Optimization of the lyophilization process for long-term stability of solid–lipid nanoparticles

Objectives: To optimize a lyophilization protocol for solid–lipid nanoparticles (SLNs) loaded with dexamethasone palmitate (Dex-P) and to compare the long-term stability of lyophilized SLNs and aqueous SLN suspensions at two storage conditions.

Materials and Methods: The effect of various parameters of the lyophilization process on SLN redispersibility was evaluated. A three month stability study was conducted to compare changes in the particle size and drug loading of lyophilized SLNs with SLNs stored as aqueous suspensions at either 4°C or 25°C/60% relative humidity (RH).

Results and Discussion: Of nine possible lyoprotectants tested, sucrose was shown to be the most efficient at achieving SLN redispersibility. Higher freezing temperatures, slower freezing rates, and longer secondary drying times were also shown to be beneficial. Loading of the SLNs with Dex-P led to slightly larger particle size and polydispersity index increases, but both parameters remained within an acceptable range. Drug loading and particle shape were maintained following lyophilization, and no large aggregates were detected. During the stability study, significant growth and drug loss were observed for aqueous SLN suspensions stored at 25°C/60% RH. In comparison, lyophilized SLNs stored at 4°C exhibited a consistent particle size and showed <20% drug loss. Other storage conditions led to intermediate results.

Conclusions: A lyophilization protocol was developed that allowed SLNs to be reconstituted with minimal changes in their physicochemical properties. During a three month period, lyophilized SLNs stored at 4°C exhibited the greatest stability, showing no change in the particle size and a minimal reduction in drug retention.     

The characterization,pharmacokinetic, and tissue distribution studies of TPGS-modified artesunate liposome in rats

Objective: The objective of this study (ARS-TPGS-Lipo) was to enhance the stability, encapsulation efficiency (EE), improve AUC, circulation time and liver targeting of ARS-TPGS-Lipo.

Methods: ARS-TPGS-Lipo was prepared by thin-film dispersion method and characterized by TEM. The EE, in vitro release and stability of ARS-TPGS-Lipo were detected by HPLC and UV. In addition to the safety evaluation, the pharmacokinetics and tissue distribution studies were also carried out after i.v. administration.

Results: The size, PDI, zeta potential, and EE of ARS-TPGS-Lipo were 126.7?±?9.9?nm, 0.182?±?0.016, ?10.1?±?1.43?mV, and 78.8?±?1.89%, respectively. ARS-TPGS-Lipo showed the slow-release effect in vitro release experiments. The AUC of ARS in the ARS-TPGS-Lipo group was 7.51 times higher than in the ARS group after i.v. administration and the circulation time was significantly prolonged. The tissue distribution results showed the components of artesunate and its metabolism DHA of the ARS-TPGS-Lipo group were much higher in liver than the ARS-Lipo group.

Conclusion: ARS-TPGS-Lipo was prepared successfully, which had the smaller vesicles size with a better PDI, better stability, higher EE, and slow-release. The results of safety evaluation indicated that ARS-TPGS-Lipo had no hematotoxicity and hepatorenal toxicity. The pharmacokinetic studies indicated ARS-TPGS-Lipo had higher AUC, longer circulation time and better liver targeting.     

Development and physico-mechanical characterization of carrageenan and poloxamer-based lyophilized matrix as a potential buccal drug delivery system

Context and objectives: The buccal mucosa presents a unique surface for non-invasive drug delivery and also avoids first-pass metabolism. The objective of this study was the formulation development of polymeric mucoadhesive lyophilized wafers as a matrix for potential buccal drug delivery.

Materials and methods: Differential scanning calorimetry (DSC) was used to develop an optimum freeze-cycle, incorporating an annealing step. The wafers were prepared by lyophilization of gels containing three polymers, κ-carrageenan (CAR 911), poloxamer (P407) and polyethylene glycol 600 (PEG 600). The formulations were characterized using texture analysis (for mechanical and mucoadhesion properties), hydration studies, thermogravimetric analysis (TGA), DSC, X-ray powder diffraction (XRPD) and scanning electron microscopy (SEM).

Results and discussion: DSC showed the eutectic temperature (12.8?°C) of the system where the liquid solution and pure solids both existed at a fixed pressure which helped determine the freeze-annealing cycle at 55?°C for 7?h. Mechanical resistance to compression, hydration and mucoadhesion studies showed that optimized wafers were obtained from aqueous gels containing 2% w/w CAR 911, 4% w/w P407 and 4.4% w/w PEG 600. TGA showed residual water of approximately 1% and SEM showed a porous polymeric network that made ease of hydration possible.

Conclusions: Lyophilized wafers by freeze-drying gels containing 2% w/w CAR 911, 4% w/w P407 and 4.4% w/w PEG 600 with optimum physico-mechanical properties has been achieved.     

Formulation design and optimization of novel soft glycerosomes for enhanced topical delivery of celecoxib and cupferron by Box–Behnken statistical design

Background: The present study describes glycerosomes (vesicles composed of phospholipids, glycerol and water) as a novel drug delivery system for topical application of celecoxib (CLX) and cupferron (CUP) compound.

Aim: The goal of this research was to design topical soft innovative vesicles loaded with CLX or CUP for enhancing the efficacy and avoiding systemic toxicity of CLX and CUP.

Methods: CLX and CUP loaded glycerosomes were prepared by hydrating phospholipid-cholesterol films with glycerol aqueous solutions (20–40%, v/v). Box–Behnken design, using Design-Expert® software, was the optimum choice to statistically optimize formulation variables. Three independent variables were evaluated: phospholipid concentration (X₁), glycerol percent (X₂) and tween 80 concentration (X₃). The glycerosomes particle size (Y₁), encapsulation efficiency percent (Y₂: EE %) and drug release (Y₃) were selected as dependent variables. The anti-inflammatory effect of CLX and CUP glycerosomal gel was evaluated by carrageenan-induced rat paw edema method followed by histopathological studies.

Results: The optimized formulations (CLX2* and CUP1*) showed spherical morphology under transmission electron microscopy, optimum particle size of 195.4?±?3.67?nm, 301.2?±?1.75?nm, high EE of 89.66?±?1.73%, 93.56?±?2.87%, high drug release of 47.08?±?3.37%, 37.60?±?1.89% and high cumulative amount of drug permeated in 8?h of 900.18?±?50.24, 527.99?±?34.90?µg.cm^?2 through hairless rat skin, respectively. They also achieved significant remarkable paw edema inhibition in comparison with the control group (p? Conclusion: Finally, the administration of CLX2* and CUP1* loaded glycerosomal gel onto the skin resulted in marked reduction of edema, congestive capillary and inflammatory cells and this approach may be of value in the treatment of different inflammatory disorders.     

Nanocrystal-based drug delivery system of risperidone: lyophilization and characterization

Objective: In the present work nanocrystal-based formulation of risperidone (RIS) was proposed to overcome solubility issue of RIS, while lyophilization technique was used effectively, for conversion of RIS nanosuspension to solid state.

Significance: RIS nanosuspension was developed and stabilized with a combination of polycaprolactone and Pluronic^® F-68 as stabilizers. With focus on critical parameters like nature of cryoprotectants and effect of eutectic temperature on properties of nanosuspension, the suitability of lyophilization technique in improving the physical stability of prepared nanosuspension was also evaluated. Additionally, the developed nanocrystals were also assessed for their solid states properties.

Methods: Various process parameters affecting average particle size and polydispersity index (PDI), viz. drug to surfactant ratio, solvent to anti-solvent ratio, stirring speed, type of stabilizer were optimized. Assessment of lyophilization as a suitable solidification technique (for conversion to powder form) was done with selective cryoprotectants (trehalose dihydrate and sorbitol).

Results: The formulation was found to be stable at 4?°C for 3 months with size, PDI and zeta potential of 214?±?3.4?nm, 0.120, and –10.2?±?0.90?mV, respectively. Release profile of developed nanosuspension showed cumulative % release of ～90% in initial 10?h whereas the value for the unprocessed drug was ～11% in same time frame.

Conclusions: These findings suggest that developed formulation was able to enhance water solubility of the drug effectively and can be potentially used in the management of psychotic disorders.     

Pharmacokinetic and pharmacodynamic studies of nisoldipine-loaded solid lipid nanoparticles developed by central composite design

Abstract

Objective: Nisoldipine (ND) is a potential antihypertensive drug with low oral bioavailability. The aim was to develop an optimal formulation of ND-loaded solid lipid nanoparticles (ND-SLNs) for improved oral bioavailability and pharmacodynamic effect by using a two-factor, three-level central composite design. Glyceryl trimyristate (Dynasan 114) and egg lecithin were selected as independent variables. Particle size (Y₁), PDI (Y₂) and entrapment efficiency (EE) (Y₃) of SLNs were selected as dependent response variables.

Methods: The ND-SLNs were prepared by hot homogenization followed by ultrasonication. The size, PDI, zeta potential, EE, assay, in vitro release and morphology of ND-SLNs were characterized. Further, the pharmacokinetic (PK) and pharmacodynamic behavior of ND-SLNs was evaluated in male Wistar rats.

Results: The optimal ND-SLN formulation had particle size of 104.4?±?2.13?nm, PDI of 0.241?±?0.02 and EE of 89.84?±?0.52%. The differential scanning calorimetry and X-ray diffraction analyses indicated that the drug incorporated into ND-SLNs was in amorphous form. The morphology of ND-SLNs was found to be nearly spherical by scanning electron microscopy. The optimized formulation was stable at refrigerated and room temperature for 3 months. PK studies showed that 2.17-fold increase in oral bioavailability when compared with a drug suspension. In pharmacodynamic studies, a significant reduction in the systolic blood pressure was observed, which sustained for a period of 36?h when compared with a controlled suspension.

Conclusion: Taken together, the results conclusively demonstrated that the developed optimal ND-SLNs caused significant enhancement in oral bioavailability along with pharmacodynamic effect.     

Fabrication of solid lipid nanoparticles of lurasidone HCl for oral delivery: optimization,in vitro characterization,cell line studies and in vivo efficacy in schizophrenia

Objective: The aim of the present investigation was to investigate the efficacy of solid lipid nanoparticles (SLNs) to enhance the absorption and bioavailability of lurasidone hydrochloride (LH) following oral administration.

Methods: The LH loaded SLNs (LH-SLNs) were prepared by high pressure homogenization (HPH) method, optimized using box Behnken design and evaluated for particle size (PS), entrapment efficiency (EE), morphology, FTIR, DSC, XRD, in vitro release, ex vivo permeation, transport studies across Caco-2 cell line and in vivo pharmacokinetic and pharmacodynamic studies.

Results: The LH-SLNs had PS of 139.8?±?5.5?nm, EE of 79.10?±?2.50% and zeta potential of ?30.8?±?3.5?mV. TEM images showed that LH-SLNs had a uniform size distribution and spherical shape. The in vitro release from LH-SLNs followed the Higuchi model. The ex vivo permeability study demonstrated enhanced drug permeation from LH-SLNs (>90%) through rat intestine as compared to LH-suspension. The SLNs were found to be taken up by energy dependent, endocytic mechanism which was mediated by clathrin/caveolae-mediated endocytosis across Caco-2 cell line. The pharmacokinetic results showed that oral bioavailability of LH was improved over 5.16-fold after incorporation into SLNs as compared to LH-suspension. The pharmacodynamic study proved the antipsychotic potential of LH-SLNs in the treatment of schizophrenia.

Conclusion: It was concluded that oral administration of LH-SLNs in rats improved the bioavailability of LH via lymphatic uptake along with improved therapeutic effect in MK-801 induced schizophrenia model in rats.     

Preparation and evaluation of Baicalin-loaded cationic solid lipid nanoparticles conjugated with OX26 for improved delivery across the BBB

Purpose: A novel brain targeting drug delivery system based on OX26 antibody conjugation on PEGylated cationic solid lipid nanoparticles (OX26-PEG-CSLN) was prepared.

Methods: The Baicalin-loaded PEGylated cationic solid lipid nanoparticles modified by OX26 antibody (OX26-PEG-CSLN) were prepared by emulsion evaporation–solidification at low temperature method. The immune-gold labeled OX26-PEG-CSLN was visualized by transmission electron microscopy. The mean diameter and zeta potential of OX26-PEG-CSLN, PEG-CSLN and CSLN were determined using a Zetasizer. The entrapment efficiency of OX26-PEG-CSLN, PEG-CSLN and CSLN was determined by ultrafiltration centrifugation method. And the solid-state characterization of OX26-PEG-CSLN and CSLN were analyzed by X-ray. Pharmacokinetics studies were conducted by in vivo microdialysis in rat cerebrospinal fluid.

Results: The results showed that the OX26-PEG-CSLN, PEG-CSLN and CSLN had average diameters of 47.68?±?1.65, 27.20?±?1.70 and 33.89?±?5.74?nm, Zeta potentials of ?0.533?±?0.115?mV, 11.200?±?0.500?mV and 11.080?±?1.170?mV and entrapment efficiencies of 83.03?±?0.01%, 92.90?±?3.50% and 97.83?±?0.19%, respectively. In the pharmacokinetics studies, the AUC value of OX26-PEG-CSLN was11.08-fold higher than that of the Baicalin solution (SOL) (p?p?>?0.05); the C_max value of OX26-PEG-CSLN was 7.88-fold higher than that of SOL (p?p?Conclusion: These results demonstrated OX26-PEG-CSLN could be a promising carrier to deliver drugs across the BBB for the treatment of brain diseases.     

Epinephrine doses delivered from auto-injectors stored at excessively high temperatures

Context: Prompt injection of epinephrine (adrenaline) from epinephrine auto-injectors (EAIs) is the primary treatment for anaphylaxis in out-of-hospital settings. Storage of EAIs at room temperature (25?°C) is advised; however, storage at excessively high temperatures sometimes occurs. To our knowledge, there are no previous publications on the doses of epinephrine ejected from EAIs after storage at such temperatures.

Objective: We examined the epinephrine doses delivered from activated EAIs stored constantly or cyclically at 70?°C.

Methods: Twenty-five in-date EAIs were stored constantly or cyclically at 70?°C (excessive heat) or 25?°C (controls) for 5?d or 10?d. EAIs were activated and the epinephrine doses in the ejected solutions were measured using HPLC-UV. The enantiomeric purity of epinephrine was also measured by HPLC-UV.

Results: Control EAIs ejected a volume of 0.300?±?0.006?mL containing 103.7?±?3.3% of labeled dose (LD). After 5?d or 10?d of constant storage at 70?°C and activation at 70?°C, EAIs ejected a volume of 0.367?±?0.008?mL containing 96.8?±?3.8% LD and 0.373?±?0.007?mL containing 77.7?±?3.3% LD, respectively. After 5?d of cyclic storage at 70?°C and cooling to 25?°C before activation, EAIs ejected a volume of 0.311?±?0.008?mL containing 87.2?±?1.9% LD. Under the experimental conditions of this study, the resultant chromatographic peaks of epinephrine solutions from all EAIs represented only the pure l-enantiomer of epinephrine.

Conclusion: EAIs should be stored under recommended conditions of the manufacturer. EAIs stored at excessively high temperatures cannot be used to treat humans while still hot, and when cooled, cannot be relied on to deliver the labeled epinephrine dose in anaphylaxis.     

Biodegradable nanoparticles for improved kidney bioavailability of rhein: preparation,characterization, plasma,and kidney pharmacokinetics

The aim of this work is to develop biodegradable nanoparticles for improved kidney bioavailability of rhein (RH). RH-loaded nanoparticles were prepared using an emulsification solvent evaporation method and fully characterized by several techniques. Kidney pharmacokinetics was assessed by implanting a microdialysis probe in rat's kidney cortex. Blood samples were simultaneously collected (via femoral artery) for assessing plasma pharmacokinetics. Optimized nanoparticles were small, with a mean particle size of 132.6?±?5.95?nm, and homogeneously dispersed. The charge on the particles was nearly zero, the encapsulation efficiency was 62.71?±?3.02%, and the drug loading was 1.56?±?0.15%. In vitro release of RH from the nanoparticles showed an initial burst release followed by a sustained release. Plasma and kidney pharmacokinetics showed that encapsulation of RH into nanoparticles significantly increased its kidney bioavailability (AUC_kidney/AUC_plasma?=?0.586?±?0.072), clearly indicating that nanoparticles are a promising strategy for kidney drug delivery.     

Formulation and characterization of bufadienolides-loaded nanostructured lipid carriers

Objective: The aim of this study was to design bufadienolides-loaded nanostructured lipid carriers (BU-NLCs) to reduce the degradation of drugs in rat plasma. Methods: BU-NLCs were prepared by a modified melt-emulsification ultrasonic technique and then characterized by particle size distribution, zeta potential, entrapment efficiency, differential scanning calorimetry, and X-ray diffraction. Results: The optimal formulation consisted of glyceryl monostearate 1.8%, medium-chain triglyceride 0.75%, oleic acid 0.45%, Lipoid E-80® 1.5%, Pluronic F68 1.0%, and sodium deoxycholate 0.25%. The particle size distribution and the range of zeta potential of BU-NLCs were 104.1 ± 51.2 nm and ?15 to ?20 mV, respectively. The entrapment efficiencies of the bufadienolides were all above 85%. In the enzymolysis study, the chemical stability of cinobufagin (C) in BU-NLCs was enhanced by being encapsulated in particles of NLC and adjusting the pH of the surrounding environment to 7.0. The half-life of C was 17-fold longer than that in bufadienolides solution. The in vitro release showed that the release from BU-NLCs was slower than from bufadienolides solution and followed the Weibull equation. Differential scanning calorimetry and X-ray diffraction showed that BU-NLC was in an amorphous state after lyophilization. Conclusion: These results indicated that NLC could be developed as a carrier with improved drug plasma stability and offering controlled drug release.     

Formulation and optimization of intranasal nanolipid carriers of pioglitazone for the repurposing in Alzheimer’s disease using Box-Behnken design

Growing evidence suggest that Alzheimer’s disease (AD), the most common cause of dementia among the elderly is a metabolic disorder associated with impaired brain insulin signaling. Hence, the diabetic drug can be a therapeutic option for the management AD. The researches in this area are ongoing and Pioglitazone (PIO) is one of the most investigated diabetic drug in AD. Eventhough PIO treatment was found to improve AD significantly in the preclinical models, the poor blood-brain barrier (BBB) permeability and serious peripheral side effects limited its success in the clinical trials. The objective of the present study was to formulate and optimize intranasal (IN) nano lipid carriers (NLC) of PIO for its targeted delivery to the brain. A Box-Behnken design was employed to optimize the effect of three independent variables on two dependent variables. The optimized formulation had a particle size (PS) of 211.4?±?3.54?nm and zeta potential of (ZP) of 14.9?±?1.09?mv. The polydispersibility index (PDI) and entrapment efficiency (EE) was found to be 0.257?±?0.108 and 70.18?±?4.5% respectively. Storage stability studies performed has confirmed the stability of NLCs at 4?°C and 25?°C. The in-vitro drug release study has exhibited a sustained release of drug from the NLC. The formulation was observed to improve the nasal permeability of PIO ex-vivo significantly. Toxicity studies were performed to confirm the safety of formulation for the in-vivo administration. In-vivo biodistribution study in rats has shown a direct transport of drug from the nose to brain from the IN-NLC.     

Cuboidal lipid polymer nanoparticles of rosuvastatin for oral delivery

The present work aimed to develop and characterize sustained release cuboidal lipid polymeric nanoparticles (LPN) of rosuvastatin calcium (ROS) by solvent emulsification-evaporation process. A three factor, two level (2³) full-factorial design was applied to study the effect of independent variables, i.e. amount of lipid, surfactant and polymer on dependent variables, i.e. percent entrapment efficiency and particle size. Optimized formulations were further studied for zeta potential, TEM, in vitro drug release and ex vivo intestinal permeability. Cuboidal nanoparticles exhibited average particle size 61.37?±?3.95?nm, entrapment efficiency 86.77?±?1.27% and zeta potential ?6.72?±?3.25?mV. Nanoparticles were lyophilized to improve physical stability and obtain free-flowing powder. Effect of type and concentration of cryoprotectant required to lyophilize nanoparticles was optimized using freeze-thaw cycles. Mannitol as cryoprotectant in concentration of 5-8% w/v was found to be optimal providing zeta potential ?20.4?±?4.63?mV. Lyophilized nanoparticles were characterized using FTIR, DSC, XRD and SEM. Absence of C=C and C–F aromatic stretch at 1548 and 1197?cm^?1, respectively, in LPN indicated coating of drug by lipid and polymer. In vitro diffusion of ROS using dialysis bag showed pH-independent sustained release of ROS from LPN in comparison to drug suspension. Intestinal permeability by non-everted gut sac model showed prolonged release of ROS from LPN owing to adhesion of polymer to mucus layer. In vivo absorption of ROS from LPN resulted in 3.95-fold increase in AUC_0–last and 7.87-fold increase in mean residence time compared to drug suspension. Furthermore modified tyloxapol-induced rat model demonstrated the potential of ROS-loaded LPN in reducing elevated lipid profile.     

Preparation and evaluation of self-assembly Soluplus®-sodium cholate-phospholipid ternary mixed micelles of docetaxel

Abstract

Ternary mixed micelles constituted of Soluplus^®, sodium cholate, and phospholipid were prepared as nano-delivery system of the anticancer drug, docetaxel. The formulation of docetaxel-loaded ternary mixed micelles (DTX-TMMs) with an optimized composition (Soluplus^®/sodium cholate/phospholipid= 3:2:1 by weight) were obtained. The main particle size of DTX-TMMs was 76.36?±?2.45?nm, polydispersity index (PDI) was 0.138?±?0.039, and the zeta potential was ?8.46?±?0.55?mv. The encapsulation efficiency was 94.24?±?4.30% and the drug loading was 1.25%. The critical micelle concentration value was used to assess the ability of carrier materials to form micelles. The results indicated that the addition of Soluplus^® to sodium cholate-phospholipid mixed micelles could reduce the critical micelle concentration and improve the stability. In vitro release studies demonstrated that compared with DTX-Injection group, the DTX-TMMs presented a controlled release property of drugs. In vivo pharmacodynamics results suggested that DTX-TMMs had the most effective inhibitory effect on tumor proliferation and had good biosafety. In addition, the relative bioavailability of mixed micelles was increased by 1.36 times compared with the DTX-Injection in vivo pharmacokinetic study indicated that a better therapeutic effect could be achieved. In summary, the ternary mixed micelles prepared in this study are considered to be promising anticancer drug delivery systems.     

Hyperoside nanocrystals for HBV treatment: process optimization,in vitro and in vivo evaluation

The aim of this study was to develop hyperoside (Hyp) nanocrystals to enhance its dissolution rate, oral bioavailability and anti-HBV activity. Hyp nanocrystals were prepared using high pressure homogenization technique followed by lyophilization. A Box–Behnken design approach was employed for process optimization. The physicochemical properties, pharmacokinetics and anti-HBV activity in vivo of Hyp nanocrystal prepared with the optimized formulation were systematically investigated. Hyp nanocrystals prepared with the optimized formulation was found to be rod shaped with particle size of 384?±?21?nm and PDI of 0.172?±?0.027. XRPD studies suggested slight crystalline change in drug. Dissolution rate obtained from Hyp nanocrystals were markedly higher than pure Hyp. The nanocrystals exhibited enhanced C_max (7.42?±?0.73 versus 3.80?±?0.66?mg/L) and AUC_0???t (193.61?±?16.30 versus 91.92?±?17.95?mg·h/L) with a 210.63% increase in relative bioavailability. Hyp nanocrystals exhibited significantly greater anti-HBV activity than Hyp. These results suggested that the developed nanocrystals formulation had a great potential as a viable approach to enhance the bioavailability of Hyp.     

Real time stability and viability prediction of the anticancer BCG after lyophilization

To test if trehalose could be a better cryoprotectant for BCG than the usually used lactose and predict viability of BCG during shelf-life, BCG was suspended into three stabilizer systems containing 15% w/v trehalose, trehalose–gelatin mixture (in ratio, 30:1 w/w) or lactose. Each formula was lyophilized and several quality parameters were tested before and after lyophilization including sterility, safety, viability, morphology and moisture content. Samples of lyophilized formulae were tested for their reconstitution time and others were charged to stability chambers at 5?°C for the performance of real time study. Shelf-life of each formula was estimated and correlation between moisture content and loss in viability was established at each time interval of the real time stability study. Sterility, safety and morphology were retained after lyophilization. Just after lyophilization, minute diminish in viability was observed in the presence of each stabilizer (0.02–0.05%). There was no significant difference in reconstitution time of the three lyophilized formulae. Lactose BCG had the highest shelf-life among the used cryoprotectants during the real time stability studies. Also, moisture content was highly correlated to viability with correlation coefficient ranged between 0.97 and 0.99 and so, the former could be used for prediction of viability throughout the vaccine shelf-life.     

The effect of nanoliposomal formulations on Staphylococcus epidermidis biofilm

Objective: The aim of the present study was to assess the in vitro antimicrobial activities of nanoliposomal formulations loaded with vancomycin or/and rifampin against the biofilm formed by Staphylococcus epidermidis at 37?°C under aerobic condition.

Materials and methods: Liposomal formulations were prepared by dehydration-rehydration (DRV) method and characterized for size, zeta potential and encapsulation efficacy. The ability of different formulations on eradication of bacterial biofilm was assessed through optical density ratio (OD_r) and the results implicate higher survival rates of S. epidermidis on biofilm. Positive control was defined as an OD_r?=?1.0.

Results: The zeta potential of anionic, cationic and PEGylated liposomes was ?35?±?2, 35?±?1 and 27?±?2?mV whereas the mean sizes of these liposomal formulations were 145?±?4, 134?±?1 and 142?±?6?nm, respectively. Encapsulation efficacy of rifampin and vancomycin was more than 60% and about 25%, respectively. Cationic liposomal rifampin lowered the OD_r to 0.61 and was the most effective formulations against S. epidermidis biofilm (p?Conclusion: The results of this study showed that rifampin-loaded liposomes were effective against bacterial biofilm.     

A pH-independent instantaneous release of flurbiprofen: a study of the preparation of complexes,their characterization and in vitro/in vivo evaluation

In this study, furbiprofen/hydroxypropyl-β-cyclodextrin (HPβCD) inclusion complexes were prepared to improve the drug dissolution and facilitate its application in hydrophilic gels. Inclusion complexes were prepared using a supercritical fluid processing and a conventional optimized co-lypholization method was employed as a reference. The entrapment efficacy and drug loading of both methods were investigated. Evaluation of drug dissolution enhancement was conducted in deionized water as well as buffer solutions of different pH. Carbopol 940 gels of both flurbiprofen and flurbiprofen/HPβCD inclusion complexes, with or without penetration enhancers, were prepared and percutaneous permeation studies were performed using rat abdominal skin samples. Formation of flurbiprofen/HPβCD inclusion complexes was confirmed by Fourier transform-infrared spectroscopy, differential scanning calorimetry, X-ray diffraction and scanning electron microscopy. The results obtained showed that SCF processing produced a higher EE (81.91?±?1.54%) and DL (6.96?±?0.17%) compared with OCL with values of 69.11?±?2.23% and 4.00?±?1.01%, respectively. A marked instantaneous release of flurbiprofen/HPβCD inclusion complexes prepared by SCF processing (103.04?±?2.66% cumulative release within 5?min, a 10-fold increase in comparison with flurbiprofen alone) was observed. In addition, this improvement in dissolution was shown to be pH-independent (the percentage cumulative release at pH 1.2, 4.5, 6.8 and 7.4 at 5?min was 95.19?±?1.71, 101.75?±?1.44, 105.37?±?4.58 and 96.84?±?0.56, respectively). Percutaneous permeability of flurbiprofen-in-HPβCD-in-gels could be significantly accelerated by turpentine oil and was related to the water content in the system. An in vivo pharmacokinetic study showed a 2-fold increase in C_max and a shortened T_max as well as a comparable relative bioavailability when compared with the commercial flurbiprofen Cataplasms (Zepolas^®). With their superior dissolution, these flurbiprofen/HPβCD inclusion complexes prepared by SCF processing could provide improved applications for flurbiprofen.     

Preparation,characterization, and pharmacokinetics study of a novel genistein-loaded mixed micelles system

Genistein (GEN), is a natural dietary isoflavone, has been reported to show anticancer activities. However, its poor aqueous solubility and oral bioavailability limit its clinical application. We designed a novel genistein-loaded mixed micelles (GEN-M) system composed of Soluplus^® and Vitamin E d-α-tocopheryl polyethylene glycol 1000 succinate (TPGS) were prepared by organic solvent evaporation aimed to overcome the challenges of GEN’s poor solubility and then further improve its oral bioavailability. The optimized, spherical-shaped GEN-M was obtained at a ratio of 10:1 (Soluplus^®:TPGS). The mean particle size of GEN-M was 184.7?±?2.8?nm, with a narrow polydispersity index (PDI) of 0.162?±?0.002. The zeta potential value of GEN-M was ?2.92?±?0.01?mV. The micelles solutions was transparent with blue opalescence has high the entrapment efficiency (EE) and drug loading (DL) of 97.12?±?2.11 and 3.87?±?1.26%, respectively. GEN-M was demonstrated a sustained release behavior when formed micelles shown in drug release in vitro. The solubility of GEN in water increased to 1.53?±?0.04?mg/mL after encapsulation. The permeability of GEN across a Caco-2 cell monolayer was enhanced, and the pharmacokinetics study of GEN-M showed a 2.42-fold increase in relative oral bioavailability compared with free GEN. Based on these findings, we conclude that this novel nanomicelles drug delivery system could be leveraged to deliver GEN and other hydrophobic drugs.     

Physical Characterization and Macrophage Cell Uptake of Mannan-Coated Nanoparticles

Abstract

Previously, we reported on a cationic nanoparticle-based DNA vaccine delivery system engineered from warm oil-in-water microemulsion precursors. In these present studies, the feasibility of lyophilizing the nanoparticles and their thermal properties were investigated. Also, the binding and uptake of the nanoparticles by a macrophage cell line were studied. The nanoparticles (prior to pDNA coating) were freeze-dried with lactose or sucrose as cryoprotectants. The stability of lyophilized nanoparticles at room temperature was monitored and compared to that of the aqueous nanoparticle suspension. The thermal properties of the nanoparticles were investigated using differential scanning calorimetry (DSC). The nanoparticles, coated or uncoated with mannan as a ligand, were incubated with a mannose receptor positive (MR+) mouse macrophage cell line (J774E), at either 4°C or 37°C to study the binding and uptake of the nanoparticles by the cells. It was found that lactose or sucrose (1–5%, w/v) was required for successful lyophilization of the nanoparticles. After 4 months of storage, the size of lyophilized nanoparticles did not significantly increase while those in aqueous suspension grew by over 900%. Unlike its individual components, emulsifying wax (m.p., ?55°C) and hexadecyltrimethyl ammonium bromide, the nanoparticles showed a melting point of ?90°C. Moreover, the DSC profile of the nanoparticles was different from that of the physical mixture of emulsifying wax and CTAB. After 1 hour incubation at 37°C, the uptake of mannan-coated nanoparticles was 50% higher than that of the uncoated nanoparticles. At 4°C and after one hour, the binding of the mannan-coated nanoparticles by J774E was over 2-fold higher than that of the uncoated nanoparticles. This increase in J774E binding could be abolished by preincubating the cells with free mannan, suggesting that the binding and uptake were receptor-mediated. In conclusion, the nanoparticles were lyophilizable, and lyophilization was shown to enhance the stability of the nanoparticles. DSC provided evidence that the nanoparticles were not a physical mixture of their individual components. Finally, cell binding and uptake studies demonstrated that the nanoparticles have potential application for cell-specific targeting.