Sustained-release solid dispersion of pelubiprofen using the blended mixture of aminoclay and pH independent polymers: preparation and in vitro/in vivo characterization

The present study aimed to develop the sustained-release oral dosage form of pelubiprofen (PEL) by using the blended mixture of 3-aminopropyl functionalized-magnesium phyllosilicate (aminoclay) and pH-independent polymers. The sustained-release solid dispersion (SRSD) was prepared by the solvent evaporation method and the optimal composition of SRSD was determined as the weight ratio of drug: Eudragit® RL PO: Eudragit® RS PO of 1:1:2 in the presence of 1% of aminoclay (SRSD(F6)). The dissolution profiles of SRSD(F6) were examined at different pHs and in the simulated intestinal fluids. The drug release from SRSD(F6) was limited at pH 1.2 and gradually increased at pH 6.8, resulting in the best fit to Higuchi equation. The sustained drug release from SRSD(F6) was also maintained in simulated intestinal fluid at fasted-state (FaSSIF) and fed-state (FeSSIF). The structural characteristics of SRSD(F6) were examined by using powder X-ray diffraction (PXRD), differential scanning calorimetry (DSC) and Fourier transform infrared spectroscopy (FT-IR), indicating the change of drug crystallinity to an amorphous form. After oral administration in rats, SRSD(F6) exhibited the prolonged drug exposure in plasma. For both PEL and PEL-transOH (active metabolite), once a day dosing of SRSD(F6) achieved oral exposure (AUC) comparable to those from the multiple dosing (3 times a day) of untreated drug. In addition, the in vivo absorption of SRSD(F6) was well-correlated with the in vitro dissolution data, establishing a good level A in vitro/in vivo correlation. These results suggest that SRSD(F6) should be promising for the sustained-release of PEL, thereby reducing the dosing frequency.     

Orally Administered DTPA Penta-Ethyl Ester for the Decorporation of Inhaled 241Am

Diethylenetriaminepentaacetic acid (DTPA) is an effective decorporation agent to facilitate the elimination of radionuclides from the body, but its permeability-limited oral bioavailability limits its utility in mass-casualty emergencies. To overcome this limitation, a prodrug strategy using the penta-ethyl ester form of DTPA is under investigation. Pharmacokinetic and biodistribution studies were conducted in rats by orally administering [¹⁴C]DTPA penta-ethyl ester, and this prodrug and its hydrolysis products were analyzed as a single entity. Compared with a previous reporting of intravenously administered DTPA, the oral administration of this prodrug resulted in a sustained plasma concentration profile with higher plasma exposure and lower clearance. An assessment of the urine composition revealed that the bioactivation was extensive but incomplete, with no detectable levels of the penta- or tetra-ester forms. Tissue distribution at 12 h was limited, with approximately 73% of the administered dose being associated with the gastrointestinal tract. In the efficacy study, rats were exposed to aerosols of ²⁴¹Am nitrate before receiving a single oral treatment of the prodrug. The urinary excretion of ²⁴¹Am was found to be 19% higher than with the control. Consistent with prior reports of DTPA, the prodrug was most effective when the treatment delays were minimized. © 2014 Wiley Periodicals, Inc. and the American Pharmacists Association.     

Physicochemical characterization of a prodrug of a radionuclide decorporation agent for oral delivery

Intravenously administered calcium and zinc complexes of diethylenetriaminepentaacetic acid (DTPA) are the agents of choice to treat individuals who have been contaminated with radioactive actinides. However, their use in a mass casualty scenario is hampered by the need for trained personnel to receive treatment. Because DTPA is a highly ionized molecule with permeability-limited bioavailability, the penta-ethyl ester prodrug of DTPA is under evaluation as an orally bioavailable radionuclide decorporation agent. In this work, the physicochemical properties of DTPA penta-ethyl ester were characterized to assess its potential for oral delivery. DTPA penta-ethyl ester was determined to be a low-viscosity liquid with Newtonian flow characteristics. Consistent with the measured pK(a) values, which range from 2.93 to 10.87, this prodrug exhibits pH-dependent solubility and lipophilicity properties that are representative of a weak base and favorable for oral absorption. It is miscible in solvents that are nonpolar to moderately polar and is sufficiently stable to avoid premature hydrolysis during gastrointestinal transit. Therapeutic effects were demonstrated in an initial efficacy study wherein oral treatments of the prodrug were given to rats contaminated with 2?1Am, providing preliminary indications of successful oral delivery. The properties of the prodrug indicate that it is conducive to oral delivery and may offer therapeutic benefits over the standard DTPA therapy following radionuclide contamination.     

Influence of magnesium stearate on the physicochemical and pharmacodynamic characteristics of insulin-loaded Eudragit entrapped mucoadhesive microspheres

Abstract

Effective oral insulin delivery has remained a challenge to the pharmaceutical industry. This study was designed to evaluate the effect of magnesium stearate on the properties of insulin-loaded Eudragit® RL 100 entrapped mucoadhesive microspheres. Microspheres containing Eudragit® RL 100, insulin, and varying concentrations of magnesium stearate (agglomeration-preventing agent) were prepared by emulsification-coacervation method and characterized with respect to differential scanning calorimetry (DSC), morphology, particle size, loading efficiency, mucoadhesive and micromeritics properties. The in vitro release of insulin from the microspheres was performed in simulated intestinal fluid (SIF, pH 7.2) while the in vivo hypoglycemic effect was investigated by monitoring the plasma glucose level of the alloxan-induced diabetic rats after oral administration. Stable, spherical, brownish, mucoadhesive, discrete and free flowing insulin-loaded microspheres were formed. While the average particle size and mucoadhesiveness of the microspheres increased with an increase in the proportion of magnesium stearate, loading efficiency generally decreased. After 12?h, microspheres prepared with Eudragit® RL 100: magnesium stearate ratios of 15:1, 15:2, 15:3 and 15:4 released 68.20?±?1.57, 79.40?±?1.52, 76.60?±?1.93 and 70.00?±?1.00 (%) of insulin, respectively. Reduction in the blood glucose level for the subcutaneously (sc) administered insulin was significantly (p?≤?0.05) higher than for most of the formulations. However, the blood glucose reduction effect produced by the orally administered insulin-loaded microspheres prepared with four parts of magnesium stearate and fifteen parts of Eudragit® RL 100 after 12?h was equal to that produced by subcutaneously administered insulin solution. The results of this study can suggest that this carrier system could be an alternative for the delivery of insulin.     

Influence of Plasticizer Level on the Drug Release from Sustained Release Film Coated and Hot-Melt Extruded Dosage Forms

In the current study, the influence of plasticizer level on drug release was investigated for solid dosage forms prepared by hot-melt extrusion and film coating. The properties of two highly water-soluble compounds, diltiazem hydrochloride (DTZ) and chlorpheniramine maleate (CPM), and a poorly water-soluble drug, indomethacin (IDM), were investigated in the melt extrudates containing either Eudragit® RSPO or Eudragit® RD 100 and triethyl citrate (TEC) as the plasticizer. In addition, pellets containing DTZ were film coated with Eudragit® RS 30D and varying levels of TEC using a fluidized bed coating unit. Differential scanning calorimetry (DSC) demonstrated that both CPM and IDM exhibited a plasticization effect on the acrylic polymers, whereas no plasticizing effect by DTZ on Eudragit® RSPO was observed. Thermogravimetric analysis (TGA) was used to investigate the thermal stability of the DTZ, Eudragit® RSPO and TEC at 140 °C, the maximum temperature used in the hot-melt extrusion process. The chemical stability of DTZ and IDM in the extrudate following hot-melt processing was determined by high pressure liquid chromatography (HPLC). Drug release rates of both DTZ and CPM from hot-melt extrudates increased with an increase in the TEC level in the formulations, while the release rate of DTZ from the Eudragit® RS 30D–coated pellets decreased with an increase in TEC in the coating dispersion. This phenomenon was due to the formation of a reservoir polymeric structure as a result of the thermal stress and shear stress involved in the hot-melt extrusion process regardless of the TEC level. In contrast, coalescence of the polymer particles in the film coating process was enhanced with higher levels of TEC, as demonstrated by scanning electron microscopy (SEM). The addition of TEC (0% to 8%) in the IDM hot-melt extrudate formulation had no influence on the drug release rate as the drug release rate was controlled by drug diffusion through the inside of the polymeric materials rather than between the polymer particles.     

Methacrylate micro/nano particles prepared by spray drying: a preliminary in vitro/in vivo study

Delivery systems controlling drug release only in the colon holds great promises since they improve utilization of drug and decrease the dosing times comparison with conventional forms. The aim of the present study was to prepare polymeric microparticles on the basis of Ciprofloxacin via oral route for the treatment of inflammatory bowel disease. Ciprofloxacin was selected because of its extensive coverage for intestinal flora, relatively favorable side-effect profile and preliminary data suggesting its efficacy in the treatment of active Crohn's Disease. Microparticles were prepared using different acrylic compounds, namely Eudragit® RL (PO) and RS (PO) and a mixture of both. Spray-drying was used as a preparation method of Ciprofloxacin/Eudragit® microparticles using a Mini Spray Dryer B-290 (Büchi, Postfach, Switzerland). In vitro dissolution studies were performed to choose the best formulation and selected microparticles were characterized by size and morphology by environmental scanning electron microscopy. Yield and encapsulation efficiency were calculated and in vivo/ex vivo experiments were investigated both of which suggest that selected microparticles can be used for colon targeting of drugs increasing residence time of the drug in the affected area.     

Diclofenac Sodium-Loaded Eudragit® Microspheres: Optimization Using Statistical Experimental Design

Purpose

In this study, polymeric microspheres containing diclofenac sodium were prepared by single emulsion (oil-in-water) solvent evaporation method and evaluated for their size, morphology, encapsulation efficiency, drug loading, and in vitro drug release.

Methods

Two nonbiodegradable polymers, Eudragit® RS100 and RL100 were used in combination. Microspheres were prepared by varying the amount of polyvinyl alcohol as a surfactant (0.05, 0.125, and 2.0 %, w/v) to the external phase; varying the amount of polymer (1:1, 2:1, and 3:1, w/w) to the drug by employing 3² full factorial design using the Design Expert (Version 8.0.7.1). The drug polymer interactions were investigated by Fourier transform infrared spectroscopy (FTIR) and X-ray powder diffractometry (XRPD). Imaging of particles was performed by field emission scanning electron microscopy.

Results

Graphical and mathematical analysis of the design showed a quadratic model was significant for the responses. Low magnitude of error and significant values of R ² proves the high prognostic ability of the RSM. Encapsulation efficiency of microspheres (41.13 to 65.33 %) increases with an increase in surfactant concentration but decreases with an increase in polymer concentration. The microspheres were found to be discrete, spherical with smooth surface. The absence of drug polymer interactions was confirmed by FTIR spectroscopy. XRPD revealed the dispersion of drug within microspheres formulation. The Perfect pH-independent release profile was achieved from Eudragit® microspheres by anomalous transport mechanism.

Conclusions

In conclusion, Eudragit® microspheres containing diclofenac sodium can be successfully prepared, and seem to be promising for sustained release application.     

Enhancement of solubility and dissolution of Coenzyme Q10 using solid dispersion formulation

This study aimed to develop a stable solid dispersion of Coenzyme Q₁₀ (CoQ₁₀) with high aqueous solubility and dissolution rate. Among various carriers screened, poloxamer 407 was most effective to form a superior solid dispersion of CoQ₁₀ having significantly enhanced solubility. Particularly, solid dispersion of CoQ₁₀ with poloxamer 407 in the weight ratio of 1:5 prepared by melting method enhanced the solubility of CoQ₁₀ to the greatest extent. However, it exhibited poor stability and hence Aerosil^® 200 (colloidal silicon dioxide) was incorporated into the solid dispersion as an adsorbent to inhibit the recrystallization process. The solid dispersion of CoQ₁₀, poloxamer 407 and Aerosil^® 200 in the weight ratio of 1:5:6 exhibited improved stability with no significant change in solubility during the 1-month stability test. Moreover, the solid dispersion formulation containing Aerosil^® 200 significantly enhanced the extent of drug release (approx. 75% release) as well as the dissolution rate of CoQ₁₀. In conclusion, the present study has developed the stable solid dispersion formulation of CoQ₁₀ with poloxamer 407 and Aerosil^® 200 for the enhanced solubility and dissolution of CoQ₁₀, which could also offer some additional advantages including ease of preparation, good flowability and cost-effectiveness.     

Influence of Fumed Silicon Dioxide on the Stabilization of Eudragit® RS/RL 30 D Film-Coated Theophylline Pellets

The objective of this study was to investigate the influence of various grades of fumed silicon dioxide on the drug release rate and physical aging of theophylline pellets coated with Eudragit® RS 30 D and RL 30 D. Free films were assessed for both physicomechanical properties and water vapor permeability with respect to time and storage conditions. The release rate of theophylline was influenced by the physical properties of the silicon dioxide employed. As the particle size of the silica dioxide decreased, there was an increase in dispersion viscosity, as well as a decrease in the theophylline release rate from the coated pellets. Films prepared from formulas containing Aeroperl® 300 had twice the water vapor transmission rate of films prepared from formulas containing Aerosil® 200 VV and Cab-O-Sil® M-5P and showed consistent moisture permeability values during storage for up to 1 month at 25°C/0% relative humidity (RH). Scanning electron microscopy (SEM) imaging of pellets coated with a formulation containing Aerosil® 200 VV or Cab-O-Sil® M-5P demonstrated film structures that were homogenous, while those coated with a formulation containing Aeroperl® 300 produced heterogeneous films with large particles of the excipient present within the polymeric matrix of the film. Stability in the drug release rate exhibited by pellets coated with a formulation containing Eudragit® RS 30 D, 15% triethyl citrate (TEC), and 30% Aeroperl® 300 was attributed to the stabilization of the moisture vapor transmission rate of the acrylic films. Increasing the concentration of Aeroperl® 300 in the coating formulation increased the theophylline release rate from coated pellets.     

冷冻干燥法制备甲苯磺酸拉帕替尼固体分散体及其大鼠药动学评价

目的用冷冻干燥技术制备甲苯磺酸拉帕替尼固体分散体,以提高其生物利用度。方法以PVPS630和soluplus^■为载体,采用冷冻干燥法制备甲苯磺酸拉帕替尼固体分散体,通过SEM、DSC、XRPD等手段对固体分散体进行表征,通过表观溶解度、溶出度和大鼠体内药动学测定,评价固体分散体的增溶效果和生物利用度的改善情况。结果在相同药载比的条件下,PVPS630组的溶出度和表观溶解度均优于soluplus^■组。DSC、XRPD、SEM等表征结果显示,PVPS630为载体的固体分散体中,原料均以非晶态存在,而以soluplus^■为载体时,只有药载比为1∶3条件下,原料才呈现非晶态特征。大鼠药动学测定结果表明,固体分散体(甲苯磺酸拉帕替尼-PVPS630为1∶3)较上市药品AUC提高23.64%。结论载体PVPS630与甲苯磺酸拉帕替尼的相容性更理想;固体分散技术有助于本品提高生物利用度。     

Curcumin-Eudragit® E PO solid dispersion: A simple and potent method to solve the problems of curcumin

Using a simple solution mixing method, curcumin was dispersed in the matrix of Eudragit® E PO polymer. Water solubility of curcumin in curcumin-Eudragit® E PO solid dispersion (Cur@EPO) was greatly increased. Based on the results of several tests, curcumin was demonstrated to exist in the polymer matrix in amorphous state. The interaction between curcumin and the polymer was investigated through Fourier transform infrared spectroscopy and ¹H NMR which implied that OH group of curcumin and carbonyl group of the polymer involved in the H bonding formation. Cur@EPO also provided protection function for curcumin as verified by the pH challenge and UV irradiation test. The pH value influenced curcumin release profile in which sustained release pattern was revealed. Additionally, in vitro transdermal test was conducted to assess the potential of Cur@EPO as a vehicle to deliver curcumin through this alternative administration route.     

Nonaqueous Gel for the Transdermal Delivery of a DTPA Penta-ethyl Ester Prodrug

Diethylenetriamine pentaacetic acid penta-ethyl ester, designated as C2E5, was successfully incorporated into a nonaqueous gel for transdermal delivery. The thermal and rheological properties of a formulation containing 40% C2E5, 20% ethyl cellulose, and 40% Miglyol 840® prepared using the solvent evaporation method demonstrated that the gel had acceptable content uniformity and flow properties. In vitro studies showed that C2E5 was steadily released from the gel at a rate suitable for transdermal delivery. Topical application of the gel at a 200 mg C2E5/kg dose level in rats achieved significantly higher plasma exposures of several active metabolites compared with neat C2E5 oil at the same dose level. The results suggest that transdermal delivery of a chelator prodrug is an effective radionuclide decorporation strategy by delivering chelators to the circulation with a pharmacokinetic profile that is more consistent with the biokinetic profile of transuranic elements in contaminated individuals.     

Dissolution stability studies of suspensions of prolonged-release diclofenac microcapsules prepared by the Wurster process: I. Eudragit-based formulation and possible drug-excipient interaction

The aim was to evaluate possible interaction in solid and liquid state of the drug with formulation excipients consequent to very fast drug release of diclofenac-Eudragit® prolonged release microcapsules. The microcapsules were prepared by drug layering on calcium carbonate cores and coated with Eudragit® RS 30D and L30D-55 as previously reported. Suspension of the microcapsules was prepared using microcrystalline cellulose/sodium carboxymethyl cellulose (Avicel® CL-611) as medium. In vitro dissolution testing of the suspension was done, and, based on the dissolution results, possible interaction between diclofenac and Eudragit and Avicel in the medium was studied. Powder X-ray diffraction (PXRD) and differential scanning calorimetry (DSC) analyses were performed using 1:1 binary, 1:1:1 ternary mixtures and a ratio equivalent to that in the formulation. The mixtures were prepared by mixing the dispersions—Eudragit RS 30D or L30D-55 with the drug or other components, followed by drying at 60°C for 48?h. Dry mixing was done using the powder equivalents of the polymers, Eudragit RS PO and L100-55, Avicel and calcium carbonate. In vitro dissolution of the suspended microcapsules showed a very fast release after 48?h (T₅₀?=?<1?h) compared to the solid microcapsules (T₅₀?=?6?h). DSC curves of the formulation components or microcapsules did not show the characteristic endothermic peak of diclofenac at 287°C. Powder X-ray diffraction of the binary or ternary mixtures of diclofenac and Eudragit polymers indicated reduction, shift or modification of the crystalline peaks of the drug or excipients at 2θ of 12° and 18°, suggestive of interaction. Some changes in drug peak characteristics at 18° and 23° were observed for Avicel/drug mixture, though not significant. The DSC curves of the binary mixture of diclofenac co-dried with liquid forms of Eudragit (i.e. RS 30D or L30D-55) revealed greater interaction compared to the curves of drug and powdered forms of Eudragit (RS PO or L100-55). This was depicted by greater shift in fusion points of the mixtures relative to the drug. However, comparing the RS and L-type Eudragit, the latter generally showed greater interaction with the drug. Interaction between diclofenac and L-type Eudragit polymers can occur in liquid formulations.     

Preparation and characterization of spray-dried valsartan-loaded Eudragit® E PO solid dispersion microparticles

The purpose of this study was to develop the immediate release stomach-specific spray-dried formulation of valsartan (VAL) using Eudragit^® E PO (EPO) as the carrier for enhancing dissolution rate in a gastric environment. Enhanced solubility and dissolution in gastric pH was achieved by formulating the solid dispersion using a spray drying technique. Different combinations of drug–polymer–surfactant were dissolved in 10% ethanol solution and spray-dried in order to obtain solid dispersion microparticles. Use of the VAL–EPO solid dispersion microparticles resulted in significant improvement of the dissolution rate of the drug at pH 1.2 and pH 4.0, compared to the free drug powder and the commercial product. A hard gelatin capsule was filled with the VAL–EPO solid dispersion powder prior to the dissolution test. The increased dissolution of VAL from solid dispersion microparticles in gastric pH was attributed to the effect of EPO and most importantly the transformation of crystalline drugs to amorphous solid dispersion powder, which was clearly shown by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), and powder X-ray diffraction (P-XRD) studies. Thus, VAL, a potential antihypertensive drug in the form of a solid dispersion microparticulate powder, can be effectively delivered in the immediate release dosage form for stomach-specific drug delivery.     

Formulation of sustained release bioadhesive minitablets containing solid dispersion of levofloxacin for once daily ocular use

This study aimed to increase ocular residence time of levofloxacin by formulation into zero-order sustained release mucoadhesive minitablets for once daily administration using a hydrophobic–hydrophilic polymeric matrix. Levofloxacin was first formulated into solid dispersion with different ratios of Eudragit^® RS then the resulting solid dispersion was mixed with different concentrations of Carbopol^® and other excipients to be finally compressed into minitablets. A 2⁴ full factorial design was employed to estimate the effects and interactions of two formulation factors, and to establish their relationships with selected responses in the developed minitablets. The studied factors were: drug to Eudragit^® RS ratio, and percent of Carbopol^® in the minitablets. Sixteen ocular minitablets formulations were prepared and evaluated for the cumulative percentages drug release at 6, 12, and 24?h, as well as mucoadhesion time, mucoadhesive strength, and swelling index as response variables. After optimizing the responses, the optimized formulation was found to be stable on sterilization using gamma-irradiation and storage at 40?°C/75% RH for six months. In vivo testing of the optimized formulation showed that the minitablets extended levofloxacin release up to 24?h without causing any ocular irritation. The optimized formulation exhibited superior microbiological activity compared to the commercial product.     

Development of Extended-Release Solid Dispersions of Nonsteroidal Antiinflammatory Drugs with Aqueous Polymeric Dispersions: Optimization of Drug Release via a Curve-Fitting Technique

Extended-release solid dispersions of nonsteroidal antiinflammatory drugs were prepared by using aqueous polymeric dispersions of Eudragit RS30D and Eudragit RL30D as the inert carriers. The effects of different polymer ratios of Eudragit RS30D and Eudragit RL30D, different particle sizes, and different combination of various formulations of solid dispersions on the in vitro release kinetics of drugs from the dosage forms were investigated. A computer curve-fitting process was developed to choose the optimum formulation of the solid dispersion with the desired drug release profile. This process might offer the advantages of efficiency and simplicity in the formulation development of extended-release solid dispersions.     

Release modulation of highly water soluble drug using solid dispersion: impact of dispersion and its compressed unit

In present day, availability of various carriers, innovative techniques of production and plenty of solvents support the growth of solid dispersion (SD) technology in pharmaceutical industries to overcome many issues. The present study was aimed to develop SD based sustained release system of Milnacipran HCl (MH). The SD containing ethyl cellulose, Eudragit RLPO and Eudragit RSPO at drug–polymer ratios of 1:1, 1:2, and 1:3 were developed using solvent evaporation technique and different waxes at ratio of 1:1, 1:1.25, 1:1.5 and 1:1.75 with drug were developed by melting method. The physicochemical properties of SD were evaluated using Fourier transform infrared spectroscopy (FTIR), differential scanning calorimetry (DSC) and X-ray diffraction (XRD). The desired SD batch was further compressed into tablet unit to achieve predetermined once a day drug release. Tablets prepared were evaluated for physicochemical parameters, in vitro drug release, drug release kinetics and scanning electron microscopy. Out of selected carriers, bees wax had shown maximum release retardation. The results of FTIR, DSC and XRD studies exhibited poor interaction amongst MH–bees wax and retention of crystalline state of MH in SD system. The presence of Benecel^® (HPMC K 200 M; 75 mg) in tablets comprising SD (1:1.25, MH:bees wax) revealed remarkable drug release extension and it was considered an optimal. The later was submitted to short term stability study and its results indicated the stable characteristic of system. Drug release from optimized formulation fitted well into Higuchi model with anomalous diffusion. The compressed unit of SD system of highly water soluble drug can be successful single day regimen.     

Interplay of formulation and process methodology on the extent of nifedipine molecular dispersion in polymers

The aim of this study is to evaluate effects of formulation and process technology on drug molecular dispersibility in solid dispersions (SDs). Nifedipine solid dispersions with ethylcellulose (EC) and/or Eudragit RL (RL) prepared by co-precipitation, co-evaporation, and fusion methods were characterized with FTIR, DSC, and XRPD for the content of nifedipine as molecular dispersion, amorphous and/or crystalline suspensions. A method was developed based on regular solution and Flory-Huggins theories to calculate drug-polymer interaction parameter in solid dispersion systems. A synergic effect of RL and EC on nifedipine molecular dispersibility in solid dispersions was observed. Increasing RL/EC ratio resulted in a higher degree of drug-polymer interaction that thermodynamically favored molecular dispersion, which, however, was counteracted by a corresponding decrease in the matrix glass transition point that kinetically favored phase-separation. Process methodology was found to play an important role in the formation of amorphous SD. The ranking of technologies with respect to the extent of molecular dispersion from high to low is fusion > co-evaporation > co-precipitation, wherein the solidification rate of polymeric solution and non-solvent effects were linked to kinetic entrapment of drug molecules in polymeric networks. Since nifedipine molecular dispersibility in EC/RL polymer(s) is a result of interplay between thermodynamic and kinetic factors, nifedipine molecular dispersions prepared for this study are thermodynamically metastable systems. To explore those supersaturation systems for use in drug delivery of poorly water soluble drugs, it is critical to balance drug-polymer interactions and matrix glass transition point and to consider a process technology with a fast solidification rate during formulation and process development of amorphous SD.     

Development of gatifloxacin-loaded cationic polymeric nanoparticles for ocular drug delivery

The present investigation aimed at improving the ocular bioavailability of gatifloxacin by prolonging its residence time in the eye and reducing problems associated with the drug re-crystallization after application through incorporation into cationic polymeric nanoparticles. Gatifloxacin-loaded nanoparticles were prepared via the nanoprecipitation and double emulsion techniques. A 50:50 Eudragit® RL and RS mixture was used as cationic polymer with other formulation parameters varied. Prepared nanoparticles were evaluated for size, zeta potential, and drug loading. An optimized formulation was selected and further characterized for in vitro drug release, cytotoxicity, and antimicrobial activity. The double emulsion method produced larger nanoparticles than the nanoprecipitation method (410?nm and 68?nm, respectively). Surfactant choice also affected particle size and zeta potential with Tween 80 producing smaller-sized particles with higher zeta potential than PVA. However, the zeta potential was positive at all experimental conditions investigated. The optimal formulation produced by double emulsion technique and has achieved 46% drug loading. This formulation had optimal physicochemical properties with acceptable cytotoxicity results, and very prolonged release rate. The particles antimicrobial activities of the selected formulation have been tested against Escherichia coli, Pseudomonas aeruginosa, and Staphylococcus aureus and showed prolonged antimicrobial effect for gatifloxacin.