Release of Ibuprofen from Polyethylene glycol solid dispersions:-Equilibrium solubility approach

Abstract

This work is an attempt to enhance the release of Ibuprofen by improving its aqueous solubility. This was done by dispersing the drug in a water soluble carrier such as polyethylene glycol (PEG). The solubility was found to depend on various factors such as method of preparation, carrier weight fraction and molecular weight and the pH of the medium. It was found that dispersions prepared by the fusion method gave higher solubilities than those prepared by the solvent technique. The solubility was found to vary with carrier molecular weight and its weight fraction. Decreasing the PEG molecular weight resulted in increased solubility. A polymer to drug ratio of 1:1 was found to give the highest solubility. The solubility decreased as the polymer weight fraciton was increased beyond this value. The solubility of the solid dispersion was found to be pH dependent. A greater solubility was obtained at higher pHs than at lower ones. This was attributed to the weakly acidic nature of Ibuprofen. Calculation of the heat of solution of the various systems studied showed that the non dispersed drug had a higher heat of solution than the dispersed systems. This was thought to be the cause of the higher solubility of the dispersions as compared to the original drug.     

Studies on the in vitro Release of Ibuprofen from Polyethylene Glycol-Polyvinyl Acetate Mixtures Liquid Filled into Hard Gelatin Capsules

The release of ibuprofen from mixtures of polyethylene glycol (PEG) with polyvinyl acetate (PVAc) has been studied in vitro and complemented by x-ray diffraction measurements, differential scanning calorimetry (DSC), and melting point determinations via hot-stage microscopy (HSM). Results indicate that ibuprofen release can be affected markedly by alteration of the PVAc concentration. The molecular weight of the PEG and the pH of the dissolution medium are also shown to affect the release profile. Visual observation during the drug release process revealed a complex behavior which included emission of liquidlike droplets, formation of a crust around the releasing mass, and/or production of flakes of solid material. This behavior appeared to have a disadvantageous effect on the reproducibility of drug release. Construction of a phase diagram from results of thermal analysis using DSC and HSM indicated the formation of an eutectic mixture with a composition of 35% ibuprofen and 65% PEG 1500 and a melting point of 36°C. The complex behavior of the drug-releasing mass is discussed in terms of this phase diagram. Only the release data for systems containing 4% w/w or more of PVAc could be linearized by plotting against the square root of time whereas data for all of the systems studied could be linearized by first-order plots.     

Enhancement of dissolution rate of valdecoxib using solid dispersions with polyethylene glycol 4000

The aim of the present study was to enhance the dissolution rate of valdecoxib using its solid dispersions (SDs) with polyethylene glycol (PEG) 4000. The phase solubility behavior of valdecoxib in the presence of various concentrations of PEG 4000 in water was obtained at 37°C. The solubility of valdecoxib increased with increasing amount of PEG 4000 in water. Gibbs free energy (ΔG°_tr) values were all negative, indicating the spontaneous nature of valdecoxib solubilization, and they decreased with increase in the PEG 4000 concentration, demonstrating that the reaction conditions became more favorable as the concentration of PEG 4000 increased. The SDs of valdecoxib with PEG 4000 were prepared at 1:1, 1:2, 1:5, and 1:10 (valdecoxib: PEG 4000) ratio by melting method. Evaluation of the properties of the SDs was performed by using dissolution, Fourier-transform infrared (FTIR) spectroscopy, differential scanning calorimetry (DSC), X-ray diffraction (XRD), and scanning electron microscopy (SEM) studies. The SDs of valdecoxib with PEG 4000 exhibited enhanced dissolution rate of valdecoxib, and the rate increased with increasing concentration of PEG 4000 in SDs. Mean dissolution time (MDT) of valdecoxib decreased significantly after preparation of SDs and physical mixture with PEG 4000. The FTIR spectroscopic studies showed the stability of valdecoxib and absence of well-defined valdecoxib-PEG 4000 interaction. The DSC and XRD studies indicated the amorphous state of valdecoxib in SDs of valdecoxib with PEG 4000. The SEM pictures showed the formation of effective SDs of valdecoxib with PEG 4000, since well-defined changes in the surface nature of valdecoxib, SDs, and physical mixture were observed.     

Dissolution, solubility, XRD, and DSC studies on flurbiprofen-nicotinamide solid dispersions

Flurbiprofen-nicotinamide solid dispersions were prepared by the fusion method. The solid dispersions were evaluated for dissolution rate. The drug-carrier interaction in the liquid and solid states were studied by using phase solubility analysis, phase diagram, X-ray diffraction (XRD), and differential scanning calorimentry (DSC). Solid dispersions gave fast and rapid dissolution of flurbiprofen compared with the pure drug and the physical mixture. Phase diagram and DSC indicated that flurbiprofen and nicotinamide form a eutectic mixture. The aqueous solubility of flurbiprofen was enhanced in the presence of nicotinamide.     

Solubility advantage from amorphous etoricoxib solid dispersions

Objective: This study aimed to evaluate kinetic solubility advantage of amorphous etoricoxib solid dispersions prepared with three water soluble polymers and correlate it with solid state and supersaturated drug solution stabilization potential of these polymers.

Methods: Amorphous solid dispersions (ASDs) of etoricoxib were prepared with polyvinyl alcohol (PVA), polyvinyl pyrrolidone (PVP) and hydroxyethyl cellulose (HEC) at 70:30w/w ratio and characterized for glass transition temperature (T_g), miscibility and intermolecular interactions. Kinetic solubility profiles of amorphous etoricoxib and its ASDs were determined in water at 37 °C. Solid-state stability was assessed by enthalpy relaxation studies at a common degree of undercooling of around 19.0 °C at 0% RH. Recrystallization behavior of supersaturated drug solution was evaluated in the absence and presence of pre-dissolved polymer at 37 °C.

Results: Amorphous etoricoxib exhibited rapid solid-to-solid transition to yield a solubility advantage of merely 1.5-fold in water. Among the ASDs, etoricoxib-PVP dispersion exhibited maximal “peak” (2-fold) and “plateau” (1.8-fold) solubility enhancement, while etoricoxib-PVA dispersion could only sustain the “peak” solubility achieved by amorphous etoricoxib. In contrast, etoricoxib-HEC dispersion displayed no solubility advantage. The rank order for solid state and supersaturated solution stabilization followed a similar trend of amorphous etoricoxib?Conclusion: Dissolution behavior of ASDs is influenced by concomitantly occurring solid phase changes, thus understanding these processes independently can enable assessment of the predominant route of drug crystallization and stabilization by the polymer.     

Kinetic analysis of chlorpropamide dissolution from solid dispersions

Solid dispersions (SDs) of chlorpropamide were prepared by the solvent deposition technique using two grades of microcrystalline cellulose as carrier materials with different ratios of drug to carrier. The dissolution rate of chlorpropmide from the SDs was carried out at two physiological pH values of 1.1 and 7.25 simulating gastric and intestinal environments. The dissolution was dependent on the grade, the ratio of drug to carrier and pH. The higher dissolution was observed for more hydrophilic grade of the carrier as well as the higher ratio of carrier to drug. At the higher pH the drug dissolved much faster than the lower pH. X-ray diffraction showed some reduced drug crystallinity in SDs whereas infrared spectroscopy revealed no drug interactions with solvent and the carriers. The enhanced dissolution was attributed to the reduced drug crystallinity, decreased particle size, increased wettability and reduced aggregation of the hydrophobic drug particles. A novel model denoted as reciprocal powered time model with its theoretical justification was employed to analyze the dissolution data and proved to be superior to commonly used models for the analysis of the data. There was a quantitative relation between the model parameter and the ratio of carrier to drug which could be of value in dissolution rate prediction.     

Medicament Release from Ointment Bases: III. Ibuprofen: In Vitro Release and In-Vivo Absorption in Rabbits

Abstract

The in-vitro release of ibuprofen from various topical bases including: water-washable base, hydrophilic base, cream, Canadian formulary base, gel, emulsion, water-soluble base and University of California Hospital base were studied. Also, the effects of the additives (ethanol, polyethylene glycol—400, urea and dimethylsulfoxide) on the release rate of the drug from the water-washable base were evaluated.

In general, the in-vitro release rate rank order of the drug was observed to be: water-washable base > hydrophilic base > Canadian formulary base > gel > PEG water washable > emulsion > cream > University of California base. The additive ingredients had a Little or no effect in enhancing the release of drug from the samples studied.

The formulations with optimum in-vitro drug release were scaled up for in-vivo percutaneous absorption in rabbits. The blood samples were analyzed by a HPLC method. Among the candidates evaluated in-vivo, the bioavailability of the drug was significantly higher from the water-washable base when compared to the hydrophilic base and others. The addition of 10% dimethylsulfoxide to the hydrophilic enhanced the release of ibuprofen and adversely affected the release from the water-washable base.

In-vitro and in-vivo data were treated by various kinetic models and the values for diffusion coefficient, permeability coefficient and partition coefficient were calculated. Also, some pharmacokinetic parameters, such as, absorption rate constant, elimination rate constant and half-life of the drug were calculated for meaningful interpretations of the data for the release of drug from topical bases.     

Role of Cellulose Ether Polymers on Ibuprofen Release from Matrix Tablets

Cellulose derivatives are the most frequently used polymers in formulations of pharmaceutical products for controlled drug delivery. The main aim of the present work was to evaluate the effect of different cellulose substitutions on the release rate of ibuprofen (IBP) from hydrophilic matrix tablets. Thus, the release mechanism of IBP with methylcellulose (MC25), hydroxypropylcellulose (HPC), and hydroxypropylmethylcellulose (HPMC K15M or K100M) was studied. In addition, the influence of the diluents lactose monohydrate (LAC) and β-cyclodextrin (β-CD) was evaluated. Distinct test formulations were prepared containing: 57.14% of IBP, 20.00% of polymer, 20.29% of diluent, 1.71% of talc lubricants, and 0.86% of magnesium stearate as lubricants. Although non-negligible drug-excipient interactions were detected from DSC studies, these were found not to constitute an incompatibility effect. Tablets were examined for their drug content, weight uniformity, hardness, thickness, tensile strength, friability, porosity, swelling, and dissolution performance. Polymers MC25 and HPC were found to be unsuitable for the preparation of this kind of solid dosage form, while HPMC K15M and K100M showed to be advantageous. Dissolution parameters such as the area under the dissolution curve (AUC), the dissolution efficiency (DE_{20 h}), dissolution time (t 50%), and mean dissolution time (MDT) were calculated for all the formulations, and the highest MDT values were obtained with HPMC indicating that a higher value of MDT signifies a higher drug retarding ability of the polymer and vice-versa. The analysis of the drug release data was performed in the light of distinct kinetic mathematical models—Kosmeyer-Peppas, Higuchi, zero-, and first-order. The release process was also found to be slightly influenced by the kind of diluent used.     

Ibuprofen Release from Beads Coated with an Experimental Latex: Effect of Certain Variables

The objective of this study was to evaluate the effect of factors such as drug loading, particle size, plasticizer type, antiadherent type, and annealing method on the release of ibuprofen from controlled-release beads coated with an experimental latex. Further, the in vitro release kinetics and mechanism of drug transport across the polymeric membrane have been investigated. Ibuprofen-loaded beads were coated with the experimental latex using a fluidized-bed coating machine (Uniglatt). The drug release from these spherical membrane reservoir systems appeared to be diffusion controlled. Evaluation of the effect of osmotic pressure by using dissolution media of various osmolal concentrations indicated that it has no significant effect on the drug release. To further elucidate the mechanism of release from these polymeric membranes, the permeation of drug through free films was studied.     

Classification of solid dispersions: correlation to (i) stability and solubility (ii) preparation and characterization techniques

Solid dispersion has been a topic of interest in recent years for its potential in improving oral bioavailability, especially for poorly water soluble drugs where dissolution could be the rate-limiting step of oral absorption. Understanding the physical state of the drug and polymers in solid dispersions is essential as it influences both the stability and solubility of these systems. This review emphasizes on the classification of solid dispersions based on the physical states of drug and polymer. Based on this classification, stability aspects such as crystallization tendency, glass transition temperature (T_g), drug polymer miscibility, molecular mobility, etc. and solubility aspects have been discussed. In addition, preparation and characterization methods for binary solid dispersions based on the classification have also been discussed.     

Improved stability of solid dispersions of manidipine with polyethylene glycol 4000/copovidone blends: application of ternary phase diagram

Context: Manidipine (MDP) is generally used clinically as an antihypertensive agent; however, the bioavailability of orally administered MDP is limited due to their very low water solubility.

Objective: The objectives of this research were, therefore, to increase the solubility of MDP by the formation of ternary solid dispersions (tSD) with polyethylene glycol 4000 (PEG4000) and copovidone and to improve their stability.

Methods: Solid ternary phase diagram was constructed to find homogeneous solid dispersion region after melting and solidifying at low temperature with different quenching substances. The pulverized powder of solid dispersions was then determined, for their physicochemical properties, by differential scanning calorimetry, powder X-ray diffractometry, Fourier transform infrared (FTIR) spectroscopy and hot stage microscopy. The solubility and dissolution of MDP from the tSD were investigated. The physical stability of tSD was also determined under accelerated condition at 40?°C/75% relative humidity (RH) for 6 months.

Results and discussion: The results showed that MDP was molecularly dispersed in PEG4000 and copovidone when the tSD was created from homogeneous region of solid ternary phase diagram. FTIR results confirmed that strong hydrogen bonding was presented between MDP and copovidone, leading to a significant increase in the solubility and dissolution of MDP. After storage at accelerated condition (40?°C/75%RH) for 6 months, the tSD still showed a good appearance and high solubility.

Conclusion: The results of this study suggest that tSD prepared by melting has promising potential for oral administration and may be an efficacious approach for improving the therapeutic potential of MDP.     

Characterization and dissolution properties of ketoprofen in binary and ternary solid dispersions with polyethylene glycol and surfactants

The effect of incorporation of an anionic [sodium dodecyl sulfate (SDS) or dioctylsulfosuccinate (DSS)] or nonionic [Tween 60 (TW60)] surfactant on the properties of ketoprofen solid dispersions in polyethylene glycol 15000 (PEG) has been investigated. Physicochemical and morphological properties of the various solid systems were determined by differential scanning calorimetry, hot stage microscopy, X-ray powder diffraction analysis, and scanning electron microscopy. The results from dissolution studies, performed according to the USP 24 basket method, indicated that all ternary dispersed systems were significantly (p < 0.001) more efficacious than the corresponding binary ones, by virtue of the additive wetting and solubilizing effect due to the presence of the surfactant. The relative effectiveness of the incorporated surfactant was in the same order as found in phase-solubility studies (i.e., SDS > DSS > TW60). With regard to the solid dispersion preparation method, coevaporated products always gave better results than the corresponding cofused ones; however, this effect was statistically significant (p < 0.001) only in the initial phase of the dissolution process. The most effective solid dispersion was the 10-80-10 w/w drug-PEG-SDS ternary coevaporate, which allowed dissolution of 50% drug after only 6 min (in comparison with > 120 min for drug alone and 17 min for the binary coevaporate) and dissolution of about 100% drug after 30 min (in comparison with > 120 min for the binary coevaporate).     

Preparation and Evaluation of Sustained Release Ibuprofen Beads

Sustained release beads of ibuprofen were prepared by a capillary method using cellulose acetate phthalate, surfactants (Tween 80 and Span 80), and polymers (K 100 M Methocel and K 100 LV Methocel). These beads were formulated into capsule and tablet dosage forms. The beads did not disintegrate in simulated gastric fluid; however, they disintegrated in simulated intestinal fluid. The dissolution profiles of ibuprofen beads and dosage forms of beads (tablets and capsules) were conducted in phosphate buffer (pH 7.2) at 37°C. The beads containing Span 80 and K 100 M Methocel resulted in prolonged drug release. The preparation containing Span 80 and equal quantities of both the polymers (K 100 M Methocel and K 100 LV Methocel), also showed good sustained release properties. The formulations prepared with Tween 80 and K 100 LV Methocel released over 90% of the drug in 2 hours indicating no sustained release properties. The beads in tablet dosage form yielded slower dissolution profiles compared to the beads in capsule form which, in turn, had slower release profiles compared to the beads alone. Release of ibuprofen was much slower from tablets after one year of storage compared to tablets immediately after their manufacture.     

Preparation and Evaluation of Sustained Release Ibuprofen Beads

Sustained release beads of ibuprofen were prepared by a capillary method using cellulose acetate phthalate, surfactants (Tween 80 and Span 80), and polymers (K 100 M Methocel and K 100 LV Methocel). These beads were formulated into capsule and tablet dosage forms. The beads did not disintegrate in simulated gastric fluid; however, they disintegrated in simulated intestinal fluid. The dissolution profiles of ibuprofen beads and dosage forms of beads (tablets and capsules) were conducted in phosphate buffer (pH 7.2) at 37°C. The beads containing Span 80 and K 100 M Methocel resulted in prolonged drug release. The preparation containing Span 80 and equal quantities of both the polymers (K 100 M Methocel and K 100 LV Methocel), also showed good sustained release properties. The formulations prepared with Tween 80 and K 100 LV Methocel released over 90% of the drug in 2 hours indicating no sustained release properties. The beads in tablet dosage form yielded slower dissolution profiles compared to the beads in capsule form which, in turn, had slower release profiles compared to the beads alone. Release of ibuprofen was much slower from tablets after one year of storage compared to tablets immediately after their manufacture.     

Evaluation of solid dispersions of Clofazimine

Clofazimine (CLF) was formulated with polyethylene glycol (PEG) and polyvinyl pyrrolidone (PVP) as a solid solid dispersion (SSD) to increase the aqueous solubility and dissolution rate of the drug. Different molecular weights of PEG (1500, 4000, 6000, and 9000 Da) and PVP (14,000 and 44,000 Da) were used in different drug:carrier weight ratios (1:1, 1:5, and 1:9) and their effect on the dissolution performance of the drug was evaluated in USP Type 2 apparatus using 0.1 N HCl medium. The dissolution rate was compared with corresponding physical mixtures, a currently marketed soft gelatin capsule product, and free CLF. The effect of different methods of preparation (solvent/melt) on the dissolution rate of CLF was evaluated for PEG solid dispersions. Saturation solubility and phase solubility studies were carried out to indicate drug:carrier interactions in liquid state. Infrared (IR) spectroscopy and X-ray diffraction (XRD) were used to indicate drug:carrier interactions in solid state. Improvement in the drug dissolution rate was observed in solid dispersion formulations as compared to the physical mixtures. The dissolution rate improved with the decreasing weight fraction of the drug in the formulation. Polyvinyl pyrrolidone solid dispersion systems gave a better drug release profile as compared to the corresponding PEG solid dispersions. The effect of molecular weight of the PEG polymers did not follow a definite trend, while PVP 14,000 gave a better dissolution profile as compared to PVP 44,000. Improvement in saturation solubility of the drug in the solid dispersion systems was noted in all cases. Further, IR spectroscopy indicated drug:carrier interactions in solid state in one case and XRD indicated reduction in the crystallinity of CLF in another. It was concluded that solid-dispersion formulations of Clofazimine can be used to design a solid dosage form of the drug, which would have significant advantages over the currently marketed soft gelatin capsule dosage form.     

Studies on solid dispersions of nifedipine

Abstract

Nifedipine-Polyethylene glycol solid dispersions were prepared by melting or fusion method in order to improve nifedipine solubility in the aqueous body fluids. The dissolution rate of the drug was markedly increased in these solid dispersion systems. The increase in dissolution was a function of the ratio of drug to polyethylene glycol used and the molecular weight of polyethylene glycol. The dissolution rate was compared with a 10% w/w physical mixture of drug with polyethylene glycol.

The physical state of nifedipine after fusion was determined by X-ray crystallography on the pure drug and on the solidified melts. The X-ray diffraction studies indicated that nifedipine in the solid dispersion which was obtained by sudden cooling of the melt, was in the thermodynamically unstable metastable form. It was established that the slow cooling of the melt as well as powdering of solid dispersion resulted in the emergence of crystallinity.

The effect of aging on nifedipine-polyethylene glycol 6000 solid dispersions has been investigated. After storage at room temperature for six months, solid dispersions showed no change in the dissolution rate and the X-ray diffraction pattern showed slight enhancement in crystallinity.     

Determination of precipitation inhibitory potential of polymers from amorphous solid dispersions

Abstract

Precipitation inhibitory potential of polymers screened from precipitation study may be altered once it is formulated in amorphous solid dispersions (ASDs).

Objective: Present study was embarked with an objective to determine whether the polymers retain the same inhibitory potential after formulating them into ASDs.

Methods: Screening of polymers was based on a new dimensionless parameter ‘Supersaturation Holding Capacity (SHC)’ calculated from the precipitation study. Nifedipine ASDs were formulated using HPMC E3 and HPMC E50 (high SHC values), and HPMC K100M, PVP K25, and HPC M (low to moderate SHC values). Generated ASDs were characterized by DSC, FTIR, and PXRD and evaluated for stability under accelerated conditions (40?C and 75% RH) for 6 months.

Results: Thermal analysis of the ASDs and theoretical prediction of the glass transition temperature (T_g) suggested a linear dependency of T_g on the content of HPMC E3 and HPMC E50. Under accelerated stability conditions, all ASDs of nifedipine with HPMC E3 and HPMC E50 (except ASDs with 70% drug load) were stable, which could be attributed to the molecular level dispersion of the drug in these polymers. SHC parameter calculated from the apparent solubility profile gave following rank order HPMC E50 (3.4)?>?HPMC E3 (3.2)?>?HPMC K100M (1.29)?>?PVP K25 (1.09)?>?HPC M (0.99). SHC calculated from the apparent solubility profile of ASDs demonstrated good agreement between the solution state and solid state screening of the polymers for precipitation inhibition. During dissolution study, nearly four-fold enhancement has been observed with ASDs comprising HPMC E3 and HPMC E50.

Conclusions: The outcome of the study concluded that SHC can be a promising parameter in the screening of polymers for the development of the ASDs.     

Preparation of amorphous solid dispersions by rotary evaporation and KinetiSol Dispersing: approaches to enhance solubility of a poorly water-soluble gum extract

Acetyl-11-keto-β-boswellic acid (AKBA), a gum resin extract, possesses poor water-solubility that limits bioavailability and a high melting point making it difficult to successfully process into solid dispersions by fusion methods. The purpose of this study was to investigate solvent and thermal processing techniques for the preparation of amorphous solid dispersions (ASDs) exhibiting enhanced solubility, dissolution rates and bioavailability. Solid dispersions were successfully produced by rotary evaporation (RE) and KinetiSol® Dispersing (KSD). Solid state and chemical characterization revealed that ASD with good potency and purity were produced by both RE and KSD. Results of the RE studies demonstrated that AQOAT®-LF, AQOAT®-MF, Eudragit® L100-55 and Soluplus with the incorporation of dioctyl sulfosuccinate sodium provided substantial solubility enhancement. Non-sink dissolution analysis showed enhanced dissolution properties for KSD-processed solid dispersions in comparison to RE-processed solid dispersions. Variances in release performance were identified when different particle size fractions of KSD samples were analyzed. Selected RE samples varying in particle surface morphologies were placed under storage and exhibited crystalline growth following solid-state stability analysis at 12 months in comparison to stored KSD samples confirming amorphous instability for RE products. In vivo analysis of KSD-processed solid dispersions revealed significantly enhanced AKBA absorption in comparison to the neat, active substance.     

Studies on solid dispersions of nifedipine

Nifedipine-Polyethylene glycol solid dispersions were prepared by melting or fusion method in order to improve nifedipine solubility in the aqueous body fluids. The dissolution rate of the drug was markedly increased in these solid dispersion systems. The increase in dissolution was a function of the ratio of drug to polyethylene glycol used and the molecular weight of polyethylene glycol. The dissolution rate was compared with a 10% w/w physical mixture of drug with polyethylene glycol.

The physical state of nifedipine after fusion was determined by X-ray crystallography on the pure drug and on the solidified melts. The X-ray diffraction studies indicated that nifedipine in the solid dispersion which was obtained by sudden cooling of the melt, was in the thermodynamically unstable metastable form. It was established that the slow cooling of the melt as well as powdering of solid dispersion resulted in the emergence of crystallinity.

The effect of aging on nifedipine-polyethylene glycol 6000 solid dispersions has been investigated. After storage at room temperature for six months, solid dispersions showed no change in the dissolution rate and the X-ray diffraction pattern showed slight enhancement in crystallinity.