Effects of liquisolid formulations on dissolution of naproxen

The aim of this study was to investigate the use of liquisolid technique in improving the dissolution profiles of naproxen in a solid dosage form. This study was designed to evaluate the effects of different formulation variables, i.e. type of non-volatile liquid vehicles and drug concentrations, on drug dissolution rates. The liquisolid tablets were formulated with three different liquid vehicles, namely Cremophor^® EL (polyoxyl 35 castor oil), Synperonic^® PE/L61 (poloxamer 181, polyoxyethylene-polyoxypropylene copolymer) and poly ethylene glycol 400 (PEG400) at two drug concentrations, 20%w/w and 40%w/w. Avicel^® PH102 was used as a carrier material, Cab-o-sil^® M-5 as a coating material and maize starch as a disintegrant. The empirical method as introduced by Spireas and Bolton (1999) [1] was applied strictly to calculate the amounts of coating and carrier materials required to prepare naproxen liquisolid tablets. Quality control tests, i.e. uniformity of tablet weight, uniformity of drug content, tablet hardness, friability test, disintegration and dissolution tests were performed to evaluate each batch of prepared tablets. In vitro drug dissolution profiles of the liquisolid formulations were studied and compared with conventional formulation, in simulated gastric fluid (pH 1.2) and simulated intestinal fluid (pH 7.2) without enzyme. Stability studies were carried out to evaluate the stability of the tablets under humid conditions. Differential scanning calorimetry and Fourier transform infrared were used to investigate physicochemical interaction between naproxen and the excipients. It was found that liquisolid tablets formulated with Cremophor^® EL at drug concentration of 20%w/w produced high dissolution profile with acceptable tablet properties. The stability studies showed that the dissolution profiles of liquisolid tablets prepared with Cremophor^® EL were not affected by ageing significantly. Furthermore, DSC revealed that drug particles in liquisolid formulations were completely solubilised.     

Liquisolid technology for dissolution rate enhancement or sustained release

Importance of the field: Most of the drugs that have been invented are of BCS Class II. Therefore, dissolution rate enhancement is the key aspect for absorption of these drugs. Liquisolid technology is very efficient in the dissolution rate enhancement of these drugs. Moreover, use of other polymers such as Eudragit and hydroxypropyl methylcellulose in the liquisolid approach can cause sustained release of drugs. This review focuses on the formulation approaches of liquisolid tablets or compacts along with its fundamental principles.

Areas covered in this review: The review focuses on the developments in liquisolid technology from 1998 to 2009 with in vitro and in vivo performance of the dosage forms prepared using this technology.

What the reader will gain: Benefits of this review include a concise evaluation of this technology by focusing on the scope of future developments to be done using this technique.

Take home message: Liquisolid technology, the next generation of powder solution technology, can be helpful for enhancing dissolution rates of poorly water-soluble drugs as well as effective at sustaining drug release.     

Enhancement of griseofulvin release from liquisolid compacts

The potential of hydrophilic aerogel formulations and liquisolid systems to improve the release of poorly soluble drugs was investigated using griseofulvin as model drug. The in vitro release rates of this drug formulated as directly compressed tablets containing crystalline griseofulvin were compared to aerogel tablets with the drug adsorbed onto hydrophilic silica aerogel and to liquisolid compacts containing the drug dissolved or suspended in PEG 300. Furthermore, the commonly used carrier and coating materials in liquisolid systems Avicel® and Aerosil® were replaced by Neusilin®, an amorphous magnesium aluminometasilicate with an extremely high specific surface area of 339 m²/g to improve the liquisolid approach.Both the liquisolid compacts containing the drug dissolved in PEG 300 and the aerogel tablets showed a considerably faster drug release than the directly compressed tablets. With liquisolid compacts containing the drug suspended in PEG 300, the release rate increased with rising fraction of dissolved drug in the liquid portion. It could be shown that Neusilin® with its sevenfold higher liquid adsorption capacity than the commonly used Avicel® and Aerosil® allows the production of liquisolid formulations with lower tablet weights.     

Liquisolid systems to improve the dissolution of furosemide

A liquisolid system has the ability to improve the dissolution properties of poorly water soluble drugs. Liquisolid compacts are flowing and compactable powdered forms of liquid medications. The aim of this study was to enhance the in vitro dissolution properties of the practically water insoluble loop diuretic furosemide, by utilising liquisolid technique. Several liquisolid tablets were prepared using microcrystalline cellulose (Avicel® pH-101) and fumed silica (Cab-O-Sil® M-5) as the carrier and coating materials, respectively. Polyoxy-ethylene-polyoxypropylene-polyoxyethylene block copolymer (Synperonic® PE/L 81); 1,2,3-propanetriol, homopolymer, (9Z)-9-octadecenoate (Caprol® PGE-860) and polyethylene glycol 400 (PEG 400) were used as non- volatile water-miscible liquid vehicles. The liquid loading factors for such liquid vehicles were calculated to obtain the optimum amounts of carrier and coating materials necessary to produce acceptable flowing and compactible powder admixtures viable to produce compacts. The ratio of carrier to coating material was kept constant in all formulations at 20 to 1. The formulated liquisolid tablets were evaluated for post compaction parameters such as weight variation, hardness, drug content uniformity, percentage friability and disintegration time. The in-vitro release characteristics of the drug from tablets formulated by direct compression (as reference) and liquisolid technique, were studied in two different dissolution media. Differential scanning calorimetry (DSC) and Fourier-Transform infrared spectroscopy (FT-IR) were performed. The results showed that all formulations exhibited higher percentage of drug dissolved in water (pH 6.4–6.6) compared to that at acidic medium (pH 1.2). Liquisolid compacts containing Synperonic® PE/L 81 demonstrated higher release rate at the different pH values. Formulations with PEG 400 displayed lower drug release rate, compared to conventional and liquisolid tablets. DSC and FT-IR indicated a possible interaction between furosemide and tablet excipients that could explain the dissolution results. Caprol® PGE-860, as a liquid vehicle, failed to produce furosemide liquisolid compacts.     

An investigation of physicochemical properties of piroxicam liquisolid compacts

The potential of liquisolid systems to improve the dissolution properties of a water-insoluble agent (piroxicam) was investigated. In this study, physicochemical properties of piroxicam liquisolid tablets, effect of aging, and type of the carrier were also investigated. To this end, several liquisolid tablets formulations containing various ratios of drug: solvent and different carriers were prepared. X-ray crystallography, differential scanning calorimetry (DSC), and contact angle measurement were used for evaluation of physicochemical properties of piroxicam. Liquisolid compacts exhibited significantly higher drug dissolution rates, in different dissolution media, than compacts prepared by the direct compression technique. The results showed that enhanced dissolution rate of piroxicam liquisolid tablets was due to an increase in wetting properties and surface area of drug available for dissolution. To investigate the effect of aging on the hardness and dissolution rate of liquisolid compacts, the formulations were stored at 25 degrees C/75% relative humidity for 9 months. The results showed that aging had no significant effect on hardness or dissolution profile of liquisolid tablets. It was shown that Avicel had more liquid retention potential than other carriers, but there were no significant differences in the dissolution profiles between formulations. The results of DSC and X-ray crystallography did not show any changes in crystallinity of the drug and interaction between piroxicam and exipients (Avicel and silica) during the process.     

Formulation factors affecting the release of ezetimibe from different liquisolid compacts

Context: Liquisolid technique is one of the methods used to improve the dissolution rate of the poorly water soluble drugs utilizing non volatile liquids.Objectives: Enhancement of the release of ezetimibe from different liquisolid formulations.Materials and Methods: Four liquid vehicles were used to prepare the liquid medications with different drug concentrations. The interaction between the drug and the excipients in liquisolid powders were characterized by DSC, X-ray, FTIR and SEM. Furthermore, the powder characteristics were evaluated by Carr’s Index and powder wetting time determinations, respectively. All prepared formulations were compressed at different pressures to end with the same constant porosity and the tablets were evaluated by different tests and compared with conventional formula. Results and Discussion: No interaction had been detected in all liquisolid formulations as shown in the results of XRD, FTIR, DSC and SEM. In addition to that, all liquisolid compacts had expressed faster dissolution profiles compared with that of conventional formula. Conclusion: The dissolution rate was affected by the drug concentration, solubility of the drug in the liquid vehicle and type of carrier. In addition, the presence of the liquid vehicle has been found to affect the mechanical properties of the liquisolid formulations.     

Preparation and in vitro dissolution of salbutamol sulphate microcapsules and tabletted microcapsules

Abstract

Salbutamol sulphate is a sympathomimetic amine having a rather short plasma half-life. Aiming to achieve sustained release of this drug through microencapsu-lation, the coacervation method with a 1:1 core-shell ratio was used. In vitro release rate experiments were performed on the microcapsules prepared using ethyl cellulose as the coating agent and compared to the results of intact drug, the tabletted microcapsules and a commercial tablet. The release rate of salbutamol sulphate could be controlled through microencapsulation. The time for the 50% release of the drug was 15 and 90 min for the tabletted microcapsules and microcapsules respectively. The specific surface area of the intact drug was 0.35m²/cc while it reduced to 0.06m²/cc after encapsulation.     

Liquisolid Tablets for Dissolution Enhancement of a Hypolipidemic Drug

This investigation was aimed to improve the dissolution rate of the poorly soluble drug lovastatin, by formulating it as a liquisolid compact. Different liquisolid compacts were prepared using mathematical formulae to calculate the required quantities of powder and liquid ingredients to produce acceptably flowable and compressible admixture. Avicel PH 200, Cab-O-Sil, sodium starch glycolate and PEG 400 were employed as carrier, coating material, disintegrant and non-volatile liquid vehicle, respectively. The various drug to liquid and carrier to coating ratio were used to prepare liquisolid compacts. The formulated liquisolid tablets were evaluated for weight variation, hardness, drug content, friability and disintegration time. The in vitro release characteristics of the drug from tablets formulated by direct compression and liquisolid technique were compared in two different dissolution media. The tableting properties of the liquisolid compacts were within the acceptable limits and drug release rates were distinctly higher as compared to directly compressed tablets. The FTIR spectra showed no interaction between drug-excipient and disappearance of the characteristic absorption band of lovastatin in liquisolid formulations could be attributed to the formation of hydrogen bonding between the drug and liquid vehicle, which resulted in dissolution enhancement. Thus, the liquisolid technique was found to be a promising approach for improving the dissolution of a poorly soluble drug like lovastatin.     

Preparation of Controlled-Release Coevaporates of Dipyridamole by Loading Neutral Pellets in a Fluidized-Bed Coating System

Purpose. The purpose of this study was to demonstrate that it is possible to prepare controlled-release drug-polymer coevaporates on an industrial scale, omitting the recovery problems and the milling and sieving processes encountered when coevaporates are prepared by the conventional solvent-evaporation technique. Methods. Controlled-release coevaporates were prepared by spraying organic solutions of dipyridamole-Eudragit^® blends onto neutral pellets using the fluidized-bed coating method. Enteric acrylic polymers Eudragit^® L100-55, L, and S were used as dispersing agents and drug/polymer ratio 2:8 was selected for all formulations. Polarized light microscopy, X-ray diffraction spectroscopy, and differential scanning calorimetry were used to determine whether the drug was amorphous or crystalline in the coating films. Moreover, in vitro dissolution tests were performed on the dipyridamole coated pellets in test media simulating the pH variations in the GI tract and the results were compared to the release data obtained from coevaporates prepared by the conventional solvent-evaporation method. Results. All the results clearly indicate that dipyridamole is amorphous in the coating films deposited on neutral pellets as well as in coevaporate particles obtained by the conventional solvent-evaporation method. When the release patterns of the dipyridamole coated pellets are compared to those of the drug coevaporate particles prepared with the same enteric acrylic polymers, the results show similar dissolution trends. Conclusions. The results obtained indicate that pelletization can be considered as a method of choice for pilot plant and/or full-scale production of controlled-release dosage forms based on the formation of amorphous solid dispersions.     

An in situ crosslinked compression coat comprised of pectin and calcium chloride for colon-specific delivery of indomethacin

Abstract

The use of pectin for colon-specific drug delivery has been extensively investigated; however, when used alone, pectin is often compromised due to its high solubility. This study explored the feasibility of using an in situ compression-coated crosslinking system, composed of pectin and calcium chloride, for colon-specific drug delivery. A pectin/calcium chloride (P/Ca) coating was compressed onto a core tablet. The colon specificity of the compression-coated tablet was verified by dissolution, pharmacokinetics and scintigraphy with ^99mTc labeling. The in situ pectin and calcium chloride gel slowed the release of indomethacin. The lag time varied between 3?h and 7?h depending on the amount of calcium chloride and the coating weight. Pectinase triggered the release of indomethacin from the compression-coated tablet, which was then accelerated by the calcium chloride in the coating layer. The compression-coated tablet had a prolonged t_max and apparent t_1/2, as well as a decreased C_max and AUC_0–t, compared with the core tablet counterpart. Evaluation with γ-scintigraphy verified colon-specific delivery of the compression-coated tablet. In conclusion, the P/Ca in situ crosslinking system worked well for colon-specific drug delivery.     

Multiple response optimisation of processing and formulation parameters of pH sensitive sustained release pellets of capecitabine for targeting colon

Purpose: To optimise the Eudragit/Surelease^®-coated pH-sensitive pellets for controlled and target drug delivery to the colon tissue and to avoid frequent high dosing and associated side effects which restrict its use in the colorectal-cancer therapy.

Methods: The pellets were prepared using extrusion-spheronisation technique. Box–Behnken and 3² full factorial designs were applied to optimise the process parameters [extruder sieve size, spheroniser-speed, and spheroniser-time] and the coating levels [%w/v of Eudragit S100/Eudragit-L100 and Surelease^®], respectively, to achieve the smooth optimised size pellets with sustained drug delivery without prior drug release in upper gastrointestinal tract (GIT).

Results: The design proposed the optimised batch by selecting independent variables at; extruder sieve size (X₁?=?1?mm), spheroniser speed (X₂?=?900 revolutions per minute, rpm), and spheroniser time (X₃?=?15?min) to achieve pellet size of 0.96?mm, aspect ratio of 0.98, and roundness 97.42%. The 16%w/v coating strength of Surelease^® and 13%w/v coating strength of Eudragit showed pH-dependent sustained release up to 22.35?h (t_99%). The organ distribution study showed the absence of the drug in the upper part of GIT tissue and the presence of high level of capecitabine in the caecum and colon tissue. Thus, the presence of Eudragit coat prevent the release of drug in stomach and the inner Surelease^® coat showed sustained drug release in the colon tissue.

Conclusion: The study demonstrates the potential of optimised Eudragit/Surelease^®-coated capecitabine-pellets for effective colon-targeted delivery system to avoid frequent high dosing and associated systemic side effects of drug.     

Preparation of pH-dependent modified-release pellets of urapidil to improve its bioavailability

Objective: Modified-release pellets containing urapidil were developed and its in vivo bioavailability was investigated.

Methods: Lactose and MCC were used as the main fillers to prepare drug-layer pellets by the powder layering method using centrifugal granulation, and coated in a fluidized bed coater. Pellets with different drug release characteristics were prepared with a methacrylic acid copolymer aqueous dispersion.

Results: Using commercial German capsules as the reference (R), two coating formulations were selected for tests after optimization: pH-dependent pellets with a ratio of Eudragit^® NE30D/L30D55 of 10:1, a 3% coating level (T₁), and pH-independent pellets with a Eudragit^® NE30D coating level (T₂) of 3.5%. The bioavailability of the pellets (T₁, T₂, containing 30?mg urapidil) was determined in six healthy subjects after oral administration of a single dose, for a period of three weeks, in the form of a crossover design with a wash-out period of one week. The plasma concentrations of urapidil were determined by HPLC with UV detection. The C_max (maximum concentration), T_max, and MRT of T₁ were 311.7?ng/mL, 5.3?h and 8.3?h, respectively. T₁ was bioequivalent to R, with a relative bioavailability 110.9%. The C_max and T_max, of T₂ were 105.3?ng/mL and 13.3?h, respectively, and the relative bioavailability was 72.7%.

Conclusion: The pH-dependent urapidil pellets have a high bioavailability.     

Enhanced oral delivery of risperidone through a novel self-nanoemulsifying powder (SNEP) formulations: in-vitro and ex-vivo assessment

Context: The oral delivery of risperidone encounters a number of problems, such as pH dependent solubility and low bioavailability, due to its lipophilicity and aqueous insolubility.

Objective: To improve the solubility, dissolution and intestinal permeation thereby bioavailability of risperidone through a novel self-nanoemulsifying powder (SNEP) formulations.

Materials and methods: Oleic acid, Tween^® 20, PEG 600 and Aerosil^® 200 were chosen as oil, surfactant, co-surfactant and carrier, respectively from solubility and emulsification studies. Ternary phase diagram was constructed to determine emulsifying region.

Results and discussion: The Z-average and polydispersity Index of developed formulation was 83.1?nm and 0.306, respectively. Ex vivo permeation studies on isolated rat intestine indicated that the amount of risperidone permeated from SNEP formulation was increased around 4- and 1.8-fold than that of pure drug and marketed formulation, respectively.

Conclusion: This developed SNEP formulations can be regarded as novel and commercially feasible alternative to the current risperidone formulations.     

Microencapsulation of terbutaline sulphate by the solvent evaporation technique

Abstract

Terbutaline sulphate microcapsules were prepared by coacervation-phase separation (solvent evaporation) technique using ethyl cellulose as a coating material. Acetone, ethyl alcohol and isopropyl alcohol were employed as solvents for coating material. Microcapsules were evaluated for their drug content, particle size distribution (microscopic method), flow properties, bulk density, in vitro dissolution, drug release kinetics and surface characteristics (scanning electron microscopy).     

Preparation,preliminary pharmacokinetics and brain tissue distribution of Tanshinone IIA and Tetramethylpyrazine composite nanoemulsions

Objective: Tanshinone IIA (TSN) and Tetramethylpyrazine (TMP) were combined in a composite, oil-in-water nanoemulsions (TSN/TMP O/W NEs) was prepared to prolong in vitro and vivo circulation time, and enhance the bioavailability of TSN.

Material and methods: Physicochemical characterization of TSN/TMP O/W NEs was characterized systematically. The in vitro dissolution and in vivo pharmacokinetic experiments of TSN/TMP O/W NEs were also evaluated.

Result: A formulation was optimized, yielding a 32.5?nm average particle size, an encapsulation efficiency of over 95 %, and were spherical in shape as shown by TEM. TSN/TMP O/W NEs were shown to extend the release and availability in vitro compared to raw compounds. In pharmacokinetic study, the AUC_0→∞ and t_1/2 of the TSN/TMP O/W NEs were 481.50?mg/L*min and 346.39?min higher than TSN solution, respectively. Brain tissue concentration of TSN was enhanced with TSN/TMP O/W NEs over raw TSN and even TSN O/W NEs.

Conclusions: Therefore, nanoemulsions are an effective carrier to increase encapsulation efficiency of drugs, improve bioavailability and brain penetration for TSN – which is further enhanced by pairing with the co-delivery of TMP, providing a promising drug delivery.     

Formulation and optimization of liquisolid compact for enhancing dissolution properties of efavirenz by using DoE approach

Efavirenz displays low and variable bioavailability because of its poor aqueous solubility and high log P-value. The present investigation was aimed to improve the dissolution profile of efavirenz by using a simple, scalable and cost-effective technique of liquisolid compact. The drug was dissolved in Trancutol-HP for preparing the liquid medicament which was subsequently mixed with carrier and coating material to make free-flowing and compressible powder. 3² full factorial design was used to optimize the formulation in which the Neusilin US2/Corn starch ratios and carrier/coating material ratio were selected as independent variables. The results of in-vitro dissolution test proved that liquisolid compacts have significantly higher dissolution rate than tablets containing pure drug. Results of DSC and XRD studies suggested that the high dissolution of the drug from the liquisolid compacts was possibly because of the drug either being in an amorphous state or being molecularly dispersed within the internal matrix of compacts.     

Enhancement of dissolution rate of piroxicam using liquisolid compacts

Piroxicam is a poorly soluble, highly permeable drug and the rate of its oral absorption is often controlled by the dissolution rate in the gastrointestinal. The poor dissolution rate of water-insoluble drugs is still a major problem confronting the pharmaceutical industry. There are several techniques to enhance the dissolution of poorly soluble drugs. Among them, the technique of liquisolid compacts is a promising technique towards such a novel aim. In this study, the dissolution behaviour of piroxicam from liquisolid compacts was investigated in simulated gastric fluid (SGF, pH 1.2) and simulated intestinal fluid (SIF, pH 7.2). To this end, several liquisolid tablets formulations containing various ratios of drug:Tween 80 (ranging from 10% to 50% w/w) were prepared. The ratio of microcrystalline cellulose (carrier) to silica (coating powder material) was kept constant in all formulations. The results showed that liquisolid compacts demonstrated significantly higher drug release rates than those of conventionally made (capsules and directly compressed tablets containing micronized piroxicam). This was due to an increase in wetting properties and surface of drug available for dissolution.     

Floating microspheres of carvedilol as gastro retentive drug delivery system: 32 full factorial design and in vitro evaluation

Abstract

Context: Designing a sustained release system for Carvedilol to increase its residence time in the stomach.

Objective: Preparation of floating microsphere by the emulsion solvent diffusion method, studying the effect of various process parameters and optimize the formulation using full factorial design.

Methods: Different microsphere formulations were prepared by varying the ratio ethanol:dichloromethane (1:0 to 1:1.5), ethyl cellulose:hydroxypropyl methyl cellulose and stirring speed (800–1600?rpm). The effect of these variables on particle size, encapsulation parameters, surface topography, in vitro floatability and drug release were evaluated.

Results: 3² full factorial design was used for the optimization of the formulation. Drug entrapment efficiency, particle size and in vitro drug release were dependent on concentration of ethyl cellulose and stirring speed. Microspheres remained buoyant for more than 10?h and showed sustained release of the drug.

Conclusion: Floating microspheres of Carvedilol with good floating ability and sustained release were developed.     

Overcoming formulation challenges for the next generation of vaccines

Introduction: In recent years, the number of active pharmaceutical ingredients with high therapeutic impact, but very low water solubility, has increased significantly. Thus, a great challenge for pharmaceutical technology is to create new formulations and efficient drug-delivery systems to overcome these dissolution problems.

Areas covered: Drug formulation in solid dispersions (SDs) is one of the most commonly used techniques for the dissolution rate enhancement of poorly water-soluble drugs. Generally, SDs can be defined as a dispersion of active ingredients in molecular, amorphous and/or microcrystalline forms into an inert carrier. This review covers literature which states that the dissolution enhancement of SDs is based on the fact that drugs in the nanoscale range, or in amorphous phase, dissolve faster and to a greater extent than micronized drug particles. This is in accordance to the Noyes–Whitney equation, while the wetting properties of the used polymer may also play an important role.

Expert opinion: The main factors why SD-based pharmaceutical products on the market are steadily increasing over the last few years are: the recent progress in various methods used for the preparation of SDs, the effect of evolved interactions in physical state of the drug and formulation stability during storage, the characterization of the physical state of the drug and the mechanism of dissolution rate enhancement.     

Optimization of self-nanoemulsifying systems for the enhancement of in vivo hypoglycemic efficacy of glimepiride transdermal patches

Objectives: To optimize and use of glimepiride (GMD)-loaded self-nanoemulsifying delivery systems (SNEDs) for the preparation of transdermal patches.

Methods: Mixture design was utilized to optimize GMD-loaded SNEDs in acidic and aqueous pH media. Optimized GMD-loaded SNEDs were used in the preparation of chitosan (acidic) and hydroxypropyl methyl cellulose (HPMC) (aqueous) films. The prepared optimized formulations were investigated for ex vivo skin permeation, for in vivo hypoglycemic activity and for their pharmacokinetic parameters using animal model.

Results: The optimized formulations showed flux value of (2.88 and 4.428 μg/cm²/h) through rat skin for chitosan and HPMC films, respectively. The pattern of GMD release from both formulations was in favor of Higuchi and approaching zero order models. The n values for Korsmeyer–Peppas equation were characteristic of anomalous (non-Fickian) release mechanism. Moreover, HPMC patches have shown significant reductions (p < 0.05) in blood glucose levels; (213.33 ± 15.19) mg/100 ml from the base-line measurement after 12 h of application.

Conclusions: Optimized GMD SNEDs patches were found to improve GMD skin permeability and the essential pharmacokinetic parameters. Further extensive pre/clinical studies are necessary prior to use transdermal GMD as a valuable alternative to peroral dosage forms with improved bioavailability, longer duration of action and more patient convenience.