Transfersomes--a novel vesicular carrier for enhanced transdermal delivery: development, characterization, and performance evaluation

This work describes the use of a novel vesicular drug carrier system called transfersomes, which is composed of phospholipid, surfactant, and water for enhanced transdermal delivery. The transfersomal system was much more efficient at delivering a low and high molecular weight drug to the skin in terms of quantity and depth. In the present study transfersomes and liposomes were prepared by using dexamethasone as a model drug. The system was evaluated in vitro for vesicle shape and size, entrapment efficiency, degree of deformability, number of vesicles per cubic mm, and drug diffusion across the artificial membrane and rat skin. The effects of surfactant type, composition, charge, and concentration of surfactant were studied. The in vivo performance of selected formulation was evaluated by using a carrageenan-induced rat paw edema model. Fluorescence microscopy by using rhodamine-123 and 6-carboxyfluorescein as fluorescence probe was performed. The stability study was performed at 4°C and 37°C. An in vitro drug release study has shown a nearly zero order release of drug and no lag phase. The absence of lag phase in comparison to liposomes and ointment is attributed to the greater deformability, which may account for better skin permeability of transfersomes. In vivo studies of transfersomes showed better antiedema activity in comparison to liposomes and ointment, indicating better permeation through the penetration barrier of the skin. This was further confirmed through a fluorescence microscopy study. Finally, it may be concluded from the study that complex lipid molecules, transfersomes, can increase the transdermal flux, prolong the release, and improve the site specificity of bioactive molecules.     

In vivo microdialysis for the evaluation of transfersomes as a novel transdermal delivery vehicle for cinnamic acid

In this study, cinnamic acid-loaded transfersomes were prepared and dermal microdialysis sampling was used in Sprague–Dawley rats to compare the amount of drug released into the skin using transfersomes as transdermal carriers with that released on using conventional liposomes. The formulation of cinnamic acid-loaded transfersomes was optimized by a uniform design through in vitro transdermal permeation studies. Hydration time was confirmed as a significant factor influencing the entrapment efficiency of transfersomes, further affecting their transdermal flux in vitro. The fluxes of cinnamic acid from transfersomes were all higher than those from conventional liposomes, and the flux from the optimal transfersome formulation was 3.01-fold higher than that from the conventional liposomes (p?in vivo microdialysis sampling method revealed that the dermal drug concentrations from transfersomes applied on various skin regions were much lower than those required with conventional liposomes. After the administration of drug-containing transfersomes and liposomes on abdominal skin regions of rats for a period of 10?h, the C_max of cinnamic acid from the compared liposomes was 3.21?±?0.25?μg/mL and that from the transfersomes was merely 0.59?±?0.02?μg/mL. The results suggest that transfersomes can be used as carriers to enhance the transdermal delivery of cinnamic acid, and that these vehicles may penetrate the skin in the complete form, given their significant deformability.     

Proniosomal gel-mediated transdermal delivery of bromocriptine: in vitro and ex vivo evaluation

Vesicular systems endow large opportunities for the transdermal delivery of therapeutics. The present study was designed to investigate the potential of a novel class of vesicular system ‘proniosome’ as a carrier for transdermal delivery of bromocriptine (BCT). Proniosome formulations were prepared by the coacervation-phase separation method and the influence of factors like surfactant type and its amount, lipid concentration, cholesterol amount and drug content were studied. Span 60 was the most appropriate surfactant, and yielded vesicle size and percentage encapsulation efficiency of 1.3 µm and 98.9%, respectively. The developed system was characterised w.r.t. morphology, transition temperature, drug release, skin permeation and skin irritancy. Proniosomes exhibited a sustained release pattern of BCT in vitro. Skin permeation study revealed high penetration of proniosomes with sustained release of BCT through rat skin. The optimised proniosomal formulation showed enhanced transdermal flux of 16.15 μg/cm²/h as compared to 3.67 μg/cm²/h for drug dispersion. The developed formulations were observed as non-irritant to the rat skin and were found as quite stable at 4 and 25 °C for 90 days w.r.t. vesicle size and drug content. The dried proniosomal formulation could act as a promising alternative to niosomes and preferably for transdermal delivery of BCT.     

Impact of various solid carriers and spray drying on pre/post compression properties of solid SNEDDS loaded with glimepiride: in vitro-ex vivo evaluation and cytotoxicity assessment

Development of self-nanoemulsifying drug delivery systems (SNEDDS) of glimepiride is reported with the aim to achieve its oral delivery. Lauroglycol FCC, Tween-80, and ethanol were used as oil, surfactant, and co-surfactant, respectively as independent variables. The optimized composition of SNEDDS formulation (F1) was 10% v/v Lauroglycol FCC, 45% v/v Tween 80, 45% v/v ethanol, and 0.005% w/v glimepiride. Further, the optimized liquid SNEDDS were solidified through spray drying using various hydrophilic and hydrophobic carriers. Among the various carriers, Aerosil 200 was found to provide desirable flow, compression, dissolution, and diffusion. Both, liquid and solid-SNEDDS have shown release of more than 90% within 10?min. Results of permeation studies performed on Caco-2 cell showed that optimized SNEDDS exhibited 1.54 times higher drug permeation amount and 0.57 times lower drug excretion amount than that of market tablets at 4?hours (p?p?>?.05, i.e. 0.74). The formulation was found stable with temperature variation and freeze thaw cycles in terms of droplet size, zeta potential, drug precipitation and phase separation. Crystalline glimepiride was observed in amorphous state in solid SNEDDS when characterized through DSC, PXRD, and FT-IR studies. The study revealed successful formulation of SNEDDS for glimepiride.     

Design and development of a safer non-invasive transungual drug delivery system for topical treatment of onychomycosis

Objective: The main objective of this study is to develop a safer non-invasive treatment for nail infections since the current treatment regimen has drawbacks like, incidence of systemic side-effects and higher cost. Proposed topical treatment on the other hand can drastically improve the situation, hence highly desirable. This work was undertaken with a hypothesis to develop a transungual microemulsion gel for topical treatment of onychomycosis.

Methods: Benzyl alcohol and isopropyl myristate were used as oil, Pluronic F68 as surfactant and ethanol as co surfactant, in double-distilled water and loading itraconazole as the model antifungal drug. Pseudo-ternary phase diagram was developed by titrating different ratios of total oil and water with total surfactant, and K_m ratio was fixed at 1:1. Microemulsion formulations were prepared based on the phase diagram and incorporated in gels by adding Carbopol 934P. Nail permeation enhancers like urea and salicylic acid were used to increase drug permeation through the nail plate. Parameters like drug loading, clarity, particle size distribution, drug entrapment efficiency (DEE), drug release profile, release kinetics and nail uptake were checked for the evaluation of the formulations.

Results: Complete release of drug from the formulation varied from 60 to 120?min. The optimized formulation had DEE of 92.75%, complete drug release in 60?min and highest nail uptake of 0.386%/mm² (39?µg of drug) with 5% urea as nail permeation enhancer.

Conclusion: The formulation may prove beneficial in safer treatment of onychomycosis.     

Improved oral delivery of valsartan from maltodextrin based proniosome powders

Proniosome powders proved to be the potential carriers for efficient oral delivery of lipophilic or amphiphilic drugs. Henceforth, an attempt was made to improve the oral delivery of valsartan by loading into maltodextrin based proniosome powders. The proniosome powders were prepared by varying the ratio of span 60 and cholesterol and evaluated for micromeritic properties and the results indicate acceptable flow properties. The formulation containing equimolar ratio of span 60 and cholesterol showed smaller vesicle size, high surface charge and entrapment efficiency. The formation of niosomes and surface morphology of optimized proniosome formulation was studied by optical and scanning electron microscopy, respectively. FT-IR, differential scanning calorimetry, and powder X-ray diffraction studies performed to understand the solid state properties of the drug reveal the absence of chemical interaction, drug transformation from crystalline to amorphous and molecular state. The in vitro dissolution study carried out in both simulated gastric and intestinal fluid demonstrate improved dissolution characteristics compared to pure drug. The augment in permeation enhancement from proniosome formulation across rat intestine suggest the potential of proniosome carriers for improved oral delivery of valsartan.     

Development and in vitro evaluation of a nanoemulsion for transcutaneous delivery

Objective: The purpose of this study is to develop a nanoemulsion formulation for its use as a transcutaneous vaccine delivery system.

Materials and methods: With bovine albumin-fluorescein isothiocyanate conjugate (FITC-BSA) as a vaccine model, formulations were selected with the construction of pseudo-ternary phase diagrams and a short-term stability study. The size of the emulsion droplets was furthered optimized with high-pressure homogenization. The optimized formulation was evaluated for its skin permeation efficiency. In vitro skin permeation studies were conducted with shaved BALB/c mice skin samples with a Franz diffusion cell system. Different drug concentrations were compared, and the effect of the nanoemulsion excipients on the permeation of the FITC-BSA was also studied.

Results: The optimum homogenization regime was determined to be five passes at 20?000?psi, with no evidence of protein degradation during processing. With these conditions, the particle diameter was 85.2?nm?±?15.5?nm with a polydispersity index of 0.186?±?0.026 and viscosity of 14.6 cP?±?1.2 cP. The optimized formulation proved stable for 1 year at 4?°C. In vitro skin diffusion studies show that the optimized formulation improves the permeation of FITC-BSA through skin with an enhancement ratio of 4.2 compared to a neat control solution. Finally, a comparison of the skin permeation of the nanoemulsion versus only the surfactant excipients resulted in a steady state flux of 23.44?μg/cm²/h for the nanoemulsion as opposed to 6.10?μg/cm²/h for the emulsifiers.

Conclusion: A novel nanoemulsion with optimized physical characteristics and superior skin permeation compared to control solution was manufactured. The formulation proposed in this study has the flexibility for the incorporation of a variety of active ingredients and warrants further development as a transcutaneous vaccine delivery vehicle.     

A modern approach for controlled transdermal delivery of diflunisal: optimization and in vivo evaluation

The purpose of the present work was to elaborate an optimized transdermal therapeutic system for diflunisal. Selection of suitable ingredients was done via solubility and phase behavior studies. Composition of microemulsion (ME) systems consisting of butyl lactate, Brij^® 97, Transcutol^® and water was optimized using augmented simplex lattice mixture design. The independent variables selected were the percentages of butyl lactate, surfactant mixture and water. The dependent variables were refractive index, pH, conductivity, viscosity, drug solubility in the ME formulation and the ex vivo skin permeation flux. Mathematical equations and response surface plots were used to relate the dependent and independent variables. The statistical validity of the polynomials was established. Optimized formulation factors were selected by desirability approach. The optimized ME formulation was converted into gel using Carbomer^® 934. The microemulsion based gel (MBG) showed better spreadability and 5.07-fold increase in the transdermal flux than Carbomer^® 934 gel. The in vivo antihyperalgesia assay performed on mice showed significant reduction of the licking time in the treated group compared to the control group. This demonstrated the reliability of the simplex lattice statistical design for predicting optimum ME formulation. The developed MBG proved its in vivo efficiency for transdermal delivery of diflunisal.     

Flurbiprofen-loaded niosomes-in-gel system improves the ocular bioavailability of flurbiprofen in the aqueous humor

The present work aimed to prolong the contact time of flurbiprofen (FBP) in the ocular tissue to improve the drug anti-inflammatory activity. Different niosome systems were fabricated adopting thin-film hydration technique and using the nonionic surfactant Span 60. The morphology of the prepared niosomes was characterized by scanning electron microscopy (SEM). Physical characterization by differential scanning calorimetry, X-ray powder diffraction and Fourier transform infrared spectroscopy were conducted for the optimized formula (F5) that was selected on the basis of percent entrapment efficiency, vesicular size and total lipid content. F5 was formulated as 1% w/w Carpobol 934 gel. Pharmacokinetic parameters of FBP were investigated following ocular administration of F5-loaded gel system, F5 niosome dispersion or the corresponding FBP ocular drops to albino rabbits dispersion. Anti-inflamatory effect of F5-loaded carbopol gel was investigated by histopathological examination of the corneal tissue before and after the treatment of inflamed rabbit eye with the system. Results showed that cholesterol content, surfactant type. and total lipid contents had an apparent impact on the vesicle size of the formulated niosomes. Physical characterization revealed reduced drug crystallinity and incidence of interaction with other niosome contents. F5-loaded gel showed higher C_max, area under the curve (AUC_0–12), and thus higher ocular bioavailability than those of the corresponding FBP ocular solution. F5-loaded gel showed a promising rapid anti-inflammatory effect in the inflamed rabbit eye. These findings will eradicate the necessity for frequent ocular drug instillation and thus, improve patient compliance.     

Formulation and ex vivo–in vivo evaluation of pH-triggered brimonidine tartrate in situ gel for the glaucoma treatment using application of 32 factorial design

Context: Short residence time, poor bioavailability and poor permeability are the major problems for conventional eye drops treatment.

Objective: The aim of this article is to develop, optimize and ex vivo–in vivo investigation of brimonidine tartrate in situ gel as compared to marketed eye drops for the treatment of glaucoma.

Materials and methods: The effect of independent variables, namely concentrations of polymers, on various dependent variables like viscosity at physiological pH and in vitro drug release were studied by using 3² factorial design. Further the optimized formulation was characterized for ex vivo and in vivo study.

Results and discussion: Experimental data demonstrated that optimized in situ gel formulation (F8) showed in vitro–ex vivo sustained release profile with polymer composites carbopol 974P and HPMC K4M. After 5?h of ex vivo transcorneal permeation study, the amount recovered from the corneal surface on the donor chamber 12.40% (124 ug) and the amount collected from the receptor chamber 76.8% (760 ug) of the initial dose 1?mg. The total amount recovered from the permeation experiment was 89.2%. Bioadhesive carbopol 974P and viscosity HPMC K4M composites optimized formulation (F 8) produce greater influence on the duration of drug action and improved intraocular pressure reduction activity as compared to marketed eye drop solution in in vivo study.

Conclusion: The developed in situ gelling system as a promising ophthalmic formulation to prolong the drug lowering effect on the intraocular pressure.     

Preparation and evaluation of a timolol maleate drug–resin ophthalmic suspension as a sustained-release formulation in vitro and in vivo

Abstract

The aim of this work was to assess the performance of resin as an ocular delivery system. Timolol maleate (TM) was chosen as the model drug and an ion exchange resin (IER) as the carrier. The drug–resin complex was prepared using an oscillation method and then characterized regarding particle size, zeta potential, morphology, and drug content. After in vitro drug release study and corneal permeation study were performed, in vivo studies were performed in New Zealand albino rabbits using a suspension with particles sized 4.8?±?1.2?μm and drug loading at 43.00?±?0.09 %. The results indicate that drug released from the drug–resin ophthalmic suspension permeated the cornea and displayed a sustained-release behavior. Drug levels in the ocular tissues after administration of the drug–resin ophthalmic suspension were significantly higher than after treatment with an eye drop formulation but were lower in body tissues and in the plasma. In conclusion, resins have great potential as effective ocular drug delivery carriers to increase ocular bioavailability of timolol while simultaneously reducing systemic drug absorption.     

Elastic liposomal formulation for sustained delivery of antimigraine drug: in vitro characterization and biological evaluation

The aim of this study was to prepare and characterize a topical formulation for sustained delivery of rizatriptan. Elastic liposomal formulation of rizatriptan was prepared and characterized for different characteristics by evaluating in vitro and in vivo parameters. The in vivo performance of optimized formulation was evaluated for antimigraine activity in mice using morphine withdrawal-induced hyperalgesia. The in vitro skin permeation study across rat skin suggested carrier-mediated transdermal permeation for different elastic liposomal formulation to range between 18.1 +/- 0.6 and 42.7 +/- 2.3 microg/h/cm(2), which was approximately 8-19 times higher than that obtained using drug solution. The amount of drug deposited was 10-fold higher for elastic liposome (39.9 +/- 3.2%) than using drug solution (3.8 +/- 1%); similarly the biological activity of optimized elastic liposome formulation was found to be threefold higher than the drug solution. On the basis of the results, it can be concluded that the elastic liposomal formulation provided sustained action of rizatriptan due to depot formation in the deeper layer of skin.     

Preparation and evaluation of optimized zolmitriptan niosomal emulgel

Objective: Novel niosomal formulation may be successfully applied to treat a systemic disease such as migraine through transdermal drug delivery system (TDDS), moreover, the treatment of topical diseases such as mycotic infections by targeting and localizing the drug to the stratum corneum. The current study aims to formulate zolmitriptan (Zt) in niosomal vesicles to potentiate its transdermal effect.

Significance: The development of a promising niosomal formulation will push the scaling up of pharmaceutical industry in this field.

Methods: Design- Expert 10 was used to design twelve formulations using Box-Behnken. Zt loaded niosomes were prepared by the thin film hydration method using Span 60(S 60), Span 80(S 80) along with cholesterol(Ch) at three different levels. The optimized formulation (F11) was formulated in Emulgel (1:1 emulsion/gel ratio).

Results: The vesicles revealed vesicle size (VS) ranging from 133.1 to 851.3?nm, zeta potential (ZP) ?43.8 to ?82.8?mV, entrapment efficiency (EE%) from 66.7 to 88.7%, and Zt release after 4?h up to 67%. Optimized niosomal formulation (F11) depicted the smallest VS (133.1?nm), highest EE (88.7%), high ZP (?80.6?mV) and satisfactory release after 4?h (61.5%). There was a significant difference (p <.05) in drug permeation after 8?h for niosomal F11(460.98?ug/cm²) and niosomal F11 loaded Emulgel (336.92?ug/cm²) compared to plain Zt loaded emulgel (160.83?ug/cm²). Niosomal F11 loaded emulgel showed thixotropic behavior of rapid recovery, significant bioavailability and pharmacokinetic parameters as compared to the plain Zt-loaded Emulgel.

Conclusion: Optimized F11 represents a promising formulation for transdermal drug delivery system to treat both topical and systemic diseases.     

Elastic Liposomal Formulation for Sustained Delivery of Antimigraine Drug: In Vitro Characterization and Biological Evaluation

The aim of this study was to prepare and characterize a topical formulation for sustained delivery of rizatriptan. Elastic liposomal formulation of rizatriptan was prepared and characterized for different characteristics by evaluating in vitro and in vivo parameters. The in vivo performance of optimized formulation was evaluated for antimigraine activity in mice using morphine withdrawal-induced hyperalgesia. The in vitro skin permeation study across rat skin suggested carrier-mediated transdermal permeation for different elastic liposomal formulation to range between 18.1 ± 0.6 and 42.7 ± 2.3 μg/h/cm², which was approximately 8–19 times higher than that obtained using drug solution. The amount of drug deposited was 10-fold higher for elastic liposome (39.9 ± 3.2%) than using drug solution (3.8 ± 1%); similarly the biological activity of optimized elastic liposome formulation was found to be threefold higher than the drug solution. On the basis of the results, it can be concluded that the elastic liposomal formulation provided sustained action of rizatriptan due to depot formation in the deeper layer of skin.     

Preparation, evaluation, and NMR characterization of vinpocetine microemulsion for transdermal delivery

A novel microemulsion was prepared to increase the solubility and the in vitro transdermal delivery of poorly water-soluble vinpocetine. The correlation between the transdermal permeation rate and structural characteristics of vinpocetine microemulsion was investigated by pulsed field gradient nuclear magnetic resonance (PFG-NMR). For the microemulsions, oleic acid was chosen as oil phase, PEG-8 glyceryl caprylate/caprate (Labrasol®) as surfactant (S), purified diethylene glycol monoethyl ether (Transcutol P®) as cosurfactant (CoS), and the double-distilled water as water phase. Pseudo-ternary phase diagrams were constructed to obtain the concentration range of each component for the microemulsion formation. The effects of various oils and different weight ratios of surfactant to cosurfactant (S/CoS) on the solubility and permeation rate of vinpocetine were investigated. Self-diffusion coefficients were determined by PFG-NMR in order to investigate the influence of microemulsion composition with the equal drug concentration on their transdermal delivery. Finally, the microemulsion containing 1% vinpocetine was optimized with 4% oleic acid, 20.5% Labrasol, 20.5% Transcutol P, and 55% double-distilled water (w/w), in which drug solubility was about 3160-fold higher compared to that in water and the apparent permeation rate across the excised rat skin was 36.4 ± 2.1 µg/cm²/h. The physicochemical properties of the optimized microemulsion were examined for the pH, viscosity, refractive index, conductivity, and particle size distribution. The microemulsion was stable after storing more than 12 months at 25°C. The irritation study showed that the optimized microemulsion was a nonirritant transdermal delivery system.     

Design and development of a novel pH triggered nanoemulsified in-situ ophthalmic gel of fluconazole: Ex-vivo transcorneal permeation,corneal toxicity and irritation testing

The objective of the present research was to develop a novel pH triggered nanoemulsified in-situ gel (NE-ISG) for ophthalmic delivery of fluconazole (FLZ) to enhance the permeation and residence time of the formulation, by overcoming the limitations associated with protective ocular barriers. Pseudoternary phase diagrams were constructed using capmul MCM (oil phase), tween 80 (surfactant) and transcutol P (cosurfactant) to identify the NE region. Nanoemulsions (NE1-NE6) of FLZ were prepared by spontaneous emulsification method and evaluated for various pharmacotechnical characteristics. NE4 was selected as optimized NE and was dispersed in carbopol 934 solution to form nanoemulsified sols (NE-ISG1 to NE-ISG5) that were expected to convert in to in-situ gels at corneal pH (7.4). The optimized NE-ISG was selected on the basis of gelation ability with a residence time up to or more than 6?h. Ex-vivo transcorneal permeation study displayed significantly higher (p?<?0.05) permeation of FLZ from NE-ISG5 (337.67 µg/cm²) and NE4 (419.30 µg/cm²) than the commercial eye drops (112.92 µg/cm²). Hen’s egg test-Chorioallantoic membrane (HET-CAM) test with zero score indicated the non-irritant property of developed NE-ISG5. Corneal toxicity study revealed no visual signs of tissue damage. Hence it can be concluded that NE-ISG5 may offer a more intensive treatment of ocular fungal infections due to higher permeation, prolonged precorneal residence time and sustained drug release along with higher in-vitro efficacy, safety and greater patient compliance.     

Nanoethosomes for transdermal delivery of tropisetron HCl: multi-factorial predictive modeling,characterization, and ex vivo skin permeation

Objective: The aim of the present work is to exclusively optimize and model the effect of phospholipid type either egg phosphatidylcholine (EPC) or soybean phosphatidylcholine (SPC), together with other formulation variables, on the development of nano-ethosomal systems for transdermal delivery of a water-soluble antiemetic drug. Tropisetron HCl (TRO) is available as hard gelatin capsules and IV injections. The transdermal delivery of TRO is considered as a novel alternative route supposing to improve BAV as well as patient convenience.

Methods: TRO-loaded ethanolic vesicular systems were prepared by hot technique. The effect of formulation variables were optimized through a response surface methodology using 3?×?2²-level full factorial design. The concentrations of both PC (A) and ethanol (B) and PC type (C) were the factors, while entrapment efficiency (Y₁), vesicle size (Y₂), polydispersity index (Y₃), and zeta potential (Y₄) were the responses. The drug permeation across rat skin from selected formulae was studied. Particle morphology, drug–excipient interactions, and vesicle stability were also investigated.

Results: The results proved the critical role of all formulation variables on ethosomal characteristics. The suggested models for all responses showed good predictability. Only the concentration of phospholipid, irrespective to PC type, had a significant effect on the transdermal flux (p?Conclusion: The study suggests the applicability of statistical modeling as a promising tool for prediction of ethosomal characteristics. The ethanolic vesicles were considered as novel potential nanocarriers for accentuated transdermal TRO delivery.     

Influence of Electrical Factors on In Vitro Iontophoretic Delivery of Timolol Maleate

The in vitro iontophoretic delivery of timolol maleate (TM) was carried out using a modified two-chambered, horizontal diffusion cell. The effect of various electrical factors on iontophoretic permeation of drug was analyzed. The iontophoretic permeation of TM through human cadaver skin was more greatly enhanced than the passive permeation. The increase in current intensity linearly increased the permeation of drug. The sine wave form showed the highest permeation than other wave forms used. Pulsed mode iontophoresis seems to be more efficient than constant current drug permeation through skin.     

Optimization of self-microemulsifying drug delivery systems (SMEDDS) using a D-optimal design and the desirability function

D-optimal design and the desirability function were applied to optimize a self-microemulsifying drug delivery system (SMEDDS). The optimized key parameters were the following: 1) particle size of the dispersed emulsion, 2) solubility of the drug in the vehicle, and 3) the vehicle compatibility with the hard gelatin capsule. Three formulation variables, PEG200, a surfactant mixture, and an oil mixture, were included in the experimental design. The results of the mathematical analysis of the data demonstrated significant interactions among the formulation variables, and the desirability function was demonstrated to be a powerful tool to predict the optimal formulation for the explored system.     

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.