demonstrated good mechanical strength and was able to penetrate up to 504 μm. Hemolysis testing showed that PSMN and TSG were safe with a hemolysis ratio of less than 5%. In vitro drug release studies showed a high OXY release of 2.24 ± 0.26 mg with the highest concentration of Pluronic F68, displaying a sustained release profile. Ex vivo permeation studies showed a significant difference (p < 0.05) between OXY permeation without and with PSMN combination. PSMN increased OXY permeation by 79-81% compared to permeation without PSMN. This study successfully developed a TRG formulation combined with PSMN to enhance transdermal delivery of OXY. These results suggest a promising new route for OXY delivery, potentially offering a more efficient and user-friendly treatment for chronic gout. Further in vivo studies are needed to evaluate the efficacy, pharmacokinetics, pharmacodynamics, drug interactions, and toxicity for further clinical applications.

Poloxamer 188 stabilized poly (ε-caprolactone) microspheres of voriconazole for targeting pulmonary aspergillosis

AIM

Voriconazole (VRZ) is highly effective in treating invasive pulmonary aspergillosis (IPA), in addition to hepatotoxicity. Therefore, the current study focuses on the development and characterization of voriconazole-loaded microspheres (VRZ@PCL MSPs) to augment pulmonary localization and antifungal efficacy.

METHODS

VRZ@PCL MSPs were fabricated by using the o/w emulsion method. The optimized F3VRZ@PCL MSPs were subjected to physicochemical characterization, in vitro release, hemocompatibility, antifungal efficacy as well as pharmacokinetic and biodistribution evaluation.

RESULTS

The optimized F3VRZ@MSPs exhibited a particle size (10.90 ± 2.61 µm), entrapment efficiency (19.35 ± 2.47%), drug loading (3.22 ± 0.41%) with sustained release behavior up to 24 h and hemocompatibility upto 50 µg/mL. Results of antifungal testing indicated the superior antifungal potential of F3VRZ@PCL MSPs as compared to free VRZ and nystatin. In vivo pharmacokinetic evaluation in Sprague-Dawley rats displayed 12.5-fold and 4.5-fold increments, respectively, in t1/2 and AUC0-t of F3VRZ@PCL MSPs as compared to free VRZ. Moreover, F3VRZ@PCL MSPs displayed relatively higher lung targeting with a drug targeting index (DTI) of 0.213 as compared to DTI of 0.037 of free VRZ.

CONCLUSION

In conclusion, F3VRZ@PCL MSPs offer a promising approach for sustained and targeted delivery of VRZ and hold the potential to offer high therapeutic efficacy in the treatment of IPA.

The latest progress in assay development in leishmaniasis drug discovery: a review of the available papers on PubMed from the past year

INTRODUCTION

Leishmaniasis is a significant neglected tropical disease with limited treatment options that urgently requires ongoing efforts in drug discovery. Recent advances have focused on the development of new assays and methods to identify effective therapeutic candidates.

AREAS COVERED

This review explores recent trends and methodologies in leishmaniasis drug discovery, with a particular focus on in silico and in vitro studies, as well as in vivo validation, using animal models. A detailed analysis of recent studies was provided, discussing the methodologies employed, such as manual and automated parasite quantification, and the use of fluorescence and luminescence-based techniques. Additionally, global research trends were analyzed, highlighting the leading countries in scientific output and the collaborative efforts driving advancements in this field.

EXPERT OPINION

The field of leishmaniasis drug discovery has rapidly progressed in the last years, but the lack of standardized methodologies and limited in vivo validation remain significant hurdles. To advance promising treatments to clinical trials, cross-validation of preclinical findings and interdisciplinary collaboration are essential. Increased funding and global partnerships are also crucial to accelerate the discovery and development of alternative and effective therapies.

Sticky tubes co-assembled by functionalised diphenylalanine and polydopamine nanoparticles form biocompatible antifouling coating

The persistent challenge of biofouling, driven by the accumulation of microorganisms and biological residues on surfaces, undermines operational efficiency and safety across multiple industries. Functionalized peptide based biocompatible and supramolecular coating can provide a substantial solution to this crucial issue. This present study describes the formation of polydopamine-comprised sticky tubes through the co-assembly of an antifouling peptide P1 (FF-PFB) and Polydopamine Nanoparticles (PDA NPs) with an adhesive catechol moiety. To overcome the synthetic complications associated with the attachment of adhesive l-DOPA or dopamine with antifouling peptides, we have employed a simple co-assembly strategy. These co-assembled sticky tubes form a stable, biocompatible coating on desired surfaces (glass and aluminium) and resist fouling. The design consists of a diphenylalanine-based antifouling peptide covalently coupled with pentafluoro benzaldehyde (PFB), which could self-assemble into a stable functional coating through the adhesive catechol moiety of PDA NPs. This functional coating effectively resists bacterial and protein adhesion. These sticky tubes coated desired surfaces (glass and aluminium) exhibit excellent antifouling activity against both tested Gram (+)ve (S. aureus) and Gram (-)ve (E. coli) bacterial strains. More importantly, this simple co-assembly and drop-coating method has significant promise, primarily attributed to its simplicity of operation, which reduces production costs and expands the potential for widespread commercialization. This study not only contributes to the fundamental understanding of the antifouling process but also offers a practical and sustainable solution to the challenges caused by biofouling. Our findings, achieved through the simple and effective co-assembly strategy with two different functional components, pave the way for developing promising antifouling materials with broad applications in industries where effective biofouling resistance is crucial.

Detection and characterization of pathogenic Bacillus haynesii from Tribulus terrestris extract: ways to reduce its levels

Plant parts such as roots, bark, leaves, flowers, and fruits that hold ethnopharmacological significance are naturally prone to microbial contamination, influenced by environmental factors like moisture and humidity. This study focuses on assessing the microbial load in the raw material of Tribulus terrestris (TT). The primary bacterium isolated from the pulverized raw material was identified as Bacillus haynesii through 16S rRNA sequencing. Biochemical assays revealed the organism's ability to utilize lysine and ornithine, produce urease, and generate hydrogen sulfide. The bacterium exhibited resistance to multiple antibiotics and caused 21.5% hemolysis in RBC lysis assays. To reduce microbial contamination, Glutaraldehyde (GA) and polyhexamethylene biguanide (PHMB) were tested, with GA at 1% reducing the microbial load by 99% without affecting the yield (0.5%) or bioactive saponin content. High-Performance Liquid Chromatography (HPLC) confirmed the absence of residual GA, ensuring an eco-friendly and safe process. This highlights the importance of quality control measures, including Hazard Analysis and Critical Control Points (HACCP) regulations, in maintaining the integrity of herbal extracts.

Thermal Characterisation and Toxicity Profile of Potential Drugs from a Class of Disubstituted Heterofused Triazinones

The thermal characterisation and toxicity profile of a class of disubstituted heterofused triazinones were revealed in this article for the first time. The thermal behaviour of molecules 1-12 was investigated by means of TG and DSC analyses performed in an air atmosphere and by the coupled TG/FTIR technique in a nitrogen atmosphere. The heating atmosphere affects both the stability of compounds and the degradation mechanism. A two-step degradation occurs in air, while a one-step degradation takes place in nitrogen, both preceded by a melting process. Compound 3 shows the highest thermal stability, while molecule 10-the lowest. The thermal decomposition of the studied heterocyclic molecules begins with the degradation of the bicyclic system, resulting in the formation of volatile gaseous products such as ammonia/hydrazine, hydrogen cyanide, carbon dioxide, and isocyanates. In the further stage, mainly aromatic compounds are released, and their chemical composition depends on the presence and type of substituents at the phenyl and benzyl moieties. In addition, the toxicity profiles of molecules were assessed in the animal (zebrafish) and cellular (erythrocytes) models, and the antihaemolytic activity was evaluated in the AAPH- and H2O2-induced haemolysis inhibition assays. It was found that all the tested compounds are safe for the developing zebrafish and red blood cells, and they are able to effectively protect erythrocytes from oxidative damage. These favourable properties make them promising drug candidates suitable for further in vivo studies.

PEGylated Platinum Nanoparticles: A Comprehensive Study of Their Analgesic and Anti-Inflammatory Effects

Pain and inflammation are common symptoms of a majority of the diseases. Chronic pain and inflammation, as well as related dreadful disorders, remain difficult to control due to a lack of safe and effective medications. In this work, biocompatible platinum nanoparticles with significant analgesic and anti-inflammatory action were synthesized through a wet chemical method using polyethylene glycol-400 as a capping agent and sodium borohydride as a reducing agent. The average particle size of these Pt nanospheres was determined to be 3.26 nm using TEM analysis, and X-ray diffraction confirmed their face-centered cubic crystalline structure. Fourier transform infrared and UV-visible spectroscopy confirm that Pt-NPs are coated with the PEG-400 molecule. The significantly negative zeta potential value (-26.8 mV) indicates the stability of the produced nanoparticles. In vitro cytotoxicity studies on normal cell lines show nontoxic behavior with over 96% cell viability at 100 μg/mL of the test sample. In vitro assays of inhibition of protein denaturation and DPPH free radical scavenging elucidated the anti-inflammatory and antioxidant properties of PEGylated Pt NPs with promising EC50 values 57.99 and 9.324 μg/mL, respectively. In vivo animal trials confirmed that PEG-capped Pt-NPs are more effective than conventional medicines. The in vivo hot plate assay for the analgesic study shows a maximum response time of 14.5 ± 1.22 s (92.54% analgesia) at a dosage of 50 mg/kg and 13.8 ± 0.71 s (86.05% analgesia) at a dosage of 25 mg/kg after 180 and 240 min of administration, respectively. In the rat paw edema model for anti-inflammatory activity, the PEG-capped Pt NPs exhibit significant inhibitory action, with the maximum percentage of edema inhibition at a dosage of 50 mg/kg identical to that of the aspirin-based standard medication administered at a higher dosage of 100 mg/kg, resulting in 42% inhibition, suggesting a versatile solution for inflammation and persistent pain.

Targeting InhA in drug-resistant Mycobacterium tuberculosis: potent antimycobacterial activity of diaryl ether dehydrozingerone derivatives

Tuberculosis (TB) remains a major global threat, with 10 million new cases and 1.5 million deaths each year. In multidrug-resistant tuberculosis (MDR-TB), resistance is most commonly observed against isoniazid (INH) and rifampicin (RIF), the two frontline drugs. Isoniazid resistance is predominantly linked to mutations in the InhA gene, which encodes an enzyme involved in mycolic acid synthesis, a vital component of the mycobacterial cell wall. Mutations in InhA reduce drug binding, rendering INH ineffective. These morbidity and mortality figures, along with the fact that the rise and global spread of drug-resistant TB, underscores the need for the discovery of novel therapeutics. In this direction, we have previously synthesized, characterized, and screened a library of diaryl ether dehydrozingerone derivatives against mycobacteria and identified two best hits, 7 and 14, based on bacteriostatic activities. The present study aimed to thoroughly investigate the antituberculosis potential of these compounds, particularly regarding drug-resistant TB. Our findings revealed that both compounds exhibited tuberculocidal activity against the standard laboratory strain Mycobacterium tuberculosis (M. tb) H37Rv, with minimal bactericidal concentrations (MBC) of 4μg/ml for compound 7 and 8 μg/ml for compound 14. Next, concentration vs time-kill kinetics of both these compounds showed concentration-dependent bactericidal activities against M. tb and complete pathogen eradication from culture at just 16× MIC. Both compounds were found to be suitable for combination regimens as their interactions with isoniazid and rifampicin against M. tb were observed to be synergistic. Additionally, 7 and 14 exhibited minimal hemolysis against human RBCs and less cytotoxicity was observed against three human cell lines up to 1000 μM. Molecular docking revealed that these compounds bind more effectively to M. tb InhA, including its mutant forms where isoniazid binding is impaired, outperforming both isoniazid and triclosan in binding affinity. Importantly 7 and 14 showed potent activity against drug-susceptible clinical isolates and two isoniazid-resistant M. tb clinical isolates equivalent to that against M. tb H37Rv. The most interesting observation was that both compounds were found to be effective against three multi-drug resistant (MDR) strains of M. tb, thereby depicting their potential against drug-resistant TB. An ex vivo assay on RAW 264 cells infected with M. tb demonstrated a significant reduction in bacterial load at 8× MIC, revealing the fact that these compounds are highly effective against intracellular M. tb H37Rv. To the best of our knowledge, this is the first study that reports promising antimycobacterial potential of 7 and 14 against drug-susceptible, isoniazid-resistant, and MDR tuberculosis which warrants further exploration considering the need for new anti-TB medicine.

Gallic acid-guar gum and chitosan-based polyelectrolyte complex film exhibited enhanced wound healing in full-thickness excision wound model

Recently, there has been a great interest in the development of innovative wound dressing materials based on natural bioactives, as they can accelerate the healing process and address the issues related to traditional wound dressings. The current study focuses on developing a novel derivative of guar gum (GG) and gallic acid (GA) using a simple, free radical-mediated polymerization reaction aimed at enhancing the antioxidant properties of GG. Multiple spectroscopic investigations were performed to validate the GA-GG conjugate. NMR and FTIR confirmed GA integration, UV spectroscopy indicated changes in electronic transition, DSC analysis suggested a reduction in crystallinity, and XRD revealed structural modifications. SEM revealed a porous structure that reflected its polymerized nature. Due to inadequate mechanical strength and film-forming ability of the synthesized GA-GG conjugate, polyelectrolyte complexation method using chitosan was explored to form a polyelectrolyte complex (PEC) film. The film exhibited a high swelling rate, excellent antioxidant properties, and was both hemocompatible and exhibited improved antimicrobial properties. In vitro, in ovo, and in vivo characterizations were performed to compare the performance of these biocomposite films to those of their counterparts. It promoted angiogenesis in the chick yolk sac membrane and demonstrated good cytocompatibility in cell proliferation studies on the viability of the L929 mouse fibroblast cell line. In vivo wound healing efficacy of the PEC film in wound closure was 94.5% as compared to the untreated disease control group (p < 0.001). This work highlights the development of an innovative GA-GG conjugate/chitosan PEC-based film with significant potential for wound healing applications.

Antimicrobial activity of ceftibuten/polymyxin B combination against polymyxin/carbapenem-resistant Klebsiella pneumoniae

OBJECTIVES

To evaluate the synergistic effect of a ceftibuten and polymyxin B combination and to determine its capacity to overcome polymyxin B resistance in polymyxin/carbapenem-resistant (PC-R) Klebsiella pneumoniae.

METHODS

To investigate the combination's antibacterial efficacy, antimicrobial susceptibility tests using broth microdilution methods, chequerboard assays and time-kill testing were performed. Antibiofilm activity was also assessed. The treatment's effect on the bacterial cell membrane was examined by quantifying intracellular protein leakage and conducting scanning electron microscopy. Haemocompatibility tests were conducted to evaluate toxicity. Additionally, an infection model was established using Swiss mice to assess in vivo antimicrobial activity.

RESULTS

The ceftibuten/polymyxin B combination demonstrated synergistic effects against several PC-R strains of K. pneumoniae, as determined by the FIC index (FICI) values, which ranged from 0.15 to 0.37. This combination was efficacious, exhibiting bactericidal activity at twice the MIC. Ceftibuten/polymyxin B also demonstrated antibiofilm activity. Additionally, ceftibuten/polymyxin B neither damaged the bacterial membrane nor exhibited haemolytic activity. Based on these findings, the in vivo therapeutic potential was investigated and it was found that ceftibuten/polymyxin B significantly decreased the bacterial load in the peritoneal lavage fluid of mice, revealing its effectiveness in treating infections caused by PC-R K. pneumoniae.

CONCLUSIONS

The ceftibuten/polymyxin B combination exhibited synergistic effects in vitro and in vivo, and thus might be a promising therapeutic alternative for treating PC-R K. pneumoniae infections. As the combination was efficacious in preclinical models, researchers may further investigate its potential in clinical studies.

The Effect of a Secondary Stressor on the Morphology and Membrane Structure of an Already Challenged Maternal and Foetal Red Blood Cell Population

The red blood cell (RBC) membrane is unique and crucial for maintaining structural-functional relationships. Maternal smoking induces significant changes in the morphological, rheological, and functional parameters of both maternal and foetal RBCs, mainly due to the continuous generation of the free radicals. The major aim of this study was to follow the consequences of a secondary stressor, like fungal infection, on the already compromised RBC populations. The impact of Candida infection, a growing health concern, was investigated on four blood sample groups: mothers and their neonates originating from non-smoking versus smoking populations. Here, we searched for phenotypical and molecular markers that precisely reflected the effect of Candida infection on the RBC membrane; this included the level of hemolysis, appearance of morphological variants, formation of the lipid peroxidation marker 4-hydroxyl-nonenal, arrangement of the Band 3 molecules and activation of the Caspase 3. In most of the examined cases, the fungal infection increased the adverse symptoms induced by smoking, indicating a general stress response, likely due to an altered redox state of the cells. However, we were able to identify an atypical phenotype (clustered populations with shrinkage and membrane blebbing) in both the non-smoking and smoking populations, which might be a unique marker for Candida spp. infection.

Optimizing Retinal Imaging: Evaluation of ultrasmall TiO2 nanoparticle- fluorescein conjugates for improved Fundus Fluorescein Angiography

Fundus Fluorescein Angiography (FFA) has been extensively used for the identification, management, and diagnosis of various retinal and choroidal diseases, such as age-related macular degeneration, diabetic retinopathy, retinopathy of prematurity, among others. This exam enables clinicians to evaluate retinal morphology and the pathophysiology of retinal vasculature. However, adverse events, including from mild to severe reactions to sodium fluorescein, have been reported. Titanium dioxide nanoparticles (NPTiO2) have shown significant potential in numerous biological applications. Coating or conjugating these nanoparticles with small molecules can enhance their stability, photochemical properties, and biocompatibility, as well as increase the hydrophilicity of the nanoparticles, making them more suitable for biomedical applications. This work demonstrates the potential use of ultrasmall titanium dioxide nanoparticles conjugated with sodium fluorescein to improve the quality of angiography exams. The strategy of conjugating fluorescein with NPTiO2 successfully enhanced the fluorescence photostability of the contrast agent and increased its retention time in the retina. Preliminary in vivo and in vitro safety tests suggest that these nanoparticles are safe for the intended application demonstrating low tendency to hemolysis, and no significant changes in the retina thickness or in the electroretinography a-wave and b-wave amplitudes. Overall, the conjugation of fluorescein to NPTiO2 has produced a nanomaterial with favorable properties for use as an innovative contrast agent in FFA examinations. By providing a clear description of our methodology of analysis, we also aim to offer better perspectives and reproducible conditions for future research.

Anti-inflammatory effects of a methanol extract from Montanoa grandiflora DC. (Asteraceae) leaves on in vitro and in vivo models

BACKGROUND

Montanoa grandiflora, a plant species native from Mexico to Central America, locally known as "Teresita" in Yucatán, México, is used to alleviate anxiety, rheumatism, and stomach issues. This study aims to investigate the anti-inflammatory properties of the methanol extract of Montanoa grandiflora leaves (MMG) in experimental models of inflammation.

METHODS

Gas chromatography-mass spectroscopy was used to characterize the MMG; cytotoxicity was assessed by MTT assay on murine macrophages and hemolysis assay. The in vitro anti-inflammatory activity was evaluated on LPS-stimulated murine macrophages by measuring of pro- and anti-inflammatory cytokines, NO and H2O2 release. The in vivo anti-inflammatory activity was evaluated using carrageenan-induced mouse paw edema, 12-O-tetradecanoylphorbol 13-acetate induced-ear edema, and 1-fluoro-2,4-dinitrobenzene induced-delayed-type hypersensitivity. In addition, the serum levels of prostaglandins and leukotrienes were assessed.

RESULTS

The main compounds found in MMG were terpenes (i.e., β-caryophyllene, (-)-α-cubebene, alloaromadendrene, ( +)-δ-cadinene, β-eudesmol), alkaloid (( ±)-nor-β-hydrastine), cyclic polyol (quinic acid), carbohydrates and their derivatives, and fatty acids (octadecatrienoic acid and octadecanoic acid). MMG did not exhibit cytotoxic or hemolytic activity. However, it demonstrated in vitro anti-inflammatory effects by increasing the production of IL-10, decreasing the levels of TNF-α, IL-1β, IL-6, NO and H2O2. MMG significantly reduced carrageenan-induced paw edema, TPA-induced ear edema, and DNFB-induced delayed-type hypersensitivity in mice with effects comparable to those of standard drugs, as well as serum levels of prostaglandins and leukotrienes.

CONCLUSION

The anti-inflammatory activity of MMG is associated with increased IL-10 levels and inhibiting inflammatory cell migration mechanisms, without causing cytotoxic or hemolytic damage in both in vitro and in vivo assays.

MicroRNAs Dependent G-ELNs Based Intervention Improves Glucose and Fatty Acid Metabolism While Protecting Pancreatic β-Cells in Type 2 Diabetic Mice

Metabolic disorders such as Type 2 diabetes mellitus (T2DM) imposes a significant global health burden. Plant-derived exosome like nanoparticles (P-ELNs) have emerged as a promising therapeutic alternate for various diseases. Present data demonstrates that treatment with Ginger-derived exosome like nanoparticles (G-ELNs) enhance insulin dependent glucose uptake, downregulate gluconeogenesis and oxidative stress in insulin resistant HepG2 cells. Furthermore, oral administration of G-ELNs in T2DM mice decreases fasting blood glucose levels and improves glucose tolerance as effectively as metformin. These improvements are attributed to the enhanced phosphorylation of Protein kinase B (Akt-2), the phosphatidylinositol 3-kinase at serine 474 which consequently leads to increase in hepatic insulin sensitivity, improvement in glucose homeostasis and decrease in ectopic fat deposition. Oral administration of G-ELNs also exerts protective effect on Streptozotocin (STZ)-induced pancreatic β-cells damage, contributing to systemic amelioration of T2DM. Further, as per computational tools, miRNAs present in G-ELNs modulate the phosphatidylinositol 3-kinase (PI3K)/Akt-2 pathway and exhibit strong interactions with various target mRNAs responsible for hepatic gluconeogenesis, ectopic fat deposition and oxidative stress. Furthermore, synthetic mimic of G-ELNs miRNA effectively downregulates its target mRNA in insulin resistant HepG2 cells. Overall, the results indicate that the miRNAs present in G-ELNs target hepatic metabolism thus, exerting therapeutic effects in T2DM.

Boc-Protected Phenylalanine and Tryptophan-Based Dipeptides: A Broad Spectrum Anti-Bacterial Agent

Dipeptides were constructed using hydrophobic amino acid residues following AMP prediction. After that Boc-modification was performed on the screened peptides and finally Boc-Phe-Trp-OMe and Boc-Trp-Trp-OMe were synthesized. Even though no inhibition zones were observed in agar well diffusion assays, minimum inhibitory concentration (MIC) analysis revealed anti-bacterial activity against both Gram-positive and Gram-negative bacteria, with MIC90 ranging from 230 to 400 μg/mL. The crystal violet assay confirmed the dipeptides' biofilm eradication and disruption capabilities. Furthermore, membrane permeabilization assays indicated outer and inner membrane permeabilization, while SEM analysis revealed the formation of fibril and spherical nanostructures, likely contributing to this effect. The peptides also exhibited resistance to protein adsorption, non-cytotoxicity, and non-hemolytic properties, making them promising broad-spectrum anti-bacterial agents with biofilm eradication and disruption potential. This study concludes that Boc-protected phenylalanine- and tryptophan-based dipeptides can self-assemble and can be used as broad-spectrum anti-bacterial agents. The self-assembly of these peptides offers a versatile platform for designing biomaterials with tailored properties and functionalities. Research exploring the anti-bacterial potential of Boc-protected dipeptides has been limited, prompting our investigation to shed light on this overlooked area. Our analysis of synthesized Boc-protected dipeptides revealed notable anti-bacterial activity, marking a significant advancement. This finding suggests that these dipeptides could emerge as potent, broad-spectrum anti-bacterial agents, addressing the urgent need for effective treatments against bacterial resistance and opening new avenues in therapy. This study not only enhances our understanding of these dipeptides but also highlights their potential as innovative and efficacious anti-bacterial agents, making a substantial impact in the clinical field.

Quinazoline derivatives as novel bacterial sphingomyelinase enzyme inhibitors

Bacillus cereus sphingomyelinase C (B. cereus SMase), which plays a crucial role in bacterial virulence, has emerged as a new therapeutic target for treating opportunistic infections caused by this pathogen. It also shares catalytic domain similarity with human neutral sphingomyelinase 2 (nSMase2), which is implicated in Alzheimer's disease. In this study, a series of quinazoline derivatives were synthesized and evaluated for their inhibition of B. cereus SMase, electric eel acetylcholinesterase (EeAChE), and equine butyrylcholinesterase (eqBuChE). Moreover, the antibacterial, anti-hemolytic and metal chelation properties of the selected compounds were determined. Among the synthesized compounds, 6-chloro-2-thioxo-2,3-dihydroquinazolin-4(1H)-one (compound 4) and 6-fluoro-2-thioxo-2,3-dihydroquinazolin-4(1H)-one (compound 5) exhibited promising inhibition of B. cereus SMase, with IC50 values of 6.43 and 6.50 µM, respectively. The mode of inhibition of compound 4 was determined as mixed-type inhibition by enzyme kinetic study. In addition, compounds 4 and 5 showed 59.50% and 51.66% eqBuChE inhibition at 50 µM concentration, respectively. Furthermore, compound 4 reduced B. cereus-induced hemolysis on sheep erythrocytes and able to form a complex with Cu2+ in ligand:metal ratio of 2:1. Additionally, cambinol, an inhibitor of both nSMase2 and B. cereus SMase, was found to exhibit inhibitory activity against eqBuChE, with IC50 value of 7.40 µM. The biological data were also supported by the results of molecular docking studies and in-silico physicochemical properties/ADME predictions of the selected compounds were determined.