Abstract: A method of producing a binding assay device provides a porous membrane comprising a material enabling capillary movement of a liquid sample from a first area on the membrane on a second area on the membrane. A detection site is disposed on the membrane between the first and second areas in a non-absorbent medium disposed on the membrane between the detection site and the membrane first area is attached by an adhesion with a dry reagent disposed between the medium and the membrane in order to enable mobilization of the reagent by passage of a liquid sample therepast.

Abstract: A fluid collection and testing device includes a collection vial having a bottom and an open top along with an expresser sized for insertion into the vial open end. The expresser includes a ribbed base enabling fluid to pass therethrough and a support member holds the expresser within the collection vial with the ribbed base in a spaced apart relationship with the vial bottom. A fluid collector includes an absorbent member capturing a fluid and the absorbent member is sized for insertion into the expresser and is compressible against the ribbed base for releasing captured fluid through the ribbed base and into the vial bottom. A catch mechanism is provided for latching the fluid collector to the expresser after insertion into the expresser for enabling simultaneous removal of the expresser and the fluid collector from the collection vial.

Abstract: A nuclear magnetic resonance (NMR) spectroscopy or tomography method wherein a sequence of temporally mutually offset radio frequency (RF) pulses is applied onto a spin ensemble like a CPMG multi echo experiment, and wherein the magnetization produced after an initial excitation pulse is transferred to or close to the static pseudo steady state of the initially applied refocussing flip angle ?1 is characterized in that magnetization is transferred through gradual change of the refocussing flip angle in subsequent refocussing intervals to or close to the static pseudo steady state of the respectively used refocussing pulse with refocussing flip angle ?n such that the echo amplitude of the nth echo generated in this fashion approaches the maximum possible value corresponding to the respective refocussing pulse with refocussing flip angle ?n. The RF energy required for excitation of the nuclear spins can thereby be considerably reduced without having to accept signal intensity losses.

Abstract: Process for the simultaneous production of alkali metal hydroxide and electricl energy. A plurality of hybrid cells (1) are operated in series with an aqueous solution of alkali metal hydroxide introduced as anolyte into an anode compartment of a first hybrid cell (6) at one end of the series and an aqueous fluid medium receptive to alkali metal ions introduced as catholyte into a cathode of a last hybrid cell (7) at an opposite end of the series of cells (1). The anolyte is caused to flow through the anode compartments (3) of the cells (1) in sequence from the first cell (6) to the last cell (7) of the series of cells (1). The catholyte is caused to flow through the cathode compartments (4) in sequence from the last cell (7) to the first cell (6) countercurrently to the flow of anolyte from hybrid cell to hybrid cell of the series of cells (1).