Topical delivery of extracted curcumin as curcumin loaded spanlastics anti-aging gel: Optimization using experimental design and ex-vivo evaluation.

Objective: This study aimed to extract and separate the organic coloring agent known as Curcumin from the rhizomes of Curcuma longa, and then to create Spanlastics that were loaded with curcumin using the ethanol injection technique. The optimized Spanlastic dispersions were then incorporated into a gel preparation for topical anti-aging use. The Spanlastic dispersions were analyzed for particle size, zeta potential, drug loading efficiency, and in vitro release profile. Furthermore, the rheological properties of the gel preparation were assessed, and a skin penetration study was conducted using confocal microscopy. Methods: Twelve different Curcumin-loaded Spanlastic dispersions using the ethanol injection method with Span® 60 as a surfactant and Tween® 80 as an edge activator in varying ratios. The dispersions were then subjected to various tests, such as particle size analysis, zeta potential measurement, drug entrapment efficiency assessment, and in vitro release profiling. The optimized formula was selected using Design-Expert® software version 13, then used to create a gel preparation, which utilized 2% HPMC E50 as a gelling polymer. The gel was evaluated for its rheological properties and analyzed using confocal microscopy. Additionally, Raman analysis was performed to ensure that the polymers used in the gel were compatible with the drug substance. Results: F5 formula, (that contains 10 mg Curcumin, and mixture 5 of span-tween mixtures that consist of 120 mg Span® 60 with 80 mg Tween® 80) was selected as the optimized formula with a desirability produced by Design Expert® software equal to 0.761, based on its particle size (212.8 ± 4.76), zeta potential (-29.4 ± 2.11), drug loading efficiency (99.788 ± 1.34), and in vitro release profile evaluations at Q 6hr equal to almost 100 %. Statistical significance (P < 0.05) was obtained using one-way ANOVA. Then F5 was used to formulate HPMC E50 gel-based preparations. The gel formula that was created and analyzed using Raman spectroscopy demonstrated no signs of incompatibility between the Curcumin and the polymers that were utilized.The confocal spectroscopy found that the anti-aging gel preparation showed promising results in terms of skin penetration. Also, images revealed that the gel could penetrate the layers of the skin (reached a depth of about 112.5 µm), where it could potentially target and reduce the appearance of fine lines and wrinkles. The gel also appeared to be well-tolerated by the skin, with no signs of irritation or inflammation observed in the images. Conclusion: The obtained results successfully confirmed the potential of the promising (F5) formula to produce sustained release action and its ability to be incorporated into 2% HPMC E50 anti-aging gel. The confocal microscopy study suggested that the anti-aging gel had the potential to be an effective and safe topical treatment for aging skin.

Formulation and optimization of ivermectin nanocrystals for enhanced topical delivery.

The increasing resistance to antiparasitic drugs and limited availability of new agents highlight the need to improve the efficacy of existing treatments. Ivermectin (IVM) is commonly used for parasite treatment in humans and animals, however its efficacy is not optimal and the emergence of IVM-resistant parasites presents a challenge. In this context, the physico-chemical characteristics of IVM were modified by nanocrystallization to improve its equilibrium water-solubility and skin penetration, potentially improving its therapeutic effectiveness when applied topically. IVM-nanocrystals (IVM-NC) were prepared using microfluidization technique. The impact of several process/formulation variables on IVM-NC characteristics were studied using D-optimal statistical design. The optimized formulation was further lyophilized and evaluated using several in vitro and ex vivo tests. The optimal IVM-NC produced monodisperse particles with average diameter of 186 nm and polydispersity index of 0.4. In vitro results showed an impressive 730-fold increase in the equilibrium solubility and substantial 24-fold increase in dissolution rate. Ex vivo permeation study using pig's ear skin demonstrated 3-fold increase in dermal deposition of IVM-NC. Additionally, lyophilized IVM-NC was integrated into topical cream, and the resulting drug release profile was superior compared to that of the marketed product. Overall, IVM-NC presents a promising approach to improving the effectiveness of topically applied IVM in treating local parasitic infections.

Nanocrystals of Fusidic Acid for Dual Enhancement of Dermal Delivery and Antibacterial Activity: In Vitro, Ex Vivo and In Vivo Evaluation.

With the alarming rise in incidence of antibiotic-resistant bacteria and the scarcity of newly developed antibiotics, it is imperative that we design more effective formulations for already marketed antimicrobial agents. Fusidic acid (FA), one of the most widely used antibiotics in the topical treatment of several skin and eye infections, suffers from poor water-solubility, sub-optimal therapeutic efficacy, and a significant rise in FA-resistant Staphylococcus aureus (FRSA). In this work, the physico-chemical characteristics of FA were modified by nanocrystallization and lyophilization to improve its therapeutic efficacy through the dermal route. FA-nanocrystals (NC) were prepared using a modified nanoprecipitation technique and the influence of several formulation/process variables on the prepared FA-NC characteristics were optimized using full factorial statistical design. The optimized FA-NC formulation was evaluated before and after lyophilization by several in-vitro, ex-vivo, and microbiological tests. Furthermore, the lyophilized FA-NC formulation was incorporated into a cream product and its topical antibacterial efficacy was assessed in vivo using a rat excision wound infection model. Surface morphology of optimized FA-NC showed spherical particles with a mean particle size of 115 nm, span value of 1.6 and zeta potential of -11.6 mV. Differential scanning calorimetry and powder X-ray diffractometry confirmed the crystallinity of FA following nanocrystallization and lyophilization. In-vitro results showed a 10-fold increase in the saturation solubility of FA-NC while ex-vivo skin permeation studies showed a 2-fold increase in FA dermal deposition from FA-NC compared to coarse FA. Microbiological studies revealed a 4-fofd decrease in the MIC against S. aureus and S. epidermidis from FA-NC cream compared to commercial Fucidin cream. In-vivo results showed that FA-NC cream improved FA distribution and enhanced bacterial exposure in the infected wound, resulting in increased therapeutic efficacy when compared to coarse FA marketed as Fucidin cream.

High-fat diet induced alteration in lipid enzymes and inflammation in cardiac and brain tissues: Assessment of the effects of Atorvastatin-loaded nanoparticles.

Treatment with Lipitor is associated with several adverse impacts. Here we investigated the effects of low Lipitor nanoparticles (atorvastatin calcium nanopartilcle [AC-NP]), with size less than 100 , on enzymes of lipid metabolism and inflammation in cardiac, hepatic, and brain tissues of hypercholestremic adult male rats. Adult male rats were divided into five experimental groups. In group 1, the intact control (normal pellet diet), animals were fed a normal control diet; the other four groups were fed a high-fat diet (HFD) for 6 weeks. After 6 weeks, groups from 2 to 5 were assigned as a positive control (HFD), HFD + Lipitor, HFD + AC-NP-R1, or HFD + AC-NP-R2. Different treatments were administrated orally for two regimen periods (R1 daily and R2 once every 3 days). The treatment was conducted for two consecutive weeks. The HFD group faced a significant elevation in 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA), associated with a significant reduction in low-density lipoprotein receptor (LDL-R) along with cholesterol 7 α-hydroxylase enzyme in hepatic tissues, compared with the control group. Also, the HFD group induced hepatic, cardiac, and brain inflammation, evidenced by increased hepatic oxidative stress markers and cardiac homocysteine, together with elevated proinflammatory cytokines interleukin-1ß (IL-1ß) and IL-6 levels in brain tissue, compared with the control group. Different AC-NP treatments significantly augmented both mRNA LDL-R and mRNA 7α-hydroxylase expression in hepatic tissues, associated with significant depletion in mRNA HMG-CoA expression, compared with HFD + Lipitor. The inflammation symptoms were ameliorated by the AC-NP treatments, compared to HFD + Lipitor. Lipitor encapsulation in NP formulation results in increased efficiency and reduced dose-related adverse effects known to be associated with the Lipitor chronic administration.

Efficient wound healing composite hydrogel using Egyptian Avena sativa L. polysaccharide containing ß-glucan.

The purpose of this study was to develop an efficient wound healing PVA-biopolymer composite hydrogel using the polysaccharide derived from Egyptian Avena sativa L. The prepared polysaccharide showed high ß-glucan content which accelerates wound healing. The ß-glucan content was 13.28% and GC analysis revealed that glucose was the major sugar component (71.19%). Different PVA-polysaccharide hydrogels combined with different polymers and loaded with 0.3% bacitracin zinc were developed using the freezing-thawing method. The used polymers were; polyvinylpyrrolidone (PVP), Carbopol 940 (CP), hydroxyethylcellulose (HEC), hydroxypropyl methylcellulose (HPMC), and sodium carboxymethylcellulose (Na CMC). The prepared hydrogels were characterized by determination of gel fraction, swelling ratio, mechanical and bioadhesive properties. The results revealed that hydrogels prepared using anionic (NaCMC and CP) and more hydrophilic (HEC) polymers showed better swelling ratio, bioadhesive and mechanical characters compared with hydrogels prepared using cationic (PVP) or less hydrophilic (HPMC) polymers. For two selected formulations containing HEC (F7) and NaCMC (F9), disk diffusion method and In vitro microbial penetration were performed for microbiological assessment. In addition, In vivo evaluation of the anti-inflammatory and wound healing activity compared with conventional products were performed on rats. The results showed higher anti-inflammatory activity of F7 (21.4% edema reduction) compared with F9 (19.8% edema reduction). Similarly, F7 showed better healing (99% relative wound size reduction) than F9 (75%). The current study revealed the potential of using the prepared Egyptian Avena sativa L. polysaccharide and HEC for development of an efficient wound healing dressing with antimicrobial and anti-inflammatory activities.

Efficacy and Safety Profiles of Oral Atorvastatin-Loaded Nanoparticles: Effect of Size Modulation on Biodistribution.

Atorvastatin calcium (AC)-loaded nanoparticles (NPs) of mean particle diameter <100 nm and narrow distribution were prepared and characterized. Their in vivo PK as well as PD measures following oral administration in different dosage regimens in hyperlipidemic rats were evaluated. The results revealed that the oral bioavailability of two selected AC-NPs formulations was 235% and 169% relative to Lipitor. However, the treatment regimens were not superior in reducing serum total cholesterol (TC), low-density lipoproteins (LDL), and triglycerides (TG) levels compared to Lipitor. Moreover, the AC-NPs treatments were associated with significant adverse effects observed biochemically and histologically. These results were contradictory with those obtained from a previous study in which similarly formulated AC-NPs of mean particle diameter >200 nm were found to be more safe and effective in reducing TC, LDL, and TG levels when administered to hyperlipiemic rats at reduced dosing frequency compared to daily dose of Lipitor despite their lower oral bioavailability. The discrepant correlation between pharmacokinetics (PK) and pharmacodynamics (PD) results was suggested to pertain to the different biodistribution profiles of AC-NPs depending on their sizes. Hereby, we provide a simple approach of particle size modulation to enhance the efficacy and safety of atorvastatin.

PD-PK evaluation of freeze-dried atorvastatin calcium-loaded poly-ε-caprolactone nanoparticles.

In this work lyophilized poly-ε-caprolactone nanoparticles (NPs) loaded with atorvastatin calcium (AC) were developed in an attempt to improve the in-vivo performance of AC following oral administration. The individual and combined effects of several formulation variables were previously investigated using step-wise full factorial designs in order to produce optimized AC-NPs with predetermined characteristics including particle size, drug loading capacity, drug release profile and physical stability. Four optimized formulations were further subjected in this work to lyophilization to promote their long-term physical stability and were fully characterized. The pharmacodynamics (PD)/pharmacokinetics (PK) properties of two optimized freeze-dried AC-NPs formulations showing acceptable long-term stability were determined and compared to a marketed AC immediate release tablet (Lipitor(®)) in albino rats. PD results revealed that the two tested formulations were equally effective in reducing low density lipoproteins (LDL) and triglycerides (TG) levels when given in reduced doses compared to Lipitor(®) and showed no adverse effects. PK results, on the other hand, revealed that the two freeze-dried AC-NPs formulations were of significantly lower bioavailability compared to Lipitor(®). Taken together the PD and PK results demonstrate that the improved efficacy obtained at reduced doses from the freeze-dried AC-NPs could be due to increased concentration of AC in the liver rather than in the plasma.