Abstract: The invention is directed to a method for determining condition parameters for photodynamic therapy in which after administration of 5-aminolevulinic acids, protoporphyrin IX accumulated in cells is irradiated with light, the method including steps of: calculating, in an experimental phase, a regression curve representing a correlation among three condition parameters: cell viability (Y), intracellular protoporphyrin IX accumulation (X), and light irradiation energy density (P); and selecting in advance, prior to initiation of therapy, two condition parameters from the cell viability (Y), the intracellular protoporphyrin IX accumulation (X), and the light irradiation energy density (P), and then determining the remaining condition parameter using the regression curve. Thus, the photodynamic therapy can be optimized.

Abstract: Provided is a web floating and conveying device which has excellent web quality maintaining property and excellent conveying-fluid precision control property in conveying a web film. A conveyance guide (1) of the web floating and conveying device (10) is formed of a lamination-type assembled body having the split structure which is constituted of plate-shaped members (2) which are approximately radially arranged from an axis of the conveyance guide (1). A fluid passing passage which forms a fluid discharge hole by connecting a web floating surface (1a) and an introduction flow passage (7) through which a pressurized fluid is supplied to each other is formed on either one or both lamination surfaces of the plate-shaped members (2) which are laminated adjacent to each other.

Abstract: A fuel cell having an electrode and/or catalyst formed from a nano-carbon material, such as fullerene, carbon nanotube, carbon nanohorn, carbon nano-fiber or metal encapsulated fullerene. Such fuel cells may not use platinum in the electrode or catalyst, or may use platinum in small amounts. The efficiency of the fuel cell may be increased by applying external energy to the electrode and/or catalyst. A cationic membrane may be positioned between the cathode and anode of the fuel cell. Also disclosed is an improved method for generating electricity from a fuel cell having at least one electrode formed from a nano-carbon material. To increase the efficiency of the fuel cell, the electrode or catalyst containing nano-carbon material may be irradiated with blue color diode light, or an electric current may be directed to the nano-carbon material.

Abstract: A fuel cell having an electrode and/or catalyst formed from a nano-carbon material, such as fullerene, carbon nanotube, carbon nanohorn, carbon nano-fiber or metal encapsulated fullerene. Such fuel cells may not use platinum in the electrode or catalyst, or may use platinum in small amounts. The efficiency of the fuel cell may be increased by applying external energy to the electrode and/or catalyst. A cationic membrane may be positioned between the cathode and anode of the fuel cell. Also disclosed is an improved method for generating electricity from a fuel cell having at least one electrode formed from a nano-carbon material. To increase the efficiency of the fuel cell, the electrode or catalyst containing nano-carbon material may be irradiated with blue color diode light, or an electric current may be directed to the nano-carbon material.

Abstract: A process for producing ultra-fine ceramic particles with the particle size of less than 1000 .ANG., which comprises the steps of forming powdered dust cloud of metal powder such as Si constituting a portion of aimed ceramic particles in a reaction gas containing the other portion of said aimed ceramic particles, igniting said powdered dust cloud to cause explosive burning and synthesizing said aimed ceramic particles and gathering said resulting ceramic particles. By the process, ceramic particles such as Al.sub.2 O.sub.3, MgO, SiO.sub.2, TiO.sub.2, TiN having particle size of 10-100 nm can be produced.