Determining the Dependence of Interfacial Tension on Molecular Area for Phospholipid Monolayers Formed at Silicone Oil-Water and Tricaprylin-Water Interfaces by Vesicle Fusion.

Phospholipid monolayers formed at oil-water interfaces have been used to explore biological interface properties. Thus, monolayer systems need to be quantitatively understood. Previously, we investigated the formation of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) monolayers at silicone oil-water interfaces to determine the dependence of interfacial tension, γ, on the area per lipid, a, compared to that of the closely packed monolayers, acp. This study aims to develop a method to obtain the γ-a relationship from the γ-a/acp data by investigating POPC monolayers at the silicone oil-water and tricaprylin-water interfaces. Pendant drop tensiometry was used to obtain the dependence of γ on a/acp. Furthermore, by calculating the surface pressure, Π, from γ and multiplying a/acp with an estimated acp value, the dependence of Π on a was obtained. When a value approximately equal to the a of POPC bilayers was assigned to acp, the resultant Π-a profile partially or approximately completely overlapped with the Π-a isotherms obtained for the monolayers at the air-water interface using a Langmuir trough. The overlap for the silicone oil-water interface occurred at a ≤ 77 Å2, while that for the tricaprylin-water interface occurred in approximately the entire a region. The results indicate that the Π of the condensed monolayers is little affected by bulk oil. Thus, the γ-a relationship for the oil-water interface can be determined by comparing the compression isotherm with the one obtained for the air-water interface.

Effect of Drug-Polymer Interactions through Hypromellose Acetate Succinate Substituents on the Physical Stability on Solid Dispersions Studied by Fourier-Transform Infrared and Solid-State Nuclear Magnetic Resonance.

The present study evaluated the specific intermolecular interactions between carbamazepine (CBZ) and substituents of hypromellose acetate succinate (HPMC-AS), as well as the mechanism of inhibition of recrystallization of solid dispersions (SDs) using Fourier-transform infrared (FTIR) and solid-state nuclear magnetic resonance (NMR) spectroscopy. CBZ and HPMC derivatives, including HPMC, hypromellose acetate (HPMC-A), and hypromellose succinate (HPMC-S), were spray-dried to prepare CBZ/polymer spray-dried samples (SPDs). CBZ/HPMC SPD and CBZ/HPMC-A SPD recrystallized within 10 days at 60 °C and 0% relative humidity, whereas CBZ/HPMC-S SPD maintained its amorphous state for a longer period. FTIR and solid-state NMR measurements using 13C cross polarization (CP), 1H single-pulse, and 1H-15N CP-based heteronuclear single quantum correlation filter experiment with very fast magic angle spinning (MAS) at 70 kHz identified molecular interactions in CBZ/polymer SPDs. Although the HPMC backbone and substituents did not interact notably with CBZ and disrupt CBZ-CBZ intermolecular interactions (formed in the amorphous CBZ), acetate and succinate substituents on HPMC-A and HPMC-S disrupted CBZ-CBZ intermolecular interactions through formation of CBZ/polymer interactions. The acetate substituent formed a hydrogen bond with the NH2 group of CBZ, whereas the succinate substituent formed molecular interactions with both the C═O and NH2 groups of CBZ. Formation of relatively strong molecular interactions between CBZ and the succinate substituent followed by disruption of CBZ-CBZ intermolecular interactions effectively stabilized the amorphous state of CBZ in CBZ/HPMC-S SPD. The correlation between CBZ-polymer interactions and ability of polymers to effectively inhibit CBZ recrystallization is reflected in various commercial HPMC-AS. For example, HPMC-AS LF grade, containing higher amounts of the succinate group, was found to effectively inhibit the recrystallization of CBZ through strong molecular interactions as compared with the HPMC-AS HF grade. The present study demonstrated that a detailed investigation of molecular interactions between the drug and the polymer using FTIR and solid-state NMR spectroscopy could contribute to a suitable selection of the SD carrier.

Mechanism of Enhanced Nifedipine Dissolution by Polymer-Blended Solid Dispersion through Molecular-Level Characterization.

We investigated the effect of polymer composition on nifedipine (NIF) dissolution through molecular-level characterization of NIF/hypromellose (HPMC)/Eudragit S (EUD-S) ternary solid dispersions. The dissolution rates and molecular states of NIF and polymers were evaluated in NIF/HPMC/EUD-S spray-dried samples (SPDs) with different polymer compositions. Blending of HPMC and EUD-S improved the dissolution property of each polymer. Moreover, polymer blending enhanced NIF dissolution from the NIF/polymer SPD with EUD-S/polymer wt % of 50-75%. NIF dissolved simultaneously with polymers from the NIF/polymer SPDs with high EUD-S/polymer wt %. In contrast, NIF and polymers separately dissolved from the NIF/polymer SPDs with EUD-S/polymer wt % of 10-25%, exhibiting a significantly reduced NIF dissolution rate. Fourier transform-infrared and solid-state NMR measurements revealed that HPMC and EUD-S formed molecular interactions with NIF via different interaction modes. Comprehensive analysis by spectroscopic measurements and modulated differential scanning calorimetry showed that the molecular interaction between NIF and EUD-S was stronger than that between NIF and HPMC. Furthermore, the 13C-spin-lattice relaxation time measurements revealed that EUD-S effectively restricted the molecular mobility of NIF compared with HPMC. The molecular interaction between NIF and EUD-S led to the simultaneous and fast dissolution of NIF with EUD-S from the NIF/polymer SPD with high EUD-S loading. Thus, enhanced NIF dissolution was ascribed to the fast dissolution properties of the blended polymer and to polymer-controlled NIF dissolution through the strong molecular interaction between NIF and EUD-S. To achieve efficient optimization of the formulation of polymer-blended solid dispersion with desired drug dissolution, it is necessary to consider both polymer-polymer and drug-polymer intermolecular interactions.

Enthalpy-driven interactions with sulfated glycosaminoglycans promote cell membrane penetration of arginine peptides.

The first step of cell membrane penetration of arginine peptides is thought to occur via electrostatic interactions between positive charges of arginine residues and negative charges of sulfated glycosaminoglycans (GAGs) on the cell surface. However, the molecular interaction of arginine peptides with GAG still remains unclear. Here, we compared the interactions of several arginine peptides of Tat, R8, and Rev and their analogues with heparin in relation to the cell membrane penetration efficiency. The high-affinity binding of arginine peptides to heparin was shown to be driven by large favorable enthalpy contributions, possibly reflecting multidentate hydrogen bondings of arginine residues with sulfate groups of heparin. Interestingly, the lysine peptides in which all arginine residues are substituted with lysine residues exhibited negligible binding enthalpy despite of their considerable binding to heparin. In CHO-K1 cells, arginine peptides exhibited a great cell-penetrating ability whereas their corresponding lysine peptides did not penetrate into cells. The degree of cell penetration of arginine peptides markedly decreased by the chlorate treatment of cells which prevents the sulfation of GAG chains. Significantly, the cell penetration efficiency of arginine peptides was found to be correlated with the favorable enthalpy of binding to heparin. These results suggest that the enthalpy-driven strong interaction with sulfated GAGs such as heparan sulfate plays a critical role in the efficient cell membrane penetration of arginine peptides.

Bio-gel nanoarchitectonics in tissue engineering.

Given the creation of materials based on nanoscale science, nanotechnology must be combined with other disciplines. This role is played by the new concept of nanoarchitectonics, the process of constructing functional materials from nanocomponents. Nanoarchitectonics may be highly compatible with applications in biological systems. Conversely, it would be meaningful to consider nanoarchitectonics research oriented toward biological applications with a focus on materials systems. Perhaps, hydrogels are promising as a model medium to realize nanoarchitectonics in biofunctional materials science. In this review, we will provide an overview of some of the defined targets, especially for tissue engineering. Specifically, we will discuss (i) hydrogel bio-inks for 3D bioprinting, (ii) dynamic hydrogels as an artificial extracellular matrix (ECM), and (iii) topographical hydrogels for tissue organization. Based on these backgrounds and conceptual evolution, the construction strategies and functions of bio-gel nanoarchitectonics in medical applications and tissue engineering will be discussed.

Influence of the Charge Ratio of Guanine-Quadruplex Structure-Based CpG Oligodeoxynucleotides and Cationic DOTAP Liposomes on Cytokine Induction Profiles.

Cationic liposomes, specifically 1,2-dioleoyl-3-trimethylammonium-propane (DOTAP) liposomes, serve as successful carriers for guanine-quadruplex (G4) structure-based cytosine-guanine oligodeoxynucleotides (CpG ODNs). The combined benefits of CpG ODNs forming a G4 structure and a non-viral vector carrier endow the ensuing complex with promising adjuvant properties. Although G4-CpG ODN-DOTAP complexes show a higher immunostimulatory effect than naked G4-CpG ODNs, the effects of the complex composition, especially charge ratios, on the production of the pro-inflammatory cytokines interleukin (IL)-6 and interferon (IFN)-α remain unclear. Here, we examined whether charge ratios drive the bifurcation of cytokine inductions in human peripheral blood mononuclear cells. Linear CpG ODN-DOTAP liposome complexes formed micrometer-sized positively charged agglomerates; G4-CpG ODN-DOTAP liposome complexes with low charge ratios (0.5 and 1.5) formed ~250 nm-sized negatively charged complexes. Notably, low-charge-ratio (0.5 and 1.5) complexes induced significantly higher IL-6 and IFN-α levels simultaneously than high-charge-ratio (2 and 2.5) complexes. Moreover, confocal microscopy indicated a positive correlation between the cellular uptake of the complex and amount of cytokine induced. The observed effects of charge ratios on complex size, surface charge, and affinity for factors that modify cellular-uptake, intracellular-activity, and cytokine-production efficiency highlight the importance of a rational complex design for delivering and controlling G4-CpG ODN activity.

Stabilization mechanism of amorphous carbamazepine by transglycosylated rutin, a non-polymeric amorphous additive with a high glass transition temperature.

α-Glycosyl rutin (Rutin-G), composed of a flavonol skeleton and sugar groups, is a promising non-polymeric additive for stabilizing amorphous drug formulations. In this study, the mechanism of the stabilization of the amorphous state of carbamazepine (CBZ) by Rutin-G was investigated. In comparison with hypromellose (HPMC), which is commonly used as a crystallization inhibitor for amorphous drugs, Rutin-G significantly stabilized amorphous CBZ. Moreover, the dissolution rate and the resultant supersaturation level of CBZ were significantly improved in the CBZ/Rutin-G spray-dried samples (SPDs) owing to the rapid dissolution property of Rutin-G. Differential scanning calorimetry measurement demonstrated a high glass transition temperature (Tg) of 186.4°C corresponding to Rutin-G. The CBZ/Rutin-G SPDs with CBZ weight ratios up to 80% showed single glass transitions, indicating the homogeneity of CBZ and Rutin-G. A solid-state NMR experiment using 13C- and 15N-labeled CBZ demonstrated the interaction between the flavonol skeleton of Rutin-G and the amide group of CBZ. A 1H-13C two-dimensional heteronuclear correlation NMR experiment and quantum mechanical calculations confirmed the presence of a possible hydrogen bond between the amino proton in CBZ and the carbonyl oxygen in the flavonol skeleton of Rutin-G. This specific hydrogen bond could contribute to the strong interaction between CBZ and Rutin-G, resulting in the high stability of amorphous CBZ in the CBZ/Rutin-G SPD. Hence, Rutin-G, a non-polymeric amorphous additive with high Tg, high miscibility with drugs, and rapid and pH-independent dissolution properties could be useful in the preparation of amorphous formulations.

Determination of the Coverage of Phosphatidylcholine Monolayers Formed at Silicone Oil-Water Interfaces by Vesicle Fusion.

Phospholipid monolayers at oil-water interfaces are used for various biological applications and often formed by vesicle adsorption. However, the adsorbed structures are not well characterized; therefore, fundamental investigation on vesicle adsorption behavior is necessary for correct understanding of the monolayer systems. Herein, we investigated the adsorption of phosphatidylcholine vesicles onto silicone oil-water interfaces using fluorescence microscopy and pendant drop tensiometry. The interfacial monolayer coverage, S, was determined by assuming S = 1 for tightly packed monolayers. Adsorption for 10 min with a lipid concentration of 0.2 mM resulted in S ≈ 0.4. An increase in lipid concentration (0.5-2 mM) and adsorption time (1 h) moderately increased monolayer coverage (S ≈ 0.6). However, extended adsorption for 24 h only slightly increased coverage (S ≈ 0.7). Monolayers with an S < 0.6 were homogeneous, while those with an S > 0.6 were associated with several vesicular structures. The surface density of these bound vesicles increased with increasing S. We conclude that vesicles readily fused with the interface to form monolayers at S < 0.6 and that their fusogenicity considerably decreased at S > 0.6. These results demonstrate that the ability of vesicles to form monolayers is determined by the interfacial coverage.

Correlation between drug dissolution and resistance to water-induced phase separation in solid dispersion formulations revealed by solid-state NMR spectroscopy.

We aimed to elucidate the dissolution mechanism of solid dispersions (SDs) according to the carrier polymers used. Nifedipine (NIF) and polymers dissolved simultaneously from NIF/Eudragit® S (EUD-S), NIF/Eudragit® L (EUD-L), and NIF/hypromellose (HPMC)/EUD-S spray-dried samples (SPDs). In contrast, NIF dissolved separately from polymers from NIF/HPMC and NIF/HPMC/EUD-L SPDs due to the formation of an amorphous NIF-rich interface. Solid-state NMR spectroscopy indicated that NIF-EUD interactions were stronger than NIF-HPMC interactions. NIF/HPMC SPD exhibited weak interactions; thus, it failed to inhibit phase separation during the dissolution process and control NIF dissolution. The hygroscopicity of SPDs was higher with HPMC mixing and increased substitution ratio of methacrylic acid in EUD. Moreover, solid-state NMR spectroscopy revealed that the NIF-EUD interactions were hindered to a large extent by the absorbed water. During the dissolution process of NIF/HPMC/EUD-L SPD, the introduction of water to the NIF-EUD-L interaction site could induce the phase separation and poor controllability of NIF dissolution. Water-induced phase separation should be considered based on molecular-level characterization to obtain SDs with enhanced drug dissolution. An investigation of the molecular state change caused by the absorbed water using solid-state NMR spectroscopy will be helpful in understanding the dissolution mechanism of SDs.

Phase separation of supersaturated solution created from amorphous solid dispersions: Relevance to oral absorption.

Dissolution of amorphous solid dispersions (ASDs) is a complicated process, which may involve phase separation from the supersaturated state and formation of a colloidal phase. However, relevance of the phase separation behavior to oral absorption from ASDs is still not well understood. We investigated phase separation of a supersaturated fenofibrate (FEN) solution in the presence of polymers, in vitro dissolution of FEN ASDs, and their in vivo absorption. The supersaturation behavior was assessed based on turbidity measurement in an artificial supersaturation system, where FEN ethanol solutions were added to aqueous polymer solutions. The phase separation concentration of FEN was ca. 1 µg/mL regardless of the presence/absence of the polymer, which was approximately 10-fold the equilibrium solubility. In the presence of 0.1% Tween 80 in the media, the phase separation concentration depended on the polymer species, presumably due to differences in their inhibitory effect of crystallization. The degrees of supersaturation achieved by the ASDs were similar to those found in the artificial system, suggesting that the artificial system works for comprehending the effect of polymer species on supersaturation ability for designing ASDs. A robust in vitro-in vivo correlation was achieved using the paddle and the flow-through cell methods by employing non-sink and pH-shift conditions. However, the phase separation concentration may rather be a good and simple indicator to estimate the absorption-enhancing ability of the polymeric excipients for ASDs, if the absorption is limited by solubility.

Impact of compression pressure on tablet appearance.

The color of model tablets deepened and tablet gloss increased with increase in compression pressure regardless of colorant type. The possible reasons for these phenomena were examined. These observations could not be explained either by polymorphic transition of the colorant or by condensation of the colorant during compression. Instead, a change in surface roughness was assumed to be the most likely reason. The increase in compression pressure made the tablet surface smoother. With the increase in the surface smoothness, diffuse reflection decreased while specular reflection increased, indicating the opposite relation between diffuse and specular reflection as a function of surface roughness. A decrease in diffuse reflection results in a deepening of color. In contrast, an increase in specular reflection causes an increase in glossiness. Thus, the surface roughness seemed to govern gloss and color. The compression pressure seems to be one of the most important factors to control tablet appearance.

Synergetic Role of Hypromellose and Methacrylic Acid Copolymer in the Dissolution Improvement of Amorphous Solid Dispersions.

Synergetic role of polymer blending on dissolution of amorphous solid dispersion was investigated. Dissolution rates of hypromellose (HPMC) and methacrylic acid copolymer (EUD) from the HPMC/EUD spray-dried sample (SPD) were improved compared to those of each single polymer SPD. Differential scanning calorimetry measurements revealed that the structural change in HPMC following heating was inhibited by co-spray-drying with EUD, suggesting an intermolecular interaction between the polymers. 13C solid-state nuclear magnetic resonance (NMR) spectroscopy detected the change induced in the hydroxyl group of HPMC by co-spray-drying with EUD. Moreover, the carbonyl peak shape of EUD in the 13C NMR spectra differed between EUD SPD and HPMC/EUD SPD, indicating that the dimer structure of the carboxylic acid of EUD was partially disrupted by the interaction with HPMC. An intermolecular interaction occurred between HPMC and EUD. The hydrogen bond reformation likely improved the dissolution rates of the polymers. The ternary griseofulvin (GRF)/HPMC/EUD SPD showed a significantly higher supersaturation level of GRF than the mixtures containing equal amounts of binary GRF/HPMC and GRF/EUD SPDs. The change of interaction mode between polymers improved the dissolution of solid dispersion. Therefore, polymer blending based on interpolymer interactions could be a practical strategy for designing excellent solid dispersion formulations.

Solubilization behavior of poorly soluble drugs with combined use of Gelucire 44/14 and cosolvent.

Gelucire 44/14 is a surface-active excipient that can solubilize poorly soluble drugs. We investigated its solubilization behavior when coexisting with dimethylacetoamide (DMA) or dimethylsulfoxide (DMSO), both of which are also expected to enhance drug solubility. Gelucire was confirmed to form micelles by surface tension and fluorescence measurements both in water and water/cosolvent mixtures. Light-scattering measurements revealed that DMA and DMSO affect the micellar morphology in a different manner. DMA helped form large structures by being entrapped in the hydrophobic region of the micelles and/or inducing the aggregation. DMSO was likely to be anchored to the interfacial layer and did not induce micelle growth. Two model drugs, phenytoin and indomethacin, were employed to observe the solubilization behavior of poorly soluble drugs in Gelucire/cosolvent mixtures. The solubility of these drugs in the mixtures could be explained very well by using the new solubility model introduced in this article. Addition of cosolvents to the Gelucire solution did not enhance the solubility very much, and thus the combined use of cosolvents with Gelucire offered only little advantage from the viewpoint of solubility.

Self-assembly study and formation of hydrophobized PVA dense and stable nanoparticles loaded with cholesterol or a steroid-type drug.

This work reports the preparation of modified poly(vinyl alcohol) PVA decorated with two different hydrophobic side-arms. Each material displays various percentages of pendant oleate and cholesteryl groups. The molar amount and the difference between their respective physico-chemical contributions are able to induce size variations of the formed micelles in aqueous media. These large amphiphilic structures hold a hydrophobic core ready for the incorporation of strong hydrophobic species such as cholesterol or prednisolone, a well-known low-water soluble steroid-type drug. In the presence of a steroid derivative, the modified PVA could form smaller and dense nanoparticles loaded in their cores. The synthesis of each polymer was controlled by (1)H NMR and FT-IR spectroscopies. The size of the empty micelles and the diameter of the loaded nanoparticles were determined by dynamic light scatting (DLS) studies. The measurement of the critical micelle concentration (CMC) was carried out for each polymer sample by fluorescence probing using pyrene. The amount of cholesterol incorporated into the hydrophobic core was estimated and all binding modes between the steroids and each amphiphilic polymer were also discussed in regard to their size distribution, concentration and stability.

Low-density microparticles with petaloid surface structure for pulmonary drug delivery.

The morphology of spray-dried particles composed of psicose and hydroxypropyl methylcellulose was modified by adding ammonium bicarbonate (ABC) to the solution. The surface structure of the particles was altered by immediate transformation of ABC to gaseous components during the spray drying. As a result, low-density microparticles with a petaloid surface structure, which was controllable by changing the evaporation rate of ABC, was obtained. This technique should be useful for modifying characteristics of solid particles for pulmonary drug delivery.

Emerging pressure-release materials for drug delivery.

Drug delivery systems for non-specialist uses and application under field conditions are required for medical action in disaster situations and in developing countries. A possible solution for drug delivery under those conditions might be provided by mechanical manipulation of host-guest interactions that could allow drug release control by simple human actions such as hand motion. This editorial article presents recent research developments on control of molecular recognition, capture and release involving macroscopic mechanical motions. In particular, pressure-induced drug release from a cyclodextrin-linked gel has been used to realize controlled release of entrapped drugs upon applying an easy-to-perform mechanical procedure. These easy-action-based drug delivery systems can be applied at will by unskilled staff or patients and are expected to be used to assist medically patients in less-favorable environments anywhere in the world.

Miscibility analysis of particulate solid dispersions prepared by electrospray deposition.

Physical characteristics of solid dispersions were investigated using carbamazepine (CBZ) and prednisolone (PDN) as model drugs, and poly(vinyl pyrrolidone) and Eudragit as polymeric excipients. Electrospray method provided particulate formulations, of which the particle size was typically in the order of micrometers, when the polymer concentration of the solution used for the preparation was below 2% (w/v). Decrease of the solution concentration and flow rate resulted in a decrease in the particle diameter, as theoretically expected. Also, the particle size could be reduced to 400 nm by increasing the conductivity of the solution by the addition of salts. When poly(vinyl pyrrolidone) K90 was used as an excipient, CBZ was homogeneously loaded up to ca. 40%, and if a greater amount was added, the excess CBZ was separated as a pure crystalline phase. PDN was homogeneously loaded up to ca. 60%. However, in contrast to CBZ, excess PDN maintained the amorphous state, even when a greater amount was added. The separated excess PDN phase was crystallized in the heating process during thermal analysis. In addition to the thermodynamic factor, there seems to be a dynamic factor to separate drug phase from the excipient phase, depending on their molecular weight and miscibility during the electrospray deposition process. The mechanism for particle formation by electrospray deposition is discussed with emphasis on the miscibility between drug and excipient.

Isothermal crystallization of Imwitor 742 from supercooled liquid state.

PURPOSE: Crystallization behavior of Imwitor 742 was investigated for use as a liquid-filled capsule carrier. MATERIALS AND METHODS: The crystallization behavior of Imwitor 742 was assessed using DSC, X-ray diffraction, and microscopy. The physical stability of Imwitor 742 under refrigerated and ambient conditions was estimated by isothermal crystallization studies using DSC. The effect of hard capsule shells and additives on crystallization kinetics was also examined. RESULTS: When Imwitor 742 was cooled in the DSC measurement, the form alpha appeared at -20 degrees C. When this form was heated from -40 degrees C, melt-crystallization into the form beta + beta' was initiated at -30 degrees C, followed by successive melting. Isothermal crystallization studies at temperatures higher than -14 degrees C yielded the form beta + beta'. The crystallization behavior was explained in terms of the Avrami model fitting by assuming 2-dimensional crystal growth. Kinetic analysis suggested that the liquid state of Imwitor 742 was maintained for 46 h and 40 months at 5 and 25 degrees C, respectively, although the deviation in induction time was expected to be large at these temperatures. Addition of hard capsule shells promoted the crystallization behavior, while addition of drug or water prolonged the induction time. CONCLUSION: The supercooled liquid state of Imwitor 742 was quite stable. However, additives to retard crystallization should be used, because the deviation in the induction time was very large. Hard capsule shells enhanced the crystallization of Imwitor 742, possibly by acting as nuclei for crystal growth.