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.     

Solid lipid nanoparticles of Annona muricata fruit extract: formulation,optimization and in vitro cytotoxicity studies

The present study was aimed to develop Annona muricata fruit extract loaded solid lipid nanoparticles (SLNs) and explore its cytotoxic potential in vitro model of breast cancers. Extract loaded SLNs were successfully prepared by high-pressure homogenization followed by ultrasonication method and optimized using 2³ full factorial design. The extract loaded SLNs were characterized using different parameters such as particle size (PS), % entrapment efficiency (EE), zeta potential (ZP) and % cumulative drug release (CDR). The SLNs formulation was optimized on the basis of software analysis with an overall desirability factor. The PS and %EE of the optimized formulation were found to be 134.8?nm and 83.26%, respectively. The optimized formulation showed a CDR of 79.83% up to 48?h. In vitro cytotoxicity efficacy of extract loaded SLNs was determined using MTT and Apoptosis assay and compared to that of a free extract. The SLNs showed a notable apoptotic effect and better efficacy to kill MCF7 cancer cells as compared to free extract. Thus, extract loaded SLNs could be an alternative dosage form which possibly controls therapeutic action with reducing side effect.     

Sigma-2 receptor ligand anchored telmisartan loaded nanostructured lipid particles augmented drug delivery,cytotoxicity, apoptosis and cellular uptake in prostate cancer cells

Recently, the anticancer activity of telmisartan (TEL) has been discovered against prostate cancer. Nevertheless, despite favorable therapeutic profile, poor aqueous solubility and suboptimal oral bioavailability hamper the anticancer efficacy of TEL. Therefore, in this investigation, sigma-2 receptor ligand, 3-(4-cyclohexylpiperazine-1-yl) propyl amine (CPPA) anchored nanostructured lipid particles of telmisartan (CPPA-TEL-NLPs) were engineered using stearic acid for targeting prostate cancer, PC-3 cells. The mean particle size of TEL-NLPs was measured to be 25.4?±?3.2?nm, significantly (p?p?p?In vitro drug release study was conducted to determine the drug delivery potential of tailored nanoparticles. TEL-NLPs released 93.36% of drug significantly (p?50 of CPPA-TEL-NLPs was measured to be 20.3?µM significantly (p?50 of 41.3?µM, significantly (p?>?0.05) not different from 43.4?µM, exhibited by TEL-NLPs in PNT-2 cells. We elucidated that CPPA-TEL-NLPs entered the PC-3 cells via receptor mediated endocytosis pathway and thus exhibited superior cytotoxicity, apoptosis and greater extent of cellular uptake in PC-3 cells. In conclusion, CPPA-TEL-NLPs may be a promising nanomedicine and warrant further in vivo investigations for gaining clinical success.     

Design and synthesis of mixed micellar system for enhanced anticancer efficacy of Paclitaxel through its co-delivery with Naringin

Emergence of multidrug resistance (MDR) has limited the success of chemotherapeutic agents. Reversal of drugs efflux systems through combination therapy has got wider attention for increasing anticancer drugs efficacy. This study aims at co-encapsulation of Paclitaxel with Naringin in mixed polymeric micelles for enhanced anticancer activity of the drug. Drug-loaded micelles were prepared using two different amphiphilic block co-polymers and were characterized for morphology, size, zeta potential, drug encapsulation, in vitro release and stability using atomic force microscope (AFM), zetasizer, UV spectrophotometer, and FT-IR. MTT assay and fluorescence microscopy were used for in vitro cytotoxicity and cellular uptake studies. Nano-size micelles with spherical morphology and negative charge encapsulated 76.52?±?0.94% and 32.87 0.61% Paclitaxel and Naringin, respectively. The micelles were thermally stable and retained 87.05?±?0.69% and 92.88?±?2.17% Paclitaxel and Naringin upon one-month storage. Maximum drug release was achieved at fourth hour of the study for both the loaded drugs. Paclitaxel co-encapsulation with Naringin synergistically improved its intracellular uptake and 65% in vitro cytotoxicity against breast cancer cells was achieved at its lower dose of 15?µg/mL. Results suggest that co-encapsulation of Paclitaxel with Naringin in mixed micelles is an effective strategy for achieving its higher anticancer activity.     

Nanoethosomal formulation of gammaoryzanol for skin-aging protection and wrinkle improvement: a histopathological study

Background: Free radical scavengers and antioxidants, with the main focus on enhanced targeting to the skin layers, can provide protection against skin ageing.

Objective: The aim of the present study was to prepare nanoethosomal formulation of gammaoryzanol (GO), a water insoluble antioxidant, for its dermal delivery to prevent skin aging.

Methods: Nanoethosomal formulation was prepared by a modified ethanol injection method and characterized by using laser light scattering, scanning electronic microscope (SEM) and X-ray diffraction (XRD) techniques. The effects of formulation parameters on nanoparticle size, encapsulation efficiency percent (EE%) and loading capacity percent (LC%) were investigated. Antioxidant activity of GO-loaded formulation was investigated in vitro using normal African green monkey kidney fibroblast cells (Vero). The effect of control and GO-loaded nanoethosomal formulation on superoxide dismutase (SOD) and malondialdehyde (MDA) content of rat skin was also probed. Furthermore, the effect of GO-loaded nanoethosomes on skin wrinkle improvement was studied by dermoscopic and histological examination on healthy humans and UV-irradiated rats, respectively.

Results: The optimized nanoethosomal formulation showed promising characteristics including narrow size distribution 0.17?±?0.02, mean diameter of 98.9?±?0.05?nm, EE% of 97.12?±?3.62%, LC% of 13.87?±?1.36% and zeta potential value of –15.1?±?0.9?mV. The XRD results confirmed uniform drug dispersion in the nanoethosomes structure. In vitro and in vivo antioxidant studies confirmed the superior antioxidant effect of GO-loaded nanoethosomal formulation compared with control groups (blank nanoethosomes and GO suspension).

Conclusions: Nanoethosomes was a promising carrier for dermal delivery of GO and consequently had superior anti-aging effect.     

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.     

Development and characterization of cationic solid lipid nanoparticles for co-delivery of pemetrexed and miR-21 antisense oligonucleotide to glioblastoma cells

The practical use of solid lipid nanoparticles (SLNs) in research has been highlighted in the literature, but few reports have combined SLNs with miRNA-based therapy and chemotherapy. We aimed to prepare cationic SLNs (cSLNs) to load anti-miR-21 oligonucleotide and pemetrexed for glioblastoma therapy in vitro. cSLNs were employed to encapsulate both pemetrexed and anti-miR-21 by a high-pressure homogenization method, and then the properties of cSLNs were characterized. We studied cellular uptake and cytotoxicity properties of cSLNs in U87MG cells. cSLNs were 124.9?±?1.6?nm in size and 27.3?±?1.6?mV in zeta potential with spherical morphology in the TEM image. cSLNs uptake by U87MG cells was increased significantly higher and more effective than free pemetrexed. These findings suggest that cSLNs represent a potential new approach for carrying both pemetrexed and anti-miR-21 for glioblastoma therapy.     

Delivery of vinblastine-containing niosomes results in potent in vitro/in vivo cytotoxicity on tumor cells

Vinblastine (VB), as a chemotherapeutic agent, is widely used in treatment of different types of cancer. However, its clinical application is limited due to its low water solubility, side effects, and multidrug resistance. The aim of this study was to increase the therapeutic efficacy of VB using drug delivery systems. For this purpose, a PEGylated niosomal formulation of vinblastine (Pn-VB) was prepared by thin film hydration method and physicochemically characterized. Drug release pattern was performed by dialysis diffusion method. The cytotoxicity of Pn-VB was investigated against murine lung cancer TC-1 cells using MTT assay and its tumor inhibitory effect was evaluated in lung tumor-bearing C57BL/6 mice. Mean particle size, zeta potential, entrapment, and loading efficiency of niosomes were obtained to be about 234.3?±?11.4?nm, -34.6?±?4.2?mV, 99.92?±?1.6%, and 2.673?±?0.30%, respectively. While, the mean particle size and zeta potential for non-PEGylated niosomes were obtained about 212.4?nm and -31.4?mV, respectively. The in vitro release pattern of drug from niosomes showed a sustained release behavior. Pn-VB indicated a significant increase in toxicity against TC-l cells as compared to free VB. In animal model, Pn-VB exhibited stronger tumor inhibitory effect and longer life time in comparison to free VB. In conclusion, Pn-VB showed appropriate stability, high-entrapment efficacy, lower releasing rate, and stronger cytotoxic activity against lung cancer TC-1 cells as compared to free drug. Thus, the Pn-VB could be a promising formulation for delivery of vinblastine to tumor cells with enhanced drug bioavailability and therapeutic efficacy.     

Development of docetaxel nanocapsules for improving in vitro cytotoxicity and cellular uptake in MCF-7 cells

The aim of this study was to fabricate docetaxel loaded nanocapsules (DTX-NCs) with a high payload using Layer-by-Layer (LbL) technique by successive coating with alternate layers of oppositely charged polyelectrolytes. Developed nanocapsules (NCs) were characterized in terms of morphology, particle size distribution, zeta potential (ζ-potential), entrapment efficiency and in vitro release. The morphological characteristics of the NCs were assessed using transmission electron microscopy (TEM) that revealed coating of polyelectrolytes around the surface of particles. The developed NCs successfully attained a submicron particle size while the ζ-potential of optimized NCs alternated between (+) 34.64?±?1.5 mV to (?) 33.25?±?2.1 mV with each coating step. The non-hemolytic potential of the NCs indicated the suitability of the developed formulation for intravenous administration. A comparative study indicated that the cytotoxicity of positively charged NCs (F4) was significant higher (p?in vitro on MCF-7 cells. Furthermore, cell uptake studies evidenced a higher uptake of positive NCs (≥1.2 fold) in comparison to negative NCs. In conclusion, formulated NCs are an ideal vehicle for passive targeting of drugs to tumor cells that may result in improved efficacy and reduced toxicity of encapsulated drug moiety.     

Development and evaluation of nanosized niosomal dispersion for oral delivery of Ganciclovir

Encapsulation of Ganciclovir in lipophilic vesicular structure may be expected to enhance the oral absorption and prolong the existence of the drug in the systemic circulation. So the purpose of the present study was to improve the oral bioavailability of Ganciclovir by preparing nanosized niosomal dispersion. Niosomes were prepared from Span40, Span60, and Cholesterol in the molar ratio of 1:1, 2:1, 3:1, and 3:2 using reverse evaporation method. The developed niosomal dispersions were characterized for entrapment efficiency, size, shape, in vitro drug release, release kinetic study, and in vivo performance. Optimized formulation (NG8; Span60:Cholesterol 3:2 molar ratio) has shown a significantly high encapsulation of Ganciclovir (89?±?2.13%) with vesicle size of 144?±?3.47?nm (polydispersity index [PDI]?=?0.08). The in vitro release study signifies sustained release profile of niosomal dispersions. Release profile of prepared formulations have shown that more than 85.2?±?0.015% drug was released in 24?h with zero-order release kinetics. The results obtained also revealed that the types of surfactant and Cholesterol content ratio altered the entrapment efficiency, size, and drug release rate from niosomes. In vivo study on rats reveals five-time increment in bioavailability of Ganciclovir after oral administration of optimized formulation (NG8) as compared with tablet. The effective drug concentration (>0.69 µg/mL in plasma) was also maintained for at least 8?h on administration of the niosomal formulation. In conclusion, niosomes can be proposed as a potential oral delivery system for the effective delivery of Ganciclovir.     

Sustained release of piroxicam from solid lipid nanoparticle as an effective anti-inflammatory therapeutics in vivo

Abstract

This study aims to investigate the solid lipid nanoparticle (SLN) as a novel vehicle for the sustained release and transdermal delivery of piroxicam, as well as to determine the anti-inflammation effect of piroxicam-loaded SLN. SLN formulation was optimized and the particle size, polydispersity index, zeta potential (ZP), encapsulation efficiency, drug release, and morphological properties were characterized. The transdermal efficiency and mechanism of the piroxicam-loaded SLNs were investigated in vitro. With the inflammation induced edema model in rat, the anti-inflammatory efficiency of piroxicam-enriched SLNs (Pir-SLNs) was evaluated. The SLN formulation was optimized as: lecithin 100?mg, glycerin monostearate 200?mg, and Tween (1%, w/w). The particle size is around 102?±?5.2?nm with a PDI of 0.262. The ZP is 30.21?±?2.05?mV. The prepared SLNs showed high entrapment efficiency of 87.5% for piroxicam. There is no interaction between piroxicam and the vehicle components. The presence of polymorphic form of lipid with higher drug content in the optimized Pir-SLNs enables the Pir-SLNs to release the drug with a sustained manner. Pir-SLNs with oleic acid as enhancer can radically diffuse into both the stratum corneum and dermal layer, as well as penetrate through the hair follicles and sebaceous glands with significantly higher density than the other control groups. Pir-SLNs promptly inhibited the inflammation since the 3rd hour after the treatment by decreasing the PGE₂ level. SLN was demonstrated to be a promising carrier for encapsulation and sustained release of piroxicam. Pir-SLN is a novel topical preparation with great potential for anti-inflammation application.     

A comparative study of chitosan and poloxamer based thermosensitive hydrogel for the delivery of PEGylated melphalan conjugates

Abstract

Objective: Although the melphalan (ML) used extensively for the management of breast cancer, its clinical application is limited due to significant hemolytic activity. In the present work, a comparative analysis of two distinct in situ-based thermogelling polymers of PEGylated ML was performed.

Methods: Briefly, the PEGylated conjugate of the melphalan (MLPEG 5000) for local and sustained drug release action is loaded into two different thermogelling polymeric systems, namely chitosan- and poloxamer-based systems. The synthesized conjugate was loaded to a chitosan (MLP 5000) and poloxamer-based (MPX-CG) thermogelling injectable hydrogels. These thermogelling hydrogels were evaluated for in vitro hydrolysis, in vitro hemolytic activity. and in vitro anticancer activity.

Results: The lower percent cumulative hydrolysis was witness for both the hydrogels. MPX-CG and MLP 5000 hydrogels as predicted had shown lower percent cumulative hydrolysis of 3.31?±?0.1 and 1.67?±?0.1 after 6?h. The percentage hemolysis of MPX-CG and MLP 5000 even at a concentration of 32?µg/ml was found to be 39.23?±?1.24% and 34.23?±?2.24%, observed at 1?h, respectively. Both the hydrogels showed similar anticancer pattern, the MPX-CG hydrogel showed low cell viability of 8.4?±?1.1% at a concentration of 150?µM and the MLP-5000 hydrogel showed slight higher cell viability (13.12?±?5.4%) as compared with MPX-CG hydrogel.

Conclusion: Hence, from the present study it can be well understood that both the chitosan- and the poloxamer-based thermogelling hydrogel proves to be an effective drug delivery systems for the delivery of the PEGylated conjugates.     

An effective treatment approach of DPP-IV inhibitor encapsulated polymeric nanoparticles conjugated with anti-CD-4 mAb for type 1 diabetes

Nanotechnology based biomedical approaches and surface modification techniques made it easier for targeting specific site and improving the treatment efficacy. The present study reports on targeted polymeric nanoparticles conjugated with antibody as a site-specific carrier system for effective treatment of type 1 diabetes. Sitagliptin (SP)-loaded Poly (lactic-co-glycolic acid) (PLGA) nanoparticles (NP) were prepared by nanoprecipitation cum solvent evaporation method and were characterized in terms of morphology, size, surface charge, and entrapment efficiency. Optimized batch demonstrated a particle size of 105.24?nm, with significant entrapment efficacy. In vitro release studies exhibited a controlled release pattern of 67.76?±?1.30% in 24?h, and a maximum of 96.59?±?1.26% at the end of 48?h. Thiol groups were introduced on the surface of SP-NPs whose concentration on SP-NPs was 27?±?2.6?mmol/mol PLGA-NPs, anti-CD4 antibody clone Q4120 was conjugated to the thiolated SP-NPs via a sulfo-MBS cross-linker, ～70% conjugation was observed. The in vitro cytotoxicity studies performed on RIN-5?F cells for mAb-SP-NPs presented an IC₅₀ of 76?µg/mL, and the insulin release assay had revealed an increased release at 5.15?±?0.16?IU/mL. The results indicate that mAb-SP-NPs allowed a controlled release of SP and thereby produced insulin levels comparable with control. Therefore, mAb-SP-NPs system appears to be effective in the treatment of auto immune diabetes, subject to further analysis.     

Preparation and characterization of solid lipid nanoparticles of furosemide using quality by design

The present work aimed to synthesize solid lipid nanoparticles (SLNs) of Furosemide (FRSM). The parameter sensitivity analysis showed a significant effect of particle size and reference solubility on the AUC_0–∞, C_max and t_max. The FRSM-encapsulated SLNs were synthesized by the phase inversion temperature (PIT) technique using 3² factorial design. The optimal level of 221.28?mg of Compritol 888 ATO and 420?mg of Cremophor RH 40 showed a mean hydrodynamic diameter (MHD) of 25.54?±?0.57?nm, a polydispersity index (PdI) of 0.158?±?0.01, the % entrapment efficiency of 80.70?±?4.06%, percent dissolution efficiency of 71.72?±?1.52% and time elapsed for 50% drug release of 3.67?±?0.15?h. The PIT was determined using the turbidity method and the values ranged between 75°C and 73°C. Transmission electron microscopy (TEM) and atomic force microscopy (AFM) images represent spherical to sub-spherical and smooth surface of SLN. The Fourier transform-infrared (FTIR), differential scanning calorimetry (DSC) and x-ray diffraction (XRD) depict the drug-excipient compatibility. Korsmeyer–Peppas was found to be the best fit release kinetics model (R²?=?0.973; K-value?=?29.96 and release exponent?=?0.40), predicting the Fickian diffusion. The results advocate that the optimized formulation (OF) could promote the controlled release, and improve the physicochemical stability of the formulation. Hence, SLN could be a potential drug carrier for the peroral delivery of FRSM.     

Improved oral bioavailability of valsartan using proliposomes: design,characterization and in vivo pharmacokinetics

Abstract

The objective of our investigational work was to develop a proliposomal formulation to improve the oral bioavailability of valsartan. Proliposomes were formulated by thin film hydration technique using different ratios of phospholipids:drug:cholesterol. The prepared proliposomes were evaluated for vesicle size, encapsulation efficiency, morphological properties, in vitro drug release, in vitro permeability and in vivo pharmacokinetics. In vitro drug-release studies were performed in simulated gastric fluid (pH 1.2) and purified water using dialysis bag method. In vitro drug permeation was studied using parallel artificial membrane permeation assay (PAMPA), Caco-2 monolayer and everted rat intestinal perfusion techniques. In vivo pharmacokinetic studies were conducted in male Sprague Dawley (SD) rats. Among the proliposomal formulations, F-V was found to have the highest encapsulation efficiency of 95.6?±?2.9% with a vesicle size of 364.1?±?14.9?nm. The in vitro dissolution studies indicated an improved drug release from proliposomal formulation, F-V in comparison to pure drug suspension in both, purified water and pH 1.2 dissolution media after 12?h. Permeability across PAMPA, Caco-2 cell and everted rat intestinal perfusion studies were higher with F-V formulation as compared to pure drug. Following single oral administration of F-V formulation, a relative bioavailability of 202.36% was achieved as compared to pure valsartan.     

In vitro comparative evaluation of monolayered multipolymeric films embedded with didanosine-loaded solid lipid nanoparticles: a potential buccal drug delivery system for ARV therapy

Drug delivery via the buccal route has emerged as a promising alternative to oral drug delivery. Didanosine (DDI) undergoes rapid degradation in the gastrointestinal tract, has a short half-life and low oral bioavailability, making DDI a suitable candidate for buccal delivery. Recent developments in buccal drug delivery show an increased interest toward nano-enabled delivery systems. The advantages of buccal drug delivery can be combined with that of nanoparticulate delivery systems to provide a superior delivery system. The aim of this study was to design and evaluate the preparation of novel nano-enabled films for buccal delivery of DDI. Solid lipid nanoparticles (SLNs) were prepared via hot homogenization followed by ultrasonication and were characterized before being incorporated into nano-enabled monolayered multipolymeric films (MMFs). Glyceryl tripalmitate with Poloxamer 188 was identified as most suitable for the preparation of DDI-loaded SLNs. SLNs with desired particle size (PS) (201?nm), polydispersity index (PDI) (0.168) and zeta potential (?18.8?mV) were incorporated into MMFs and characterized. Conventional and nano-enabled MMFs were prepared via solvent casting/evaporation using Eudragit RS100 and hydroxypropyl methylcellulose. Drug release from the nano-enabled films was found to be faster (56% versus 20% in first hour). Conventional MMFs exhibited higher mucoadhesion and mechanical strength than nano-enabled MMFs. SLNs did not adversely affect the steady state flux (71.63?±?13.54?µg/cm²?h versus 74.39?±?15.95?µg/cm²?h) thereby confirming the potential transbuccal delivery of DDI using nano-enabled MMFs. Nano-enabled buccal films for delivery of DDI can be successfully prepared, and these physico-mechanical studies serve as a platform for future formulation optimization work in this emerging field.     

Formulation,optimization, and characterization of rifampicin-loaded solid lipid nanoparticles for the treatment of tuberculosis

Abstract

Mycobacterium tuberculosis, being the causative infectious agent, is the leading cause of death worldwide amongst the infectious disease. The low bioavailability of rifampicin (RIF), one of the vital constituent of antitubercular therapy, instigates an urge to develop nanocarrier, which can prevent its degradation in the acidic pH of the stomach. Solid lipid nanoparticles (SLNs) have been proven to be promising versatile platform for oral delivery of lipophilic drugs. Therefore, the current investigation demonstrates development of RIF-loaded solid lipid nanoparticles (RIF-SLNs) using high-pressure homogenization technique by employing a three-level, three-factor Box–Behnken design. Concentration of drug, concentration of emulsifier, and homogenization pressure were selected as an independent variables, and %drug loading (%DL), %entrapment efficiency (%EE), and particle size were selected as dependent variables. The developed RIF-SLNs were characterized for particle size, polydispersity index, zeta potential, %EE, %DL, differential scanning calorimetry, X-ray diffraction, and TEM analysis. The mean diameter of RIF-SLNs was found to be 456?±?11?nm, %EE of 84.12?±?2.78%, and %DL of 15.68?±?1.52%. The in vitro lipolysis experiments revealed that RIF-SLNs stabilized using poloxamer 188, exhibited antilipolytic effect. Furthermore, the in vitro GI stability studies (at pH 1.2, pH 4.5, pH 6.8, and pH 7.4) revealed that the developed system could withstand various gastrointestinal tract media. The in vitro dissolution studies depicted biphasic drug release profile for drug-loaded SLNs revealing best fit with Weibull model. The accelerated stability studies for 6?months does not revealed any significant change in characteristics of developed RIF-SLNs.     

Formulation development and accelerated stability testing of a novel sunscreen cream for ultraviolet radiation protection in high altitude areas

The present study is aimed at the development of a sunscreen cream for use in high altitude areas which have been found to possess superior sun protection factor (SPF) along with remarkable antioxidant activity. The topical formulation is a standard oil-in-water emulsion of a combination of United States Food and Drug Administration (US FDA) approved ultraviolet filters; along with melatonin and pumpkin seed oil. The in-silico optimized formulation was characterized using established methods and the stability study was carried out as per International Conference on Harmonization guidelines. The formulation was prepared after requisite pre-formulation analysis by Fourier-transform infrared spectroscopy, differential scanning calorimetric and thermogravimetric analyses; followed by characterization based on color, odor, phase separation, spreadability, specific gravity, homogeneicity, centrifugation and sensitivity. For the stability study, a total of three samples from three batches of the finished product were subjected to the stability study. The samples were analyzed for content uniformity, pH, in vitro SPF, rheology, zeta potential, droplet diameter and microbial analysis of the 0th day and also the the end of the storage period. Results obtained from the stability study indicated that the formulation possesses 50+ in vitro SPF value and remained stable for 6?months and 12?months under storage at 40?±?2?°C and 75?±?5% relative humidity; and ?20?°C?±?5?°C respectively.     

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.     

Formulation and pharmacokinetics of gelucire solid dispersions of flurbiprofen

Context: Development of solid dispersions is to improve the therapeutic efficacy by increasing the drug solubility, dissolution rate, bioavailability as well as to attain rapid onset of action.

Objective: The present research deals with the development of solid dispersions of flurbiprofen which is poorly water soluble to improve the solubility and dissolution rate using gelucires.

Materials and methods: In this study, solid dispersions were prepared following solvent evaporation method using gelucire 44/14 and gelucire 50/13 as carriers in different ratios. Then the formulations were evaluated for different physical parameters, solubility studies, DSC, FTIR studies and in vitro dissolution studies to select the best formulation that shows rapid dissolution rate and finally subjected to pharmacokinetic studies.

Results and discussion: From the in vitro dissolution study, formulation F3 showed the better improvement in solubility and dissolution rate. From the pharmacokinetic evaluation, the control tablets produced peak plasma concentration (C_max) of 9140.84?±?614.36?ng/ml at 3?h T_max and solid dispersion tablets showed C_max?=?11?445.46?±?149.23?ng/ml at 2?h T_max. The area under the curve for the control and solid dispersion tablets was 31?495.16?±?619.92 and 43?126.52?±?688.89?ng h/ml and the mean resident time was 3.99 and 3.68?h, respectively.

Conclusion: From the above results, it is concluded that the formulation of gelucire 44/14 solid dispersions is able to improve the solubility, dissolution rate as well as the absorption rate of flurbiprofen than pure form of drug.