A technique for the estimation of plasma flow in single capillaries using photobleached dyes

Monitoring electroosmotic flow by periodic photobleaching of a dilute, neutral fluorophore

Electroosmotic flow has been monitored in a capillary using a method based on periodic photobleaching of a neutral, fluorescent buffer additive. Rhodamine B was determined to be neutral between pH 6.0 and 10.8 and was added to the running buffer at a concentration of 400 nM. Rhodamine B was photobleached by opening a shutter under computer control for 250 ms every 5.00 s, to expose the dye to a laser beam and create a photobleached zone. The time was measured for the photobleached zone to migrate 6.13 mm to a downstream laser-induced fluorescence detector, to determine the rate of electroosmotic flow in the entire capillary. The flow rate was sampled every 5.00 s, and the precision of the flow measurements was 0.7% or better. Three fluorescent compounds were separated and detected by capillary electrophoresis with laser-induced fluorescence detection, while simultaneously monitoring the electroosmotic flow rate.

Method to create small photo-bleached volumes to monitor blood plasma flow in capillaries

A method has been developed to examine the movement of plasma in capillaries using intravital microscopy. Spatial transients in fluorescence properties are instantaneously induced by laser photo-bleach pulses after which the convective recovery can be monitored. The plasma is tagged with fluorescent dyes coupled to bovine serum albumin, which is injected well before the measurements and circulates with the blood stream. A laser beam from an argon laser source, set to emit light with a wavelength of 488 nm, is focused on the illumination field diaphragm and creates a spot in the object plane of the microscope. At low laser power, the laser spot is aimed at a blood plasma gap between red blood cells in a capillary segment, using a steerable mirror. Light sensors, coupled to photo-multipliers in the secondary image plane of the microscope, record the light intensity of the moving plasma/dye while the preparation is continuously illuminated with a xenon epi-illuminating set-up. The laser photo-bleach spot is then used to bleach the dye complex within a 5.4 microns segment of the capillary for less than 20 ms. The movement of the bleached plasma bolus is tracked by the photo-sensors, placed sequentially along the capillary. Both dye and red blood cell passage can be detected in the photo-multiplier signals, and the relative velocities of the two blood components can be measured. Measurements reveal that the ratio of transit times between blood plasma and red blood cells is 1.23 (SD = 0.22, N = 18), which is in good agreement with measurements by other techniques.