Synthetic polymer-tissue adhesion using an ultrasonic scalpel.

Background: Interface phenomena such as encapsulation and formation of dead space around implanted biomaterials lower biomaterial performance. To advance tissue adhesive technology, understanding the interactions between tissue (collagen) and polymer is indispensable. Adhesion between tissue and polymer was studied using an ultrasonically activated scalpel (UAS).

Control of cell function on a phospholipid polymer having phenylboronic acid moiety.

We synthesized a water-insoluble phospholipid polymer bearing a phenylboronic acid moiety (PMBV), which induces cell adhesion through a specific interaction with the glycoprotein, fibronectin. Surface plasmon resonance analysis revealed that fibronectin was adsorbed on the PMBV surface. When fibroblasts were cultured on the PMBV surface, the cells adhered and proliferated normally while showing a spherical morphology.

Characteristics of compacted plasmid DNA by high pressurization.

In order to investigate the effect of pressure on the tertiary structure of plasmid DNA having the supercoiled and relaxed forms, the solution of plasmid DNA was hydrostatically pressurized at different atmosphere and 40 degrees C for various times. For dynamic light scattering (DLS) measurement of the pressurized plasmid DNA, the hydrodynamic diameters of the super-coiled and relaxed plasmid DNA were decreased with increasing pressure. Also, at constant pressure, a long period of pressure treatment effectively induced the decrease in plasmid DNA.

Selective biorecognition and preservation of cell function on carbohydrate-immobilized phosphorylcholine polymers.

To obtain synthetic materials capable of selectively recognizing proteins and cells, and preserving their functions, biomembrane mimetic polymers having a phospholipid polar group and carbohydrate side chains were designed. Poly[2-methacryloyloxyethyl phosphorylcholine (MPC)-co-n-butyl methacrylate (BMA)-co-2-lactobionamidoethyl methacrylate (LAMA)] (PMBL) was synthesized and coated on substrates by solvent evaporation. Selective binding of galactose-recognized lectin, RCA120, to a PMBL surface was investigated by measurement of surface plasmon resonance.

A stereocomplex platform efficiently detecting antigen-antibody interactions.

Ultrathin poly(methyl methacrylate) (PMMA) stereocomplex films with macromolecularly double-stranded regular nanostructures were prepared by layer-by-layer assembly of isotactic and syndiotactic PMMAs on solid surfaces. Antibodies were immobilized through the Fc region-capturing protein A, which had been physically adsorbed on the complex film, and the binding of antigens to immobilized antibodies was quantitatively investigated by the quartz crystal microbalance technique. Greater amounts of protein A with native forms were adsorbed on the complex film than those on conventional single-component PMMA films.

The movement of a water droplet on a gradient surface prepared by photodegradation.

A hydrophobic to hydrophilic gradient surface was prepared using the tuned photodegradation of an alkylsilane self-assembled monolayer (SAM) using irradiation of vacuum ultraviolet light (wavelength=172 nm). The water contact angle on the photodegraded SAM surface was adjusted using the intensity and time photoirradiation parameters. The formation of a gradient was confirmed by fluorescent labeling.

Change of the persistence lengths in the conformational transitions of pullulan- and amylose-tricarbanilates.

With raising temperature in the domain of 20 to 60 degrees C, the intrinsic viscosity [eta] for pullulan-tricarbanilate PTC and amylose-tricarbanilate ATC in solutions was found to decrease, indicating that they exhibited thermal-induced conformational transition from expanded form to compact form. The persistence length P(l) of the chains, evaluated with small-angle X-ray scattering, has also decreased as the temperature is raised and, moreover, it significantly depended on the solvents employed, where as P(l) of pullulan, having no carbanilate groups, has exhibited neither temperature- nor solvent-dependence. The temperature dependence of [eta] for PTC and ATC was well elucidated in terms of the temperature-dependent P(l) with the wormlike chain model.

Formation of embryoid bodies by mouse embryonic stem cells on plastic surfaces.

Mouse embryonic stem (ES) cells were cultured on artificial polymeric biomembranes with a phospholipid polymer (phosphatidylcholine, PC) surface. ES cells aggregated to form an embryoid body (EB) on the PC surface immediately after seeding. Single EBs formed on the PC surface after 3 d, and their size was depended on the initial number of cells that were seeded.

Selective cell attachment to a biomimetic polymer surface through the recognition of cell-surface tags.

Reactive phosphorylcholine polymers, which can recognize biosynthetic cell-surface tags, were synthesized to control cell attachment. Human promyelocytic leukemia cells (HL-60) with unnatural carbohydrates as cell-surface tags were harvested by treatment with N-levulinoylmannosamine (ManLev). The attachment of ManLev-treated HL-60 cells to 2-methacryloyloxyethyl phosphorylcholine (MPC) polymers with hydrazide groups was studied.

Changes in the morphology of cell-size liposomes in the presence of cholesterol: formation of neuron-like tubes and liposome networks.

Spontaneous changes in the morphology of cell-size liposomes (dioleoylphosphatidylcholine, DOPC and egg PC) as model cells were investigated in the presence of cholesterol. Tube structures and liposome networks connected by the tubes were observed in the presence of 5-30% cholesterol by dark-field and laser-scanning microscopy. Furthermore, in the presence of more than 40 mol% of cholesterol, the tubes disappeared and changed to small liposomes.

Conformation of poly(sodium ethacrylate) in solution studied by small-angle X-ray scattering.

The pH-induced conformational transition of poly(sodium ethacrylate) PNaEA in aqueous solution, which occurs between a compact form at low charge-density and an extended coil at high charge-density, was studied by small-angle X-ray scattering and the structure at an each conformational state was analyzed and compared with the corresponding one of poly(sodium methacrylate) PNaMA. The conformational transition for PNaEA induced a remarkable change in the scattering data plotted in the form of the Kratky plot. By comparing the scattering data with theoretical scattering functions, it was clarified that the structures of the compact form and the extended coil are well mimicked by a swollen gel having a network structure and by a wormlike chain, respectively.

Importance of a biofouling-resistant phospholipid polymer to create a heparinized blood-compatible surface.

Heparinization is believed to be one of the methods to suppress thrombus formation on blood-contacting surfaces. However, this study hypothesizes that heparinization alone might not be sufficient to provide a blood-compatible surface; that is, a surface property that resists biofouling is necessary to obtain an effective heparin-modified surface. 2-Methacryloyloxyethyl phosphorylcholine (MPC) polymers with 2-aminoethyl methacrylate (AEMA) were synthesized to immobilize heparin through ionic bonding.

A nonthrombogenic gas-permeable membrane composed of a phospholipid polymer skin film adhered to a polyethylene porous membrane.

Polymer membranes are widely used in biomedical applications such as hemodialysis, membrane oxygenator, etc. When the membranes come in contact with blood or body fluids, protein adsorption and cell adhesion occur rapidly. Nonspecific protein adsorption and cell adhesion on the membranes induce not only various bio-rejections but also a decrease in their performance.