Hybrid Methacrylated Gelatin and Hyaluronic Acid Hydrogel Scaffolds. Preparation and Systematic Characterization for Prospective Tissue Engineering Applications.

Hyaluronic acid (HA) and gelatin (Gel) are major components of the extracellular matrix of different tissues, and thus are largely appealing for the construction of hybrid hydrogels to combine the favorable characteristics of each biopolymer, such as the gel adhesiveness of Gel and the better mechanical strength of HA, respectively. However, despite previous studies conducted so far, the relationship between composition and scaffold structure and physico-chemical properties has not been completely and systematically established. In this work, pure and hybrid hydrogels of methacroyl-modified HA (HAMA) and Gel (GelMA) were prepared by UV photopolymerization and an extensive characterization was done to elucidate such correlations. Methacrylation degrees of ca. 40% and 11% for GelMA and HAMA, respectively, were obtained, which allows to improve the hydrogels' mechanical properties. Hybrid GelMA/HAMA hydrogels were stiffer, with elastic modulus up to ca. 30 kPa, and porous (up to 91%) compared with pure GelMA ones at similar GelMA concentrations thanks to the interaction between HAMA and GelMA chains in the polymeric matrix. The progressive presence of HAMA gave rise to scaffolds with more disorganized, stiffer, and less porous structures owing to the net increase of mass in the hydrogel compositions. HAMA also made hybrid hydrogels more swellable and resistant to collagenase biodegradation. Hence, the suitable choice of polymeric composition allows to regulate the hydrogels´ physical properties to look for the most optimal characteristics required for the intended tissue engineering application.

Preparation of antioxidant active films based on chitosan: diffusivity study of α-tocopherol into food simulants.

New active films based on chitosan and polycaprolactone blends and containing α-tocopherol were designed for food packaging applications. Mechanical properties, stability against temperature and swelling degree in 50 % ethanol (v/v) were evaluated. Migration kinetics of α-tocopherol from the developed films into butter and food simulants [50 % ethanol (v/v), 95 % ethanol (v/v), and isooctane] at different temperatures were studied. α-Tocopherol was quantified in the food simulants by means of high performance liquid chromatography with diode-array detection at 292 nm. The proposed method exhibited a good sensitivity with a limit of detection of 0.1 mg/L. The kinetics release of α-tocopherol was characterized by determining the partition and the diffusion coefficients by using a mathematical modeling based on Fick's Second Law. The diffusion coefficients obtained ranged between 1.03 × 10(-13) and 2.24 × 10(-12) cm(2)/s for 95 % ethanol (v/v) at 4 and 20 °C, respectively. Developed films maintained the antioxidant activity for more than 20 days.

Cytocompatibility and P-glycoprotein inhibition of block copolymers: structure-activity relationship.

Amphiphilic polymeric micelles greatly improve the solubilization and sustained release of hydrophobic drugs and provide a protective environment for the cargo molecules in aqueous media, which favors lower drug administration doses, reduces adverse side effects, and increases blood circulation times and passive targeting to specific cells. These capabilities depend, among other variables, on the structure and composition of the polymer chains. Composition and, in particular, block length have been shown to play an important role in the modification of cellular responses such as drug internalization processes or transduction pathways when polymeric unimer/micelles are in close contact with cells. Here we present a detailed study about the role copolymer structure and composition play on cell viability and cellular response of several cell lines. To do that, more than 30 structurally related copolymers with diblock and triblock architectures containing different hydrophobic blocks and poly(ethylene oxide) as the common hydrophilic unit have been analyzed regarding cytocompatibility and potential as "active" cell response modifiers by testing their influence on the P-gp pump efflux mechanism responsible of multidrug resistance in cancerous cells. An empirical threshold for cell viability could be established at a copolymer EO/POeffective value above ca. 1.5 for copolymers with triblock structure, whereas no empirical rule could be observed for diblocks. Moreover, some of the tested copolymers (e.g., BO12EO227BO12 and EO57PO46EO57 that notably increased and C16EO455C16 that decreased the P-gp ATPase activity) were observed to act as efficient inhibitors of the P-gp efflux pump promoting an enhanced doxorubicin (DOXO) accumulation inside multidrug resistant (MDR) NCI-ADR-RES cells.

Estradiol sustained release from high affinity cyclodextrin hydrogels.

Hydrogels for loading estradiol and controlling its release were prepared cross-linking various cyclodextrins with ethyleneglycol diglycidylether. To select the more adequate cyclodextrins, estradiol solubility diagrams in water with beta-cyclodextrin (betaCD), methyl-beta-cyclodextrin (MbetaCD), hydroxypropyl-beta-cyclodextrin (HPbetaCD), and sulfobutyl-beta-cyclodextrin (SBbetaCD) were made in absence and presence of hydroxypropyl methylcellulose (HPMC) applying or not autoclaving. Although all cyclodextrins showed enough complexation capability, the low solubility of betaCD and the high anionic character of SBbetaCD hindered the cross-linking process, and these cyclodextrins were discarded for preparing hydrogels. Hydrogels prepared with MbetaCD (20%, 25%) or HPbetaCD (20%, 25%, and 30%), with or without HPMC 0.25%, absorbed 4-10 times their weight in water and loaded up to 24 mg estradiol per gram, which is 500 times greater than the amount of drug that can be dissolved in their aqueous phase. Positive linear correlation was found between the stability constant and the network/water partition coefficients of drug. The hydrogels sustained the release up to one week; the affinity of estradiol for the cyclodextrin units controlling the process, as shown by the negative correlation with the release rate constants. These results highlight the potential of cyclodextrin complexation for the development of hydrogels useful in loading hydrophobic drugs and controlling their release.

Microparticle-embedded fibroin/alginate beads for prolonged local release of simvastatin hydroxyacid to mesenchymal stem cells.

In the present work, we propose silk fibroin/alginate (SF/Alg) beads embedding simvastatin-loaded biodegradable microparticles as a versatile platform capable of tuning SVA release and in so doing osteogenic effects. In a first part of the study, microparticles of poly(lactic-co-glycolic) acid incorporating simvastatin either as lactone (SVL) or as hydroxyacid form (SVA) were prepared by spray-drying. While SVA-loaded microparticles released the drug in three days, long-term release of SVA could be obtained from SVL-loaded microparticles. In this latter case, SVL was promptly transformed to the osteogenic active SVA during release. When tested on mesenchymal stem cells, a time- and dose-dependent effect of SVL-loaded microparticles on cell proliferation and alkaline phosphatase (ALP) activity was found. Thereafter, SVL-loaded microparticles were embedded in SF/Alg beads to limit the initial simvastatin burst and to achieve easier implantation as well. Microparticle-embedded beads showed no cytotoxicity while ALP activity increased. If correctly exploited, the developed system may be suitable as osteogenic polymer scaffolds releasing correct amount of the drug locally for long time-frames.

Drug solubilization and delivery from cyclodextrin-Pluronic aggregates.

Colloidal systems based on Pluronic F127 (PF127) and hydroxypropyl-beta-cyclodextrin (HPbetaCD) have been characterized with a view to their potential use as delivery systems of hydrophobic drugs. Complexation of PF127 and HPbetaCD was evaluated by surface tension measurements, 1H-NMR spectroscopy and transmission electron microscopy. The critical micellar concentration, CMC, at 25 degrees C of PF127 (0.39 mM in pH 5.8 and 7.4 phosphate buffers, and 0.59 mM in pH 4.5 acetic/acetate and lactic/lactate buffers) was shifted to higher values by the addition of 38.17 mM HPbetaCD (CMC(app) = 1.18 mM). This is related to the threading of HPbetaCD onto the PF127 chains, as confirmed by 1H NMR experiments. HPbetaCD at this concentration notably raised the sol-gel transition temperature; the minimum PF127 concentration required for providing gelling systems in physiological environments being 13.4 mM. Both HPbetaCD and PF127 by themselves are able to notably increase the solubility of sertaconazole (SN). At HPbetaCD concentrations below 80 mM, an additive effect of both components on SN solubility was observed. At greater HPbetaCD concentrations, a non-additive increase occurred, which is related to the complexation of some PF127 unimers with HPbetaCD molecules, decreasing the total number of micelles and HPbetaCD cavities available for interacting with SN. The 13.4 mM PF127/38.17 mM HPbetaCD system, able to increase up to 100 times the SN solubility in pH5.8 phosphate buffer, showed temperature-dependent drug diffusion coefficients, able to control the release for one week at 37 degrees C.

Preparation of chitosan beads by simultaneous cross-linking/insolubilisation in basic pH. Rheological optimisation and drug loading/release behaviour.

A one-step procedure to prepare chitosan beads by simultaneous cross-linking with glutaraldehyde and insolubilisation in 1.5 M NaOH solution has been developed. The optimisation of the procedure was carried out by monitoring the evolution of the loss and storage moduli of chitosan solutions (1.5% (w/v), in acetic acid 0.2 M) in the presence of different proportions of glutaraldehyde. Increasing the chitosan molecular weight, glutaraldehyde concentration and/or process temperature from 20 to 37 degrees C, a reduction of time to reach the gel point was observed. The diameter of freshly prepared swollen beads was 3.2+/-0.4 mm and, after drying 0.48+/-0.18 mm. Swollen or previously dried beads were loaded with metronidazole by immersion in 0.1% (w/v), drug solution in a phosphate buffer pH 7.5, purified water, 0.2 M acetic acid or 0.1 M HCl. Beads synthesised at 37 degrees C experimented faster swelling than the ones prepared at 20 degrees C and even disintegrated in acetic acid. The amounts of metronidazole loaded (ranging from 1 to 286 mg/g dried beads) increased with swelling capacity of beads. The release studies carried out in 0.1 M HCl indicated that, regardless of the medium used to load the beads, all of them released the dose in less than 30 min. In summary, applying this one-step procedure and choosing the adequate glutaraldehyde proportion, it is possible to obtain particles of chitosan cross-linked with itself, which exhibit pH-sensitive swelling and which are able to release all the drug quickly into an acidic environment such as the stomach. The results obtained also highlight the importance of the pH of the medium for modulating the amount of drug loaded (it is remarkably greater at lower pHs) and the influence of temperature at which the beads are prepared on their tendency to disintegrate.

Polysaccharide-based aerogel microspheres for oral drug delivery.

Polysaccharide-based aerogels in the form of microspheres were investigated as carriers of poorly water soluble drugs for oral administration. These bio-based carriers may combine the biocompatibility of polysaccharides and the enhanced drug loading capacity of dry aerogels. Aerogel microspheres from starch, pectin and alginate were loaded with ketoprofen (anti-inflammatory drug) and benzoic acid (used in the management of urea cycle disorders) via supercritical CO2-assisted adsorption. Amount of drug loaded depended on the aerogel matrix structure and composition and reached values up to 1.0×10(-3) and 1.7×10(-3) g/m(2) for ketoprofen and benzoic acid in starch microspheres. After impregnation, drugs were in the amorphous state in the aerogel microspheres. Release behavior was evaluated in different pH media (pH 1.2 and 6.8). Controlled drug release from pectin and alginate aerogel microspheres fitted Gallagher-Corrigan release model (R(2)>0.99 in both cases), with different relative contribution of erosion and diffusion mechanisms depending on the matrix composition. Release from starch aerogel microspheres was driven by dissolution, fitting the first-order kinetics due to the rigid starch aerogel structure, and showed different release rate constant (k1) depending on the drug (0.075 and 0.160 min(-1) for ketoprofen and benzoic acid, respectively). Overall, the results point out the possibilities of tuning drug loading and release by carefully choosing the polysaccharide used to prepare the aerogels.

Bone critical defect repair with poloxamine-cyclodextrin supramolecular gels.

The aim of this study was to evaluate the osteoinductive capacity of a poloxamine (Tetronic(®) 908, T) and α-cyclodextrin (αCD) supramolecular gel (T-CD) as scaffold in a critical size defect in rat calvaria. The T-CD gel was evaluated solely and after being loaded with simvastatin (SV) and bone morphogenetic protein (BMP-2) separately and in combinations in order to reduce the doses of the active substances. Three doses of SV (7.5, 75, 750 µg) and two doses of BMP-2 (3 and 6 µg) were tested. The histology and histomorphometrical analysis showed improved bone repair with T-CD compared to T, probably due to better release control of both SV and BMP-2. In addition, as T-CD eroded more slowly than poloxamine alone, it remained longer in the defect site. Although synergism was not obtained with BMP-2 and SV, according to the observed regeneration of the defect, the dose of BMP-2 and SV can be reduced to 3 µg and 7.5 µg, respectively.

A novel hanging spherical drop system for the generation of cellular spheroids and high throughput combinatorial drug screening.

We propose a novel hanging spherical drop system for anchoring arrays of droplets of cell suspension based on the use of biomimetic superhydrophobic flat substrates, with controlled positional adhesion and minimum contact with a solid substrate. By facing down the platform, it was possible to generate independent spheroid bodies in a high throughput manner, in order to mimic in vivo tumour models on the lab-on-chip scale. To validate this system for drug screening purposes, the toxicity of the anti-cancer drug doxorubicin in cell spheroids was tested and compared to cells in 2D culture. The advantages presented by this platform, such as feasibility of the system and the ability to control the size uniformity of the spheroid, emphasize its potential to be used as a new low cost toolbox for high-throughput drug screening and in cell or tissue engineering.

Rheological properties of PLGA film-based implants: correlation with polymer degradation and SPf66 antimalaric synthetic peptide release.

This paper reports on the rheological properties of poly(D,L-lactic-co-glycolic acid) polymers (PLGA) dispersions used to form films and of the implants prepared by compression of SPf66 antimalaric peptide between several films, before application and during drug release. 25% PLGA (M(w)=48,000Da) dispersions in dichloromethane showed viscous Newtonian behaviour, being easy flowing and adaptable to the moulds. Evolution of viscoelastic properties, polymer molecular weight, and SPf66 release pattern from the implants immersed in various media was evaluated. Oscillatory shear test showed that freshly prepared implants have an elastic modulus, G', greater than the viscous modulus, G", being both practically independent of angular frequency. After 6 weeks immersion in a pH 7.4 phosphate buffer, G' and G" increased in almost one order of magnitude, despite of a significant polymer degradation. Polymer molecular weight decreased slowly during the first 10 days of immersion (a similar pattern was obtained at pHs 2 and 7.4) and then the degradation process accelerated (degradation index on day 7 equals to 0.89, and on day 14 equals to 16.5). SPf66 release profile followed a pattern similar to that of the polymer degradation index. These observations are explained in terms of changes in polymer structure and conformation that happen in the implant.

Incorporation of small quantities of surfactants as a way to improve the rheological and diffusional behavior of carbopol gels.

This paper analyzes the effects of Tween 80, Pluronic F-127, sodium dodecylsulfate (SDS), and benzalkonium chloride on the macro and microviscosity of Carbopol 934NF (0.25-0.50 g/dl) pharmaceutical gels. Carbopol/surfactant interactions, which were reflected in changes in the intrinsic viscosity of the polymer and in shifts of IR spectra bands of films, considerably modified the rheological properties of the gel (flow and oscillatory rheometry) and the diffusion coefficients of polystyrene particles (dynamic light scattering, DLS). At pH 4, any surfactant at a concentration of 0.01 g/dl promoted interpolymer connections producing an open three-dimensional network with maximum viscous and elastic moduli, which does not disturb the diffusive movement of polystyrene particles. An increase in non-ionic surfactant (0.05-0.50 g/dl) gradually decreased viscosity and elasticity since there were more surfactant molecules to surround each carbopol particle, forming intrapolymeric micelles and breaking the interpolymer connections. This macroscopic effect is, however, not reflected in a decrease but in an increase in microviscosity (estimated by DLS) owing to the formation of larger carbopol/surfactant aggregates and free micelles that contribute significantly to the obstruction of the diffusional path. Both ionic surfactants decreased macroviscosity owing to ionic aggregation (benzalkonium chloride) or increase in ionic strength (mainly SDS), while the repercussion on the diffusion of polystyrene particles was dramatically different, and was hindered (due to the carbopol/surfactant aggregates) or enhanced (due to the shrinking of carbopol microgels), respectively. At pH 7.4, the ionization of the carboxylic groups produced an expansion of the polymer chains accompanied by a huge increase in viscosity and elasticity and a decrease in diffusion coefficients in comparison with those obtained at pH 4. The effects of the surfactants were similar to those observed at pH 4 but less intense. Chloramphenicol release studies (Franz-Chien cells) revealed that 0.01 g/dl surfactant did not affect the diffusion while a change in pH dramatically altered the process. The results show that by choosing the appropriate proportion of the most suitable surfactant, it is possible to modulate the flow behavior, elastic properties, and diffusional microenvironment of carbopol gels, without losing the pH-dependent gelling ability, which could improve the suitability of carbopol gels for drug delivery through different routes.

Influence of cationic cellulose structure on its interactions with sodium dodecylsulfate: implications on the properties of the aqueous dispersions and hydrogels.

The interactions of sodium dodecylsulfate (SDS) with the aqueous dispersions and the chemically cross-linked hydrogels of two cationic hydroxyethylcelluloses, polyquaternium-4 (PQ-4) and polyquaternium-10 (PQ-10), commonly used in cosmetics and in topical drug delivery devices, were analyzed. This surfactant was chosen not only for its interest as excipient, but also as a model of the amphiphilic behavior shown by many drugs. In aqueous dispersions, the interaction process was studied through transmittance, surface tension, fluorescence, microcalorimetry titration, viscosity and oscillatory rheometry measurements. The ammonium/sulfate groups ratios at the critical aggregation concentration (0.05% SDS) were 2.61 for PQ-4 and 4.02 for PQ-10; while at the saturation concentration (0.25% SDS), these ratios decreased to 0.52 and 0.80, respectively. The binding process, through ionic and hydrophobic interactions, was strongly exothermic in both water and aqueous NaCl 0.9% solution, which indicates that the salt did not modify the interaction. PQ-4/SDS dispersions had, for all SDS concentrations, higher viscous (G") and, especially, elastic (G') moduli than the polymer solution. The maxima in G' and G" (four orders of magnitude greater than PQ-4 only solutions) were observed at the SDS concentrations in which the ammonium/sulfate groups ratio is close to 1. PQ-10/SDS dispersions behaved very differently and, near the neutralization point, the precipitation of the system caused G" to decrease abruptly, and G' to disappear. The contrasting behavior of the two cationic celluloses may be attributed to their structural differences; PQ-4 has less ammonium groups, in small chains grafted to the cellulose backbone, and more free hydroxyethyl substituents than PQ-10. Therefore, although the neutralization of charges causes the formation of a neutral polyampholyte, the presence of the free hydrophilic hydroxyethyl groups in PQ-4 avoids the precipitation of the aggregates and contributes to the establishment of a three-dimensional network. In contrast, in PQ-10, the ammonium groups are directly bonded to the hydroxyethyl substituents and, in the aggregation process, they may be included in the polyampholyte complex, contributing to the precipitation. This different behavior was easily seen in the surfactant-induced shrinking of the hydrogels around the charges neutralization. Although the SDS binding isotherms were very similar, PQ-10 hydrogels decreased their volume up to 20 times at the neutralization point, while PQ-4 hydrogels reduced their initial volume only three times under the same conditions. These results suggest that the phase transitions of the hydrogels may be used as quick predictors of the behavior of the polymer dispersions.

Interactions between hydroxypropylcelluloses and vapour/liquid water.

Understanding of the uptake of water vapour or liquid water by cellulose-based polymers is important because of the influence of these processes on many of the biologically or technologically relevant properties of these polymers. In this work we studied these processes in the cases of twelve hydroxypropylcelluloses with low or medium-high degrees of substitution (L-HPCs and HPCs, respectively), characterization of which showed significant differences in structural and physical parameters (substitution pattern, crystallinity, particle size, specific surface area, and intraparticular porosity). Water vapour sorption-desorption isotherms determined to characterize the uptake of water vapour were fitted well by the Young-Nelson model, the optimized parameters of which indicated that at all relative humidities the capacity to bind water vapour as a surface monolayer is greater for HPCs than L-HPCs, but the capacity to absorb water vapour internally is greater for L-HPCs than HPCs. Guggenheim-Anderson-deBoer (GAB) models fitted the sorption-desorption isotherms less well. Differential scanning calorimetry (DSC) experiments showed all sorbed water vapour to be held as non-freezing water. Isoperibol microcalorimetry experiments carried out to investigate interactions with liquid water showed enthalpies of hydration/dissolution of between -62.86 and -71.35 J g(-1) for L-HPCs and between -82.95 and -99.80 J g(-1) for HPCs, and DSC showed average numbers of non-freezing water molecules per polymer repeat unit of 2.65-4.19 for L-HPCs and 18.10-22.42 for HPCs. DSC characterization of the kinetics of the water uptake by 10 mg compacts obtained by direct compression of hydroxypropylcelluloses showed faster uptake by L-HPC compacts than by HPC compacts, among which there were significant differences in capacity for diffusive uptake. The explanations of the above differences in terms of the different substituent contents, particle sizes and porosities of the HPCs is supported by multiple linear regression analyses.

Poly(acrylic acid) microgels (carbopol 934)/surfactant interactions in aqueous media. Part I: nonionic surfactants.

The interaction between Tween 80 and Pluronic F-127 with carbopol in water was studied as a function of surfactant concentration. 0.25% carbopol microgels dispersions showed a continuous decrease in transmittance, viscosity and conductivity when surfactant concentration ranged from 0.01-0.02% to 0.50% Tween 80 or from 0.03-0.06% to 0.30% Pluronic F-127. These limit values can be considered as the critical association concentration and the saturation binding concentration, respectively. In this concentration range, a strong rise in pH (from 3.18 to 3.50) suggested that surfactant-polymer binding occurred mainly through a stoichiometric hydrogen-bonding interaction between the oxyethylene and carboxylic groups. In the presence of carbopol, the concentration of Tween 80 at the air/water interface decreases as the surfactant is adsorbed onto the polymer and drawn into the bulk solution. In contrast, the interaction with the polymer seems to change the conformation of the expanded chains of Pluronic F-127, making it easier for more molecules of surfactant to be at the interface and increasing the thickness of the interfacial surfactant layer. Fluorescence probes indicated that the carbopol network presents a more apolar medium than pure water, and the differences in the hydrophile-lipophile balance (HLB) of each surfactant were responsible for the lower I(I)/I(III) values obtained with Tween 80/carbopol systems. Microcalorimetry titration data made it possible to conclude that Tween 80/carbopol interaction, at 298K, is an enthalpy-driven process due to stabilization of Tween 80 units inside the polymer network. In contrast, Pluronic F-127/carbopol association (endothermic process) occurs owing to a gain in entropy when polymer-surfactant interaction allows the restoration of free water hydrogen-bonding structure, resembling the micellization process.

Poly(acrylic acid) microgels (carbopol 934)/surfactant interactions in aqueous media. Part II: Ionic surfactants.

The interaction of sodium dodecylsulfate (SDS) or benzalkonium chloride (BkCl) with carbopol microgels (0.25% (w/w)) in water was studied through pH, trasmittance, viscosity, surface tension, conductivity, fluorescence, oil solubilization, and microcalorimetry measurements. In the case of the anionic surfactant, enthalpy-driven hydrophobic absorption of SDS into carbopol microgels began when SDS concentration reached 0.05-0.08% and ended around 0.6%. These concentrations were estimated as the critical aggregation (cac) and saturation binding concentration, respectively. The hydrophobic absorption of the surfactant accompanied by its counter-ion caused carbopol microgels to swell and promoted the occurrence of bridges among several carbopol microgels. As a consequence, the consistency of the dispersions increased significantly. Above binding saturation, further addition of SDS produced a shielding effect among the anionic charges of carbopol and its dehydration, which was shown as a decrease in the viscosity of the dispersions. At low shear rates, the dispersions behaved as pseudoplastic owing to orientation of carbopol/SDS aggregates in the flow direction. Increasing shear rates caused the inter-microgel bridges to break, the water layer surrounding them to diminish, and the system to show a shear-thickening behavior. In contrast, carbopol/BkCl aggregates showed shear-thickening flow in the whole range of shear rates analyzed. Electrostatic interactions between BkCl and carbopol carboxylic groups release protons to the medium and decrease the internal osmotic pressure of the microgels. This may favor the establishment of hydrophobic interactions among surfactant tails, and induces carbopol microgels to collapse. The cac was approximately 0.01% BkCl. Saturation binding occurred at 0.3-0.5%, indicating that only 25-40mol% carboxylic groups were neutralized with BkCl. The shrinking of carbopol microgels as BkCl is absorbed prevents additional surfactant molecules from interacting with the remaining carboxylic groups. Microcalorimetry assays revealed that the aggregation process occurred with a strong gain in enthalpy.

Glass transitions and viscoelastic properties of carbopol and noveon compacts.

Glass transitions of five varieties of Carbopol (acrylic acid polymers cross-linked with allyl sucrose or allyl pentaerythritol) and two varieties of Noveon (calcium salts of acrylic acid polymer cross-linked with divinylglycol) differing in cross-linking density and nature and content in residual solvents, were analysed (as compressed probes) by differential scanning calorimetry (DSC), modulated temperature differential scanning calorimetry (MTDSC), and oscillatory rheometry. All carbopol compacts showed a main glass transition, at a temperature between 130 and 140 degrees C, Tg, independently of their cross-linking degree and molecular weight. Additionally two batches of Carbopol 971P, which had greater contents in residual solvents, also presented a secondary transition at 65-70 degrees C. Sorption of water during storage of carbopol compacts at different relative humidity environments caused the Tg to strongly decrease. Compacts stored at 97.5% relative humidity have Tg below 0 degrees C and behave, at room temperature, as flexible hydrogels. The Gordon-Taylor/Kelley-Bueche equation only fit the dependence of Tg on water content well for carbopol compacts containing less than 15% water. The plasticizing effect of water was clearly evidenced in the considerable decrease in the storage and loss moduli of the compacts. Although the energy associated to the glass transitions of carbopol polymers, 0.40-0.50 Jg(-1) degrees C(-1), is high enough to be clearly detected by DSC, in some cases the evaporation of residual solvents may make it difficult to observe the Tg. This inconvenience is overcome using MTDSC or oscillatory rheometry. The decrease in Tg of carbopol caused by water sorption when compacts were stored at 97.5% R.H. explains why their loss (G") and storage (G') moduli at room temperature decreased four orders of magnitude. In contrast, in noveon varieties, calcium ions act as ionic cross-linkers of the carboxylic groups, providing rigid networks with much higher Tg, and storage and loss moduli. This explains that despite sorbing similar amounts of water to carbopol, the changes on the mechanical properties of noveon compacts were much less important (i.e., G' and G" decreased up to one order of magnitude).

Microviscosity of hydroxypropylcellulose gels as a basis for prediction of drug diffusion rates.

This study investigated the influence of the rheological properties of hydroxypropylcellulose (HPC) gels on the in vitro release of theophylline included in the gel at 0.2 g/l. Experiments were performed with six HPC varieties (mean molecular weight between 5x105 and 1.2x106, nominal viscosity between 100 and 4000 mPa.s) at concentrations of 0-2% (w/w). Theophylline diffusion coefficients at 37 degrees C ranged from 3.5x10-7 to 1.1x10-3 cm2/min, and were in all cases markedly higher than those predicted on the basis of gel macroviscosity as determined by capillary viscometry. In general, the theophylline diffusion coefficient declined exponentially with HPC concentration; in the case of the lowest-molecular-weight HPC, however, the diffusion coefficient remained constant to HPC concentrations of up to 0.8%, probably because of the high entanglement concentration of the HPC. Gel microviscosities as determined by dynamic light scattering (DLS) with latex microspheres (162 nm diameter) were considerably lower than the macroviscosities determined by capillary viscometry, and similar to microviscosities estimated on the basis of theophylline diffusion. Nevertheless, macroviscosity was correlated with microviscosity, suggesting that it is of value for approximate estimates of rates of diffusion of theophylline from HPC gels.

Degradation of hydroxypropylcellulose by Rhizomucor: effects on release from theophylline-hydroxypropylcellulose tablets.

The stability of several varieties of hydroxypropylcellulose was monitored during 3 years of storage (1) under the conditions recommended by manufacturers and official pharmacopoeias (simple storage in closed containers) and (2) at zero relative humidity. After 1 year, severe degradation of the varieties with lower initial pH and particle size stored at ambient relative humidity was shown by changes in their molecular weight and in the pH and apparent viscosity of 2% aqueous dispersions. Microbiological analyses showed the observed degradation to be attributable to the action of fungi of the genus Rhizomucor. The changes in apparent viscosity significantly affected the release of theophylline from direct compression tablets formulated with the degraded excipients.

Evaluation of low-substituted hydroxypropylcelluloses (L-HPCs) as filler-binders for direct compression.

The aims of this study were to assess the potential value of low-substituted hydroxypropylcelluloses (L-HPCs) as excipients of direct compression, and to investigate relationships between the chemical and physical properties of the polymers and (a) the powder rheological behavior and (b) drug release profiles from direct compressed tablets elaborated with (1:1) theophylline:L-HPC mixtures. Experiments were performed with five L-HPC varieties of different nominal particle sizes and degree of substitution. The products were characterized with regard to the moisture content, density, IR and Raman spectroscopy, hydroxypropyloxy content, heat of hydration, particle size, specific surface and porosity, and important differences were found in relation with all these properties. The differences in specific surface principally determine the flow and compaction properties of the powders, and the mechanical and microstructural properties of the tablets. The control of the hydroxypropyloxy content and the particle size of the L-HPCs allow the theophylline release profile to be regulated.