Preparation and evaluation of immediate release ibuprofen solid dispersions using polyethylene glycol 4000

To improve its dissolution, ibuprofen solid dispersions (SDs) were prepared in a relatively easy and simple manner, characterized by scanning electron microscopy (SEM), differential scanning calorimetry (DSC) and Fourier transform infrared spectroscopy (FT-IR), and evaluated for solubility, in-vitro drug release and oral bioavailability of ibuprofen in rats. Loss of individual surface properties during melting and resolidification as revealed by SEM micrographs indicated the formation of effective SDs. Absence or shifting towards the lower melting temperature of the drug peak in SDs and physical mixtures in DSC study indicated the possibilities of drug-polymer interactions. FT-IR spectra showed the presence of drug crystalline in SDs. Quicker release of ibuprofen from SDs in rat intestine resulted in a significant increase in AUC and Cmax, and a significant decrease in Tmax over pure ibuprofen. Preliminary results from this study suggested that the preparation of fast dissolving ibuprofen SDs by low temperature melting method using polyethylene glycol 4000 (PEG 4000) as a meltable hydrophilic polymer carrier could be a promising approach to improve solubility, dissolution and absorption rate of ibuprofen.     

Preparation and evaluation of fast dissolving ibuprofen-polyethylene glycol 6000 solid dispersions

To improve its oral absorption, rapidly dissolving ibuprofen solid dispersions (SD) were prepared in a relatively easy, simple, quick, inexpensive, and reproducible manner, characterized by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), and Fourier transform infrared spectroscopy (FTIR). They were evaluated for solubility, in vitro release, and oral bioavailability of ibuprofen in rats. Loss of individual surface properties during melting and resolidification as revealed by SEM indicated the formation of effective SDs. Absence or shifting toward the lower melting temperature of the drug peak in SDs and physical mixtures in DSC study indicated the possibilities of drug-polymer interactions. However, no such interactions in the solid state were confirmed by FTIR spectra that showed the presence of drug crystalline in SDs. Quicker release of ibuprofen from SDs in rat intestine resulted in a significant increase in AUC and C(max), and a significant decrease in T(max) over pure ibuprofen. Preliminary results from this study suggested that the preparation of fast-dissolving ibuprofen SDs by low temperature melting method using PEG 6000 as a meltable hydrophilic polymer carrier could be a promising approach to improve solubility, dissolution, and absorption rate of ibuprofen.     

Preparation and Evaluation of Fast Dissolving Ibuprofen-Polyethylene Glycol 6000 Solid Dispersions

To improve its oral absorption, rapidly dissolving ibuprofen solid dispersions (SD) were prepared in a relatively easy, simple, quick, inexpensive, and reproducible manner, characterized by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), and Fourier transform infrared spectroscopy (FTIR). They were evaluated for solubility, in vitro release, and oral bioavailability of ibuprofen in rats. Loss of individual surface properties during melting and resolidification as revealed by SEM indicated the formation of effective SDs. Absence or shifting toward the lower melting temperature of the drug peak in SDs and physical mixtures in DSC study indicated the possibilities of drug-polymer interactions. However, no such interactions in the solid state were confirmed by FTIR spectra that showed the presence of drug crystalline in SDs. Quicker release of ibuprofen from SDs in rat intestine resulted in a significant increase in AUC and C_max, and a significant decrease in T_max over pure ibuprofen. Preliminary results from this study suggested that the preparation of fast-dissolving ibuprofen SDs by low temperature melting method using PEG 6000 as a meltable hydrophilic polymer carrier could be a promising approach to improve solubility, dissolution, and absorption rate of ibuprofen.     

Drug release from tableted wet granulations comprising cellulosic (HPMC or HPC) and hydrophobic component.

The effects of component nature, proportion and processing on the release rate and mechanism were investigated for tablets comprising drug, cellulosic polymer and hydrophobic components. Four drugs differing in solubility (diclofenac sodium, ibuprofen, naproxen and indomethacin), two cellulosic polymers (HPC and HPMC) and hydrophobic Emvelop were used in two levels of mass fraction and weight ratio of drug:carrier and of cellulosic-hydrophobic component. Compression was applied after granulation or physical mixing. Drug release was evaluated in pH 6.5 phosphate buffer BP and elucidation of the release mechanism was attempted by fitting kinetic models. Statistical significance of the effects of formulation variables on the release rate and mechanism expressed by the coefficient, k, and exponent, n, of the power law kinetic model, respectively, was evaluated by ANOVA. It was found that for the release mechanism most significant is the effect of drug solubility followed by cellulosic polymer type, mixing procedure and drug mass fraction. Significant interaction between drug solubility and type of cellulosic polymer indicated that alteration in the swelling of HPMC and HPC is caused by the drug solubility. Weight ratio of cellulosic-hydrophobic component does not affect the release mechanism, but only the release rate. Similarly, for the release rate most significant was found the effect of drug solubility, followed by cellulosic polymer type, weight ratio of cellulosic-hydrophobic component, mixing method and drug mass fraction. Also significant were the interactions of drug solubility with the type and proportion of the cellulosic polymer and the processing applied. Depending on the drug solubility and type of polymer present, wet granulation can increase or decrease the release rate.     

聚L-乳酸与聚乙二醇-b-聚L-乳酸电纺纤维中布洛芬的释放

目的制备并评价包载有布洛芬的聚L-乳酸和聚乙二醇嵌段聚L-乳酸电纺纤维毡。方法静电纺丝法制备包载布洛芬的纤维毡,扫描电子显微镜观察纤维形态,广角X射线衍射扫描观察纤维表面结晶状态,差示扫描量热评价药物在高分子材料中的结合状态。高效液相色谱测定体外酶降解药物释放结果。结果纤维直径在0.3～1.5μm之间,表面光滑无结晶态物质析出,X射线衍射没有发现布洛芬特征峰出现。差示扫描量热结果显示布洛芬的加入使纤维的玻璃化温度降低。药物释放结果显示相对于纯聚乳酸材料,当载体材料为聚乙二醇嵌段的聚乳酸时,纤维中的布洛芬呈现更快的释放速率,聚乙二醇有利于释放介质中酶对纤维的作用。20%载药量纤维中的药物释放速率大于10%载药量纤维中的药物释放速率,蛋白酶K加快药物的释放速率。结论成功制得布洛芬电纺纤维,药物被较好包裹在纤维内部,聚乳酸电纺纤维中聚乙二醇嵌段对布洛芬释放行为有明显的影响,需要在进一步研究中注意。     

Design and study of ibuprofen disintegrating sustained-release tablets comprising coated pellets.

One challenge in tableting of sustained-release multiparticulates is maintaining the desired drug release after compaction. The aim of this study was to design sustained-release ibuprofen tablets which upon oral ingestion rapidly disintegrate into sustained-release pellets in which the integrity of the pellet core and/or coat is preserved. First free films composed of Eudragit RS 30D and RL 30D in 4:1 ratio and containing different levels of triethyl citrate (TEC) were prepared and tested to optimize the plasticizer level. Cured Eudragit based pellets with 60% ibuprofen loading which in our previous study showed proper mechanical properties for compression were coated with Eudragit RS 30D/RL 30D (4:1) containing 20% triethyl citrate at different coating levels. The mechanical properties of the coated pellets were tested. Polymer coated pellets were compacted into tablets either alone or with a blend of excipients comprising Avicel, PEG 4000, cross-linked PVP. A 3(2) full factorial design was used to optimize the filler blend composition. Effects of pellet to filler ratio, compression force and granulation of filler on tablet characteristics were investigated. Results of mechanical test showed that the coating of cured pellets had no significant effect on yield point and elastic modulus of the pellets. In the case of 5% coating level sustained release of ibuprofen over a period of 24h was achieved. The results obtained from tableting procedure showed that by selecting suitable filler blend (60% Avicel, 10% cross-linked PVP and 30% PEG 4000), compression force, and granulation of filler it was possible to prepare sustained-release tablets containing high ratio of coated pellets (even 80%) with desirable strength, disintegration time, and drug release rate. It was observed that compression force, pellet to filler ratio, composition of filler blend and granulation of fillers had no effect on drug release rate from compacted pellets but had significant influence on tablet strength, friability, and disintegration time. SEM graphs and in vitro release profiles for compacted pellets showed no apparent damage to the coated pellets as a result of the compaction process.     

Preparation and evaluation of fast-release mephenamic acid microspheres

Mephenamic acid is characterized by low solubility, which affects its dissolution rate and bioavailability. The objective of this study was to develop fast-release microspheres of ammonium salt of the drug (AMM) by emulsion congealing.The effect of polymer, drug to polymer ratio, surfactant, type and volume of oil phase, stirring rate, microsphere size, encapsulation efficiency and stability of the microspheres were investigated. The results pointed out a good yield (69–98%) and encapsulation efficiency (71–100%). Optimum conditions include moderate molecular weight PEG, inclusion of Tween 20 and/or Span 80, high ratio of PEG (1 : 4, drug : PEG), use of mineral oil and high stirring rate (2000 rpm). Dissolution efficiency ranged between 57% and 90%. Effect of ageing on drug content and release revealed that the microspheres prepared remained stable throughout 1 year of storage. The described method was simple, efficient and resulted in stable microspheres with enhanced drug release.     

Determination of ibuprofen solubility in wax: a comparison of microscopic, thermal and release rate techniques.

The solubility of ibuprofen in Witepsol H15, a semi-solid wax matrix, was determined using microscopy, Higuchi release rates and HyperDSC (high speed differential scanning calorimetry); solubility values of 15-20%, 18.6% and 12.7% w/w resulted from the three techniques, respectively. Microscopy was useful in additionally examining crystal size, shape and homogeneity. Release rate experiments showed that release from these formulations followed Higuchi kinetics with an inflection in release rate constant at the drug loading corresponding to drug solubility. HyperDSC not only measured solubility but also determined the melting point of the formulation. The results from these three techniques correlated well, suggesting that the simpler techniques of microscopy or HyperDSC are appropriate to determine the solubility in semi-solid pharmaceutical formulations.     

Enhanced controlled release of loratadine from the ethylene-vinyl acetate matrix containing plasticizer

An ethylene-vinyl acetate (EVA) matrix containing plasticizer was prepared as a potential controlled release system for loratadine. The EVA matrix containing loratadine was prepared as the transdermal device using casting methods. The solubility of loratadine according to the volume fraction of PEG 400 was determined. The effects of the drug concentration, temperature, and plasticizers on the release of the drug were determined at 37 degrees C using 40% PEG 400 solution as the receptor medium using the modified Keshary-Chien cell. Some types of plasticizers. such as citrates and phthalates, were used to prepare the pores and increase the flexibility of the EVA matrix. The solubility test according to the PEG 400 volume fraction revealed the highest solubility in the 40% PEG 400 solution. The rate of drug released from the EVA matrix increased with increasing temperature and drug loading. There was a linear relationship between the release rate and the square root of the loading dose. The activation energy for drug release from the EVA matrix with a loading dose of 1%, 2%, 3%, 4%, and 5% was estimated to be 6.83, 6.80, 6.77, 6.71, and 6.65 kcal/mol, respectively Among the plasticizers used, diethyl phthalate showed the highest level of loratadine release. In conclusion, an EVA matrix containing plasticizer could be used to enhance the controlled release of loratadine.     

Enhanced Controlled Release of Loratadine From the Ethylene-vinyl Acetate Matrix Containing Plasticizer

An ethylene-vinyl acetate (EVA) matrix containing plasticizer was prepared as a potential controlled release system for loratadine. The EVA matrix containing loratadine was prepared as the transdermal device using casting methods. The solubility of loratadine according to the volume fraction of PEG 400 was determined. The effects of the drug concentration, temperature, and plasticizers on the release of the drug were determined at 37°C using 40% PEG 400 solution as the receptor medium using the modified Keshary-Chien cell. Some types of plasticizers. such as citrates and phthalates, were used to prepare the pores and increase the flexibility of the EVA matrix. The solubility test according to the PEG 400 volume fraction revealed the highest solubility in the 40% PEG 400 solution. The rate of drug released from the EVA matrix increased with increasing temperature and drug loading. There was a linear relationship between the release rate and the square root of the loading dose. The activation energy for drug release from the EVA matrix with a loading dose of 1%, 2%, 3%, 4%, and 5% was estimated to be 6.83, 6.80, 6.77, 6.71, and 6.65 kcal/mol, respectively Among the plasticizers used, diethyl phthalate showed the highest level of loratadine release. In conclusion, an EVA matrix containing plasticizer could be used to enhance the controlled release of loratadine.     

Enhanced dissolution of ibuprofen using solid dispersion with poloxamer 407

To improve its dissolution, ibuprofen solid dispersions (SDs) were prepared, characterized by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), and Fourier transform infrared spectroscopy (FTIR), and evaluated for solubility, and in-vitro ibuprofen release. Loss of individual surface properties during melting and re-solidification as revealed by SEM micrographs indicated the formation of effective SDs. Absence or shifting towards the lower melting temperature of the drug peak in SDs and physical mixtures in DSC study indicated the possibilities of drug-polymer interactions. FTIR spectra showed the presence of drug crystalline in SDs. The effect of improved dissolution on the oral absorption of ibuprofen in rats was also studied. Quicker release of ibuprofen from SDs in rat intestine resulted in a significant increase in AUC and C_max, and a significant decrease in T_max over pure ibuprofen. Comparison of the enhanced solubility, dissolution, AUC, and C_max of ibuprofen from different poloxamers suggested that the preparation of ibuprofen SDs using P 407 as a meltable hydrophilic polymer carrier could be a promising approach to improve its solubility, dissolution and absorption rate.     

Enhanced rectal bioavailability of ibuprofen in rats by poloxamer 188 and menthol

To improve the bioavailability of poorly water-soluble ibuprofen in the rectum with poloxamer and menthol, the effects of menthol and poloxamer 188 on the aqueous solubility of ibuprofen were investigated. The dissolution and pharmacokinetic study of ibuprofen delivered by the poloxamer gels composed of poloxamer 188 and menthol were then performed. In the absence of poloxamer, the solubility of ibuprofen increased until the ratio of menthol to ibuprofen increased from 0:10 to 4:6 followed by an abrupt decrease in solubility above the ratio of 4:6, indicating that four parts menthol formed eutectic mixture with six parts ibuprofen. In the presence of poloxamer, the solutions with the same ratio of menthol to ibuprofen showed abrupt increase in the solubility of ibuprofen. The poloxamer gel with menthol/ibuprofen ratio of 1:9 and higher than 15% poloxamer 188 showed the maximum solubility of ibuprofen, 1.2mg/ml. Menthol improved the dissolution rates of ibuprofen from poloxamer gels. Release mechanism showed that the release rate of ibuprofen from the poloxamer gels without menthol was independent of the time but the drug might be released from the poloxamer gels with menthol by Fickian diffusion. Furthermore, the poloxamer gel with menthol (poloxamer/menthol/ibuprofen (15%/0.25%/2.5%)) gave significantly higher initial plasma concentrations, C(max) and AUC of ibuprofen than did solid suppository, indicating that the drug from poloxamer gel could be more absorbed than that from solid one in rats. Thus, the poloxamer gel with poloxamer 188 and menthol was a more effective rectal dosage form for ibuprofen.     

Synthesis and hydrolytic behavior of ibuprofen prodrugs and their PEGylated derivatives

Polyethylene glycol (PEG) derivatives of ibuprofen were prepared by esterification of PEG monosuccinate with hydroxy ethyl ester (HEE), hydroxy ethylamide (HEA), and hydroxy ethyl thioester (HET) of ibuprofen. Hydrolysis of HEE-PEG, HEA-PEG, and HET-PEG were studied in vitro with or without esterases to investigate the applicability of these PEGylated prodrugs. The polymeric prodrugs released major fraction of the parent drug (ibuprofen) and a small fraction of hydroxy ethyl derivatives after 48 hr. In HET-PEG, the amount of drug release was higher than HEE-PEG and HEA-PEG. The difference between acidic and alkali buffered solutions was considerable. In human plasma, 50% of drug was released after 150 hr incubation at 37°C from HET-PEG.     

Synthesis and Hydrolytic Behavior of Ibuprofen Prodrugs and their PEGylated Derivatives

Polyethylene glycol (PEG) derivatives of ibuprofen were prepared by esterification of PEG monosuccinate with hydroxy ethyl ester (HEE), hydroxy ethylamide (HEA), and hydroxy ethyl thioester (HET) of ibuprofen. Hydrolysis of HEE-PEG, HEA-PEG, and HET-PEG were studied in vitro with or without esterases to investigate the applicability of these PEGylated prodrugs. The polymeric prodrugs released major fraction of the parent drug (ibuprofen) and a small fraction of hydroxy ethyl derivatives after 48 hr. In HET-PEG, the amount of drug release was higher than HEE-PEG and HEA-PEG. The difference between acidic and alkali buffered solutions was considerable. In human plasma, 50% of drug was released after 150 hr incubation at 37°C from HET-PEG.     

Application of TPX polymer membranes for the controlled release of triprolidine.

Oral administration of triprolidine, antihistamines, may cause many adverse effects such as dry mouth, sedation, dizziness and transdermal drug delivery was considered. Poly(4-methyl-1-pentene) (TPX) membrane, which has good mechanical strength was fabricated by the casting method. TPX membranes was a little brittle and the plasticizers was added for preparing the membranes. The present study was carried out to evaluate the possibility of using the polymer TPX membrane as a controlling membrane and further develop a TPX matrix system for transdermal delivery of triprolidine. The effects of molecular weights of TPX, plasticizers, polyethylene glycol (PEG) 400, drug concentration, and temperature on drug release were studied. The solubility of triprolidine increased exponentially as the increased volume fraction of PEG 400 in saline, and the rate of permeation through TPX membrane was proportional to PEG 400 volume fraction. The release rate of drug from the TPX matrix increased with increased temperature and drug concentration. Among the plasticizers used such as alkyl citrates, phthalates and sebacate, tetra ethyl citrate (TEC) showed the best enhancing effects. Enhancement factor of TEC was 3.76 from TPX matrix at 37 degrees C. The transdermal controlled release of triprolidine system could be developed using the TPX polymer including the plasticizer.     

Synthesis,characterization, in vitro and in vivo evaluation of PEGylated oridonin conjugates

Oridonin (ORI), a diterpenoid compound with promising antitumor activity, was proved to possess potent antileukemia efficacies in vitro and in vivo recently. However, the development and application of ORI was limited by its poor solubility and rapid plasma clearance. The purpose of this study was to solve these problems. PEGylated oridonin linked with succinic acid (SA) as spacer moiety (PEG-SA-ORI conjugate) was synthesized. mPEG amines with four specifications of molecular weight (MW) were utilized. All polymeric conjugates showed satisfactory aqueous solubility and in vitro studies implied that the drug solubility and release features of conjugates were relevant to PEGs. The drug solubility increased more when the MW of PEG was lower, while more significant sustained-release effect was shown with higher PEG MW. Moreover, the release behaviors of conjugates showed a pH-sensitive property. In vivo pharmacokinetic studies demonstrated that the elimination half-life was prolonged in comparison with ORI solution. PEGylation could be a promising method to obtain better efficacy in the field of drug delivery system.     

Preparation and characterization of controlled release matrices based on novel seaweed interpolyelectrolyte complexes

Novel interpolyelectrolyte complexes (IPECs) between naturally sulfated polysaccharides of the seaweed Polysiphonia nigrescens (PN) and cationized agaroses (CAG) and Eudragit E (EE) were prepared using an organic solvent free process, characterized, and explored for controlled drug release. Tablets containing model drug ibuprofen and IPECs were prepared by direct compression. Drug release in acid medium was low owing to the low solubility of ibuprofen in that condition and to the matrix action. Zero order drug release was determined in the buffer stage (pH=6.8), with Fickian diffusion predominating over relaxation during the initial phases. Relaxation appears to increase along the release process and even overcomes diffusion for some systems. Drug release profiles could be controlled by varying the content of IPECs in the tablets. Also, the change in molecular weight and the degree of substitution of the components allowed altering the release profiles.     

Formulation and in vivo hypoglycemic effect of glipizide solid dispersion

The present study was carried out with a view to enhance dissolution rate of poorly water-soluble drug glipizide (GZ) (BCS class II) using polyethylene glycol (PEG) 6000, PEG 8000 and poloxamer (PXM) 188 as carriers. Solid dispersions (SDs) were prepared by melting method using different ratios of glipizide to carriers. Phase solubility study was conducted to evaluate the effect of carrier on aqueous solubility of glipizide. SD was optimized by drug content estimation and in vitro dissolution study and optimised SD was subjected to bulk characterization, Scanning electron microscopy (SEM), Fourier transformation infrared spectroscopy (FTIR), Differential scanning calorimetry (DSC) and X-ray diffraction study (XRD). Preclinical study was performed in mice to study the decrease in blood glucose level from prepared SD compared with pure drug. Due to high solubility and drug release, PXM 188 in weight ratio of 1:2 was optimized. Decrease in blood glucose level in mice from SD was significantly higher (p < 0.05) compared to pure glipizide. Thus, solid dispersion technique can be successfully used for the improvement of the dissolution profile of GZ.     

Development of novel ibuprofen-loaded solid dispersion with improved bioavailability using aqueous solution

To develop a novel ibuprofen-loaded solid dispersion with enhanced bioavailability, various ibuprofen-loaded solid dispersions were prepared with water, HPMC and poloxamer. The effect of HPMC and poloxamer on aqueous solubility of ibuprofen was investigated. The dissolution and bioavailability of solid dispersion in rats were then evaluated compared to ibuprofen powder. When the amount of carrier increased with a decreased in HPMC/poloxamer ratio, the aqueous solubility of ibuprofen was elevated. The solid dispersion composed of ibuprofen/HPMC/poloxamer at the weight ratio of 10:3:2 improved the drug solubility approximately 4 fold. It gave significantly higher initial plasma concentration, AUC and Cmax of drug than did ibuprofen powder in rats. The solid dispersion improved the bioavailability of drug about 4-fold compared to ibuprofen powder. Thus, this ibuprofen-loaded solid dispersion with water, HPMC and poloxamer was a more effective oral dosage form for improving the bioavailability of poor water-soluble ibuprofen.     

Effect of drug solubility on in vitro availability rate from suppositories with polyethylene glycol excipients

Factors involved in the availability mechanism of different drugs from suppositories with polyethylene glycol (PEG) excipients were studied using an in vitro model of the rectal compartment with a porous membrane simulating the rectal barrier. Different from lipophilic excipients, the drug is released as a consequence of the progressive dissolution of PEG into the intrarectal aqueous phase. Drug concentration in this small intrarectal phase produces the gradient against the large volume of the plasmatic phase, which regulates the diffusion rate through the barrier. As with lipophilic excipients, drug solubility in water was found to be an important factor influencing suppository release rate. Nevertheless, PEG influenced in vitro drug availability considerably, by increasing both drug solubility and dissolution rate. The osmotic effect of PEG in the intrarectal compartment influenced the increase in volume of the aqueous phase. The results, compared with those obtained from suppositories with a lipophilic excipient, show a higher dissolution rate from PEG excipient, but a higher diffusion rate across the barrier did not always correspond. Drugs less soluble in water showed a greater availability from PEG suppositories. On the contrary the more soluble drugs were less available.