Influence of Bile Salts on the Permeability Through the Nasal Mucosa of Rabbits of Insulin in Comparison with Dextran Derivatives

The nasal drug absorption and the effect of absorption promoters have been studied in rabbits. Nasal mucosa excised from rabbits was mounted as a flat sheet in an in vitro chamber. The result indicates that the change in the porosity of the membrane by pretreatment with bile salts increased the permeability coefficient of sodium chloride in the nasal membrane. The permeabilities of dextran derivatives were enhanced by pretreatment with sodium glycocholate (GC). The permeability coefficient (P) of fluorescein isothiocyanate diethylaminoethyl dextran     

Transport Characteristics of a Beta Sheet Breaker Peptide Across Excised Bovine Nasal Mucosa

ABSTRACT

The purpose of the present study was to investigate the permeation characteristics of the beta sheet breaker peptide AS 602704 (BSB) on excised bovine nasal mucosa using an Ussing chamber model. The influence of various absorption enhancers such as sodium cholate, sodium dodecyl sulfate (SDS), cetrimidum, sodium caprate, Na₂EDTA, polycarbophil (PCP), the thiomer conjugate polycarbophil-cysteine (PCP-Cys), and poly-l-arginine (poly-l-arg; 100 kDa) was evaluated. Additionally, the influence of temperature and pH on the transport rate as well as the stability of the peptide drug against enzymatic degradation were investigated in vitro.

The effective permeability coefficient (P_eff) of BSB in Krebs-Ringer-buffer (KRB) pH 7.4 was (1.89 ± 0.44)* 10^?5, while in the presence of sodium caprate (0.5%) a P_eff of (9.58 ± 1.82)*10^?5 was achieved. Rank order of enhancement ratio was sodium caprate > SDS > sodium cholate > Na₂EDTA > poly-l-arg = PCP-Cys. In case of cetrimidum and PCP even a decrease in the absorption of BSB was determined. Na₂EDTA reduced the enzymatic degradation of BSB when exposed to a nasal tissue homogenate by more than the half. An increased lipophilicity of BSB because of a more acidic milieu (pH 5.5) did not lead to an increased transcellular transport. Permeation studies carried out at 4°C compared to 37°C demonstrated a temperature dependent permeation behaviour suggesting an additional active carrier mediated transport.

The results obtained within these studies should facilitate the development of a nasal delivery system for AS 602704 for the treatment of Alzheimer's disease.     

Administration Route Dependent Bioavailability of Interferon-α and Effect of Bile Salts on the Nasal Absorption

Abstract

Administration route dependent bioavailability of recombinant human interferon alpha (IFN-α) and effect of seven bile salts and polyoxyethylene-9-lauryl ether (BL-9) on nasal absorption of IFN-a were studied in rats. IFN-a (1.5 × 10 ⁷ IU/kg) was administered through iv, pv, po and ip routes and AUC of the routes were compared. As a result, it was found that IFN-α is extracted almost completely during its passage through the GI lumen, and is not absorbed from the GI lumen. Moreover, IFN-α sparingly transported through the GI lumen suffers additional extraction by the GI mucosa (57%) and the liver (8%) consecutively and only about 40% of it can reach the systemic circulation. Therefore, a high bioavailability of IFN-a cannot be expected through the oral route even with the aid of absorption enhancers. On the other hand, significant absorption of IFN-α could be attained through the nasal route with some absorption enhancers (1% w/v). Among the enhancers examined, sodium cholate (CH), sodium glycocholate (GC), sodium taurocholate (TC), sodium glycodeoxycholate (GDC), sodium taurodeoxycholate (TDC) and BL-9 increased the nasal bioavailability of IFN-a. However, sodium dehydrocholate (DHC) and sodium deoxycholate (DOC) did not show such effect. Nasal bioavailability of IFN-a was increased up to 32.3 (± 15.5)% by 1% TC. The enhancing effect of TC was significantly (p<0.05) greater than those of CH, DOC, DHC and BL-9. TC and GC seemed to be potential candidates for the nasal absorption enhancers of IFN-α, considering that they are reportedly less toxic than GDC and TDC.     

Nasal absorption of sulfobromophthalein and amaranth

Abstract

Nasal absorption of sulfobromophthalein (BSP) and amaranth (AM) was investigated and compared with oral absorption in the rat. Bioavailability of BSP and AM after nasal administration was about 26% and 30% respectively. Oral absorption of them was not detected. Nasal route was considered more effective than oral route for these anionic model drugs, but their nasal bioavailability was not so good as expected from the reports for other drugs. High nasal mucus binding of BSP and AM were implied by their high binding to plasma protein (97% and 94%) or to intestinal mucus (78% and 81%). They seemed to have very low lipophilicity since their apparent partition coefficient(APC) between phosphate buffer of various pH and n-octanol were almost zero. They have too large molecular size to pass through the pore (<0.4nm) of nasal mucus membrane. Therefore it was concluded that the low nasal bioavailability of these anionic model drugs might be due to either nonspecific binding to nasal mucus, or low lipophilicity to pass the nasal mucus membrane, or their large molecular size to pass through the pore route of the nasal mucus. Possibility of nasal metabolism in the mucus membrane was excluded since the reported enzymes in the nasal mucus may not affect the metabolism of them.     

Systemic enhancement of papaverine transdermal gel for erectile dysfunction

To enhance the systemic transdermal delivery of papaverine for the treatment of erectile dysfunction, several factors that influence transdermal delivery of papaverine HCl were studied. The effects of membrane types for in vitro permeation study, human skin layers, solvent/cosolvent systems and the penetration enhancers on the transdermal permeation of papaverine HCl were investigated. A combination of caproic acid, ethanol and water in the volume ratio of 50%:30%:20% was chosen as penetration enhancer and incorporated in two gel bases: 18% Pluronic F-127 and 2% Carbopol 940. In vivo skin permeation studies were performed with two loading doses (0.6% and 2%) in rabbits. The flux and permeability coefficient of papaverine HCl through different human skin layers suggested that the major barrier layer for papaverine HCl was residing primarily in the stratum corneum. However, the viable epidermis and dermis layer also contributed certain degrees of diffusion resistance. Differential Scanning Calorimetry study showed that penetration enhancer exhibited a counter effect with papaverine HCl on the temperature and enthalpy in both gels. In vitro drug release study demonstrated significant increases in the steady-state flux, permeability coefficient and enhancement ratio in these gels. Faster drug transports and higher bioavailability were also observed in rabbits. Skin irritation test performed in rabbits demonstrated a mild skin reaction with mean PII scores of 2 and below; however the recovery was fast. In conclusion, caproic acid, ethanol and water in the volume ratio of 50%:30%:20% is an effective penetration enhancer to deliver papaverine HCl transdermally for systemic absorption.     

In vitro and in vivo effects of morin on the intestinal absorption and pharmacokinetics of olmesartan medoxomil solid dispersions

Abstract

Purpose: In-situ evaluation to corroborate morin effects on the intestinal absorption and pharmacokinetic behavior of freeze-dried OLM-loaded solid dispersions with Caco-2 and in-vivo studies

Methods: Intestinal transport and absorption studies were examined by Caco-2 permeability, in-situ single pass perfusion and closed-loop models along with in-vivo pharmacokinetic studies to evaluate and confirm the effect of P-gp-mediated activity of morin. We evaluated the intestinal membrane damage in the presence of morin by measuring the release of protein and lactate dehydrogenase (LDH) followed by using qualitative and quantitative morphometric analysis to describe the surface characteristics of intestinal epithelium.

Results: Morin showed the highest P_eff value 13.8?±?0.34?×?10^?6?cm/s in jejunum than ileum (p?<?.01) at 100?µM with absorption enhancement of 1.31-fold together with enhanced (p?<?.01) secretory transport of 6.27?±?0.27?×?10?^?6?cm/s in Caco-2 monolayer cells. Our findings noticed 2.37 (in-situ); 2.39 (in-vivo) and 1.43 (in-situ); 1.36 (in-vivo) fold increase in AUC_0–t with elevated C_max and shortened T_max for freeze-dried solid dispersion in the presence of morin as compared to pure OLM and freeze-dried solid dispersions without morin, respectively.

Conclusions: Our study demonstrated that increased solubilization through freeze-dried OLM-loaded solid dispersion together with efflux inhibition improved intestinal permeability to one system that might lead to novel solubilization and efflux pump inhibition as a novel alternative potential to increase oral absorption and bioavailability of OLM.     

Effect of Colloidal Carriers on the Disposition and Tissue Uptake of Doxorubicin: I. Conjugation with Oxidized Dextran Particles

Abstract

Dextrans are water soluble polymers of glucose, with varying molecular weights. The free hydroxyl groups offer attractive sites for conjugation of drugs with the potential for altering the pharmacokinetic profile of the drug. Doxorubicin is a useful anticancer drug with cardiotoxicity as its most serious side effect. This drug was conjugated to dextran in the following manner. A Schiffs base was formed by incubating oxidized dextran (generated using sodium periodate) with doxorubicin. This mixture was then reduced using sodium borohydride. The conjugates, in the size range of 20 nm, were studied in vitro for the maximum uptake and the release of the drug. In vivo, the conjugates showed a markedly altered disposition profile from the control group. The total body clearance of the drug associated with the conjugate decreased. Additionally, lower concentrations of the drug were found in the heart of animals treated with the conjugates indicating the possibility of reduced cardiotoxicity.     

Percutaneous Absorption of LHRH Through Porcine Skin: Effect of N-Methyl 2-Pyrrolidone and Isopropyl Myristate

Abstract

The effect of penetration enhancer (PE) on the in vitro permeability of luteinizing hormone-releasing hormone (LHRH) through porcine epidermis was investigated. The permeability coefficient of LHRH significantly increased (p < 0.05) through PE-(e.g., n-methyl 2-pyrrolidone [NMP], and isopropyl myristate [IPM]) treated epidermis in comparison to the control (without PE-pretreated epidermis). The higher permeability coefficient was observed with NMP followed by IPM. This shows that PE such as NMP and IPM can enhance the percutaneous absorption of peptides such as LHRH.     

Increased absorption of mangiferin in the gastrointestinal tract and its mechanism of action by absorption enhancers in rats

The therapeutic efficiency of mangiferin is restricted by its low intestinal permeability. In order to improve the oral absorption of mangiferin, potential of enhancers, including TPGS, sodium deoxycholate and Carbopol 974P, were investigated in a series of in vivo experiments. After administration of mangiferin at a dose of 30?mg/kg combining with sodium deoxycholate, the bioavailability of mangiferin increased four-fold, and this may be due to sodium deoxycholate weakening the compactness between lecithin molecules and increased the paracellular permeability. When Carbopol 974P (100?mg/kg) was combined with mangiferin, the oral bioavailability of it increased seven-fold compared with the control group, and this may be related to the mucoadhesive properties of Carbopol 974P and paracellular drug permeation. However, following coadministration of TPGS (50?mg/kg), the oral absorption of mangiferin increased slightly compared with that of the control group (p > 0.05). The increased oral absorption by the three coexcipients was in the order of Carbopol 974P > sodium deoxycholate > TPGS. The absolute bioavailability of mangiferin in the three different doses following oral administration were evaluated based on the AUC_(0–t) of the intravenous dose and there was no increase from low doses to high doses (25?mg/kg to 100?mg/kg). The above results show that the low absorption of mangiferin was due to presence of a narrow absorption window, which may also exist in these compounds, which have structures similar to mangiferin including three fused aromatic rings with polyphenolic hydroxyl groups. Bioadhesion polymers are effective enhancers of the absorption of mangiferin in the gastrointestinal tract.     

Mucosal Delivery of Progestational Steroids from a Controlled Release Device: In-Vitro/In-Vivo Relationships

Abstract

The mucosal delivery of progestational steroids from a model controlled release device was studied using female New Zealand White rabbits as the animal model. A controlled release device was developed which was suitable for nasal, rectal and vaginal application. The in-vitro permeation and in-vivo absorption of progesterone from the model controlled release device was investigated through the nasal, rectal and vaginal mucosa. The influence of penetrant hydrophilicity on the in-vitro permeation and in-vivo absorption from the controlled release device was also investigated using the mono-hydroxy, di-hydroxy and tri-hydroxy derivatives of progesterone. The results indicate that the nasal route demonstrates a significantly higher rate of in-vitro permeation and extent of in-vivo absorption than the rectal and vaginal mucosa. The in-vitro permeation rates and steady-state plasma concentrations achieved from the device tend to decrease with increasing penetrant hydrophilicity. A linear in-vitro/in-vivo correlation was obtained for all the mucosa studied. The slope of the relationship between the in-vitro and in-vivo data was similar for the rectal and vaginal mucosa. The results of this investigation agree with the results of a previous investigation with a solution formulation, and suggest that the hydrodynamic and/or membrane barrier properties of the nasal mucosa may from that of the rectal and vaginal mucosa.     

Tanshinol sustained-release pellets with absorption enhancer: optimization,characterization, pharmacokinetics and pharmacodynamics

The objective of this study was to develop tanshinol sustained-release pellets (TS–SRPs) for the treatment of angina. Considering the poor intestinal absorption of TS, sodium caprate (SC) was used as an absorption enhancer for bioavailability improvement. Single-pass intestinal perfusion in rats demonstrated that the permeability of TS was remarkably enhanced, when the weight ratio of TS to SC was 1:3. Then, the cores were prepared with TS, SC and MCC at a weight ratio of 1:3:16 via extrusion–spheronization, followed by coating with Eudragit^® RS30D/RL30D dispersion (9:1, w/w). In vitro release studies revealed that release methods and rotation rates had no significant effects on the drug release of optimized TS–SC–SRPs except for the dissolution media. The release behavior was characterized as non-Fick diffusion mechanism. The pellets possessed a dispersion-layered spherical structure and were stable during three months of storage at 40?°C/75% RH. Compared with TS immediate-release pellets, the AUC_0–24 in healthy rabbits was increased by 1.97-fold with prolonged MRT (p?相似文献   

Effect of Sodium Lauryl Sulphate and TweenR80 on the Therapeutic Efficacy of Glibenclamide Tablet Formulations in Terms of BSL Lowering in Rabbits and Diabetic Human Volunteers

Abstract

Glibenclamide has limited gastrointestinal absorption. Therefore, different concentrations of sodium lauryl sulphate and tween^R80 were included into the tablet formulations to increase the absorption of the drug and hence, to enhance the BSL lowering in rabbits and human volunteers suffering from maturity onset diabetes mellitus. It was found that the surfactants had enhanced both the rate and extent of BSL lowering in rabbits as well as in diabetic patients in higher concentrations present in the tablet formulations.     

Heating Effect in Biocompatible Magnetic Fluid

This work is devoted to the study of heating of a biocompatible magnetic fluid due to time-varying magnetic induction. The adsorption of dextran on magnetite particles was confirmed by IR spectroscopy. A considerable thickness of the surfactant layer (oleate sodium + dextran) of about 4.3 nm prevents the formation of clusters made of nanomagnetic particles as evidenced by the fact that no maxima of the ultrasound wave absorption coefficient corresponding to cluster formation have been detected. The results show that the observed heating effect may be applied in hyperthermia treatments especially in the preferable region of 500 – 800 kHz. An “H ²– law” observed for the dependence of the SAR on the square of the amplitude of the magnetic field demonstrates the presence of superparamagnetic particles in the ferrofluid. Paper presented at the Seventeenth European Conference on Thermophysical Properties, September 5-8, 2005, Bratislava, Slovak Republic.     

Nanoneurotherapeutics approach intended for direct nose to brain delivery

Abstract

Context: Brain disorders remain the world's leading cause of disability, and account for more hospitalizations and prolonged care than almost all other diseases combined. The majority of drugs, proteins and peptides do not readily permeate into brain due to the presence of the blood–brain barrier (BBB), thus impeding treatment of these conditions.

Objective: Attention has turned to developing novel and effective delivery systems to provide good bioavailability in the brain.

Methods: Intranasal administration is a non-invasive method of drug delivery that may bypass the BBB, allowing therapeutic substances direct access to the brain. However, intranasal administration produces quite low drug concentrations in the brain due limited nasal mucosal permeability and the harsh nasal cavity environment. Pre-clinical studies using encapsulation of drugs in nanoparticulate systems improved the nose to brain targeting and bioavailability in brain. However, the toxic effects of nanoparticles on brain function are unknown.

Result and conclusion: This review highlights the understanding of several brain diseases and the important pathophysiological mechanisms involved. The review discusses the role of nanotherapeutics in treating brain disorders via nose to brain delivery, the mechanisms of drug absorption across nasal mucosa to the brain, strategies to overcome the blood brain barrier, nanoformulation strategies for enhanced brain targeting via nasal route and neurotoxicity issues of nanoparticles.     

Effect of Various Lipid-Bile Salt Mixed Micelles on Transfer of Amphotericin-B Across the Everted Rat Intestine

Abstract

The effect of various lipid-bile salt mixed micelles on the transfer of Amphotericin B (AmB) across the everted rat intestine were investigated. The results indicated that both bile salt solutions and mixed micellar solutions alter membrane permeability and thereby significantly improved transfer of AmB across the membrane. Mixed micelles composed of mono olein and oleic acid with sodium desoxycholate markedly enhanced the intestinal transfer of AmB. On the other hand, Glyceryl monosterate with bile salts caused a small alteration of the permeability. The present study revealed that the therapeutic efficacy of poorly absorbable drugs can be improved by delivering the drug with mixed micelles based microcarrier systems.     

Development of a Soluplus budesonide freeze-dried powder for nasal drug delivery

Objective: The aim of this work was to develop an amorphous solid dispersions/solutions (ASD) of a poorly soluble drug, budesonide (BUD) with a novel polymer Soluplus^® (BASF, Germany) using a freeze-drying technique, in order to improve dissolution and absorption through the nasal route.

Significance: The small volume of fluid present in the nasal cavity limits the absorption of a poorly soluble drug. Budesonide is a corticosteroid, practically insoluble and normally administered as a suspension-based nasal spray.

Methods: The formulation was prepared through freeze-drying of polymer-drug solution. The formulation was assessed for its physicochemical (specific surface area, calorimetric analysis and X-ray powder diffraction), release properties and aerodynamic properties as well as transport in vitro using RPMI 2650 nasal cells, in order to elucidate the efficacy of the Soluplus–BUD formulation.

Results: The freeze-dried Soluplus–BUD formulation (LYO) showed a porous structure with a specific surface area of 1.4334?±?0.0178 m²/g. The calorimetric analysis confirmed an interaction between BUD and Soluplus and X-ray powder diffraction the amorphous status of the drug. The freeze-dried formulation (LYO) showed faster release compared to both water-based suspension and dry powder commercial products. Furthermore, a LYO formulation, bulked with calcium carbonate (LYO-Ca), showed suitable aerodynamic characteristics for nasal drug delivery. The permeation across RPMI 2650 nasal cell model was higher compared to a commercial water-based BUD suspension.

Conclusions: Soluplus has been shown to be a promising polymer for the formulation of BUD amorphous solid suspension/solution. This opens up opportunities to develop new formulations of poorly soluble drug for nasal delivery.     

Capsaicin pretreatment enhanced the bioavailability of fexofenadine in rats by P-glycoprotein modulation: in vitro,in situ and in vivo evaluation

Background and objective: Capsaicin is the main pungent principle present in chili peppers has been found to possess P-glycoprotein (P-gp) inhibition activity in vitro, which may have the potential to modulate bioavailability of P-gp substrates. Therefore, purpose of this study was to evaluate the effect of capsaicin on intestinal absorption and bioavailability of fexofenadine, a P-gp substrate in rats.

Methods: The mechanistic evaluation was determined by non-everted sac and intestinal perfusion studies to explore the intestinal absorption of fexofenadine. These results were confirmed by an in vivo pharmacokinetic study of oral administered fexofenadine in rats.

Results: The intestinal transport and apparent permeability (P_app) of fexofenadine were increased significantly by 2.8 and 2.6 fold, respectively, in ileum of capsaicin treated rats when compared to control group. Similarly, absorption rate constant (K_a), fraction absorbed (F_ab) and effective permeability (P_eff) of fexofenadine were increased significantly by 2.8, 2.9 and 3.4 fold, respectively, in ileum of rats pretreated with capsaicin when compared to control group. In addition, maximum plasma concentration (C_max) and area under the concentration-time curve (AUC) were increased significantly by 2.3 and 2.4 fold, respectively, in rats pretreated with capsaicin as compared to control group. Furthermore, obtained results in rats pretreated with capsaicin were comparable to verapamil (positive control) treated rats.

Conclusions: Capsaicin pretreatment significantly enhanced the intestinal absorption and bioavailability of fexofenadine in rats likely by inhibition of P-gp mediated cellular efflux, suggesting that the combined use of capsaicin with P-gp substrates may require close monitoring for potential drug interactions.     

COMPARISON OF NASAL INSULIN POWDERS PREPARED BY SUPERCRITICAL FLUID AND FREEZE-DRYING TECHNIQUES

ABSTRACT

In this study, the effect of drug loading on the nasal absorption of insulin was determined. Human insulin was loaded into different drug carriers by two methods: supercritical fluid processing and freeze-drying. The powder formulations were characterized and then evaluated after nasal administration to alloxan induced diabetic rabbits at a dose of 5U/kg and 7.5U/kg. The blood glucose levels and serum insulin levels were monitored for five hours after administration of insulin formulations. The drug carriers evaluated were: ammonium glycyrrhizinate (AG), polyacrylic acid (PAA), cross-linked polyacrylic acid (CPAA), polyethylene oxide (PEO) and chitosan (CHTN).

Nasal administration of AG infused with insulin by carbon dioxide resulted in absolute bioavailability of 9.81% as compared to 2.86% observed with same powder loaded with insulin by freeze-drying. 8.05% bioavailability was obtained with PAA powder loaded with insulin by carbon dioxide as compared to much lower absorption seen with freeze-dried formulation. Similarly a two fold increase in absolute bioavailability was observed when carbon dioxide infused CPAA powder formulation was compared to the lyophilized powder. Nasal administration of PEO and CHTN loaded with insulin by carbon dioxide resulted in bioavailabilities of 1.55% and 1. 18% respectively.

The drug-loading process seems to have a significant effect on nasal absorption of insulin. The powders loaded with insulin by carbon dioxide infusion resulted in significantly higher absorption. The exact mechanism is still not known and a possible explanation for increased absorption may be due to improved stability of insulin in carbon dioxide infused formulations. Among the powders evaluated, polyacrylic acid and ammonium glycyrrhizinate prepared by carbon dioxide infusion as drug-loading method seem to offer good potential for development of nasal powder dosage forms for insulin.     

The influence of bile salts on the distribution of simvastatin in the octanol/buffer system

Abstract

Introduction: Distribution coefficient (D) is useful parameter for evaluating drugs permeability properties across biological membranes, which are of importance for drugs bioavailability. Given that bile acids are intensively studied as drug permeation-modifying and -solubilizing agents, the aim of this study was to estimate the influence of sodium salts of cholic (CA), deoxycholic (DCA) and 12-monoketocholic acids (MKC) on distribution coefficient of simvastatin (SV) (lactone [SVL] and acid form [SVA]) which is a highly lipophilic compound with extremely low water solubility and bioavailability.

Methods: LogD values of SVA and SVL with or without bile salts were measured by liquid–liquid extraction in n-octanol/buffer systems at pH 5 and 7.4. SV concentrations in aqueous phase were determined by HPLC-DAD. Chem3D Ultra program was applied for computation of physico-chemical properties of analyzed compounds and their complexes.

Results: Statistically significant decrease in both SVA and SVL logD was observed for all three studied bile salts at both selected pH. MKC exerted the most pronounced effect in the case of SVA while there were no statistically significant differences between observed bile salts for SVL. The calculated physico-chemical properties of analyzed compounds and their complexes supported experimental results.

Conclusions: Our data indicate that the addition of bile salts into the n-octanol/buffer system decreases the values of SV distribution coefficient at both studied pH values. This may be the result of the formation of hydrophilic complexes increasing the solubility of SV that could consequently impact the pharmacokinetic parameters of SV and the final drug response in patients.     

Nanosuspension of efavirenz for improved oral bioavailability: formulation optimization,in vitro,in situ and in vivo evaluation

Context: Nanosuspensions (NSs) of poorly water-soluble drugs are known to increase the oral bioavailability.

Objectives: The purpose of this study was to develop NS of efavirenz (EFV) and to investigate its potential in enhancing the oral bioavailability of EFV.

Materials and methods: EFV NS was prepared using the media milling technique. The Box–Behnken design was used for optimization of the factors affecting EFV NS. Sodium lauryl sulfate and PVP K30 were used to stabilize the NS. Freeze-dried NS was completely re-dispersed with double-distilled filtered water.

Results: Mean particle size and zeta potential of the optimized NS were found to be 320.4?±?3.62?nm and –32.8?±?0.4 mV, respectively. X-ray diffraction and differential scanning calorimetric analysis indicated no phase transitions. Rate and extent of drug dissolution in the dissolution medium for NS was significantly higher compared to marketed formulation. The parallel artificial membrane permeability assay revealed that NS successfully enhanced the permeation of EFV. Results of in situ absorption studies showed a significant difference in absorption parameters such as K_a, t_1/2 and uptake percentages between lyophilized NS and marketed formulation of EFV. Oral bioavailability of EFV in rabbits resulting from NS was increased by 2.19-fold compared to the marketed formulation.

Conclusion: Thus, it can be concluded that NS formulation of EFV can provide improved oral bioavailability due to enhanced solubility, dissolution velocity, permeability and hence absorption.