Dissolution Behavior of Griseofulvin Solid Dispersions Using Polyethylene Glycol, Talc, and Their Combination as Dispersion Carriers

Griseofulvin solid dispersions were prepared using polyethylene glycol 6000 (PEG), talc, and their combination as carriers by the solvent method. The dissolution of griseofulvin from these dispersions was studied. It was found that in these carriers the drug dissolution rate was a function of drug loading. The dissolution rate from dispersions prepared using PEG was similar to that from PEG/talc dispersions, especially at a low percentage of drug loading. Dispersions of PEG and PEG/talc provided dissolution rates faster than those from dispersions of talc. The incorporation of talc in PEG yielded dispersions with properties of less tackiness and ease for handling. Dissolution kinetics, based on the Hixson-Crowell equation, was used to determine the characteristics of griseofulvin particles in dispersions. Linear relationships were obtained for PEG and PEG/talc dispersions that indicated the presence of a uniformly sized monoparticulate system, whereas deviation from linearity was observed for talc dispersions. This appeared to be a multiparticulate system in which particles were present as free form and adsorbed form on the surface of talc.     

Enhanced Dissolution of Ibuprofen Using Solid Dispersion with Polyethylene Glycol 20000

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 (FTIR), and evaluated for solubility and in vitro drug 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 toward the lower melting temperature of the drug peak in SDs 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. Preliminary results from this study suggested that the preparation of fast dissolving ibuprofen SDs by low-temperature melting method using polyethylene glycol 20000 as a meltable hydrophilic polymer carrier could be a promising approach to improve solubility, dissolution, and absorption rate of ibuprofen.     

Carbamazepine and Polyethylene Glycol Solid Dispersions: Preparation,in Vitro Dissolution,and Characterization

Abstract

The objective of this study was to prepare solid dispersions of carbamazepine (CBZ) using polyethylene glycol (PEG) 4000 and PEG 6000, measure the dissolution, and characterize using x-ray diffraction, DSC, and IR spectroscopy. Solid dispersions were prepared by either the melt or solvent methods. A comparison of dissolution profiles of the solid dispersions indicated dramatic increases in the rate and extent of CBZ dissolution from solid dispersions. The dissolution of physical mixtures provided evidence of the solubilizing effects of PEGs. Untreated CBZ exhibited 10.09 ± 2.92% dissolution in 10 min (D_l0); whereas, a melt of PEG 6000 and CBZ at a ratio of 6: 1 provided 36.49 ± 1.97% and a melt of PEG 4000 and CBZ at a ratio of 6: 1 gave a D₁₀ of 23.59 ± 1.45%. The rate and extent of dissolution of CBZ were significantly higher when blends of the PEGs were employed to prepare solid dispersion. The melt method provided significantly higher rate and extent of dissolution of CBZ than the solvent method. Also, the rate and extent of dissolution of CBZ were significantly greater when the solid dispersion was cooled at room temperature as opposed to with ice (faster). X-ray diffractometry revealed almost a complete loss of crystallinity of CBZ in solid dispersions. IR spectrometry indicated an increase in amorphocity of the PEGs after melting. IR spectra suggested that no complexation occurred between the PEGs and CBZ. Alterations in the crystallinity of the system were also supported by the DSC thermograms. Decreasing heats of fusion implied decrease in crystallinity, which would be expected to provide greater dissolution rates. Peak melting temperatures obtained from the thermograms ruled out the possibility of the formation of a eutectic mixture. However, the formation of solid solution could also be a possible mechanism for the increase in dissolution.     

Carbamazepine and Polyethylene Glycol Solid Dispersions: Preparation, in Vitro Dissolution, and Characterization

The objective of this study was to prepare solid dispersions of carbamazepine (CBZ) using polyethylene glycol (PEG) 4000 and PEG 6000, measure the dissolution, and characterize using x-ray diffraction, DSC, and IR spectroscopy. Solid dispersions were prepared by either the melt or solvent methods. A comparison of dissolution profiles of the solid dispersions indicated dramatic increases in the rate and extent of CBZ dissolution from solid dispersions. The dissolution of physical mixtures provided evidence of the solubilizing effects of PEGs. Untreated CBZ exhibited 10.09 ± 2.92% dissolution in 10 min (D_l0); whereas, a melt of PEG 6000 and CBZ at a ratio of 6: 1 provided 36.49 ± 1.97% and a melt of PEG 4000 and CBZ at a ratio of 6: 1 gave a D₁₀ of 23.59 ± 1.45%. The rate and extent of dissolution of CBZ were significantly higher when blends of the PEGs were employed to prepare solid dispersion. The melt method provided significantly higher rate and extent of dissolution of CBZ than the solvent method. Also, the rate and extent of dissolution of CBZ were significantly greater when the solid dispersion was cooled at room temperature as opposed to with ice (faster). X-ray diffractometry revealed almost a complete loss of crystallinity of CBZ in solid dispersions. IR spectrometry indicated an increase in amorphocity of the PEGs after melting. IR spectra suggested that no complexation occurred between the PEGs and CBZ. Alterations in the crystallinity of the system were also supported by the DSC thermograms. Decreasing heats of fusion implied decrease in crystallinity, which would be expected to provide greater dissolution rates. Peak melting temperatures obtained from the thermograms ruled out the possibility of the formation of a eutectic mixture. However, the formation of solid solution could also be a possible mechanism for the increase in dissolution.     

Stability and Dissolution Rates of Corticosteroids in Polyethylene Glycol Solid Dispersions

A study has been made to examine the stability and dissolution rates of prednisolone, prednisone and hydrocortisone formulated as solid dispersions in polyethylene glycols. Of the five PEG samples used, three enhanced the chemical instability of the steroids; the effect being dependent on the PEG sample and storage conditions of the solid dispersions. Dissolution rates of the steroids were relatively fast from the solid dispersions and showed no significant changes upon storage. Using two methods of analysis (direct UV spectrophotometry and the USP blue tetrazolium method), it is concluded that the chemical instability of the steroids in some PEG samples was due to alterations in the dihydroxy acetone side chain. One of the decomposition products found appeared to be an acidic compound resulting from oxidation of the C₁₇ side chain. The oxidation is presumably accelerated by a peroxide impurity in PEG samples.     

Stability and Dissolution Rates of Corticosteroids in Polyethylene Glycol Solid Dispersions

Abstract

A study has been made to examine the stability and dissolution rates of prednisolone, prednisone and hydrocortisone formulated as solid dispersions in polyethylene glycols. Of the five PEG samples used, three enhanced the chemical instability of the steroids; the effect being dependent on the PEG sample and storage conditions of the solid dispersions. Dissolution rates of the steroids were relatively fast from the solid dispersions and showed no significant changes upon storage. Using two methods of analysis (direct UV spectrophotometry and the USP blue tetrazolium method), it is concluded that the chemical instability of the steroids in some PEG samples was due to alterations in the dihydroxy acetone side chain. One of the decomposition products found appeared to be an acidic compound resulting from oxidation of the C₁₇ side chain. The oxidation is presumably accelerated by a peroxide impurity in PEG samples.     

Enhancement of Dissolution of Ethopropazine Using Solid Dispersions Prepared with Phospholipid and/or Polyethylene Glycol

The purpose of this study was to improve the dissolution properties of a poorly water soluble and bioavailable drug, ethopropazine HCl (ET), by incorporating the drug in three different types of solid dispersion systems. Solid dispersions of ET were prepared using 1:1 (w/w) ratios of (1) phospholipid (1,2 dimyristoyl-sn-glycerophosphocholine) (DMPC), (2) polyethylene glycol 8000 (PEG8000), and (3) a novel combination of both DMPC and PEG8000. Using the solvent method of preparation, ET and DMPC and/or PEG were dissolved in chloroform, and solvent subsequently was evaporated using nitrogen gas. The resulting solid dispersion(s) was passed through a 60-mesh sieve. Characterization of ET/DMPC solid dispersion was performed by differential scanning calorimetry (DSC) and X-ray diffractometry studies. Dissolution studies conducted in phosphate buffered saline (PBS) (pH 7.4, 37°C ± 0.5°C) using the USP type II (paddle) dissolution apparatus showed significant increases in the dissolution rate of ET with all the solid dispersions in this study. Specifically, within the first 5 min (D5), solid dispersions containing ET/DMPC (1:1) showed an eightfold increase in dissolution; in combination with DMPC and PEG8000 (1:1), there was an approximately sixfold increase; and a fourfold increase was observed with PEG8000 (1:1). Complete dissolution of all solid dispersions occurred within 60 min (D60) of the run. Storage of the ET/DMPC sample for over 4.5 months revealed a decrease in the dissolution rate when compared to freshly prepared sample. Overall, it was concluded that the dissolution rate of ET significantly improved when dispersed in all the selected carrier systems. However, the solid dispersion of ET/DMPC was observed to be superior to the other combinations used.     

Enhancement of Dissolution of Ethopropazine Using Solid Dispersions Prepared with Phospholipid and/or Polyethylene Glycol

The purpose of this study was to improve the dissolution properties of a poorly water soluble and bioavailable drug, ethopropazine HCl (ET), by incorporating the drug in three different types of solid dispersion systems. Solid dispersions of ET were prepared using 1:1 (w/w) ratios of (1) phospholipid (1,2 dimyristoyl-sn-glycerophosphocholine) (DMPC), (2) polyethylene glycol 8000 (PEG8000), and (3) a novel combination of both DMPC and PEG8000. Using the solvent method of preparation, ET and DMPC and/or PEG were dissolved in chloroform, and solvent subsequently was evaporated using nitrogen gas. The resulting solid dispersion(s) was passed through a 60-mesh sieve. Characterization of ET/DMPC solid dispersion was performed by differential scanning calorimetry (DSC) and X-ray diffractometry studies. Dissolution studies conducted in phosphate buffered saline (PBS) (pH 7.4, 37°C ± 0.5°C) using the USP type II (paddle) dissolution apparatus showed significant increases in the dissolution rate of ET with all the solid dispersions in this study. Specifically, within the first 5 min (D5), solid dispersions containing ET/DMPC (1:1) showed an eightfold increase in dissolution; in combination with DMPC and PEG8000 (1:1), there was an approximately sixfold increase; and a fourfold increase was observed with PEG8000 (1:1). Complete dissolution of all solid dispersions occurred within 60 min (D60) of the run. Storage of the ET/DMPC sample for over 4.5 months revealed a decrease in the dissolution rate when compared to freshly prepared sample. Overall, it was concluded that the dissolution rate of ET significantly improved when dispersed in all the selected carrier systems. However, the solid dispersion of ET/DMPC was observed to be superior to the other combinations used.     

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 in Vitro Dissolution Profiles of Tolazamide-Polyethylene Glycol Solid Dispersions

The objective of this study is to prepare solid dispersions of tolazamide (TLZ) using polyethylene glycol (PEG) and measure the dissolution of TLZ. PEG 8000 was used as carrier to prepare solid dispersions by melt and solvent methods. Dissolution studies indicated a remarkable increase in the rate of dissolution of TLZ when dispersed in PEG as well as with physical mixture of TLZ and PEG. The rate of dissolution of TLZ was faster with solid dispersions containing TLZ:PEG (1:5) and (1:10) compared to physical mixtures and pure TLZ. The effect of buffer on dissolution was studied. In general the dissolution of TLZ was less in phosphate buffered saline (PBS, pH 7.4) compared to Tris buffer. However, there was no significant difference in the extent of dissolution of TLZ from solid dispersions and physical mixture compared to pure TLZ. Solid dispersions prepared by solvent method showed faster dissolution rates compared to melt method. These results suggest that the rate of dissolution can be increased by improving the wetting property of tolazamide.     

Preparation and Characterization of Solid Dispersions of Piroxicam with Hydrophilic Carriers

ABSTRACT

The objective of this study was to improve the dissolution rate of a poor water soluble drug, piroxicam, by solid dispersion technique. Solid dispersions were prepared by three different methods depending on the type of carrier. The dissolution rate of piroxicam was markedly increased in solid dispersion of myrj 52, Eudragit® E100 and mannitol. Solubility studies revealed a marked increase in the solubility of piroxicam with an increase in myrj 52 and Eudragit® E100 concentrations. Data from the X-ray diffraction and FT-IR spectroscopy showed that piroxicam was amorphous in the solid dispersions prepared with dextrin and Eudragit® E100.     

Solubility and Dissolution of Etoposide from Solid Dispersions of PEG 8000

The Solubility and dissolution of etoposide from solid dispersion of PEG 8000, prepared by the fusion method, were investigated. Stability studies revealed that the etoposide was stable in water for three days at 37 ± 0.5°C alone and as a physical mixture with PEG 8000. However, nearly 5% decomposition was oberved in aqueous solutions made from solid dispersions. TLC, IR and HPLC studies showed both the drug and carrier were stable during the fusion process. Aqueous solubility of etoposide from solid dispersions with etoposide: PEG 8000 ratios of 1:5, 1:10, 1:20, 1:30 and 1:40, was studied at 37 ± 0.5°C, and found to be significantly higher than that of etoposide alone or from its physical mixtures with PEG 8000. These dispersions increased the solubility of etoposide by 32.3%, 96.8%, 133.5%, 280.7% and 326.6% respectively compared to that of etoposide alone, whereas only 1:40 etoposide: PEG 8000 physical mixture demonstrated a significant increase in etoposide solubility (16.1%). Dissolution studies, on the solid dispersions in water at 37 ± 0.5°C, revealed a marked increase in the dissolution rate of etoposide from 1:20, 1:30 and 1:40 solid dispersions with 100% drug dissolving within 1 minute; dissolution time for 1:5 and 1:10 dispersions, and all physical mixtures was 3 minutes while etoposide alone required 30 minutes for complete drug dissolution. The melting behavior of the etoposide-PEG 8000 mixtures and subsequent thermal analysis of the melts suggested that the increase of solubility of etoposide was mostly due to the formation of a solid solution of etoposide in PEG 8000.     

Processing of Nimesulide-PEG 400-PG-PVP Solid Dispersions: Preparation,Characterization, and In Vitro Dissolution

Abstract

The objective of this investigation was to study the influence of dissolution enhancers such as polyethylene glycol 400, propylene glycol, polyvinylpyrrolidone K30, sodium lauryl sulfate, and Tween 80 on in vitro dissolution of a model active pharmaceutical material—nimesulide. Preliminary studies were conducted using a physical blend of nimesulide, and the adjuvants and solid dispersions were prepared using solvent evaporation and cogrinding methods. Aqueous solution of adjuvants was first triturated with nimesulide, followed by mixing with lactose and microcrystalline cellulose, and finally water was evaporated under vacuum in a cogrinding method. A 3³ factorial design was adopted in a cogrinding method using the concentration of polyethylene glycol 400, propylene glycol, and polyvinylpyrrolidone K30 as independent variables. Tween 80 and sodium lauryl sulfate were added in all the batches. Full and reduced models were evolved for different dependent variables. The reduced models were validated using two checkpoints. Angle of repose <35°, percentage of drug released in 30 min (Q₃₀)>40%, 45 min (Q₄₅)>50%, and 120 min (Q₁₂₀)>60% were used as constraints for the selection of an optimized batch. Contour plots are presented for the selected dependent variables. Polyvinylpyrrolidone was found to be more effective in increasing the drug dissolution, compared with polyethylene glycol 400 and propylene glycol. The granule flow was adversely affected when high levels of liquid adjuvants were used in formulations. Wettability study was conducted to measure wetting time for pure drug and the optimized batch. Improved drug dissolution was attributed to improved wetting and the solubilizing effect of adjuvants from the pseudosolid dispersions of nimesulide. Significant improvement in drug dissolution was observed (Q₁₂₀ = 70%), compared with pure drug powder (Q₁₂₀ = 15%). In conclusion, dissolution of nimesulide can be modulated using an appropriate blend of pharmaceutical adjuvants.     

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.     

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.     

Improving the Dissolution and Bioavailability of Nifedipine Using Solid Dispersions and Solubilizers

ABSTRACT

Nifedipine (NF) is a poorly water-soluble drug, of low and irregular bioavailability after oral administration. Although some reports have attempted to improve the dissolution of NF using solid dispersions and solubilizers, little literature information is available on the in vivo performance of such preparations. The aim of the present work was to improve the therapeutic efficacy of NF via incorporation into different types of carriers, and to investigate their in vitro dissolution and bioavailability in rabbits. Nifedipine solid dispersions were prepared by fusion, solvent, and freeze-drying methods with polyethylene glycol (PEG) 6000 and PEG monomethylether 5000 (PEG MME 5000). Complexation of NF with β-cyclodextrin (β-CyD) and solubilization by sodium lauryl sulfate (SLS) have also been studied. The dissolution was determined by the flow-through cell in order to maintain perfect sink conditions. The solid dispersions resulted in a significant increase in the dissolution rate as compared to pure drug. The highest NF dissolution rate was obtained from solid dispersions containing 95% PEG 6000 prepared by the solvent method. While, unexpectedly, the highest absorption in rabbits was obtained from 95% PEG 6000 prepared by the fusion method. Compared to SLS, β-CyD gave higher in vitro and in vivo values. Differential scanning calorimetry (DSC) and powder x-ray diffractometry indicated that NF in solid dispersions is homogeneously distributed, and no drug crystallized out of the system. The DSC thermograms of NF-β-CyD complex and NF/SLS solid mixture showed a decrease in the NF endothermic peak. The x-rays showed different diffraction patterns of pure NF and pure carrier, suggesting the formation of a new solid form.     

Preparation,Characterization and In Vitro Evaluation of Solid Dispersions Containing Docetaxel

Solid dispersions using water-soluble carriers were studied for improving the dissolution of docetaxel, a poorly soluble compound. In order to obtain the most optimized formulation, we prepared many solid dispersions with different carriers, different solvents, or at a series of drug-to-carrier ratios, and compared their dissolution. The accumulative dissolution of docetaxel from poloxamer 188 was more excellent than that from PVP_k30 and glyceryl monostearate, and the dissolution of docetaxel from solid dispersion was markedly higher than that of pure docetaxel; meanwhile the increased dissolution was partly dependent on the ratios of docetaxel and poloxamer 188. The ethanol used to prepare solid dispersion is of more significant effect on the dissolution of docetaxel than that of acetone. The docetaxel/poloxamer 188 system was characterized by differential scanning calorimetry (DSC), X-ray diffractometry (XRD), and environmental scanning electron microscope (ESEM). The results of DSC, XRD, and ESEM analyses of docetaxel/poloxamer 188 system showed that there are intermolecular interactions between docetaxel and poloxamer, and the crystallinity of docetaxel disappeared. These results show that solid dispersion is a promising approach of developing docetaxel drug formulates.     

Dissolution, Bioavailability and Ulcerogenic Studies on Solid Dispersions of Indomethacin in Water Soluble Cellulose Polymers

The dissolution rate, bioavailability and ulcerogenic activity of indomethacin dispersed in water soluble cellulose polymers was investigated. Solid dispersions of indomethacin in hydroxypropyl cellulose-SL (HPC-SL), hydroxypropylmethyl cellulose (HPMC) and hydroxyethyl cellulose (HEC) were prepared by common solvent method with a view to improve its dissolution and absorption characteristics. The dispersions were evaluated by X-ray diffraction, TLC, IR, dissolution rate, bioavailability and ulcerogenic studies. TLC and IR studies indicated no interaction between indomethacin and carriers. Indomethacin in the dispersions was found to be in amorphous form. Marked increase in the dissolution rate and efficiency of indomethacin was observed in the case of solid dispersions. HPC-SL gave the highest dissolution improvement. A 30-fold increase in dissolution was observed with indomethacin-HPC-SL (9:1) dispersion.

In vivo studies in human subjects showed a significant increase in absorption rate (k_a) and serum levels of indomethacin with solid dispersions when compared to indomethacin alone. However, the extent of bioavailabilty was the same with both indomethacin and its solid dispersions. About 70-80 per cent reduction in ulcerogenic activity was observed with solid dispersions and the dispersions were found to have negligible ulcerogenic activity.     

Solid State and Dissolution Rate Characterization of Co-Ground Mixtures of Nifedipine and Hydrophilic Carriers

ABSTRACT

Co-ground powders of the poorly water-soluble drug nifedipine and a hydrophilic carrier, [partially hydrolyzed gelatin (PHG), polyvinylpyrrolidone (PVP), sodium dodecyl sulfate (SDS), hydroxypropyl methylcellulose (HPMC), polyethylene glycol (PEG), urea or Pluronic F108] were prepared in order to improve the dissolution rate of nifedipine. The effects of type of grinding equipment, grinding time, and type of hydrophilic carrier on the crystallinity of nifedipine (x-ray diffraction and differential scanning calorimetry) on the interaction between drug and carriers (differential scanning calorimetry), on the particle size and appearance (scanning electron microscopy), on the wettability (contact angle measurements), and on the drug release were investigated. Grinding nifedipine together with these carriers improved the dissolution rate. PHG-ground mixtures resulted in the fastest dissolution rate followed by PVP, SDS, HPMC, Pluronic, urea, and PEG. This effect was not only due to particle size reduction, which increased in the order PHG < PEG = SDS < Pluronic < drug < urea < HPMC < PVP, but also resulted from the ability of some carriers (PVP and HPMC) to prevent reaggregation of the finely divided drug particles. PVP, HPMC, and PHG formed a powder with amorphous drug. The carriers improved the wettability of the ground products in the order HPMC < drug < urea < PVP < SDS < PHG < PEG < Pluronic. Differential scanning calorimetry (DSC) measurements gave valuable information about the nature of drug crystallinity and the interactions with the carriers within the ground mixtures.     

Preparation of Budesonide-Poly (Ethylene Oxide) Solid Dispersions Using Supercritical Fluid Technology

The purpose of this study was to investigate the possibility of preparing solid dispersions of the poorly soluble budesonide by supercritical fluid (SCF) technique, using poly (ethylene oxide) (PEO) as a hydrophilic carrier. The budesonide-PEO solid dispersions were prepared, using supercritical carbon dioxide (SC CO₂) as the processing medium, and characterized by scanning electron microscopy (SEM), powder X-ray diffraction (PXRD), differential scanning calorimetry (DSC), solubility test and dissolution test in order to understand the influence of the SCF process on the physical status of the drug. The endothermic peak of budesonide in the SCF-treated mixtures was significantly reduced, indicating that budesonide was in amorphous form inside the carrier system. This was further confirmed by SEM and PXRD studies. The enhanced dissolution rates of budesonide were observed from SCF-treated budesonide-PEO mixtures. The amorphous characteristic of the budesonide, the better mixing of drug and PEO powders in the presence of SC CO₂, together with the improved wettability of the drug in PEO, produced a remarkable enhancement of the in vitro drug dissolution rate. Thus, budesonide-PEO solid dispersions with enhanced dissolution rate can be prepared using organic solvent-free SCF process.