Molecular Dynamics Simulation of Amorphous Indomethacin-Poly(Vinylpyrrolidone) Glasses: Solubility and Hydrogen Bonding Interactions

Amorphous drug dispersions are frequently employed to enhance solubility and dissolution of poorly water-soluble drugs and thereby increase their oral bioavailability. Because these systems are metastable, phase separation of the amorphous components and subsequent drug crystallization may occur during storage. Computational methods to determine the likelihood of these events would be very valuable, if their reliability could be validated. This study investigates amorphous systems of indomethacin (IMC) in poly(vinylpyrrolidone) (PVP) and their molecular interactions by means of molecular dynamics (MD) simulations. IMC and PVP molecules were constructed using X-ray diffraction data, and force-field parameters were assigned by analogy with similar groups in Amber-ff03. Five assemblies varying in PVP and IMC composition were equilibrated in their molten states then cooled at a rate of 0.03 K/ps to generate amorphous glasses. Prolonged aging dynamic runs (100 ns) at 298 K and 1 bar were then carried out, from which solubility parameters, the Flory-Huggins interaction parameter, and associated hydrogen bonding properties were obtained. Calculated glass transition temperature (T_g) values were higher than experimental results because of the faster cooling rates in MD simulations. Molecular mobility as characterized by atomic fluctuations was substantially reduced below the T_g with IMC–PVP systems exhibiting lower mobilities than that found in amorphous IMC, consistent with the antiplasticizing effect of PVP. The number of IMC–IMC hydrogen bonds (HBs) formed per IMC molecule was substantially lower in IMC–PVP mixtures, particularly the fractions of IMC molecules involved in two or three HBs with other IMC molecules that may be potential precursors for crystal growth. The loss of HBs between IMC molecules in the presence of PVP was largely compensated for by the formation of IMC–PVP HBs. The difference (6.5 MPa^1/2) between the solubility parameters in amorphous IMC (25.5 MPa^1/2) and PVP (19.0 MPa^1/2) suggests a small, positive free energy of mixing, although it is close to the criterion for miscibility (< 7 MPa^1/2). In contrast to the solubility-parameter method, the calculated Flory-Huggins interaction parameter (? 0.61 ± 0.25), which takes into account the IMC–PVP interaction energy, predicts complete miscibility at all PVP compositions, in agreement with experimental observations. These results from MD simulations were combined with experimental values for the crystalline γ-polymorph of IMC and amorphous IMC to estimate the solubility of IMC in amorphous PVP dispersions and the theoretical enhancement in the aqueous solubility of IMC molecularly dispersed in PVP at various volume fractions. © 2012Wiley Periodicals, Inc. and the American Pharmacists Association J Pharm Sci 102:876–891, 2013     

Probing Beta Relaxation in Pharmaceutically Relevant Glasses by Using DSC

Purpose This study was conducted to demonstrate the use of differential scanning calorimetry (DSC) in detecting and measuring β-relaxation processes in amorphous pharmaceutical systems. Methods DSC was employed to study amorphous samples of poly(vinylpyrrolidone) (PVP), indomethacin (IM), and ursodeoxycholic acid (UDA) that were annealed at temperatures (T_a) around 0.8 of their glass transition temperatures (T_g). Dynamic mechanical analysis (DMA) was used to measure β-relaxation in PVP. Results Reheating the annealed samples gives rise to annealing peaks that occur below T_g. The peaks cannot be generated when annealing below the low temperature limit of β-relaxation. These limits are around 50°C for PVP, −20°C for IM, and 30°C for UDA. The effective activation energy (E) of the sub-T_g relaxation has been estimated for each T_a and found to increase with T_a, reflecting increasing contribution of the α-process. Estimates of E for β-relaxation have been obtained from the lowest T_a data, and are as follows: 68 (PVP), 56 (IM), 67 (UDA) kJ mol⁻¹. Conclusions DSC can be used for detecting β-relaxation processes and estimating its low temperature limit, i.e., the temperature below which amorphous drugs would remain stable. It can also provide comparative estimates of low temperature stability of amorphous drugs in terms of the activation energies of the β-relaxation.     

Physicochemical Characterization of Hot Melt Extruded Bicalutamide–Polyvinylpyrrolidone Solid Dispersions

Solid molecular dispersions of bicalutamide (BL) and polyvinylpyrrolidone (PVP) were prepared by hot melt extrusion technology at drug‐to‐polymer ratios of 1:10, 2:10, and 3:10 (w/w). The solid‐state properties of BL, physical mixtures of BL/PVP, and hot melt extrudates were characterized using differential scanning calorimetry (DSC), powder X‐ray diffractometry (PXRD), Raman, and Fourier transform infrared (FTIR) spectroscopy. Drug dissolution studies were subsequently conducted on hot melt extruded solid dispersions and physical mixtures. All hot melt extrudates had a single T_g between the T_g of amorphous BL and PVP indicating miscibility of BL with PVP and the formation of solid molecular dispersions. PXRD confirmed the presence of the amorphous form of BL within the extrudates. Conversely, PXRD patterns recorded for physical mixtures showed sharp bands characteristic of crystalline BL, whereas DSC traces had a distinct endotherm at 196°C corresponding to melting of crystalline BL. Further investigations using DSC confirmed solid‐state plasticization of PVP by amorphous BL and hence antiplasticization of amorphous BL by PVP. Experimentally observed T_g values of physical mixtures were shown to be significantly higher than those calculated using the Gordon–Taylor equation suggesting the formation of strong intermolecular interactions between BL and PVP. FTIR and Raman spectroscopy were used to investigate these interactions and strongly suggested the presence of secondary interaction between PVP and BL within the hot melt extrudates. The drug dissolution properties of hot melt extrudates were enhanced significantly in comparison to crystalline BL and physical mixtures. Moreover, the rate and extent of BL release were highly dependent on the amount of PVP present within the extrudate. Storage of the extrudates confirmed the stability of amorphous BL for up to 12 months at 20°C, 40% RH whereas stability was reduced under highly humid conditions (20°C, 65% RH). Interestingly, BL recrystallization after storage under these conditions had no effect on the dissolution properties of the extrudates. © 2009 Wiley‐Liss, Inc. and the American Pharmacists Association J Pharm Sci 99: 1322–1335, 2010     

Effects of Molecular Interactions on Miscibility and Mobility of Ibuprofen in Amorphous Solid Dispersions With Various Polymers

Hydrogen bonds (HBs) in amorphous solid dispersions may influence physical stability through effects on both drug miscibility and mobility. Amorphous solid dispersions containing the HB-donor ibuprofen (IBP) alone or with one of four model polymers (poly(vinyl pyrrolidone) [PVP], poly(vinyl pyrrolidone/vinyl acetate) [PVP/VA], poly(vinyl acetate) [PVA], or polystyrene [PST]) were monitored by molecular dynamics simulation. HB distributions and contributions of electrostatic, van der Waals, and internal interactions to miscibility and mobility were analyzed versus drug concentration. The probability of IBP-IBP HBs decreases markedly (0.6→0.0) with dilution (100→10% drug) in PVP due to IBP-PVP HBs while dilution in the nonpolar PST has a more modest effect on IBP-IBP HB probability (0.6→0.3). Concentration-dependent Flory-Huggins interaction parameters (χ) were determined to assess drug-polymer miscibility. χ_IBP-PVP values were ?0.9 to ?1.8 with a plateau near 50% w/w PVP, whereas χ_IBP-PST fluctuated near zero (?0.1 to 0.3), suggesting that IBP is more soluble in PVP than in PST. χ_IBP-polymer values in polymers varying in pyrrolidone/acetate composition were in the order PVP (most favorable) > PVP/VA > PVA (least favorable). Decreased local mobility of IBP measured by the atomic fluctuation correlates with more IBP-PVP HBs with increasing PVP content. The opposite trend in IBP-PST may arise from IBP-IBP HB disruption on dilution.     

Synthesis and In Vitro Release of Adriamycin from Star-Shaped Poly(Lactide-co-Glycolide) Nano- and Microparticles

The star-shaped poly(lactide-co-glycolide (PLGA)–β-cyclodextrin (PLGA–β-CD) copolymer was synthesized by reacting L-lactide, glycolide, and β-cyclodextrin in the presence of stannous octoate as a catalyst. The structure of PLGA–β-CD copolymer was confirmed with ¹H-NMR, ¹³C-NMR, and FT-IR spectra. Adriamycin (ADR), which is an antitumor antibiotic, was encapsulated within micro- and nanoparticles made of PLGA–β-CD with a modified double emulsion method. Relatively low amount of β-CD and catalyst were used in order to obtain high molecular weight polymers. Differential scanning calorimetry (DSC) was used to determine the thermal properties of star-shaped copolymers. The reduction of interactions between the starshaped polyester molecules is due to their branched structure lowered T_g and T_m compared to linear PLGA copolymers. Effects of the experimental parameters, such as copolymer composition, ADR concentration, copolymer concentration, and poly(vinyl alcohol) concentration, on particular size and encapsulation efficiency were investigated. An increase in the internal aqueous phase volume led to a decrease in particles average size. A decrease in the polymer concentration resulted in increasing the particle average size from 135.5 to 325.6 nm. The high entrapment efficiency (EE) (about 65%) was obtained for 220 μm particles. All of the release profiles indicated a close relationship between each formulation variable and the amount of ADR released.     

Effect of Polymer Content and Molecular Weight on the Morphology and Heat- and Moisture-Induced Transformations of Spray-Dried Composite Particles of Amorphous Lactose and Poly(vinylpyrrolidone)

Purpose. The aim was to investigate the influence of polymer content and molecular weight on the morphology and heat- and moisture-induced transformations, as indicators of stability, of spray-dried composite particles of amorphous lactose and poly(vinylpyrrolidone) (PVP). Methods. Amorphous lactose and composite particles of amorphous lactose with different contents and molecular weights of PVP were prepared by spray drying. The nanostructure of the particles was analyzed by x-ray powder diffractometry, the morphology by light microscopy and SEM, the glass transition temperatures (T_g), crystallization temperatures (T_c), heats of crystallization and melting temperatures by differential scanning calorimetry, and moisture-induced crystallizations gravimetrically and by microcalorimetry. Results. All the types of particles prepared were amorphous. The T_g was unchanged or only marginally increased as a result of the inclusion of PVP. However, crystallization temperature, time to moisture-induced crystallization, and particle morphology were affected by both content and molecular weight of PVP. Conclusions. Increased content and molecular weight of PVP may have the potential to increase the physical stability of amorphous lactose. However, T_g seems not to be a relevant indicator for the stability of this type of amorphous composite materials.     

Solid-State NMR Investigation of Drug-Excipient Interactions and Phase Behavior in Indomethacin-Eudragit E Amorphous Solid Dispersions

Purpose

To investigate the nature of drug-excipient interactions between indomethacin (IMC) and methacrylate copolymer Eudragit® E (EE) in the amorphous state, and evaluate the effects on formulation and stability of these amorphous systems.

Methods

Amorphous solid dispersions containing IMC and EE were spray dried with drug loadings from 20% to 90%. PXRD was used to confirm the amorphous nature of the dispersions, and DSC was used to measure glass transition temperatures (T_g). ¹³C and ¹⁵N solid-state NMR was utilized to investigate changes in local structure and protonation state, while ¹H T₁ and T_1ρ relaxation measurements were used to probe miscibility and phase behavior of the dispersions.

Results

T_g values for IMC-EE solid dispersions showed significant positive deviations from predicted values in the drug loading range of 40–90%, indicating a relatively strong drug-excipient interaction. ¹⁵N solid-state NMR exhibited a change in protonation state of the EE basic amine, with two distinct populations for the EE amine at ?360.7 ppm (unprotonated) and ?344.4 ppm (protonated). Additionally, ¹H relaxation measurements showed phase separation at high drug load, indicating an amorphous ionic complex and free IMC-rich phase. PXRD data showed all ASDs up to 90% drug load remained physically stable after 2 years.

Conclusions

¹⁵N solid-state NMR experiments show a change in protonation state of EE, indicating that an ionic complex indeed forms between IMC and EE in amorphous solid dispersions. Phase behavior was determined to exhibit nanoscale phase separation at high drug load between the amorphous ionic complex and excess free IMC.

     

Prediction of Onset of Crystallization in Amorphous Pharmaceutical Systems: Phenobarbital,Nifedipine/PVP,and Phenobarbital/PVP

The aim of this work is to determine if a stability testing protocol based on the correlations between crystallization onset and relaxation time above the glass transition temperature (T_g) can be used to predict the crystallization onsets in amorphous pharmaceutical systems well below their T_g. This procedure assumes that the coupling between crystallization onset and molecular mobility is the same above and below T_g. The stability testing protocol has been applied to phenobarbital, phenobarbital/polyvinylpyrrolidone (PVP) (95/5, w/w), and nifedipine/PVP (95/5, w/w). Crystallization onsets have been detected by polarized light microscopy examination of amorphous films; molecular mobility has been determined by dielectric relaxation spectroscopy above T_g and by both isothermal calorimetry and modulated differential scanning calorimetry below T_g. We find that small amounts of PVP significantly retard re-crystallization. This dramatic effect of PVP is not related to mobility, so this approach applies, at best, to extrapolation of high temperature data on a given formulation to low temperatures. Variation in molecular mobility at these concentrations of PVP is not the dominant factor in determining variation in propensity for re-crystallization from glassy systems; we suggest surface interactions between PVP and nuclei and/or small crystals slowing growth control variation in crystallization kinetics between formulations. © 2010 Wiley-Liss, Inc. and the American Pharmacists Association J Pharm Sci 99:3887-3900, 2010     

The Effects of Absorbed Water on the Properties of Amorphous Mixtures Containing Sucrose

Purpose. To measure the water vapor absorption behavior of sucrose-poly(vinyl pyrrolidone) (PVP) and sucrose-poly(vinyl pyrrolidone co-vinyl acetate) (PVP/VA) mixtures, prepared as amorphous solid solutions and as physical mixtures, and the effect of absorbed water on the amorphous properties, i.e., crystallization and glass transition temperature, T_g, of these systems. Methods. Mixtures of sucrose and polymer were prepared by co-lyophilization of aqueous sucrose-polymer solutions and by physically mixing amorphous sucrose and polymer. Absorption isotherms for the individual components and their mixtures were determined gravimetrically at 30°C as a function of relative humidity. Following the absorption experiments, mixtures were analyzed for evidence of crystallization using X-ray powder diffraction. For co-lyophilized mixtures showing no evidence of crystalline sucrose, T_g was determined as a function of water content using differential scanning calorimetry. Results. The absorption of water vapor was the same for co-lyophilized and physically mixed samples under the same conditions and equal to the weighted sums of the individual isotherms where no sucrose crystallization was observed. The crystallization of sucrose in the mixtures was reduced relative to sucrose alone only when sucrose was molecularly dispersed (co-lyophilized) with the polymers. In particular, when co-lyophilized with sucrose at a concentration of 50%, PVP was able to maintain sucrose in the amorphous state for up to three months, even when the T_g was reduced well below the storage temperature by the absorbed water. Conclusions. The water vapor absorption isotherms for co-lyophilized and physically mixed amorphous sucrose-PVP and sucrose-PVP/VA mixtures at 30°C are similar despite interactions between sugar and polymer which are formed when the components are molecularly dispersed with one another. In the presence of absorbed water the crystallization of sucrose was reduced only by the formation of a solid-solution, with PVP having a much more pronounced effect than PVP/VA. The effectiveness of PVP in preventing sucrose crystallization when significant levels of absorbed water are present was attributed to the molecular interactions between sucrose, PVP and water.     

Effect of temperature and moisture on the miscibility of amorphous dispersions of felodipine and poly(vinyl pyrrolidone)

The physical stability of amorphous molecular level solid dispersions will be influenced by the miscibility of the components. The goal of this work was to understand the effects of temperature and relative humidity on the miscibility of a model amorphous solid dispersion. Infrared spectroscopy was used to evaluate drug–polymer hydrogen bonding interactions in amorphous solid dispersions of felodipine and poly(vinyl pyrrolidone) (PVP). Samples were analyzed under stressed conditions: high temperature and high relative humidity. The glass transition temperature (T_g) of select systems was studied using differential scanning calorimetry (DSC). Atomic force microscopy (AFM) and transmission electron microscopy (TEM) were used to further investigate moisture-induced changes in solid dispersions. Felodipine-PVP solid dispersions showed evidence of adhesive hydrogen bonding interactions at all compositions studied. The drug–polymer intermolecular interactions were weakened and/or less numerous on increasing the temperature, but persisted up to the melting temperature of the drug. Changes in the hydrogen bonding interactions were found to be reversible with changes in temperature. In contrast, the introduction of water into amorphous molecular level solid dispersions at room temperature irreversibly disrupted interactions between the drug and the polymer resulting in amorphous-amorphous phase separation followed by crystallization. DSC, AFM, and TEM results provided further evidence for the occurrence of moisture induced immiscibility. In conclusion, it appears that felodipine-PVP solid dispersions are susceptible to moisture-induced immiscibility when stored at a relative humidity ≥75%. In contrast, the solid dispersions remained miscible on heating. © 2009 Wiley-Liss, Inc. and the American Pharmacists Association J Pharm Sci 99:169–185, 2010     

The Study of Phase Separation in Amorphous Freeze-Dried Systems. Part I: Raman Mapping and Computational Analysis of XRPD Data in Model Polymer Systems

Phase separation in amorphous freeze-dried mixtures is likely in many systems. However, suitable detection methodology has been lacking, as the classical technique, differential scanning calorimetry (DSC), relies upon detection of multiple glass transition temperatures (T_g), each of which is characteristic of a given amorphous phase. The lack of a detectable glass transition temperature in protein-rich phases, limits the application of DSC. Here, we focus on evaluating new methods for detection of phase separation in amorphous freeze-dried mixtures. A novel Raman mapping technique has been evaluated using model binary polymer mixtures of PVP and dextran known to phase separate. The sensitivity of this Raman technique in detecting phase separation was comparable to DSC. Phase separation was detected in compositions of 1:9 to 3:2 (PVP 10,000/dextran 5000) and 3:7 to 4:1 (PVP 29,000/dextran 10,000) by DSC and Raman. Computational methodologies applied to X-ray powder diffraction (XRPD) data from these systems are also shown to reliably detect the presence of phase separation. However, some differences between techniques were observed in cases lying on the boundary of phase separation. Thus, Raman and XRPD show promise for detecting phase separation in systems, which do not exhibit detectable glass transitions by calorimetry.     

Bulk,surface properties and water uptake mechanisms of salt/acid amorphous composite systems

Developing amorphous pharmaceuticals can be desirable due to advantageous biopharmaceutical properties. Low glass transition temperature (T_g) amorphous drugs can be protected from crystallisation by mixing with high T_g excipients, such as polymers, or with salt forms. However, both polymers and salts can enhance the water uptake. The aim of this study was to formulate physico-chemically stable amorphous materials, by co-processing different proportions of sulfathiazole and its sodium salt to produce an optimum ratio, characterised by the best physical stability and lowest hygroscopicity. Both sulfathiazole and salt amorphised upon spray drying. At room temperature, sulfathiazole crystallised within 1 h at <5% relative humidity while the salt deliquesced when exposed to ambient humidity conditions. In the case of composite systems, FTIR spectroscopy, thermal and surface analysis suggested interactions with an acid:salt stoichiometry of 1:2. Increasing proportions of salt raised the T_g, enhancing the storage stability, however this was opposed by an enhanced hygroscopicity. The water uptake mechanism within the different amorphous systems, analysed by fitting the water sorption isotherms with the Young and Nelson equation, was dependent on the ratio employed, with the salt and the acid facilitating absorption and adsorption, respectively. Tuning the properties of amorphous salt/acid composites by optimising the ratio appears potentially promising to improve the physical stability of amorphous formulations.     

Modelling of molecular phase transitions in pharmaceutical inhalation compounds: An in silico approach

Molecular dynamic simulations have been successfully utilised with molecular modelling to estimate the glass transition temperature (T_g) of polymers. In this paper, we use a similar approach to predict the T_g of a small pharmaceutical molecule, beclomethasone dipropionate (BDP). Amorphous beclomethasone dipropionate was prepared by spray-drying. The amorphous nature of the spray-dried material was confirmed with scanning electron microscopy, differential scanning calorimetry (DSC) and X-ray powder diffraction (XRD). Molecular models for amorphous BDP were constructed using the amorphous cell module in Discovery studio™. These models were used in a series of molecular dynamic simulations to predict the glass transition temperature. The T_g of BDP was determined by isothermal-isobaric molecular dynamic simulations, and different thermodynamic parameters were obtained in the temperature range of −150 to 400 °C. The discontinuity at a specific temperature in the plot of temperature versus amorphous cell volume (V) and density (ρ) was considered to be the simulated T_g. The predicted T_g from four different simulation runs was 63.8 °C ± 2.7 °C. The thermal properties of amorphous BDP were experimentally determined by DSC and the experimental T_g was found to be ∼65 °C, in good agreement with computational simulations.     

The characterization and dissolution performances of spray dried solid dispersion of ketoprofen in hydrophilic carriers

Solid dispersion is one of the most promising strategies to improve oral bioavailability of poorly soluble API. However, there are inconsistent dissolution performances of solid dispersion reported which entails further investigation. In this study, solid dispersions of ketoprofen in three hydrophilic carriers, i.e. PVP K30, PVPVA 6:4 and PVA were prepared and characterized. Physical characterization of the physical mixture of ketoprofen and carriers shows certain extent of amorphization of the API. This result is coinciding to evaluation of drug–polymer interaction using ATR-FTIR whereby higher amorphization was seen in samples with higher drug–polymer interaction. XRPD scanning confirms that fully amorphous solid dispersion was obtained for SD KTP PVP K30 and PVPVA system whereas partially crystalline system was obtained for SD KTP PVA. Interestingly, dissolution profiles of the solid dispersion had shown that degree of amorphization of KTP was not directly proportional to the dissolution rate enhancement of the solid dispersion system. Thus, it is concluded that complete amorphization does not guarantee dissolution enhancement of an amorphous solid dispersion system.     

Freeze-Concentration Separates Proteins and Polymer Excipients Into Different Amorphous Phases

Purpose. To study the miscibility of proteins and polymer excipients in frozen solutions and freeze-dried solids as protein formulation models. Methods. Thermal profiles of frozen solutions and freeze-dried solids containing various proteins (lysozyme, ovalbumin, BSA), nonionic polymers (Ficoll, polyvinylpyrrolidone [PVP]), and salts were analyzed by differential scanning calorimetry (DSC). The polymer miscibility was determined from the glass transition temperature of maximally freeze-concentrated solute (T_g) and the glass transition temperature of freeze-dried solid (T_g). Results. Frozen Ficoll or PVP 40k solutions showed T_g at –22°C, while protein solutions did not show an apparent T_g. All the protein and nonionic polymer combinations (5% w/w, each) were miscible in frozen solutions and presented single T_gs that rose with increases in the protein ratio. Various salts concentration-dependently lowered the single T_gs of the proteins and Ficoll combinations maintaining the mixed amorphous phase. In contrast, some salts induced the separation of the proteins and PVP combinations into protein-rich and PVP-rich phases among ice crystals. The T_gs of these polymer combinations were jump-shifted to PVP's intrinsic T_g at certain salt concentrations. Freeze-dried solids showed varied polymer miscibilities identical to those in frozen solutions. Conclusions. Freeze-concentration separates some combinations of proteins and nonionic polymers into different amorphous phases in a frozen solution. Controlling the polymer miscibility is important in designing protein formulations.     

A Quantitative Assessment of the Significance of Molecular Mobility as a Determinant for the Stability of Lyophilized Insulin Formulations

Purpose The purpose was to explore a method for quantitatively assessing the contribution of molecular mobility to the chemical reactivity of amorphous solids. Degradation of insulin in lyophilized formulations containing trehalose and poly(vinylpyrrolidone)(PVP) was chosen as a model system, and the temperature- and glass transition temperature (T_g)-dependence of the degradation rate was analyzed to obtain the relative contributions of molecular mobility and that of the chemical activational barrier reflected in the energy of activation.Methods Insulin degradation and dimerization in lyophilized trehalose and PVP formulations were monitored at various relative humidities (6–60% RH) and temperatures (10–60°C) by reverse-phase high-performance liquid chromatography (HPLC) and high-performance size-exclusion chromatography (HP-SEC), respectively. The T_g and fragility parameter of the lyophilized insulin formulations were determined by differential scanning calorimetry (DSC).Results Insulin degradation in the initial stage was describable with first-order kinetics for both of the trehalose and PVP formulations. The temperature- and T_g-dependence of the degradation rate indicated that the reactivity of insulin in the trehalose formulation is affected by molecular mobility at low humidity (12% RH), such that the ratio of the observed rate constant (k′) to the rate constant governed only by the activational barrier (k) was 0.051 at the T_g. At higher humidities, in contrast, the value of k′/k was much higher (0.914, 0.978, and 0.994 for 23% RH, 33% RH, and 43% RH, respectively), indicating that insulin degradation rate is determined predominantly by the activational barrier. For insulin degradation in the PVP formulation at temperatures below T_g, the contribution of molecular mobility to the degradation rate appeared to be negligible, as the extrapolated value of t₉₀ at the T_g exhibited a large difference between the formulations with differing T_g values (because of differing water contents).Conclusions The reactivity of insulin in the trehalose and PVP formulations can be described by an equation including factors reflecting the activational barrier (activation energy and frequency coefficient) and factors reflecting the molecular mobility (T_g, fragility parameter and a constant representing the relationship between the molecular mobility and the reaction rate). Thus, analysis of temperature dependence based on the proposed equation allows quantitative assessment of the significance of molecular mobility as a factor affecting chemical reactivity.     

Influence of Glass Forming Ability on the Physical Stability of Supersaturated Amorphous Solid Dispersions

In this study, the influence of the glass-forming ability (GFA) of a drug on its physical stability in a supersaturated solid dispersion was investigated. Nine drugs were classified according to their GFA using their respective critical cooling rate. Their respective solubility in poly(vinylpyrrolidone-co-vinyl acetate) 6:4 (PVPVA64) was predicted using the melting point depression method based on the Flory-Huggins lattice theory. Supersaturated amorphous solid dispersions at a level of 25% w/w drug above saturation solubility in the polymer were prepared by film-casting, and their respective physical stability at temperatures of 10°C or 20°C above or below their respective T_g (dry conditions) was monitored by the use of polarized light microscopy. This study showed that drugs with good GFA (class 3) on average have higher physical stability in supersaturated amorphous solid dispersion compared to drug with modest GFA (class 2), which in turn have higher physical stability in supersaturated amorphous solid dispersion than drugs with poor GFA (class 1). These results indicate that the GFA of a drug and its physical stability in a supersaturated amorphous solid dispersion stored at a temperature above or below its T_g are correlated.     

Recrystallization of Nifedipine and Felodipine from Amorphous Molecular Level Solid Dispersions Containing Poly(vinylpyrrolidone) and Sorbed Water

Purpose To compare the physical stability of amorphous molecular level solid dispersions of nifedipine and felodipine, in the presence of poly(vinylpyrrolidone) (PVP) and small amounts of moisture. Methods Thin amorphous films of nifedipine and felodipine and amorphous molecular level solid dispersions with PVP were stored at various relative humidities (RH) and the nucleation rate was measured. The amount of water sorbed at each RH was measured using isothermal vapor sorption and glass transition temperatures (T _g) were determined using differential scanning calorimetry. The solubility of each compound in methyl pyrrolidone was measured as a function of water content. Results Nifedipine crystallizes more easily than felodipine at any given polymer concentration and in the presence of moisture. The glass transition temperatures of each compound, alone and in the presence of PVP, are statistically equivalent at any given water content. The nifedipine systems are significantly more hygroscopic than the corresponding felodipine systems. Conclusions Variations in the physical stability of the two compounds could not be explained by differences in T _g. However, the relative physical stability is consistent with differences in the degree of supersaturation of each drug in the solid dispersion, treating the polymer and water as a co-solvent system for each drug compound.     

One-step preparation of nano-in-micro poly(vinyl alcohol) embolic microspheres and used for dual-modal T1/T2-weighted magnetic resonance imaging

It is crucial to develop dual or multi-modal self-imaging embolic microspheres to evaluate the effects of transcatheter arterial embolization therapy of tumor. However, the preparation of such hybrid microspheres always involved in multiple steps or complicated conditions. Here, poly(vinyl alcohol) (PVA) hybrid microspheres with dual-modal T₁/T₂-weighted magnetic resonance imaging (MRI) have been prepared based on microfluidic technique in one step. Gd₂O₃ and Fe₃O₄ nanoparticles with a size of ~5 nm act as T₁- and T₂-weighted MRI contrast agents, respectively, which are simultaneously in-situ synthesized in the PVA matrix via the reaction of metal ions and alkali with PVA chains as a soft template. Meanwhile, these metallic-oxide nanoparticles act as cross-linker to gelatinize the PVA droplets to obtain nano-in-micro PVA microspheres in one step. This procedure is simple, economic and feasible. The obtained nano-in-micro PVA microspheres show good magnetothermal effect, enhanced T₁- and T₂-weighted MRI and embolization effect.     

The Effect of Low Concentrations of Molecularly Dispersed Poly(Vinylpyrrolidone) on Indomethacin Crystallization from the Amorphous State

Purpose. To investigate the effect of low concentrations of molecularly dispersed poly(vinylpyrrolidone) (PVP) on indomethacin (IMC) crystallization from the amorphous state using particle size effects to identify possible mechanisms of crystallization inhibition. Methods. Different particle sizes of amorphous IMC and 1, 2, and 5% PVP were stored dry at 30°C for 84 days. PXRD was used to calculate the rate and extent of crystallization and the polymorph formed. Results. Crystallization from amorphous IMC and IMC/PVP molecular dispersions yielded the polymorph of IMC. Crystallization rates were reduced at larger particle size and in the presence of 1, 2, and 5%PVP. Crystallization did not reach completion in some IMC/PVP samples, with the quantity of uncrystallized amorphous phase proportional to particle size. Conclusions. Low concentrations of molecularly dispersed PVP affected IMC crystallization from the amorphous state. Formation of -IMC at rates dependent on particle size indicated that surface nucleation predominated in both the absence and presence of PVP. Excellent correlation was seen between the extent of crystallization and simulated depths of crystal penetration, supporting the hypothesis that increasing local PVP concentration inhibits crystal growth from surface nuclei into the amorphous particle.