Effect of varying preparing-concentration on the equilibrium swelling of polyacrylamide gels

Bioinspired design of a polymer gel sensor for the realization of extracellular Ca(2+) imaging

Although the role of extracellular Ca²⁺ draws increasing attention as a messenger in intercellular communications, there is currently no tool available for imaging Ca²⁺ dynamics in extracellular regions. Here we report the first solid-state fluorescent Ca²⁺ sensor that fulfills the essential requirements for realizing extracellular Ca²⁺ imaging. Inspired by natural extracellular Ca²⁺-sensing receptors, we designed a particular type of chemically-crosslinked polyacrylic acid gel, which can undergo single-chain aggregation in the presence of Ca²⁺. By attaching aggregation-induced emission luminogen to the polyacrylic acid as a pendant, the conformational state of the main chain at a given Ca²⁺ concentration is successfully translated into fluorescence property. The Ca²⁺ sensor has a millimolar-order apparent dissociation constant compatible with extracellular Ca²⁺ concentrations, and exhibits sufficient dynamic range and excellent selectivity in the presence of physiological concentrations of biologically relevant ions, thus enabling monitoring of submillimolar fluctuations of Ca²⁺ in flowing analytes containing millimolar Ca²⁺ concentrations.

Hydrogel Synthesis Directed Toward Tissue Engineering: Impact of Reaction Condition on Structural Parameters and Macroscopic Properties of Xerogels

The existence of correlation and functional relationships between reaction conditions (concentrations of crosslinker, monomer and initiator, and neutralization degree of monomer), primary structural parameters (crosslinking density of network, average molar mass between crosslinks, and distance between macromolecular chains), and macroscopic properties (equilibrium swelling degree and xerogel density) of the synthesized xerogels which are important for application in tissue engineering is investigated. The structurally different xerogels samples of poly(acrylic acid), poly(methacrylic acid), and poly(acrylic acid-g-gelatin) were synthesized by applying different methods of polymerization: crosslinking polymerization, crosslinking polymerization in high concentrated aqueous solution, and crosslinking graft polymerization. The values of primary structural parameters and macroscopic properties were determined for the synthesized xerogels samples. For all of the investigated methods of polymerization, an existence of empirical power function of the dependence of primary structural parameters and macroscopic properties on the reaction conditions was established. The scaling laws between primary structural parameters and macroscopic properties on average molar mass between crosslinks were established. It is shown that scaling exponent is independent from the type of monomer and other reaction conditions within the same polymerization method. The physicochemical model that could be used for xerogel synthesis with predetermined macroscopic properties was suggested.

Kinetic aspects, rheological properties and mechanoelectrical effects of hydrogels composed of polyacrylamide and polystyrene nanoparticles

Snake-cage gels were prepared using monodisperse polystyrene (PS) nano-sized particles ( = 200 nm) in place of the more commonly used linear polymer. The kinetics of the formation of the complementary polyacrylamide (PAM) hydrogel was studied alone or in the presence of the PS nanoparticles by H-NMR. Without PS, the reactivity ratios of the acrylamide (Am) and the cross-linking agent ,'-methylene-bisacrylamide (BisAm) were computed using the initial kinetics of PAM gel at high cross-linker concentration ( = 0.52 and = 5.2 for Am and BisAm, respectively). In the presence of PS, during the formation of nanoparticle composite (NPC) gels, there was a decrease in the conversion rate with an increasing fraction of PS nanoparticles. This could be explained by steric effects, which induce an increase of the elastic modulus of the matrix with the increasing fraction of PS nanoparticles. There was a considerable increase in the rheological properties of the NPC gels ( tensile modulus), which was more pronounced at higher fractions of nanoparticles. We used particular mechanical properties to develop a stimulus-responsive ("smart") material, a mechanoelectrical effect, which may be used in the development of soft and wet tactile-sensing devices.

Visualizing conformations of subchains by creating optical wavelength-sized periodically ordered structure in hydrogel

Thick single-crystalline fcc colloidal crystals exhibiting structural color are obtained by a solvent evaporation method from silica colloidal particle suspensions. A periodically ordered interconnecting porous structure can be imprinted in thermosensitive N-isopropylacrylamide (NIPA) gels by using the colloidal crystals as templates. The porous structure endows a structural color to the NIPA gels. We find that the peak position of the reflection spectra from the porous gels (lamdamax') is expressed as a function of the swelling degree and is synchronized with the change in the swelling degree. The color can be precisely tuned by simply changing the amount of the monomer and the cross-linker in the pre-gel solutions. We can estimate the linear expansion factor (> or =1) of the subchains by comparing the peak position at a given situation (lamdamax') and the reference state (lamdamax,0'), in which the subchains behave as Gaussian coils. Creating the periodically ordered structure, which is similar in size to the wavelength of optical light, in the gels allows us to determine the behavior of polymer chains by observing the structural color.

Swelling-induced modulation of static and dynamic fluctuations in polyacrylamide gels observed by scanning microscopic light scattering

The nature of inhomogeneities in vinylpolymer gels has hardly been clarified yet. Inhomogeneities on submicron and nanometer scales in polyacrylamide gels have been investigated by using a scanning microscopic light-scattering system and applying a general formula for an ensemble-averaged correlation function. The network structure of the gels is modified by varying the preparation conditions and can be roughly divided into two types. Swelling-induced modulation of inhomogeneities depends on the type of the network structure. At low monomer concentrations in preparation, both submicron- and nanometer-scale inhomogeneities increase with swelling. At high monomer concentrations in preparation, submicron-scale inhomogeneities increase with swelling, but nanometer-scale inhomogeneities decrease anomalously. This behavior is explained by a model of inhomogeneous network structure of vinylpolymer gels, where macrogel is formed from a large number of microgel particles.

Polyacrylamide gel as an acoustic coupling medium for focused ultrasound therapy

A hydrogel acoustic coupling medium was investigated as a practical alternative to water for clinical applications of focused ultrasound (US) therapy. Material characterization and functional testing of polyacrylamide gel couplers were performed. Acoustic, bulk and thermal properties were measured. Conical couplers were designed and fabricated to fit a 3.5-MHz, spherically concave transducer for functional tests, including Schlieren imaging, power efficiency measurements and in vivo hemostasis experiments. Polyacrylamide was shown to have favorable acoustic properties that varied linearly with acrylamide concentration from 10% to 20% weight in volume. Attenuation coefficient, sound speed and impedance ranged from 0.08 to 0.14 dB/cm at 1 MHz, 1546 to 1595 m/s and 1.58 to 1.68 Mrayl, respectively. An intraoperative in vivo hemostasis experiment in a sheep model demonstrated that the gel-coupled transducer was capable of inducing hemostasis in actively bleeding splenic and hepatic incisions. The results of this study show that polyacrylamide may be a promising coupling material for focused US therapy.