Efficient Drug Release Research Articles

Preparation and Characterization of Nanostructured Lipid Carriers (NLCs) Containing Glycyrrhiza glabra Extract for the Treatment of Skin Hyperpigmentation.

This study aimed to prepare, characterize, and in vitro and in vivo evaluate a novel nanostructured lipid carriers (NLCs) formulation containing two fractions of Glycyrrhiza glabra L. (licorice) extract for the treatment of hyperpigmentation. Two fractions, one enriched with glabridin (FEG) and the other enriched with liquiritin (FEL), were obtained by partitioning the methanol (MeOH) extract of licorice roots with ethyl acetate (EtOAc) and partitioning the EtOAc fraction with butanol (n-BuOH) and water. The quantities of glabridin (Glab) and liquiritin (LQ) in the fractions were determined by high-performance liquid chromatography (HPLC). FEG and FEL were loaded in different NLC formulations, and surface characterization and long-term stability were studied using Dynamic Light Scattering (DLS). The best formulation was chosen for further surface characterization, including Transmission Electron Microscopy (TEM), Differential Scanning Calorimetry (DSC), and Fouriertransform infrared (FTIR) spectroscopy. Moreover, entrapment efficiency percentage (EE%), in vitro drug release, in vivo skin penetration, cytotoxicity on B16F10 melanoma cells, effect on melanin production, and anti- tyrosinase activity were tested for the selected formulation. Based on HPLC results, FEG contained 34.501 mg/g of Glab, and FEL contained 31.714 mg/g of LQ. Among 20 different formulations, NLC 20 (LG-NLCs) showed desirable DLS results with a Z-average size of 185.3±1.08 nm, polydispersity index (PDI) of 0.229±0.35, and zeta potential of -16.2±1.13 mV. It indicated good spherical shape, high EE% (79.01% for Glab and 69.27% for LQ), two-stage release pattern (an initial burst release followed by sustained release), efficient in vivo skin penetration, and strong anti-tyrosinase activity. LG-NLCs had acceptable physiochemical stability for up to 9 months and were non-cytotoxic. The LG-NLC formulation has revealed desirable surface characterization, good physiochemical stability, efficient drug release pattern and in vivo penetration, and high EE%. Therefore, it can be a suitable nanosystem for the delivery of licorice extract in the treatment of hyperpigmentation.

Inhalable Anti-EGFR Antibody-Conjugated Osimertinib Liposomes for Non-Small Cell Lung Cancer

Background: Non-small cell lung cancer (NSCLC) is a leading cause of cancer deaths globally. The most extensive treatment is Tyrosine Kinase Inhibitors (TKIs) that target epidermal growth factor receptor (EGFR) overexpression. Osimertinib, a third-generation TKI is approved to target EGFR exon 19 deletions or exon 21 L858R mutations. However, resistance is inevitable due to emergence of triple mutations (sensitizing mutations, T790M and C797S). To overcome this challenge, a combinatorial approach was used wherein Osimertinib liposomes were conjugated with cetuximab (CTX), an anti-EGFR monoclonal antibody, to improve drug efficacy and delivery. Additionally, pulmonary administration was employed to minimize systemic toxicity and achieve high lung concentrations. Methods: Osimertinib liposomes (OB-LPs) were prepared using thin film hydration method and immunoliposomes (CTX-OB-LPs) were prepared by conjugating the OB-LPs surface with CTX. Liposomes were characterized for particle size, zeta-potential, drug loading, antibody conjugation efficiency, in vitro drug release, and aerosolization performance. Further, the in vitro efficacy of immunoliposomes was evaluated in H1975 cell line. Results: Immunoliposomes exhibited a particle size of 150 nm, high antibody conjugation efficiency (87%), efficient drug release, and excellent aerosolization properties with an aerodynamic diameter of 3 μm and fine particle fraction of 88%. Furthermore, in vitro studies in H1975 cells showed enhanced cytotoxicity with CTX-OB-LPs displaying 1.7-fold reduction and 1.2-fold reduction in IC50 compared to Osimertinib and OB-LPs, respectively. The CTX-OB-LPs also significantly reduced tumor cell migration and colonization compared to Osimertinib and OB-LPs. Conclusions: These successful results for EGFR-targeting inhalable immunoliposomes exhibited potential for contributing to greater anti-tumor efficacy for the treatment of non-small cell lung cancer.

DEVELOPMENT OF GABAPENTIN-LOADED SOLID LIPID NANOPARTICLE FOR ALLEVIATING SEIZURE ACTIVITY IN PICROTOXIN AND BICUCULLINE-INDUCED RATS

Objective: The current research aimed to prepare gabapentin-loaded Solid Lipid Nanoparticles (SLN) for alleviating seizure activity in picrotoxin and bicuculline-induced Wistar rats. Methods: Gabapentin-loaded SLNs were formulated using a Box-Behnken experimental design with three-level three-factor consisting of 17 experimental runs by micro-emulsification. Three independent parameters were considered in this study, namely sodium glyceryl tripalmitate (A), RPM (B), and Poloxamer-188 (C). Particle size, drug release, and Encapsulation Efficiency (EE) as dependent variables. The formulation was evaluated for drug release, EE, Attenuated Total Reflection (ATR), Differential Scanning Calorimetry (DSC), X-ray diffraction (XRD), surface morphology, particle size, zeta potential, in vivo anti-convulsion study. Results: The data collected during the experiment includes the measurements of EE (Encapsulation Efficiency), drug release at the 12th h, and particle size. It was reported that formulations containing a high concentration of Glyceryl tripalmitate (50%) had a high Encapsulation Efficiency (EE). The in vitro release results indicate that F17 demonstrated a maximum drug concentration of 99.99% within a 12 h. The optimization process was conducted using mathematical and graphical methods. From ATR spectra, it was found that there are no such major interactions between gabapentin and excipients. A significant endothermal peak was seen in the DSC investigation at 208.81 °C. X-ray diffraction revealed that gabapentin was present in the crystalline form. Drug crystals and SLN were seen to be dispersed and scattered from Scanning Electron Microscope (SEM). The optimized formulation's particle size was found to be 203.4 nm, the Polydispersity Index (PI) of 0.426, and the zeta value of 16.5 mV; indicating stability. Following a lethal and chronic dosage of picrotoxin, the gabapentin-SLN exhibited a higher anticonvulsant efficacy, according to in vivo research on rats (p<0.05). Conclusion: Compared to the Bicuculline model, the optimized SLN demonstrated superior outcomes regarding seizure initiation in the Picrotoxin-induced convulsion.

Physically crosslinked chitosan/αβ–glycerophosphate hydrogels enhanced by surface-modified cyclodextrin: An efficient strategy for controlled drug release

This study reports physically crosslinked chitosan/αβ–glycerophosphate (CS/GP) hydrogels containing surface-modified cyclodextrin for efficient controlled drug release. Highly water-soluble β–cyclodextrin-grafted L–serine (CD–g–Ser) compounds were synthesized, and employed as an effective carrier of berberine hydrochloride (Ber) for CS/GP hydrogels. Various characterizations, including gelation time determination, scanning electron microscopy, and viscosity measurement, indicated that the introduction of CD–g–Ser led to increased crosslinking degree, improved temperature sensitivity, and shortened sol–gel phase transition time of the hydrogel. Meanwhile, the sustained release ability for Ber was achieved due to the hydrophobic association between cyclodextrin and Ber. It was observed that within 4 h, the hydrogel containing CD–g–Ser released 40 % of Ber, while the CS/GP hydrogel without CD–g–Ser released 65 % of Ber. Furthermore, in vitro bacteriostasis experiments confirmed the drug-loaded hydrogel had an excellent antibacterial effect against E. coli and S. aureus (diameter of the inhibition zone up to (16.4 and 34.7) mm, respectively), low hemolysis rate (<2 %), and high cell viability (>90 %). The findings indicate that the physical crosslinked CS hydrogel can be used as a new drug delivery system, and its excellent antibacterial effect makes it a potential wound dressing candidate.

A modified self-micro emulsifying liposome for bioavailability enhancement of quercetin and its biological effects

Quercetin (QT) is a chief dietary flavonoid with a myriad of health benefits, however, its poor solubility and low bioavailability restrict its food application. Thus, the present study aimed at enhancing its solubility using a modified self-micro emulsifying system (QT-TPGS-QS). The stability of liposome was assessed via monitoring of its particle indexes (size, zeta potential, PDI, stability towards in-vitro digestion, drug release, and encapsulation efficiency). Further, antibacterial and cellular antioxidant potential of liposomes were determined. QT-TPGS-QS exhibited good optical clarity with a loading ratio of 2.1%. The liposome showed uniform spherical and regular shape (<100 nm) with a QT release rate of 85.61% ± 0.32% in simulated in-vitro digestion. QT-TPGS-QS demonstrated superior antibacterial activity compared to QT alone against Escherichia coli, Staphylococcus aureus, and Salmonella. In-vitro antioxidant evaluation confirmed that the QT-TPGS-QS exhibited a significantly higher free radical scavenging ability than QT alone. Cellular assay confirmed that QT-TPGS-QS (15 μg/mL) exhibited a good protection effect on oxidative stress induced by H2O2. Catalase (CAT) and glutathione peroxidase (GSH-Px) levels were significantly upregulated, concurrent with a reduction of malondialdehyde (MDA) suggesting that QT-TPGS-QS might be effective in inhibiting the production of intracellular reactive oxygen species (ROS), and to be considered as food additive or in nutraceuticals.

Preparation, optimization, and evaluation of ligand-tethered atovaquone-proguanil-loaded nanoparticles for malaria treatment

This work focused on improving antimalarial therapy through the development and characterization of Atovaquone-Proguanil-loaded nanoparticles employing a 32 factorial design. The nanoparticles were prepared from combinations of Poly(lactic-co-glycolic acid) (PLGA) and Eudragit L100 polymers and different concentrations of PVA (polyvinyl alcohol). Based on the results obtained the formulations were characterized for the particle size, zeta potential, encapsulation efficiency, and percent drug release. Among the nine formulations, F5 proved to be the most favorable in the biophysical parameters with a particle size of 176.3 nm, a zeta potential of −33.5 mV, and an encapsulation efficiency of 86% was found in the present investigation. Experimental dissolution profile analysis indicated that F5 had a slow and controlled-release profile where approximately 92.5%. Besides, cytotoxicity studies employing MTT, LDH (lactate dehydrogenase), and Trypan blue reduction test also supported the biocompatibility of nanoparticles and F5 had the highest cell viability (96%) with the least LDH release of 4%. In stability studies conducted for six months, F5 was found to remain stable regarding physicochemical characteristics and drug release profile at different temperature conditions such as room temperature, 4 °C, and 45 °C. The use of folic acid-functionalized nanoparticles is more effective, according to parasitemia, survival rate, and weight loss in mice treated with the nanoparticles. This is because functionalized nanoparticles could be used to enhance anti-malarial therapies.

Hepatic stellate cell-targeted chemo-gene therapy for liver fibrosis using fluorinated peptide-lipid hybrid nanoparticles

Exploring precise and effective treatments for liver fibrosis is urgent. The effective therapy for liver fibrosis depends on the specific delivery of antifibrotic drugs to activated hepatic stellate cells (aHSCs). However, this is a challenging task due to pathological barriers, primarily caused by collagen deposition. This study developed vitamin A-functionalized fluorinated peptide/lipid hybrid nanoparticles to co-deliver sorafenib and siRNA against HSP47 (SF-siHSP47@VFPL NPs). This nanoparticle formulation offers significant advantages due to its fluorine‑fluorine and electrostatic interactions, allowing for high SF and siHSP47 loading efficiency and sustained drug release. Importantly, in vitro cell uptake and in vivo biodistribution revealed that VA functionalization significantly improved aHSC-targeted delivery efficiency by engaging retinol-binding protein receptors on HSCs. Furthermore, it dramatically reduced extracellular matrix deposition, as evidenced by diminished levels of liver fibrosis-associated genes (HSP47, TIMP-1, and collagen I), promoting collagen breakdown and preventing collagen production, thus overcoming drug delivery barriers. Thus, SF-siHSP47@VFPL NPs demonstrated optimal antifibrotic effects by triggering apoptosis and ferroptosis in aHSCs. In liver fibrosis mouse models, SF-siHSP47@VFPL NPs remodeled the pathological environment and restored liver functionality through a marked reduction in serum liver transferases, hydroxyproline content, collagen deposition, and α-SMA and CD31 expression in liver tissue, resulting in alleviated liver fibrosis. Consequently, SF-siHSP47@VFPL NPs showed significant potential for HSC-targeted, chemo-gene therapy in the treatment of liver fibrosis.

Zwitterionic Polymers for Biomedical Applications: Antimicrobial and Antifouling Strategies toward Implantable Medical Devices and Drug Delivery.

Poly(ethylene glycol) (PEG) is extensively utilized in biomedical applications due to its biocompatibility; however, its thermal instability and susceptibility to oxidative degradation significantly constrain its long-term effectiveness. Zwitterionic polymers, characterized by their distinctive structure, enhanced stability, and superior biocompatibility, offer a more advantageous alternative. These polymers exhibit super hydrophilicity, resist nonspecific protein adsorption, and maintain stability in biological environments due to their charge-neutral ionic nature. Zwitterionic polymers enhance anticancer drug delivery by precisely targeting tumor cells and facilitating an efficient drug release. Their inherent antifouling properties and prolonged circulation within the bloodstream render them highly suitable for redox-sensitive drug carriers, thereby augmenting the antitumor efficacy. Moreover, zwitterionic polymers markedly mitigate biofouling in implants, biosensors, and wound dressings, thereby improving both their functionality and their therapeutic outcomes. These advantages arise from the formation of robust hydration layers, which significantly enhance the hemocompatibility and inhibit the adhesion of proteins, platelets, and bacteria. Zwitterionic polymers, including sulfobetaine (SB), phosphorylcholine (PC), and carboxybetaine (CB), are increasingly employed in blood-contacting devices and as effective coating materials for implantable devices. This mini-review paper aims to explore the recent diverse biomedical applications of zwitterionic polymers and highlight their advantageous properties compared with unmodified polymers. We will cover their use in drug delivery systems, tumor targeting nanocarriers, antibiofouling and antibacterial activities in implantable devices, tissue engineering, and diagnostic devices, demonstrating how their unique properties can translate into different applications. Through this exploration, this Perspective will display the potential of zwitterionic polymers as innovative polymer materials in the field of biomedical engineering and beyond.

Supramolecular Assemblies via Host-Guest Interactions for Tumor Immunotherapy.

Cancer immunotherapy has emerged as one of the most promising modalities for cancer treatment providing hopes of cancer patients with the significant advantages over traditional antitumor therapy methods. Supramolecular assemblies based on host-guest interactions have been widely explored in the field of cancer immunotherapy as the delivery systems. A variety of supramolecular materials show unique features for efficient drug encapsulation, targeting delivery and release, which are favorable to activate antitumor immune responses especially through combination of different treatment strategies. In this review article, we summarize the research progresses of supramolecular assemblies via host-guest interactions for tumor immunotherapy. The construction of various drug delivery systems including hydrogels, liposomes, and polymeric nanoparticles, the drug encapsulation and delivery, as well as advantages and disadvantages are discussed. The perspectives related to future developments in this field are also described.

Form Equals Function: Influence of Coacervate Architecture on Drug Delivery Applications.

Complex coacervates, formed through electrostatic interactions between oppositely charged polymers, present a versatile platform for drug delivery, providing rapid assembly, selective encapsulation, and responsiveness to environmental stimuli. The architecture and properties of coacervates can be tuned by controlling structural and environmental design factors, which significantly impact the stability and delivery efficiency of the drugs. While environmental design factors such as salt, pH, and temperature play a crucial role in coacervate formation, structural design factors such as polymer concentration, polymer structure, mixing ratio, and chain length serve as the core framework that shapes coacervate architecture. These elements modulate the phase behavior and material properties of coacervates, allowing for a highly tunable system. In this review, we primarily analyze how these structural design factors contribute to the formation of diverse coacervate architecture, ranging from bulk coacervates to polyion complex micelles, vesicles, and cross-linked gels, though environmental design factors are considered. We then examine the effectiveness of these architectures in enhancing the delivery and efficacy of drugs across various administration routes, such as noninvasive (e.g., oral and transdermal) and invasive delivery. This review aims to provide foundational insights into the design of advanced drug delivery systems by examining how the origin and chemical structure of polymers influence coacervate architecture, which in turn defines their material properties. We then explore how the architecture can be tailored to optimize drug delivery for specific administration routes. This approach leverages the intrinsic properties derived from the coacervate architecture to enable targeted, controlled, and efficient drug release, ultimately enhancing therapeutic outcomes in precision medicine.

Novel combination therapy using recombinant oncolytic adenovirus silk hydrogel and PD-L1 inhibitor for bladder cancer treatment

Recombinant oncolytic adenovirus offers a novel and promising cancer treatment approach, but its standalone efficacy remains limited. This study investigates a combination treatment strategy by co-administering recombinant oncolytic Adv-loaded silk hydrogel with a PD-L1 inhibitor for patients with bladder cancer to enhance treatment outcomes. Bladder cancer tissues from mice were collected and subjected to single-cell sequencing, identifying CRB3 as a key gene in malignant cells. Differential expression and functional enrichment analyses were performed, validating CRB3’s inhibitory role through in vitro experiments showing suppression of bladder cancer cell proliferation, migration, and invasion. Recombinant oncolytic adenoviruses encoding CRB3 and GM-CSF were constructed and encapsulated in silk hydrogel to enhance drug loading and release efficiency. In vivo experiments demonstrated that the nano-composite hydrogel significantly inhibited tumor growth and increased immune infiltration in tumor tissues. Co-administration of adenovirus silk hydrogel (Adv-CRB3@gel) with a PD-L1 inhibitor significantly enhanced T-cell infiltration and tumor killing. The combination of recombinant oncolytic Adv-loaded nano-composite hydrogel encoding CRB3 and GM-CSF with a PD-L1 inhibitor improves bladder cancer treatment outcomes by effectively recruiting T cells, providing a novel therapeutic strategy.

Construction of Methotrexate-Loaded Bi2S3 Coated with Fe/Mn-Bimetallic Doped ZIF-8 Nanocomposites for Cancer Treatment Through the Synergistic Effects of Photothermal/Chemodynamic/Chemotherapy.

A combination of therapeutic modalities in a single nanostructure is crucial for a successful cancer treatment. Synergistic photothermal therapy (PTT) can enhance the effects of chemodynamic therapy (CDT) and chemotherapy, which could intensify the therapeutic efficacy to induce cancer cell apoptosis. In this study, Fe and Mn on a zeolitic imidazolate framework (ZIF-8) (Fe/Mn-ZIF-8; FMZ) were synthesized through ion deposition. Furthermore, bismuth sulfide nanorods (Bi2S3 NRs; BS NRs) were synthesized via a hydrothermal process and coated onto FMZ to generate the core-shell structure of the Bi2S3@FMZ nanoparticles (B@FMZ). Next, methotrexate (MTX) was loaded effectively onto the porous surface of ZIF-8 to form the B@FMZ/MTX nanoparticles. The Fenton-like reaction catalyzes Fe2+/Mn2+ ions by decomposing H2O2 in the tumor microenvironment, resulting in the formation of toxic hydroxyl radicals (·OH), which promotes the CDT effect of killing cancer cells. Furthermore, under 808 nm laser irradiation, these B@FMZ nanoparticles showed a strong PTT effect, owing to the presence of intense BS NRs as a photothermal agent. The B@FMZ nanoparticles exhibited a prominent drug release efficiency of 87.25% at pH 5.5 under near-infrared laser irradiation due to the PTT effect can promote the drug delivery performance. The B@FMZ nanoparticles were subjected to dual-modal imaging, guided magnetic resonance imaging, and X-ray computed tomography imaging. Both in vitro and in vivo results suggested that the B@FMZ/MTX nanoparticles exhibited enhanced antitumor effects through the combined therapeutic effects of PTT, CDT, and chemotherapy. Therefore, these nanoparticles exhibit good biocompatibility and are promising candidates for cancer treatment.

One-pot biocatalysis of potato rhamnogalacturonan and the role of its deacetylation in efficient inhibition of colon cancer cells and hydrogel mediated colon-targeted drug delivery

Deacetylation of potato rhamnogalacturonan (PRG) by rhamnogalacturonan acetyl esterase (CtPae12B) was explored for enhanced hydrolysis of PRG by rhamnogalacturonan lyase (CtRGLf) and the effects of deacetylated PRG were studied in enhancing inhibition of colon-cancer cells and formation of colon-targeting drug delivery material. Pre-treatment of PRG with CtPae12B resulted in increased relative activity of CtRGLf. CtPae12B removed acetyl groups from both O-2 and O-3 positions of D-galactopyranosyluronic acid residues of PRG, resulting in 98 % deacetylation. PRG displayed 21.9 % degree of acetylation and 7.7 % degree of methylation. TLC and ESI-MS analysis of CtRGLf hydrolysed PRG showed unsaturated RG di-saccharide as the smallest product, with m/z 322. Deacetylated PRG-oligosaccharides displayed higher, 50 % inhibition of colon-cancer HCT-116 cells (with shrunken and globular morphology) than 35 % inhibition by acetylated PRG-oligosaccharides. FESEM and BET analysis of CtPae12B-treated PRG showed porous structure and significantly higher total surface area and pore volume than non-enzyme treated PRG. Higher drug entrapment efficiency and lower drug release rate of CtPae12B-treated PRG hydrogel (0.0033 min−1 at pH 1.2 and 0.009 min−1 at pH 7.4), than non-enzyme treated PRG hydrogel, (0.0057 min−1 at pH 1.2 and 0.02 min−1 at pH 7.4), showed it to be a potential biomaterial for sustainable colon-targeted drug delivery.

Targeted delivery of letrozole-loaded Mg-doped cobalt ferrite nanoparticles for breast cancer treatment

Breast cancer is the most common cancer in women globally. Letrozole is an aromatase inhibitor used as an anticancer drug. Conventional Letrozole therapies for breast cancer often cause adverse effects when administered orally or parenterally. Efforts have been made to develop an advanced drug delivery system for breast cancer treatment, aiming to improve drug release accuracy and therapeutic efficacy while minimizing side effects. This study focuses on magnesium-doped cobalt ferrite nanoparticles (Mg-doped CFNPs) as potential drug delivery carrier for breast cancer treatment. Mg-doped CFNPs with the chemical formula Co1-xMgxFe2O4 (where x = 0.0, 0.05, 0.10, 0.15, 0.20 and 0.25) were synthesized with different concentrations of 5 %, 10 %, 15 %, 20 %, and 25 % by the sol gel method with a fine size of 30–70 nm and their characteristics such as surface morphology, structural properties, chemical composition, and charge were investigated using scanning electron microscopy (SEM), X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), and zeta potential analysis respectively. After synthesis, the Mg-doped CFNPs were coated with Poly ethylene glycol (PEG) and encapsulated with Letrozole, which exhibited <10 % hemolytic activity across all concentrations, as well as minimal cytotoxic effects on non-cancerous cells (HEK-293) but exhibited significant toxicity towards breast cancer cell lines (MCF-7, MDA-MB-231).The best results were obtained at a concentration of 25 % in both the hemolytic assay and the MTT assay, which indicated that increasing the amount of magnesium in cobalt decreased the toxicity and increased the drug release efficiency of nanoparticles.

Locust bean gum glutarate nanocomposite hydrogel microspheres of gliclazide: Optimization by box-Behnken design and preclinical evaluation of anti-diabetic efficacy

In this study, carboxymethyl locust bean gum was synthesized and nanocomposite hydrogel microspheres (GHMs) of gliclazide were produced based on nanosilicate reinforcement and aluminium-ion driven gelation process, followed by covalent crosslinking with glutaric anhydride (GA). The effect of three independent variables (polymer and GA concentration, incubation time) on the drug entrapment efficiency (DEE%) and percent drug release at 8 h, was optimized using Box-Behnken design. The highest DEE (%) and lowest drug release was achieved at the following optimized conditions: polymer (2.43 %), GA (0.34 %), and incubation (27 min). The nanoscilicate-enriched matrix provided a maximum of 75.13 % DEE, 92.33 % gel fraction, and excellent flowability. The optimized microspheres had virtually spherical morphology, according to FE-SEM analysis. FTIR study indicated a hydrogen bonding interaction between the drug and other formulation components. X-ray and DSC measurements suggested that the crystallinity of the drug decreased following integration into the matrix. The optimized GHM demonstrated anomalous diffusion of gliclazide in simulated gastrointestinal fluids for 12 h without disintegration. In streptozotocin (50 mg/kg BW)-induced diabetic rats, the optimized formulation diminished blood glucose level by about 72 % in 12 h. Thus, the nanocomposite GHMs created by combining nanosilicate with GA had an outstanding potential for long-term control of diabetes.

Design and Development of Solid Lipid Nanoparticles of Tofacitinib Citrate for the Treatment of Rheumatoid Arthritis: A Quality by Design Approach.

Solid lipid nanoparticles, or SLNs, have gained popularity recently as a possible drug delivery method. However, the idea of using SLNs for organ and site-specific drug administration is still in its early stages due to the difficulties associated with this approach. The aim of this study is to develop SLNs with improved pharmaceutical characterization and anti-arthritic efficacy. Tofacitinib citrate (TC)-loaded SLNs were created using the microemulsification method, with the addition of stearic acid, chitosan, and Tween 80 to improve skin permeability. Seventeen SLNs were developed and characterized for particle size, entrapment efficiency (EE), and percentage drug release according to the Box-Behnken design. The DSC analysis revealed a strong endothermic peak at 166.18°C, significantly different from the pure TC reported at 218.05°C. This indicates a notable alteration in the endothermic peak of the SLNs, demonstrating a relationship with the excipients used in this investigation. XRD study highlighted significant characteristic drug peaks at positions 21.06 and 23.63 (2ɵ). These peaks represented the modifications that were seen in pure TC. The SEM analysis of the optimized lipid nanoparticles showed a smooth surface and a spherical appearance. The particle size analysis of the optimized formulation showed an average size of 181.5 nm. Also, the polydispersity index (PI) revealed a value of 0.495, indicating homogeneous dispersion. The zeta value was 8.2 mV, indicating stability.

Comprehensive Evaluation of Process Parameters in the Green Synthesis of Iron Oxide Nanoparticles Using Moringa olifera extract.

This study investigates the green synthesis of iron oxide nanoparticles using Moringa olifera ethanolic extract and evaluates the impact of various process parameters on their physicochemical characteristics. The parameters examined include synthesis time, temperature, pH, stirring speed (RPM), and the ratio of extract to iron precursors. The findings reveal that a lower proportion of the extract increases the entrapment efficiency of the nanoparticles. Specifically, batch ME3 (3:1 ratio) produced the smallest nanoparticles at 117.8 nm, with a drug release of 75.54% and the highest entrapment efficiency at 60.28%. Extending the synthesis time to three hours in batch TM3 resulted in a drug release of 74.23% and a particle size of 116.3 nm. Batch TEM1, synthesized at 70°C, showed the highest entrapment efficiency and a favorable drug release profile of 71.09%, with the smallest particle size of 105.24 nm, suggesting that higher synthesis temperatures favor smaller particle sizes. Adjusting the pH to 10 in batch PM3 achieved a drug release efficiency of 76.02%. Batch RM5, synthesized with a stirring speed of 750 RPM, demonstrated a particle size of 95.7 nm and a drug release of 78.26%, indicating that higher stirring rates produce smaller nanoparticles and enhance drug release. These results highlight the significance of optimizing synthesis conditions to produce nanoparticles with desired properties. The use of M. olifera extract as a sustainable reducing and stabilizing agent presents an environmentally friendly approach to nanotechnology. This method has potential applications in drug delivery systems and various other industries, emphasizing the importance of green synthesis in creating sustainable and efficient nanomaterials.

Synergistic antibacterial and wound healing effects of chitosan nanofibers with ZnO nanoparticles and dual antibiotics

One concern that has been considered potentially fatal is bacterial infection. In addition to the development of biocompatible antibacterial dressings, the screening and combination of new antibiotics effective against antibiotic resistance are crucial. In this study, designing hemostasis electrospun composite nanofibers containing chitosan (CS), polyvinyl pyrrolidone (PVP) and Gelatin (G) as the major components of hydrogel and natural nanofibrillated sodium alginate (SA)/polyvinyl alcohol (PVA) and ZnO nanoparticles (ZnONPs) combination as the nanofiller ingredient, has been investigated which demonstrated significant potential for accelerating wound healing. The hydrogels were developed for the delivery of the amikacin and cefepime antibiotics, along with zinc oxide nanoparticles that were applied to an electrospun layer. Amikacin is a highly effective aminoglycoside antibiotic, particularly for hospital-acquired infections, but its use is limited due to its toxicity. By utilizing it in low concentrations in the form of nanofibers and combining it with cefepime, which exhibits synergistic effects, enhanced efficacy against bacterial pathogens is achieved while potentially minimizing cytotoxicity compared to individual antibiotics. This dressing demonstrated efficient drug release, flexibility, and good swelling properties, indicating its suitable mechanical properties for therapeutic applications. After applying the biocompatible hydrogel to wounds, a significant acceleration in wound closure was observed within 14 days compared to the control group. Furthermore, the notable antibiotic and anti-inflammatory properties underscore its effectiveness in wound healing, making it a promising candidate for medical applications.

Preparation and Evaluation of Itraconazole Nanoparticle Lipid Carrier Gel for Dermatophytosis

Fungal infection is one of the common dermatological diseases. Drug delivery systems for topical use have shown significant advantages in targeting the drug to the action site in the body and also reduces the systemic side effects. Itraconazole was chosen as a model drug with low aqueous solubility. In the present study an attempt was made to prepare itraconazole loaded nanostructured lipid carrier (NLC). Different formulations were prepared by hot homogenization technique using solid lipid and liquid lipid (Compritol 888 &amp; Caprol PGE 860) and surfactants (Poloxamer 188, tween 80). All the Formulations were characterized for drug content, entrapment efficiency, particle size, poly dispersity index, zeta potential &amp;in vitro drug release and FTIR was done to study any interaction between excipients. The best formulation shows better drug release and entrapment efficiency 83.2%. the best formulation F3 showed better in-vitro drug release 55.46% at the end of 8th hour. The F3 was made into gel using Carbopol as a gelling agent. SEM study revealed that the NLC gel shows the particle size was found to be 500 nm in size smooth surfaces. NLC gel shows Drug release of NLC gel followed non- Fickian diffusion. NLC gel were stable at 40 ± 2ֹ°C and 75 ± 5% RH. Thus, the prepared NLC gel proved to be a potential candidate as a topical nanoparticulate sustained drug delivery system for itraconazole (BCS class II drug). keywords: Itraconazole, Nanoparticle Lipid Carrier, Lipids.

A Self-Skin Permeable Doxorubicin Loaded Nanogel Composite as a Transdermal Device for Breast Cancer Therapy.

Modern drug delivery research focuses on developing biodegradable nanopolymer systems. The present study proposed a polymer-based composite nanogel as a transdermal drug delivery system for the pH-responsive targeted and controlled delivery of anticancer drug doxorubicin (DOX). Nanogels have properties of both hydrogels and nanomaterials. The β-cyclodextrin-based nanogels can enhance the loading capacity of poorly soluble drugs and promote a sustained drug release. The β-cyclodextrin-grafted methacrylic acid conjugated hyaluronic acid composite nanogel was successfully synthesized. β-Cyclodextrin was first grafted onto methacrylic acid. The composite nanogel-based drug carrier was prepared by controlled radical polymerization (CRP) of β-cyclodextrin-grafted methacrylic acid with hyaluronic acid. The doxorubicin-loaded carrier was characterized by Fourier transform infrared (FTIR) spectroscopy, nuclear magnetic resonance (NMR) spectroscopy, ultraviolet-visible (UV-vis) spectroscopy, zeta potential analysis, dynamic light scattering (DLS), scanning electron microscopy (SEM), and transmission electron microscopy (TEM). The drug loading and release efficiencies were carried out at different pH levels. The maximum drug loading and encapsulation efficiencies of the synthesized final nanogel composite material at pH 8.0 were 86.44 ± 2.12 and 96.07 ± 2.01%, respectively. The DOX-loaded final material showed a 90.0 ± 2.6% release percentage of DOX at pH 5.5, whereas at pH 7.4, the release percentage of DOX was observed to be only 35.0 ± 0.3%. In vitro swelling, degradation, hemocompatibility, drug release kinetics, cytotoxicity, apoptosis, cell colocalization, skin irritation, and skin permeation studies, along with in vivo pharmacokinetic studies, were performed to prove the efficacy of the synthesized nanogel composite as a transdermal carrier for doxorubicin.