Hydrosoluble cyclodextrin/poloxamer polypseudorotaxanes at the air/water interface, in bulk solution, and in the gel state.

The interactions between poloxamer 407 (Pluronic F127, PF127) and two hydrophilic derivatives of beta-cyclodextrin, i.e., hydroxypropyl-beta-cyclodextrin (HPbetaCD; molar substitution (MS) 0.65) and methylated-beta-cyclodextrin (MbetaCD; MS 0.57), were characterized by means of surface tension measurements, pi-A isotherms, isoperibol microcalorimetry, 1H NMR, and rheometry. An effective complexation of poloxamer with the two CDs was evidenced as a change in the surface pressure of the pi-A isotherm of PF127 on a subphase of CD solution, with a positive excess being observed at the expanded region and a negative excess at the collapsed region. Such changes indicated that when the CD lies with the main axis perpendicular to the interface at low pressure no complexation occurs, but as the pressure increases and the CDs eventually change their arrangement to be with the main axis parallel to the interface, the amphiphilic copolymer can form polypseudorotaxanes. Addition of CDs to PF127 micellar solutions led to the exothermic rupture of micelles, a shift in the cmc toward higher values, changes in the chemical shifts of H3, H4, and H5 of MbetaCD and of the methyl groups of PF127, and an increase in the gel temperature. The interaction was stronger between poloxamer and MbetaCD, compared to HPbetaCD, with the stoichiometry of the polypseudorotaxanes being preferably ca. 1:20 in both cases. SEM images revealed formation of nanorods of stacked polypseudorotaxanes. Complexation with a high affinity constant between unimers and CDs in bulk solution was also evidenced by competitive displacement of methyl orange. Feasible structural models of the PF127:CD polypseudorotaxanes at both the air-water interface and in the bulk solution are proposed.

Tetronic micellization, gelation and drug solubilization: Influence of pH and ionic strength.

The aim of this work was to gain an insight into the self-associative processes and drug solubilization ability of a Tetronic variety, T904 (4 x 15 EO units; 4 x 17 PO units; HLB 15), in aqueous media covering the physiological range of pH and ionic strength, applying isoperibol microcalorimetry, transmission electronic microscopy (TEM), dynamic light scattering (DLS), oscillatory rheometry, and drug diffusion experiments. T904 shows two pK(a) (pK(a1)=4.0 and pK(a2)=7.9) and, at pH<5.8, the diprotonated form predominates over the non-protonated one. Deprotonization of the central diamine group is a required condition for micellization, which is an endothermic entropy-driven process owing to hydrophobic interactions between the PPO chains. As the pH of the solutions decreases, the coulombic repulsions among the positively charged amine groups make the aggregation more difficult, raising the critical micellar concentration (CMC) and decreasing the size of the micelles. The changes in the conformation and hydrophilicity of the Tetronic were reflected in its gelation temperature (around 30 degrees C at neutral-alkaline pH; no gelation at pH<2) and solubilization capacity for griseofulvin (2-fold greater at neutral-alkaline pH than at pH<2) and rate of diffusion (slower at pH 7.4). Such alterations in self-assembly are relevant when using Tetronic in the design of drug delivery systems.

A multitechnique approach on adsorption, self-assembly and quercetin solubilization by Tetronics® micelles in aqueous solutions modulated by glycine.

Ethylene oxide-propylene oxide (EO-PO) block copolymer micelles are useful potential nanoreservoirs for the delivery of hydrophobic drugs. Considering that glycine is an excipient and can favorably affect the surface/micellar behavior and thus improve solubilization power/dispersion stability/wetting characteristics we have reported here studies on aqueous solution behavior of two commercially available branched block copolymers (Tetronics®) with differing hydrophobicities namely Tetronics® 1307 and 1304, hereafter referred as T1307 and T1304, in the presence of glycine. Steady state fluorescence studies using pyrene as a probe, equilibrium and dynamic surface tension measurements, wetting and dispersion stability studies of Teflon (polytetrafluoroethylene; PTFE) and solubilization studies of a hydrophobic antioxidant/anticancer drug quercetin (QN) have been examined. The cloud point (CP) and critical micelle temperature (CMT) decrease while micelle hydrodynamic size (Dh) increases with the addition of glycine as well as on loading of the drug in the micelles. Water penetration through packed PTFE powder and dynamic surface tension confirm the enhanced micellization process for aqueous Tetronic® solutions in presence of glycine and accordingly restricted diffusion for the surfactant molecules towards air-water and PTFE-water interface. The contact angles for Tetronic® solutions in presence of glycine indicate moderate decrease. The pressure-area curves of the copolymers in water and glycine solutions were also constructed. Surface and micellar properties of copolymers are markedly altered in the presence of glycine and can be tuned for use of these nanocarriers in delivery systems.

Interaction of poloxamine block copolymers with lipid membranes: Role of copolymer structure and membrane cholesterol content.

Interactions of X-shaped poly(ethylene oxide)-poly(propylene oxide) (PEO-PPO) block copolymers with cell membranes were investigated recording the π-A isotherms of monolayer systems of dipalmitoylphosphatidylcholine (DPPC):cholesterol 100:0; 80:20 and 60:40 mol ratio and evaluating the capability of the copolymers to trigger haemolysis or to protect from haemolytic agents. Four varieties of poloxamine (Tetronic 904, 908, 1107 and 1307) were chosen in order to cover a wide range of EO and PO units contents and molecular weights, and compared to a variety of poloxamer (Pluronic P85). The π-A isotherms revealed that the greater the content in cholesterol, the stronger the interaction of the block copolymers with the lipids monolayer. The interactions were particularly relevant at low pressures and low lipid proportions, mimicking the conditions of damaged membranes. Relatively hydrophobic copolymers bearing short PEO blocks (e.g., T904 and P85) intercalated among the lipids expanding the surface area (ΔGexc) but not effectively sealing the pores. These varieties showed haemolytic behavior. Oppositely, highly hydrophilic copolymers bearing long PEO blocks (e.g., T908, T1107 and T1307) caused membrane contraction and outer leaflet sealing due to strong interactions of PEO with cholesterol and diamine core with phospholipids. These later varieties were not haemolytic and exerted a certain protective effect against spontaneous haemolysis for both intact erythrocytes and cholesterol-depleted erythrocytes.

NaCl-triggered self-assembly of hydrophilic poloxamine block copolymers.

Tetronic 1307 (T1307) is a hydrophilic poloxamine (HLB>24) with a high molecular mass owing to its long PEO and PPO blocks. In spite of good biocompatibility, its use as a component of drug delivery systems is limited by its high critical micelle concentration (CMC) and temperature (CMT). The aim of this work was to elucidate whether the addition of NaCl or the combination of salts and temperature may bring T1307 micellization and gelling features into more practically useful values. Increasing NaCl concentration in the 0.154 M (isotonic) to 2M (hypertonic) range made the copolymer more hydrophobic and more prone to self-assemble into unimodal micelles, as observed by means of π-A isotherms, (1)H NMR, dynamic light scattering (DLS), small-angle neutron scattering (SANS), and pyrene fluorescence. The decrease in CMC and CMT observed for T1307 in 0.5 M NaCl medium (tolerable hypertonic solution), compared to water, notably favored the solubility of hydrophobic drugs such as curcumin and quercetin. Moreover, phase diagram, intrinsic viscosity and sol-to-gel transition were markedly affected by NaCl concentration. Overall, the strong dependence of T1307 self-assembly features on NaCl opens interesting possibilities for tuning the performance of T1307 as a component of nanocarriers and in situ gelling systems.

Poloxamine micellar solubilization of α-tocopherol for topical ocular treatment.

Ophthalmic delivery of α-tocopherol (TOC), which is the most active and cost/effective form of vitamin E, is receiving increasing attention as a way of preventing and treating glaucoma, cataracts, and dry eye syndrome, among other ocular pathologies. The aim of this work was to elucidate the possibility of using poly(propylene oxide) (PPO) and poly(ethylene oxide) (PEO) block copolymers of poloxamine family (namely, Tetronic 1107) to develop polymeric micelles that can host TOC, enhance the apparent solubility and sustain the release of this vitamin in lachrymal fluid. The interactions of Tetronic 1107 with TOC were analyzed at the air-water interface recording the π-A isotherms at various temperatures, indicating favorable interactions as temperature increased from 10 to 29 °C. In 0.9% NaCl aqueous medium, a sharp increase in TOC solubility was observed when T1107 surpasses the critical micellar concentration (CMC); the apparent solubility in 20% T1107 being more than 600-fold and 6000-fold that observed in the absence of copolymer at 4 and 25 °C, respectively. Micelles were characterized before and after loading by means of dynamic light scattering (DLS) and transmission electronic microscopy (TEM). TOC sustained release profiles were recorded in Franz-Chien diffusion cells. After storage for 3 months at 4 °C, TOC-loaded T1107 10% micellar system retained 84% TOC solubilized, which maintained the antioxidant activity. Furthermore, the rheological properties of the micellar systems were not altered either; the viscoelastic parameters being dependent on T1107 concentration, which opens the possibility of developing from free-flowing eye-drops to in situ gelling systems.

Self-associative behavior and drug-solubilizing ability of poloxamine (tetronic) block copolymers.

The incidence of the structural features on the self-assembly of different poloxamines (the conventional sequential Tetronic 304, 901, 904, 908, 1107, 1301, and 1307; a reverse-sequential counterpart Tetronic 150R1; and a chemically modified derivative, N-methylated Tetronic 1107) was thoroughly studied in 10 mM HCl by means of pi-A isotherm, surface tension, and pyrene fluorescence measurements. The size and size distribution of the aggregates were investigated by dynamic and static light scattering, and the morphology was probed by transmission electron microscopy. The abilities of the different derivatives to solubilize the drug simvastatin were also evaluated. Poloxamines with both higher PO/EO ratio and molecular weight (T1301 and T150R1) led to micelles with larger and more hydrophobic cores, particularly adequate for hosting hydrophobic molecules and protecting the labile lactone form of simvastatin from hydrolysis. On the other hand, the hydroxy acid form of simvastatin interacted with the central ethylenediamine group under alkaline pH (T304) or when a permanent positive charge due to methylation was present. Micelles of long poloxamine molecules containing large PPO blocks (with 23-29 units, namely, T1301, T1307, and T150R1), particularly the one that also has long PEO blocks, were the most physically stable toward dilution.

Temperature- and light-responsive blends of pluronic F127 and poly(N,N-dimethylacrylamide-co-methacryloyloxyazobenzene).

Photoresponsive poly(N,N-dimethylacrylamide-co-methacryloyloxyazobenzene) (DMA-MOAB) and temperature-responsive Pluronic F127 (F127) copolymers were blended to obtain systems responsive to both stimuli that are potentially useful for pharmaceutical formulations. The random DMA-MOAB copolymer undergoes a trans to cis isomerization when irradiated by 366 nm light, which modifies both the air-water interfacial behavior and the self-associative properties of the copolymer. Under dark conditions the azobenzene groups of DMA-MOAB in the trans conformation self-associate and the interactions with F127 are minimal. The cis conformation of the azobenzene groups of the DMA-MOAB copolymer is relatively more hydrophilic than the trans conformation, which causes the copolymer micelles to dissociate upon irradiation, allowing the unimers to form mixed micelles with the F127. This causes the sol-gel transition temperature of the DMA-MOAB:F127 blend to be 10 degrees C lower upon irradiation at 366 nm compared to that for the dark conditions. It has been found that F127 (10-12 wt %):DMA-MOAB (5-6 wt %) aqueous solutions have at body temperature a low viscosity when equilibrated in the dark and undergo a sol-gel transition when irradiated. Such a transition strongly alters the diffusion of solutes such as methylene blue within the solutions. This light-induced interaction between the azobenzene moieties of DMA-MOAB and F127 micelles disappears when hydroxypropyl-beta-cyclodextrin (HPbetaCD) is added to the medium. In the presence of HPbetaCD, the cis-azobenzene groups are hosted in the cyclodextrin cavities and the mixed micelles are not formed. Therefore, changes in HPbetaCD concentration could be used to modulate the response of the copolymer blends to light.