Regular arrays of intramembranous particles in the plasmalemma of guard cell and mesophyll cell protoplasts of Vicia faba

Freeze fractures of the plasmalemma membranes of guard-cell and mesophyll protoplasts of Vicia faba demonstrate that the inner monolayer of the plasmalemma is compartmentalized into areas with distinct, highly organized structures. Between areas of intramembranous particles dispersed randomly on a relatively smooth fracture face, membrane domains showing an extremely regular planar, hexagonal array of particles are interspersed. The dimensions of these hexagonal lattices are about 0.5 μm in diameter, the center-to-center spacing is about 22 nm, and the particle size is about 9 nm. The particle in the hexagonal arrays are accompanied by complementary pits in the opposite monolayer fracture of the plasmalemma membrane.The freeze-fracture preparation was performed by using an improved Leybold Bioetch device which provides a sufficiently high cooling rate and allows the omission of cryoprotectants, like glycerol.

Erythrocytes and lymphocytes as drug carrier systems: techniques for entrapment of drugs in living cells

Mouse thymocytes and erythrocytes are loaded electrically with drugs in isotonic solution. The loaded cells are used for targeting the drugs to specific sites in the organism in order to achieve a controlled drug release in time and space. The field technique used for the loading of the cells is based on the dielectric breakdown of the cell membrane which is observed when cell suspensions are subjected to external field pulses of 2-20 kV/cm for short time intervals (ns to microseconds). When an apparent membrane potential of about 1 V is reached in response to the external field, the membrane breaks down reversibly. The breakdown of the membrane is associated with a remarkable and reversible permeability increase of the cell membrane. The increase in permeability depends on the strength and the duration of the field pulse.

Penetration and entrapment of large particles in erythrocytes by electrical breakdown techniques

Human erythrocytes suspended in isotonic solutions were subjected to haemolysis by application of an electric field pulse to the cell suspension. The field strengths used were 12 and 16kV/cm, respectively; the pulse duration 40 microseconds. The lysed cells showed resealing properties. The permeability change of the membrane generated by the field pulse and by the subsequent osmotic processes were large enough to facilitate the penetration and entrapment of ferritin and Latex particles (diameter: 0.091 and 0.176 micron, respectively) as revealed by electron microscopy. Correct identification of the Latex particles in the electron-micrographs indicated that LOYTER et al. [J. Cell Biol. 66, 292 (1975)], who recently demonstrated the entrapment of Latex spheres in erythrocytes prepared by osmotic haemolysis mistook electron-dense bodies probably consisting of denaturated protein for Latex particles. Under conditions of osmotic haemolysis, carried out according to BODEMANN and PASSOW, particles could only occasionally be detected within the membrane itself and never within the cell interior, suggesting that the electrical haemolysis method is much more effective in the generation of large holes in the membrane.