Enhancing mechanism of intestinal absorption of highly lipophilic compounds using microemulsion – Quantitative analysis of the partitioning to the mesenteric lymph in intestinal cells

The purpose of this study was to quantify the effect of the fatty acid alkyl-chain length of a polyethylene glycol (PEG) glyceryl ester, which was used as a microemulsion oil component, on the partitioning of highly lipophilic compounds to the mesenteric lymph after oral administration. Oil blue N, a highly lipophilic anthraquinone derivative, was orally administered to lymph duct-cannulated and untreated rats in two kinds of different microemulsions. Gelucire^® 50/13 and Gelucire^® 44/14 were used as the oil component with long chain and medium chain fatty acid portions, respectively, of PEG glyceryl esters in microemulsions. The cumulative amount of oil blue N in lymph fluid was almost the same between the two microemulsions, although the transferred amount of oil component (triglyceride) in the lymph after administration of the Gelucire^® 50/13 microemulsion was significantly higher than that of the Gelucire^® 44/14 microemulsion. On the other hand, the solubility of oil blue N in Gelucire^® 44/14 was much higher than that in Gelucire^® 50/13. No significant differences were observed between microemulsions in the bioavailability of oil blue N. From these data, the partitioning of oil blue N to the lymph was calculated using a mathematical model, showing that the partitioning ratios of oil blue N to the lymph fluid were almost the same for both microemulsions. The solubility of oil blue N to the oil component of the microemulsions and the transfer of triglycerides to the lymph after administration of the microemulsions counteract each other, leading to similar partitioning ratios of oil blue N to the lymph.     

A Gelucire 44/14 and labrasol based solid self emulsifying drug delivery system: formulation and evaluation

A solid self emulsifying formulation (S-SEF) has been developed with an intention to improve the dissolution characteristics of poorly water soluble lercanidipine hydrochloride (LH). Suitable components for the formulation of liquid self emulsifying drug delivery systems (SEDDS) were selected after screening various vehicles via solubility studies. Formulations were designed with Gelucire^® 44/14 as oil, labrasol as surfactant and transcutol-P as co surfactant. The prepared formulations were evaluated for self emulsifying efficiency and ternary phase diagram was used to designate optimum systems in the emulsifying domain. These systems were further investigated for robustness towards different pH conditions, globule size, thermodynamic stability, surface morphology, cloud point and in vitro drug release. The optimized LH loaded formulation possessed a mean globule size of 142.5 ± 5.37 nm and cloud point of 72 ± 2.66 °C. The liquid SEDDS was transformed into free flowing S-SEF by adsorbing on to an inert carrier, Neusilin US2^®. The results revealed no difference in globule size and emulsification characteristics between liquid SEDDS and S-SEF. The solid state characterization studies indicated loss of crystallinity for the drug. Significant improvement in dissolution characteristics of LH for prepared S-SEF was observed compared with pure drug.     

Physical stability of solid dispersions of the antiviral agent UC-781 with PEG 6000, Gelucire 44/14 and PVP K30

This paper describes the physical stability of solid dispersions of UC-781 with PEG 6000, Gelucire 44/14 and PVP K30 prepared by the solvent and melting methods. The concentration of the drug in the solid dispersions ranged from 5 to 80% w/w. The solid dispersions were stored at 4-8 and 25 degrees C (25% RH), then their physicochemical properties were analysed by differential scanning calorimetry (DSC), X-ray powder diffraction and dissolution studies as a function of storage time. The DSC curves of solid dispersions of UC-781 with PVP K30 did not show any melting peaks corresponding to UC-781 after storage, indicating no recrystallization of the drug. The DSC data obtained from PEG 6000 and Gelucire 44/14 showed some variations in melting peak temperatures and enthalpy of fusion of the carriers. It was shown that the enthalpy of fusion of PEG 6000 in the dispersions increased after storage; it was more pronounced for samples stored at 25 degrees C compared to those at 4-8 degrees C indicating the reorganization of the crystalline domains of the polymer. Similarly, the enthalpy of fusion of Gelucire 44/14 in the solid dispersions increased as a function of time. Dissolution of UC-781 from all solid dispersions decreased as a function of storage time. While these observations concurred with the DSC data for all solid dispersions, they were not reflected by X-ray powder diffraction data. It was concluded that it is the change of the physical state of the carriers and not that of the drug, which is responsible for the decreased dissolution properties of the solid dispersions investigated.     

Characterization and stability of solid dispersions based on PEG/polymer blends

Solid dispersions were prepared by a melting method from the water-insoluble model drugs carbamazepine and nifedipine and polyethylene glycol 1500 (PEG 1500) or 1:1 mixtures of PEG 1500 and the polymers polyvinylpyrrolidone (PVP 30, PVP 12), polyvinylpyrrolidone-co-vinylacetate (PVPVA) and Eudragit EPO (Eudragit) in order to combine advantages of the different carrier polymers (recrystallization inhibition, processability and stability). The solid dispersions were characterized by dissolution, powder X-ray diffractometry and microscopy directly after preparation and after storage for 3 and 6 months at 25 °C/0% relative humidity (RH) or 3 months at 40 °C/75% RH. More than 80% drugs were released from all solid dispersions within 20 min. The dissolution rate of carbamazepine decreased in the order of PEG 1500 > PEG 1500/Eudragit > PEG 1500/PVP 30 > PEG 1500/PVPVA > PEG 1500/PVP 12. The dissolution rank order was not directly correlated to the amorphous/crystalline state of the drugs, but rather to the properties of the PEG 1500/polymer compositions. Nifedipine was released in the order of PEG 1500 > PEG 1500/PVPVA > PEG 1500/PVP 30 > PEG 1500/PVP 12 > PEG 1500/Eudragit. Amorphous nifedipine was present in all PEG 1500/polymer dispersions except in pure PEG 1500 solid dispersion. The significant increase in dissolution rate of PEG 1500 solid dispersions was due to the reduced crystallinity of the drug and the excellent solubilisation properties of PEG 1500. After 6 months storage at 25 °C/0% RH, the solid dispersions released both drugs in the order PEG 1500/PVPVA > PEG 1500/PVP 30 > PEG 1500/PVP 12 > PEG 1500/Eudragit > PEG 1500. The stabilized amorphous state of the drug resulted in stable dissolution profiles of PEG 1500/PVPVA, PEG 1500/PVP 30 and PEG 1500/PVP 12 when compared to the PEG 1500 solid dispersions, which contained a higher amount of crystalline drug. The solid dispersions with PEG 1500/PVPVA or PEG 1500/PVP stored for 3 months at 40 °C/75% RH showed phase separation due to the hygroscopic properties of the polymers. The influence of 10% (w/w) of the solubilisers polyoxyl 40 hydrogenated castor oil (Cremophor), macrogol-15-hydroxystearate (Solutol) and fatty alcohol alkoxylate (Pluronic) on the dissolution rate and the physical state of the drug was significant.     

Development of Solid Dispersion by Hot Melt Extrusion Using Mixtures of Polyoxylglycerides With Polymers as Carriers for Increasing Dissolution Rate of a Poorly Soluble Drug Model

Various polyoxylglycerides have been researched extensively in the development of solid dispersions (SDs) for bioavailability enhancement of poorly water-soluble drugs. However, because of their low melting points (40°C-60°C), SDs produced are usually soft and semisolid. The objective of present study was to prepare SDs of a Biopharmaceutical Classification System class II drug, carvedilol, in mixtures of stearoyl polyoxylglycerides (Acconon^® C-50; m.p. ～50°C) with polymers by hot melt extrusion to obtain free-flowing powder upon grinding. Miscibility of carvedilol with Kollidon^® VA64, hydroxypropyl methylcellulose acetate succinate, and Klucel^? EXF was first evaluated by film casting, and Kollidon^® VA64 was selected for further study. SDs containing 5%-20% carvedilol, 0%-20% Acconon^® C-50, and the remaining Kollidon^® VA64 were prepared for hot melt extrusion. SDs were characterized by differential scanning calorimetry and powder X-ray diffraction analysis, and dissolution tests were conducted in 250 mL of pH 6.8 phosphate buffer by filling powders in capsules. Carvedilol was miscible with all polymers tested up to 50% and remained amorphous in SDs. The drug release from formulations containing 20% carvedilol and 0, 5%, 10%, and 20% Acconon^® C-50 were 30%, 30%, 70%, and 90%, respectively, in 60 min. SDs containing carvedilol and Acconon^® C-50, up to 20% each, as well as Kollidon^® VA64, were physically stable after 3 months of storage at 25°C/60% relative humidity.     

Effect of physiochemical variables on phase solubility and dissolution behavior of indomethacin solid dispersion system

To study the influence of temperature and pH on solubility and dissolution behavior of indomethacin solid dispersions were prepared using several classes of hydrophilic carriers. Investigations on dissolution of indomethacin in binary system are reported earlier. However the phase solubility and dissolution behavior at different pH and temperature left void. The present investigation includes: phase solubility study at various pH; preparation of solid dispersion by solvent evaporation, melting and kneading method; characterization of various blends by dissolution study, and solid state studies to ensure interaction of drug with carrier. The binding between drug and carriers (PVP K30, βCD and PEG) was explained by thermodynamic parameters as calculated from phase solubility study. Indomethacin in association with PVP K30 showed very high apparent binding constant (Ka) and Gibb’s free energy change (?G) in comparison to other blends. The ternary system (drug:βCD:PVP K30, 1:5:1) showed better dissolution of about 80.97 and 99 % at pH 7.2 after 5 and 30 min respectively. At higher proportion of carrier (1:9) in binary solid dispersion of drug and PVP K30, drug dissolution was 96.23 and 97.85 % after 5 and 30 min respectively. This raised solubility of indomethacin would be helpful in designing a dosage form.     

The Influence of Drug Physical State on the Dissolution Enhancement of Solid Dispersions Prepared Via Hot-Melt Extrusion: A Case Study Using Olanzapine

In this study, we examine the relationship between the physical structure and dissolution behavior of olanzapine (OLZ) prepared via hot-melt extrusion in three polymers [polyvinylpyrrolidone (PVP) K30, polyvinylpyrrolidone-co-vinyl acetate (PVPVA) 6:4, and Soluplus® (SLP)]. In particular, we examine whether full amorphicity is necessary to achieve a favorable dissolution profile. Drug–polymer miscibility was estimated using melting point depression and Hansen solubility parameters. Solid dispersions were characterized using differential scanning calorimetry, X-ray powder diffraction, and scanning electron microscopy. All the polymers were found to be miscible with OLZ in a decreasing order of PVP>PVPVA>SLP. At a lower extrusion temperature (160°C), PVP generated fully amorphous dispersions with OLZ, whereas the formulations with PVPVA and SLP contained 14%–16% crystalline OLZ. Increasing the extrusion temperature to 180°C allowed the preparation of fully amorphous systems with PVPVA and SLP. Despite these differences, the dissolution rates of these preparations were comparable, with PVP showing a lower release rate despite being fully amorphous. These findings suggested that, at least in the particular case of OLZ, the absence of crystalline material may not be critical to the dissolution performance. We suggest alternative key factors determining dissolution, particularly the dissolution behavior of the polymers themselves. © 2014 The Authors. Journal of Pharmaceutical Sciences published by Wiley Periodicals, Inc. and the American Pharmacists Association J Pharm Sci 103:1214–1223, 2014     

环孢素固体分散体的制备及溶出研究

目的: 提高难溶性药物环孢素(CsA)的溶出速率.方法: 选择聚乙二醇(PEG4000)和聚乙烯吡咯烷酮(PVPK30)两种载体,分别以溶剂熔融法和溶剂法制备CsA固体分散体;建立HPLC法检测固体分散体的体外溶出度,并考察不同载体、不同比例及溶出介质、桨法转速对CsA溶出速率的影响.对溶出度结果用Weibull分布模型进行拟合,计算体外溶出参数T50和Td,并进行方差分析.结果: 使用HPLC法测定CsA的体外溶出量准确、稳定、可靠、载体无干扰.制备成的固体分散体能显著提高CsA的体外溶出速率,PVPK30载体的固体分散体的溶出速率明显快于PEG4000载体的固体分散体.溶出介质对药物溶出没有明显影响.结论: CsA: PVPK30为1: 6的固体分散体具有良好的体外速释作用.     

Improvement of dissolution rate of tacrolimus by solid dispersion technique

Tacrolimus has a poor solubility in water ranging from 4 to 12 μg mL^?1. The mean bioavailability is ~21 %.The present study was carried out with a view to enhance the dissolution rate of poorly water-soluble drug tacrolimus using Gelucire 44/14^® and Gelucire 50/13^® as carriers and lactose monohydrate as an adsorbent. A combination of melt and adsorption techniques was employed for the preparation of solid dispersions (SD) to make final product easy for handling. Phase solubility study was conducted to evaluate the effect of carriers on aqueous solubility of tacrolimus. In order to elucidate the mechanism of dissolution enhancement, solid state characteristics were investigated using Fourier transform infrared spectroscopy, differential scanning calorimetry and powder X-ray diffraction. Mathematical modeling of in vitro dissolution data indicated the best fitting with Korsemeyer–Peppas model and the drug release kinetics primarily as Fickian/anomalous diffusion. All prepared solid dispersions showed dissolution improvement compared to pure drug, with Gelucire 50/13^® as the superior carrier over Gelucire 44/14^®. Almost similar dissolution profile was obtained as a function of storage time; this can be explained by no change in XRD and DSC pattern after 45 days storage period.     

Physicochemical Characterization and Dissolution Study of Solid Dispersions of Lovastatin with Polyethylene Glycol 4000 and Polyvinylpyrrolidone K30

Solid dispersions in water-soluble carriers have attracted considerable interest as a means of improving the dissolution rate, and hence possibly bioavailability, of a range of hydrophobic drugs. The aim of the present study was to improve the solubility and dissolution rate of a poorly water-soluble drug, Lovastatin, by a solid dispersion technique. Solid dispersions were prepared by using polyethylene glycol 4000 (PEG 4000) and polyvinylpyrrolidone K30 (PVP K30) in different drug-to‐carrier ratios. Dispersions with PEG 4000 were prepared by fusion-cooling and solvent evaporation, whereas dispersions containing PVP K30 were prepared by solvent evaporation technique. These new formulations were characterized in the liquid state by phase solubility studies and in the solid state by differential scanning calorimetry, X-ray powder diffraction, and FT-IR spectroscopy. The aqueous solubility of Lovastatin was favored by the presence of both polymers. The negative values of the Gibbs free energy and enthalpy of transfer explained the spontaneous transfer from pure water to the aqueous polymer environment. Solid-state characterization indicated Lovastatin was present as amorphous material and entrapped in polymer matrix. In contrast to the very slow dissolution rate of pure Lovastatin, the dispersion of the drug in the polymers considerably enhanced the dissolution rate. This can be attributed to improved wettability and dispersibility, as well as decrease of the crystalline and increase of the amorphous fraction of the drug. Solid dispersion prepared with PVP showed the highest improvement in wettability and dissolution rate of Lovastatin. Even physical mixture of Lovastatin prepared with both polymers also showed better dissolution profile than that of pure Lovastatin. Tablets containing solid dispersion prepared with PEG and PVP showed significant improvement in the release profile of Lovastatin compared with tablets containing Lovastatin without PEG or PVP.     

Physicochemical characterization and dissolution study of solid dispersions of Lovastatin with polyethylene glycol 4000 and polyvinylpyrrolidone K30

Solid dispersions in water-soluble carriers have attracted considerable interest as a means of improving the dissolution rate, and hence possibly bioavailability, of a range of hydrophobic drugs. The aim of the present study was to improve the solubility and dissolution rate of a poorly water-soluble drug, Lovastatin, by a solid dispersion technique. Solid dispersions were prepared by using polyethylene glycol 4000 (PEG 4000) and polyvinylpyrrolidone K30 (PVP K30) in different drug-to-carrier ratios. Dispersions with PEG 4000 were prepared by fusion-cooling and solvent evaporation, whereas dispersions containing PVP K30 were prepared by solvent evaporation technique. These new formulations were characterized in the liquid state by phase solubility studies and in the solid state by differential scanning calorimetry, X-ray powder diffraction, and FT-IR spectroscopy. The aqueous solubility of Lovastatin was favored by the presence of both polymers. The negative values of the Gibbs free energy and enthalpy of transfer explained the spontaneous transfer from pure water to the aqueous polymer environment. Solid-state characterization indicated Lovastatin was present as amorphous material and entrapped in polymer matrix. In contrast to the very slow dissolution rate of pure Lovastatin, the dispersion of the drug in the polymers considerably enhanced the dissolution rate. This can be attributed to improved wettability and dispersibility, as well as decrease of the crystalline and increase of the amorphous fraction of the drug. Solid dispersion prepared with PVP showed the highest improvement in wettability and dissolution rate of Lovastatin. Even physical mixture of Lovastatin prepared with both polymers also showed better dissolution profile than that of pure Lovastatin. Tablets containing solid dispersion prepared with PEG and PVP showed significant improvement in the release profile Lovastatin compared with tablets containing Lovastatin without PEG or PVP.     

Effect of substitution of plasticizer dibutyl phthalate with dibutyl sebacate on Eudragit® RS30D drug release rate control

In the current study, the influence of type of plasticizer used with Eudragit^® RS 30D on the drug release was investigated in solid dosage form extrusion/spheronization, and film coating. The drug pellets were coated for controlling drug release with Eudragit^® RS 30D containing dibutyl phthalate and compared with dibutyl sebacate as an alternative plasticizer. To study the influence of pH of the dissolution medium on the drug release profile, capsules are tested for drug release profile at pH 1.2, 4.4, and 6.3. Additionally, the aging effect on the curing of Eudragit^® RS 30D is evaluated by exposing the capsules dosage form to room temperature (25?°C?±?2?°C/60%?±?5% RH) for time 0, 3, 6, and 9?months, accelerated temperature (40?°C?±?2?°C/75%?±?5% RH) for time 0, 3, and 6?months, and intermediate temperature (30?°C?±?2?°C/65%?±?5% RH) for time 0, 6, and 9?months. The replacement of dibutyl phthalate, with dibutyl sebacate for polymer coating system in similar concentration is comparable with respect to plasticization effect. The coalescence of the polymer particles is not changed and requires no additional processing parameter control or additional curing time.     

Formulation and in vitro evaluation of a PEGylated microscopic lipospheres delivery system for ceftriaxone sodium

The aim of this study was to formulate and evaluate in vitro, ceftriaxone sodium lipospheres dispersions for oral administration. Ceftriaxone sodium lipospheres were prepared by melt-emulsification using 30%w/w Phospholipon^® 90H in Softisan^® 154 as the lipid matrix containing increasing quantities of PEG 4000 (10, 20, 30, and 40%w/w). Characterization based on particle size, particle morphology, encapsulation efficiency, loading capacity and pH were carried out on the lipospheres. Microbiological studies of the ceftriaxone sodium-loaded lipospheres were performed using Escherichia coli as the model organism. In vitro permeation of ceftriaxone sodium from the lipospheres through artificial membrane (0.22?μm pore size) was carried out using Franz cell and simulated intestinal fluid (SIF) without pancreatin as acceptor medium. Photomicrographs revealed spherical particles within a micrometer range with minimal growth after 1 month (Maximum size?=?64.76?±?3.81?μm). Microbiological studies indicated that lipospheres formulated with 20%w/w of PEG 4000 containing 2%w/w or 3%w/w of ceftriaxone sodium gave significantly (p?<?0.05) higher inhibition zone diameter than those with 30%w/w or 40%w/w of PEG 4000. The result also indicated that lipospheres with 10%w/w PEG 4000 resulted in significantly higher encapsulation efficiency (p?<?0.05) while those with 30%w/w gave the least, while the loading capacity values ranged from 3.22?mg of ceftriaxone sodium/100?mg of lipid to 6.36?mg of ceftriaxone sodium/100?mg of lipid. Permeation coefficient values varied and ranged from 8.55?×?10^?7 cm/s to 2.08?×?10^?6 cm/s depending on the concentration of PEG 4000. The result of this study gave insight that the issue of ceftriaxone stability in oral formulation could be adequately addressed by tactical engineering of lipid drug delivery systems such as lipospheres.     

Immediate Release 3D-Printed Tablets Produced Via Fused Deposition Modeling of a Thermo-Sensitive Drug

Purpose

Dissolution speeds of tablets printed via Fused Deposition Modeling (FDM) so far are significantly lower compared to powder or granule pressed immediate release tablets. The aim of this work was to print an actual immediate release tablet by choosing suitable polymers and printing designs, also taking into account lower processing temperatures (below 100°C) owing to the used model drug pantoprazole sodium.

Methods

Five different pharmaceutical grade polymers polyvinylpyrrolidone (PVP K12), polyethylene glycol 6000 (PEG 6000), Kollidon® VA64, polyethylene glycol 20,000 (PEG 20,000) and poloxamer 407 were successfully hot-melt-extruded to drug loaded filaments and printed to tablets at the required low temperatures.

Results

Tablets with the polymers PEG 6000 and PVP K12 and with a proportion of 10% pantoprazole sodium (w/w) demonstrated a fast drug release that was completed within 29 min or 10 min, respectively. By reducing the infill rate of PVP tablets to 50% and thereby increase the tablet porosity it was even possible to reduce the mean time for total drug release to only 3 min.

Conclusions

The knowledge acquired through this work might be very beneficial for future FDM applications in the field of immediate release tablets especially with respect to thermo-sensitive drugs.

     

Formulation of 3D Printed Tablet for Rapid Drug Release by Fused Deposition Modeling: Screening Polymers for Drug Release,Drug-Polymer Miscibility and Printability

The primary aim of this study was to identify pharmaceutically acceptable amorphous polymers for producing 3D printed tablets of a model drug, haloperidol, for rapid release by fused deposition modeling. Filaments for 3D printing were prepared by hot melt extrusion at 150°C with 10% and 20% w/w of haloperidol using Kollidon^® VA64, Kollicoat^® IR, Affinsiol^?15 cP, and HPMCAS either individually or as binary blends (Kollidon^® VA64 + Affinisol^? 15 cP, 1:1; Kollidon^® VA64 + HPMCAS, 1:1). Dissolution of crushed extrudates was studied at pH 2 and 6.8, and formulations demonstrating rapid dissolution rates were then analyzed for drug-polymer, polymer-polymer and drug-polymer-polymer miscibility by film casting. Polymer-polymer (1:1) and drug-polymer-polymer (1:5:5 and 2:5:5) mixtures were found to be miscible. Tablets with 100% and 60% infill were printed using MakerBot printer at 210°C, and dissolution tests of tablets were conducted at pH 2 and 6.8. Extruded filaments of Kollidon^® VA64-Affinisol^? 15 cP mixtures were flexible and had optimum mechanical strength for 3D printing. Tablets containing 10% drug with 60% and 100% infill showed complete drug release at pH 2 in 45 and 120 min, respectively. Relatively high dissolution rates were also observed at pH 6.8. The 1:1-mixture of Kollidon^® VA64 and Affinisol^?15 cP was thus identified as a suitable polymer system for 3D printing and rapid drug release.     

聚维酮和聚乙二醇对吡罗昔康-β-环糊精包合的影响

研究了聚乙烯吡咯烷酮 (PVPK -3 0 )和聚乙二醇 (PEG 40 0 0 )对吡罗昔康 β 环糊精包合作用的影响 ,用热力学的方法求出了包合物在高聚物存在下的热力学函数 .结果表明 ,吡罗昔康 β 环糊精包合物在PVP和PEG的存在下包合反应表观稳定常数 (KC)增大 ,包合反应的自由焓 (ΔG)减小 .高聚物的最佳浓度为 3～ 5 g /L     

Implication of inclusion complexation of glimepiride in cyclodextrin-polymer systems on its dissolution, stability and therapeutic efficacy

The effect of complexation of glimepiride, a poorly water-soluble antidiabetic drug, with β-cyclodextrin and its derivatives (HP-β-CyD and SBE-β-CyD) in presence of different concentrations of water-soluble polymers (HPMC, PVP, PEG 4000 and PEG 6000) on the dissolution rate of the drug has been investigated. The results revealed that the dissolution rate of the drug from these ternary systems is highly dependent on polymer type and concentration. The dissolution rate of the drug from ternary systems containing PEG 4000 or PEG 6000 seems to be generally higher than from systems containing HPMC or PVP. An optimum increase in the dissolution rate of the drug was observed at a polymer concentration of 5% for PEG 4000 or PEG 6000 and at 20% concentration of HPMC or PVP. The dissolution rate of the drug from the ternary system glimepiride–HP-β-CyD–5% PEG 4000 was high compared to the other systems. Tablets containing the drug or its equivalent amount of this ternary system were prepared and subjected to accelerated stability testing at 40 °C/75% R.H. to investigate the effect of storage on the chemical stability as well as therapeutic efficacy of the tablets. The results revealed stability of the tablets and consistent therapeutic efficacy on storage.     

Impact of Drug-Polymer Miscibility on Enthalpy Relaxation of Irbesartan Amorphous Solid Dispersions

Purpose

Drug-polymer miscibility has been proposed to play a critical role in physical stability of amorphous solid dispersions (ASDs). The purpose of the current work was to investigate the role of drug-polymer miscibility on molecular mobility, measured as enthalpy relaxation (ER) of amorphous irbesartan (IBS) in ASDs.

Methods

Two polymers, i.e. polyvinylpyrrolidone K30 (PVP K30) and hydroxypropyl methylcellulose acetate succinate (HPMCAS), were used to generate ASDs with 10% w/w of the polymer. Drug-polymer miscibility was determined using melting point depression (MPD) method. Molecular mobility was assessed from ER studies at a common degree of undercooling (DOU) (T_g???13.0°C?±?0.5°C).

Results

IBS exhibited higher miscibility in PVP K30 as compared to HPMCAS at temperature?>?140°C. However, extrapolation of miscibility data to storage temperature (62°C) using Flory-Huggins (F-H) theory revealed a reversal of the trend. Miscibility of IBS was found to be higher in HPMCAS (2.6%) than PVP K30 (1.3%) at 62°C. Stretched relaxation time (τ^β) of 17.4365 h and 7.0886 h was obtained for IBS-HPMCAS and IBS-PVP K30 ASDs, respectively.

Conclusion

Miscibility of drug-polymer at storage temperature explained the behavior of the molecular mobility, while miscibility near the melting point provided a reverse trend. Results suggest that drug-polymer miscibility determined at temperatures higher than the storage temperature should be viewed cautiously.

     

The properties of solid dispersions of indomethacin or phenylbutazone in polyethylene glycol

The effects of molecular weight of polyethylene glyeols (PEGs) on the dissolution rates and crystallinity of its solid dispersions with indoniethacin and phenylbutazone have been examined. The dissolution rates of both solid-dispersed drugs decreased as the molecular weight of PEG increased. The indoniethacin dissolution profiles were essentially linear using constant surface area disc methodology and a limiting dissolution rate of about 10.6 mg · min⁻¹ was observed. The phenylbutazone dissolution profiles were. however, generally linear-curvic usually giving lower release rates than the comparative indomethacin weight fractions. A limiting dissolution rate for the linear portions of the profiles was about 1.8 mg · min⁻¹. Infra-red spectra indicated that the differences between the two drugs could partly be explained on the basis of PEG crystallinity. Generally bands in the ranges 1100–1130 and 1200–1400 cm⁻¹ were poorly differentiated in indomethacin dispersions (PEG 1500, PEG 4000 and PEG 6000) but were better differentiated in phenylbutazone dispersions (PEG 4000, PEG 6000 and PEG 20,000). A greater proportion of amorphousness within the PEG moiety was predicted in indomethacin dispersions by the appearance of a new weak band at 1326 cm⁻¹ and by a decrease in intensity of the band at 845 cm⁻¹ at the expense of the peak at 960 cm⁻¹. The evidence was supported by differential scanning calorimetry. The heats of fusion were 44.7, 46.4, 47.2 and 39.5 cal · g⁻¹ for PEG 1500, PEG 4000, PEG 6000 and PEG 20.000 respectively. Heats of fusion for indomethacin dispersions (2, 5 and 10% drug) were generally lower than for the corresponding values for phenylbutazone dispersions-with the exception of PEG 20,000 dispersions. For example, values were obtained of 30.6 and 37.9 cal · g⁻¹ for PEG 1500 dispersions containing 10% indomethacin and phenylbutazone, respectively.