Junji Watanabe

Awareness of Central Luminance Edge is Crucial for the Craik-O'Brien-Cornsweet Effect.

The Craik-O’Brien-Cornsweet (COC) effect demonstrates that perceived lightness depends not only on the retinal input at corresponding visual areas but also on distal retinal inputs. In the COC effect, the central edge of an opposing pair of luminance gradients (COC edge) makes adjoining regions with identical luminance appear to be different. To investigate the underlying mechanisms of the effect, we examined whether the subjective awareness of the COC edge is necessary for the generation of the effect. We manipulated the visibility of the COC edge using visual backward masking and continuous flash suppression while monitoring subjective reports regarding online percepts and aftereffects of adaptation. Psychophysical results showed that the online percept of the COC effect nearly vanishes in conditions where the COC edge is rendered invisible. On the other hand, the results of adaptation experiments showed that the COC edge is still processed at the early stage even under the perceptual suppression. These results suggest that processing of the COC edge at the early stage is not sufficient for generating the COC effect, and that subjective awareness of the COC edge is necessary.

Antifouling blood purification membrane composed of cellulose acetate and phospholipid polymer.

The ideal surface of an artificial blood purification membrane needs hemocompatibility and durability of high performance; it should not adsorb any proteins or cells but should still have high permeability in the desired range of solute size. To improve the anti-fouling property of cellulose acetate (CA) membranes, a CA membrane blended with poly(2-methacryloyloxyethyl phosphorylcholine (MPC)-co-n-butyl methacrylate (BMA)) (PMB30) was designed as a blood purification membrane. The polymer solutions for preparing the membrane were prepared using a solvent mixture composed of N, N-dimethylformamide, acetone, 2-propanol or water. The CA and CA/PMB30 blend membranes with an asymmetric and porous structure were prepared by a phase inversion process. The characteristics of the CA/PMB30 blend membrane, such as structural properties, mechanical properties, and solute permeability were examined with attention to changes in the preparation conditions of the membrane. The CA/PMB30 blend membrane had good water and solute permeability and a sharp molecular weight cut-off property. Moreover, the amount of proteins adsorbed on the CA/PMB30 blend membrane surface was less than that of the original CA membrane and a conventional polysulfone membrane. Adhesion and activation of platelets on the CA/PMB30 blend membrane were reduced compared with that on a CA membrane. In addition, the CA/PMB30 blend membrane showed good permselectivity and an antifouling property during a long time ultrafiltration experiment with protein solutions.

Novel cellulose acetate membrane blended with phospholipid polymer for hemocompatible filtration system

To improve the blood compatibility of cellulose acetate (CA) membranes for hemofiltration, a novel CA membrane blended with 2-methacryloyloxyethyl phosphorylcholine (MPC) copolymer was designed for a hemocompatible filtration system. The MPC copolymer (PMB30) was synthesized from MPC and n-butyl methacrylate. The polymer solution for making the membrane was prepared from a solvent mixture composed of N,N-dimethylformamide, acetone, and 2-propanol. The CA and CA/PMB30 blended membranes with an asymmetric and porous structure were prepared by a phase inversion process. The mechanical properties and solute permeability of the CA/PMB30 blended membrane could be controlled by preparation conditions such as the composition of the solvents and the solvent evaporation time. The CA/PMB30 blended membrane showed both good water and solute permeabilities in comparison with the CA membrane. Also, the molecular weight of the solute passed through the membrane was changed by the addition of PMB30, and good permselectivity could be obtained. Moreover, the CA/PMB30 blended membranes had excellent blood compatibility such as protein adsorption resistivity compared to the CA membrane due to location of the MPC units in the PMB30 at the surface.

Effect of water-soluble phospholipid polymers conjugated with papain on the enzymatic stability.

To maintain enzymatic activity during long-term storage by conjugation with water-soluble 2-methacryloyloxyethyl phosphorylcholine (MPC) polymers (PMPC-COOH) having various molecular weights with a carboxylic group on the terminal, such compounds were synthesized as a polymer modifier using a photoinduced living radical polymerization technique. A poly(ethylene oxide) with a carboxyl group (PEO-COOH) was used as the control. The PMPC-COOHs were reacted with the amino groups of the enzyme, papain, via amide bonds. With an increase in the molecular weight in the range between 5 and 20K of the PMPC-COOH, the modification degree and alpha-helix content of the conjugated papain slightly decreased, but the remaining enzymatic activity did not depend on the molecular weight of the PMPC-COOH. However, when a much higher molecular weight PMPC-COOH (40K) was conjugated with a reduction in the modification degree, alpha-helix content was higher compared with the other PMPC-conjugated papain. Modification with PEO-COOH showed little reduction of the alpha-helix content of papain. The time dependence of the remaining enzymatic activity of the polymer-conjugated papains was evaluated during storage at 40 degrees C. The native papain diminished activity within one week. PEO-conjugated papain had decreased activity with time, but after one week it had half its initial level. The same tendency was observed when papain was modified with PMPC-COOHs 5 and 40K, that is, the enzymatic activity did not decrease even when they were stored for 4 weeks. We concluded that the PMPC chain could stabilize the enzyme by control of the molecular weight of the PMPC and modification degree to the enzyme.

Biocompatible polymer alloy membrane for implantable artificial pancreas

Abstract The preparation of a novel polymer alloy membrane with both biocompatibility and permeability for fabrication of an implantable artificial pancreas was carried out. The polymer alloy was composed of a segmented polyurethane (SPU) and phospholipid polymer with 2-methacryloyloxyethyl phosphorylcholine (MPC) units. The MPC polymer was poly(MPC-co-2-ethylhexyl methacrylate) (PMEH), which can be dissolved in the same solvent for SPU. The SPU/PMEH alloy membrane was prepared by a solvent evaporation method. The X-ray photoelectron spectra indicated that the MPC units were located on the subsurface of the membrane. The functions of the SPU/PMEH alloy membrane were characterized in terms of permeability of glucose and insulin, biocompatibility, and mechanical properties. The SPU/PMEH alloy membrane had excellent mechanical properties, which were confirmed by tensile-strain measurements. The glucose and insulin could permeate through the SPU/PMEH alloy membrane. The reduction of the number of fibroblasts that adhered to the surface of the SPU/PMEH alloy membrane was observed. That is, it has a good biocompatible surface compared with the original SPU. It was suggested that excellent functions, such as good insulin permeability, and reduction of fibroblast adhesion were promoted by the PMEH which dispersed both on the surface and inside the membrane. It was concluded that the SPU/PMEH alloy membrane has useful functions for the fabrication of an implantable chemically-controlled artificial pancreas.

Degradation of phospholipid polymer hydrogel by hydrogen peroxide aiming at insulin release device

The purpose of this study is to ascertain the applicable possibility of H(2)O(2) degradable hydrogel for fabrication of insulin release system synchronized with the change in the glucose concentration in the medium. The hydrogel was prepared by using 2-methacryloyloxyethyl phosphorylcholine (MPC) and crosslinker. The favorable characteristic of the hydrogel was H(2)O(2) concentration responsive degradation. The H(2)O(2) was utilized and produced by enzymatic reaction between glucose oxidase and glucose. Poly(MPC) (PMPC) was easily degraded in H(2)O(2) aqueous solution, and the PMPC hydrogel was also degraded in H(2)O(2) aqueous solution. The degradation mechanism was considered to be main chain scission of PMPC. The degradation profile was evaluated by using weight swelling ratio and volume swelling ratio. The weight swelling ratio of PMPC hydrogel firstly increased due to the reduction of crosslink density, then the ratio decreased to zero (complete degradation). The degradation profile was proportional to the H(2)O(2) concentration. Furthermore, volume swelling ratio also increased, and complex elastic modulus decreased with degradation in H(2)O(2) aqueous solution. These results indicated that the hydrogel was degraded by hydroxy and/or hydroperoxy radicals which was produced by H(2)O(2), the crosslink density and mechanical property decreased. The release profile from the hydrogel was estimated by using lipid microsphere (LM) as an insulin model. The LM was released with the degradation of PMPC hydrogel. Taking these results into account, the PMPC hydrogel was available for H(2)O(2) degradable hydrogel for synchronization with glucose concentration by using enzymatic reaction.

Polyethylene/phospholipid polymer alloy as an alternative to poly(vinylchloride)-based materials.

To develop new biomaterials for making medical devices, polymer alloys composed of a phospholipid polymer, poly(2-methacryloyloxyethyl phosphorylcholine) (PMPC), and polyethylene (PE) were prepared. The PE/PMPC alloy membrane could be obtained by a combination of solution mixing and solvent evaporation methods using xylene and n-butanol mixture as a solvent. Moreover, thermal treatment was applied to improve the mechanical properties of the PE/PMPC alloy membrane. In the PE/PMPC alloy membrane, the PMPC domains were located not only inside the membrane but also at the surface. Surface analysis of the PE/PMPC alloy membrane with X-ray photoelectron spectroscopy, wettability evaluation, and dynamic contact angle measurements revealed that the phospholipid polar groups in the PMPC covered the surface even after thermal treatment. Blood compatibility tests with attention to platelet adhesion and change in morphology of adhered platelets showed that the PE/PMPC alloy membrane had excellent platelet adhesion resistance. We finally concluded that the PE/PMPC alloy could be used as biomaterials instead of poly(vinyl chloride)-based materials.

Perisaccadic perception of continuous flickers

To realize perceptual space constancy, the visual system compensates for the retinal displacement caused by eye movements. It has been reported that the compensation process does not function perfectly around the time of a saccade--a perisaccadic flash is systematically mislocalized. However, observations made with transient flash stimuli do not necessarily indicate a general perisaccadic failure of space constancy. To investigate how the visual system realizes perisaccadic space constancy for continuous stimuli, we examined the time course of localization for a perisaccadic 500 Hz flicker with systematic variation of the onset timing, the offset timing and the duration. If each flash in the flicker is localized individually in the same way as a single flash, the apparent position and length of the flicker should be predicted from the time course of mislocalization of a perisaccadic flash. However, the results did not support this prediction in many respects. A dot array (of half the length of the retinal image) was perceived when the flicker was presented during a saccade, while only a single dot was perceived when the flicker was presented only before or after the saccade. A flash in a flicker was localized at a different position, depending on the onset timing, the offset timing and the duration of the flicker, even if the flash was presented at the same timing to the saccade. In general, our results support a two-stage localization in which the local geometrical configuration is first generated primarily based on the retinal information, and then localized as a whole in the egocentric or exocentric space. The localization is based on the eye position signal sampled at a time temporally distant from the saccade, which enables precise localization and space constancy for continuous stimuli.

Cellulose acetate hollow fiber membranes blended with phospholipid polymer and their performance for hemopurification

Commercially available hollow fiber membranes (HFMs) made from synthetic polymers, including cellulose acetate (CA) HFMs, used as hemopurification membranes, need to improve in hemocompatibility, by suppressing protein adsorption and clot formation. In this study, CA HFMs blended with 2-methacryloyloxyethyl phosphorylcholine (MPC) copolymer (PMB30 composed of MPC and n-butyl methacrylate (BMA)) were prepared by a dry-jet wet spinning process. Their performances were evaluated by characterizing their properties such as structure, permeability and protein adsorption. CA/PMB30-blend HFMs showed structure changes such as increase of porosity, development of large pores and decreasing of the thickness of the active layer. And the structure and permeability of CA/PMB30-blend HFMs were controllable by changing preparation conditions. Also, the CA/PMB30-blend HFMs had good permeability, low protein adsorption and low fouling property during the permeability experiment in comparison with CA HFMs, because the hydrophilic and hemocompatible MPC copolymer (PMB30) existed on the surface of the HFM.

Shoe-shaped interface for inducing a walking cycle

We propose a shoe-shaped interface designed to induce a specific walking cycle, and investigate stimulation techniques for effective induction of the walking cycle. The proposed interface is useful for walking navigation system, which enables the wearers locomotion without paying attention to surrounding circumstances. The interface consists of a vibration motor for stimulation and pressure sensors for measuring walking cycle. Using sensory-motor synchronization of human body, this interface can induce a walking cycle effectively without mechanical constraint. The results of our experiments indicate that vibration stimuli at heel grounding timing enable effective induction and that wearers can smoothly shift their walking cycles to the indicated cycle, if the shift of the stimulation cycle is within the range of -100 and +150 ms from their walking cycle.