Electrofusion of Mucor circinelloides protoplasts

Summary Electrical parameters were optimized for induction of the fusion of protoplasts formed from two auxotrophic (leu^–, ade^–) Mucor circinelloides strains. These proved to be a pulse voltage of 66 V, a pulse duration of 66 us and six pulses at intervals of 1.0 s. Nutritionally complementing colonies were obtained at an average frequency up to 12.4%, which is substantially higher than achieved earlier with the PEG-Ca²⁺ method.     

Electrofusion parameters for mouse two-cell embryos

We studied electrofusion of mouse two-cell embryos in order to define parameters which would result in a high yield of fused embryos. Various cell alignment times (from <10 to >60 s) and alternating current percentages (2 to 100%) were examined. The fusion parameters tested were the number of fusion pulses (1-9), pulse length (30-90 mus) and pulse strength (0.50-1.79 kV/cm). Furthermore different combinations of these three parameters were tested. In addition the influence of several embryo culture media on the fusion rates was examined. The results show that the fusion rate of the embryos increases with shorter alignment and higher percentages of the alternating current. The highest fusion rate (95%) was obtained by use of one pulse with a duration of 70 mus and a field strength of 0.60-0.79 kV/cm. The survival rate of the embryos was best if Whitten Medium was used before and after the fusion pulses. The fusion of two-cell stages results in tetraploid embryos which can serve as models for studies in polyploid cells.     

Correlation between electric field pulse induced long-lived permeabilization and fusogenicity in cell membranes.

Electric field pulses have been reported to induce long-lived permeabilization and fusogenicity on cell membranes. The two membrane property alterations are under the control of the field strength, the pulse duration, and the number of pulses. Experiments on mammalian cells pulsed by square wave form pulses and then brought into contact randomly through centrifugation revealed an even stronger analogy between the two processes. Permeabilization was known to affect well-defined regions of the cell surface. Fusion can be obtained only when permeabilized surfaces on the two partners were brought into contact. Permeabilization was under the control of the pulse duration and of the number of pulses. A similar relationship was observed as far as fusion is concerned. But a critical level of local permeabilization must be present for fusion to take place when contacts are created. The same conclusions are obtained from previous experiments on ghosts subjected to exponentially decaying field pulses and then brought into contact by dielectrophoresis. These observations are in agreement with a model of membrane fusion in which the merging of local random defects occurs when the two membranes are brought into contact. The local defects are considered part of the structural membrane reorganization induced by the external field. Their density is dependent on the pulse duration and number of pulses. They support the long-lived permeabilization. Their number must be very large to support the occurrence of membrane fusion.     

Importance of association between permeabilization and electrophoretic forces for intramuscular DNA electrotransfer

Gene transfer using electrical pulses is a rapidly expanding field. Many studies have been performed in vitro to elucidate the mechanism of DNA electrotransfer. In vivo, the use of efficient procedures for DNA electrotransfer in tissues is recent, and the question of the implied mechanisms is largely open. We have evaluated the effects of various combinations of square wave electric pulses of variable field strength and duration, on cell permeabilization and on DNA transfection in the skeletal muscle in vivo. One high voltage pulse of 800 V/cm, 0.1 ms duration (short high pulse) or a series of four low voltage pulses of 80 V/cm, 83 ms duration (long low pulses) slightly amplified transfection efficacy, while no significant permeabilization was detected using the (51)Cr-EDTA uptake test. By contrast, the combination of one short high pulse followed by four long low pulses led to optimal gene transfer efficiency, while inducing muscle fibers permeabilization. These results are consistent with additive effects of electropermeabilization and DNA electrophoresis on electrotransfer efficiency. Finally, the described new combination, as compared to the previously reported use of repeated identical pulses of intermediate voltage, leads to similar gene transfer efficiency, while causing less permeabilization and thus being likely less deleterious. Thus, combination of pulses of various strengths and durations is a new procedure for skeletal muscle gene transfer that may represents a clear improvement in view of further clinical development.     

Advanced high-power pulsed light device to decontaminate food from pathogens: effects on Salmonella typhimurium viability in vitro

AIMS: The aim of this study was to construct an advanced high-power pulsed light device for decontamination of food matrix and to evaluate its antibacterial efficiency. Key parameters of constructed device-emitted light spectrum, pulse duration, pulse power density, frequency of pulses, dependence of emitted spectrum on input voltage, irradiation homogenicity, possible thermal effects as well as antimicrobial efficiency were evaluated. METHODS AND RESULTS: Antimicrobial efficiency of high-power pulsed light technique was demonstrated and evaluated by two independent methods - spread plate and Miles-Misra method. Viability of Salmonella typhimurium as function of a given light dose (number of pulses) and pulse frequency was examined. According to the data obtained, viability of Salmonella typhimurium reduced by 7 log order after 100 light pulses with power density 133 W cm(-2). In addition, data indicate, that the pulse frequency did not influence the outcome of pathogen inactivation in the region 1-5 Hz. Moreover, no hyperthermic effect was detected during irradiation even after 500 pulses on all shelves with different distance from light source and subsequently different pulse power density (0-252 W cm(-2)). CONCLUSION: Newly constructed high-power pulsed light technique is effective nonthermal tool for inactivation of Salmonella typhimurium even by 7 log order in vitro. SIGNIFICANCE AND IMPACT OF THE STUDY: Novel advanced high-power pulsed light device can be a useful tool for development of nonthermal food decontamination technologies.     

The structure and function of songs emitted by southern green stink bugs from Brazil, Florida, Italy and Slovenia

Nezara viridula (L.) (Pentatomidae: Heteroptera) from Brazil, Florida, Italy and Slovenia, communicate by vibratory songs associated with long‐range calling and close‐range courting, rivalry and repelling. Each song is composed of spectrally and temporally different units. Spectrally different pulses of duration less than 300 ms are present in the male calling song. The female calling song is characterized by pulse trains composed of pulses shorter than 150 ms and pulse trains composed of a longer (> 700 ms) and shorter (< 250 ms) pulse. Shorter and longer pulses have different spectral characteristics. The male and female courtship songs are characterized by fusion of shorter (< 150 ms) pulses into a pulse train usually followed by a shorter (< 200 ms) postpulse in the case of the male courtship song. The female repelling song is a several seconds long vibration of irregular temporal structure. The short (< 400 ms) male rival song pulses are frequency modulated. The dominant frequency peaks of the songs investigated lie between 70 and 130 Hz. The dominant frequency and the microstructure of song spectra show no population specificity. The average duration varies more in calling than in courtship songs. The repetition time varies extensively in songs of different populations. Normal communication followed by copulation was observed between mates from Slovenia and Brazil and between mates from Florida and Italy. The potential role of different temporal and spectral parameters for species recognition and mate location is discussed in view of the expected distortion of the characteristic signal structure during transmission through plants.     

Effective donor cell fusion conditions for production of cloned dogs by somatic cell nuclear transfer

As shown by the birth of the first cloned dog ‘Snuppy', a protocol to produce viable cloned dogs has been reported. In order to evaluate optimum fusion conditions for improving dog cloning efficiency, in vivo matured oocytes were reconstructed with adult somatic cells from a female Pekingese using different fusion conditions. Fusion with needle vs chamber methods, and with low vs high pulse strength was compared by evaluating fusion rate and in vivo development of canine cloned embryos. The fusion rates in the high voltage groups were significantly higher than in the low voltage groups regardless of fusion method (83.5 vs 66.1% for the needle fusion method, 67.4 vs 37.9% for the fusion chamber method). After embryo transfer, one each pregnancy was detected after using the needle fusion method with high and low voltage and in the chamber fusion method with high voltage, whereas no pregnancy was detected using the chamber method with low voltage. However, only the pregnancy from the needle fusion method with high voltage was maintained to term and one healthy puppy was delivered. The results of the present study demonstrated that two DC pulses of 3.8 to 4.0 kV/cm for 15 μsec using the needle fusion method were the most effective method for the production of cloned dogs under the conditions of this experiment.     

Electrofusion between heterogeneous-sized mammalian cells in a pellet: potential applications in drug delivery and hybridoma formation.

High-efficiency electrofusion between cells of different sizes was achieved by application of fusing electric pulses to cells in centrifuged pellets. Larger target cells (Chinese hamster ovary or L1210 cells) were stacked among smaller human erythrocytes or erythrocyte ghosts by sequential centrifugation at 700 g to form five-tier pellets in a specially designed centrifugation-electrofusion chamber. The membranes of erythrocytes and ghost were labeled with fluorescent membrane dye (1,1' dioctadecyl-3,3,3'3'-tetramethylindocarbocyanine (Dil)), and the contents of ghosts were loaded with water-soluble fluorescent dye (42-kDa fluorescein isothiocyanate dextran (FITC-dextran)), to monitor heterogeneous cell fusion. Fusion efficiency was assayed by the extent of either membrane dye mixing or contents (FITC-dextran) mixing with target cells. Four rectangular electric pulses at 300 V and 80 microseconds each were found to give the optimal fusion results of approximately 80% heterogeneous fusion by the content-mixing assay and approximately 95% by the membrane-dye-mixing assay. Cell viability remained greater than 80% after electrofusion. Because of the electric breakdown of cell membranes at the beginning of the pulse, the pellet resistance and hence the partial voltage across the pellet reduced rapidly during the remaining pulse time. This voltage redistribution favored the survival of fused cells. The limited colloidal-osmotic swelling of cells in pellets enhanced cell-cell contact and increased the pellet resistance after each pulse. As a result, the partial voltage across the pellet was restored when the next pulse was applied. This redistribution of pulse voltage in the pellet system permitted the breakdown of cell membranes at a lower applied voltage threshold than that required for electrofusion of cells in suspension or in dielectrophoretic cell chains. The cell viability and soluble dye retention within cells (FITC-dextran) remained at the same high levels for 3 h when the cells were incubated in respective culture media with serum at 37 degrees C. Viability and dye retention decreased significantly within 30 min when cells were incubated in phosphate-buffered saline without serum. The pellet technique was applied to form hybridomas by fusion of larger SP2/0 murine myelomas with smaller naive mouse lymphocytes. An optimum of 173 +/- 70 hypoxanthine aminopterin thymidine (HAT)-selected clones of the hybridomas was obtained from 40,000 SP2/0 cells and 1.5 x 10(6) lymphocytes used in each trial. This high-efficiency fusion technique may be adapted to mediate drug and gene transfer to target cells ex vivo as well as to form hybrid cells with limited cell sources.     

Leukemic cell intracellular responses to nanosecond electric fields

Intense, nanosecond (ns) pulsed electric fields (PEFs) are known to affect the intracellular structures of cells. The probability of preferentially inducing subcellular effects increases with decreasing pulse length while effects on the plasma membrane are diminished. This has been demonstrated by applying electrical pulses of 60 and 10 ns duration with electric field intensities of up to 6.5 MV/m to HL-60 cells. Using confocal microscopy, PEF-induced changes in the integrity of the plasma membrane and nucleus were measured by recording fluorescence changes with propidium iodide (PI) and acridine orange (AO), respectively. Results suggest that high voltage, nsPEFs target the nucleus and modify cellular functions while plasma membrane effects are delayed and become smaller as pulse duration is shortened. Cell viability was not affected by these pulses. In spite of the high pulsed electric fields, thermal effects can be neglected because of the ultrashort pulse duration. The results suggest application of this ultrashort pulse technology to modulate nuclear structure and function for potential therapeutic benefit.     

Electroporation of human embryonic stem cells: Small and macromolecule loading and DNA transfection

Cryopreservation, directed differentiation, and genetic manipulation of human embryonic stem cells (hESCs) all require the transport of exogenous small molecules, proteins, or DNA into the cell. The absence of standard small and macromolecule loading techniques in hESCs as well as the inadequacies of current DNA transfection techniques have led us to develop electroporation as an efficient loading and transfection methodology. The electroporation parameters of pulse voltage, duration, and number have been explored and evaluated in terms of cell viability, molecular loading, and transfection efficiency on a per cell basis. Small molecule loading was assessed using propidium iodide (PI) and the disaccharide trehalose. Additionally, protein loading was investigated using a glutathione-S-transferase green fluorescent protein (GST-GFP) conjugate, and DNA transfection optimization was performed by constitutive expression of GFP from a plasmid. The optimum pulse voltage must balance cell viability, which decreases as voltage increases, and loading efficiency, which increases at higher voltages. Short pulse times of 0.05 ms facilitated PI and trehalose loading, whereas 0.5 ms or more was required for GST-GFP loading and DNA transfection. Multiple pulses increased per cell loading of all molecules, though there was a dramatic loss of viability with GST-GFP loading and DNA transfection, likely resulting from the longer pulse duration required to load these molecules.     

Effects of various electric fields on the fusion and in vitro development of mouse two-cell embryos

This study was undertaken to examine the effects of various electric fields such as alternating current (a.c.) voltage, fusion pulse strength, pulse duration, pulse number and electrode geometry on blastomere fusion and developmental rates of mouse two-cell embryos. The a.c. voltages (6 and 12 V/mm) did not affect the fusion and developmental rates. High fusion and developmental rates were obtained when pulse strengths of 1.0 to 2.5 kV/cm, pulse durations of 30 to 90 mu sec and pulse numbers of 1 to 6 were applied using a wire chamber. Comparison of electrode geometries showed that fusion rates were similarly high (93 to 98%) when pulse strengths of 1.0 to 2.5 kV/cm were applied, regardless of the electrode geometry. However, significantly lower developmental rates were observed in a rectangular chamber compared with those in a wire chamber, except when the pulse strength was 1.0 kV/cm. It was further observed that in a rectangular chamber, the developmental rate decreased with increasing pulse strength from 1.0 to 2.0 and 2.5 kV/cm. The results of this study indicate that by using a wire chamber, electric fields can be successfully applied across a relatively wide range of pulse strength, duration and number to provide sufficiently high fusion and subsequent developmental rates. The fusion conditions did, however, vary with chambers of different electrode geometries.     

Dependence of the electrical breakdown voltage on the charging time inValonia utricularis

Summary Charge-pulse experiments were performed on giant algal cells ofValonia utricularis. For a charging time of 420 sec the breakdown voltage is about 750 mV (18°C), a value that is in close agreement with earlier results obtained with current pulses (Coster & Zimmermann, 1975;J. Membrane Biol. 22:73). If the membrane is charged to the breakdown voltage in a shorter time, the breakdown voltage is found to be a function of the duration of the charge pulses. Whereas towards smaller pulse lengths down to 10 sec only a small, but significant, increase in the breakdown voltage is observed (1.1 V at 10 sec pulse length and 18°C), a strong increase in the breakdown voltage is found for even shorter charging times. For a pulse length of 800 nsec the breakdown voltage has a value of about 2.4 V (18°C) and a plateau seems to be reached for a pulse duration of 500 nsec. The influence of temperature on the breakdown voltage as observed for short charging times is very similar to that reported earlier for current pulses of 500 sec duration. For charge pulses of 1 to 2 sec duration the breakdown voltage decreases from 3.6 V at 3°C to 1.6 V at 25°C by more than a factor of two.Voltage relaxation studies in the low-field range suggest that the time constants of the two membranes arranged in series, tonoplast and plasmalemma, are similar. From this, it is suggested that both membranes show electrical breakdown, whereby the breakdown voltage of a single membrane is probably half the value of the total breakdown voltage. Its dependence on pulse length is therefore considered to be an intrinsic property of one single membrane. The strong dependence of the breakdown voltage on the charging time of the membrane further supports the interpretation of the breakdown phenomenon on the basis of the electro-mechanical model proposed earlier. In this model it is assumed that the electrical and mechanical compressive forces are counter balanced by elastic restoring forces within the membrane. However, towards very short pulses (less than 800 nsec), where a plateau seems to be reached, other processes may be generated by the application of the electric field. We discuss whether one of these processes is the ion movement through the membranes induced by a high electric field (Born energy).     

Kinetic analysis of phasic inhibition of neuronal sodium currents by lidocaine and bupivacaine.

Phasic ("use-dependent") inhibition of sodium currents by the tertiary amine local anesthetics, lidocaine and bupivacaine, was observed in voltage-clamped node of Ranvier of the toad, Bufo marinus. Local anesthetics were assumed to inhibit sodium channels through occupation of a binding site with 1:1 stoichiometry. A three-parameter empirical model for state-dependent anesthetic binding to the Na channel is presented: this model includes two discrete parameters that represent the time integrals of binding and unbinding reactions during a depolarizing pulse, and one continuous parameter that represents the rate of unbinding of drug between pulses. The change in magnitude of peak sodium current during a train of depolarizing pulses to 0 mV was used as an assay of the extent of anesthetic binding at discrete intervals; estimates of model parameters were made by applying a nonlinear least-squares algorithm to the inhibition of currents obtained at two or more depolarizing pulse rates. Increasing the concentration of drug increased the rate of binding but had little or no effect on unbinding, as expected for a simple bimolecular reaction. The dependence of the model parameters on pulse duration was assessed for both drugs: as the duration of depolarizing pulses was increased, the fraction of channels binding drug during each pulse became significantly larger, whereas the fraction of occupied channels unbinding drug remained relatively constant. The rate of recovery from block between pulses was unaffected by pulse duration or magnitude. The separate contributions of open (O) and inactivated (I) channel binding of drug to the net increase in block per pulse were assessed at 0 mV: for lidocaine, the forward binding rate ko was 1.3 x 10(5) M-1 s-1, kl was 2.4 x 10(4) M-1 s-1; for bupivacaine, ko was 2.5 x 10(5) M-1 s-1, kl was 4.4 x 10(4) M-1 s-1. These binding rates were similar to those derived from time-dependent block of maintained Na currents in nodes where inactivation was incomplete due to treatment with chloramine-T. The dependence of model parameters on the potential between pulses (holding potential) was examined. All three parameters were found to be nearly independent of holding potential from -70 to -100 mV. These results are discussed with respect to established models of dynamic local anesthetic-Na channel interactions.     

Fusion and development rates of single blastomere pairs of mouse two- and four-cell embryos using the electrofusion method

The present study was undertaken to find suitable conditions for blastomere fusion of mouse two- and four-cell embryos using the electrofusion method to simplify the nuclear transfer procedure. Single blastomeres of ICR and F1 (C57BL/6J x CBA/N) two-cell embryos or ICR four-cell embryos and F1 two-cell embryos were paired and treated with electric stimulus under different fusion conditions. Two hours after electrofusion treatment, the fused blastomere pairs were encapsulated in alginate gel and cultured for 96 hours to observe their developmental potential. When the single blastomere pairs of two-cell embryos were exposed to electric pulses of 1.0, 1.5 and 2.0 kV/cm for 30, 60 and 90 mu sec, high fusion rates were obtained (84.6 to 100%). However, when two-cell blastomere were paired with four-cell blastomere and then treated under the same conditions, the fusion rates (27.5 to 87.5%) were lower than that of single blastomere pairs of two-cell embryos regardless of the duration and strength of the d.c. pulses. The blastocyst developmental rate after in vitro culture of the fused blastomere pairs of two-cell embryos using the above electrofusion conditions was high (81.8 to 100%). Lower blastocyst developmental rates were obtained on the fused blastomere pairs of two- and four-cell embryos (46.4 to 76.2%). Based on the results of this study, a pulse duration of 60 mu sec and a pulse strength of 1.0kV/cm were the most suitable conditions for single blastomere pair fusion of two-cell or two- and four-cell embryos. The study further showed that alginate gel is a good substitute for zonae pellucidae for encapsulating zona-free embryos.     

Effect of stimulus (postsynaptic current) shape on fibre excitation.

Effects of variation of the stimulus pulse shape on the excitation of a nonmyelinated nerve fibre were studied using a mathematical model based on the Hodgkin-Huxley equations. Efficiency of smoothly changing pulses was compared with that of rectangular pulses. For pulses shorter than the time to excitation, the rate of the stimulus rise did not determine the ability of a smoothly changing pulse to excite the fibre. For a given stimulus duration, the main factor was the pulse area or the charge delivered by the pulse. The strength-duration curve for smoothly changing pulses was a nonmonotonic function, in contrast to the curve for rectangular pulses. The dependence of latency on changes in the pulse area was non-linear. It would be nonmonotonic when the pulse area variation were due to the stimulus duration or the stimulus rise duration. More that one propagating intracellular action potential (IAP) could arise upon fibre activation by a long smoothly changing threshold stimulus. Upon activation of relatively short fibres the IAP could arise not at the site of the smoothly changing stimulus injection. The rectangular pulses of long duration were more efficient than the corresponding smoothly changing ones. Irrespective of the shape, the pulses whose duration at the foot is 1-2 ms, are more suitable for a prolonged threshold fibre activation.     

Membrane fusion without cytoplasmic fusion (hemi-fusion) in erythrocytes that are subjected to electrical breakdown

There are many reports of hemi-fusion in phospholipid vesicles but few published studies on hemi-fusion in cells. We report evidence from both fluorescence microscopy and freeze-fracture electron microscopy for hemi-fusion in the electrofusion of human erythrocytes. We have also characterised the conditions that favour hemi-fusion as opposed to complete fusion, and discuss the possibility that hemi-fusion might precede complete electrically-induced cell fusion. A membrane probe (DiIC16) and a cytoplasmic probe (6-carboxyfluorescein) were used to investigate the behaviour of doubly-labelled human erythrocytes which were aligned in chains by dielectrophoresis and then exposed to high voltage breakdown pulses. Some of the cells were fused by the pulses, as shown by diffusion of both membrane and cytoplasmic probes from labelled to unlabelled cells. With other cells, the membrane probe diffused into unlabelled cells after the breakdown pulses, without the cytoplasmic probe diffusing into unlabelled cells or leaking into the medium. Membrane fusion (hemi-fusion) thus occurred without cytoplasmic fusion in these erythrocytes. Such cells were irreversibly, but fragilely, attached to their neighbours by the breakdown pulses. There was an inverse relationship between conditions that permit complete fusion and those that favour hemi-fusion, with respect to breakdown pulse length, breakdown voltage and, in particular, osmolarity and temperature. The incidence of hemi-fusion in 250 mM erythritol was twice that in 150 mM erythritol, and hemi-fusion was 5-fold greater at 25 degrees C than at 20 degrees C. Hemi-fused erythrocytes occasionally fused completely on heating to 50 degrees C, demonstrating that hemi-fusion can proceed to complete cell fusion. Freeze fracture electron micrographs of preparations of hemi-fused cells revealed long-lived, complementary depressions and protrusions on the E- and P-fracture faces, respectively, of tightly apposed cells that may mediate hemi-fusion. The possibility that the fusion of closely adjacent human erythrocytes by electrical breakdown pulses may involve an intermediate, shared bilayer structure, which is stable in certain conditions but which can be ruptured by osmotic swelling of the permeabilised cells, is discussed.     

Electropermeabilization of mammalian cells to macromolecules: control by pulse duration.

Membrane electropermeabilization to small molecules depends on several physical parameters (pulse intensity, number, and duration). In agreement with a previous study quantifying this phenomenon in terms of flow (Rols and Teissié, Biophys. J. 58:1089-1098, 1990), we report here that electric field intensity is the deciding parameter inducing membrane permeabilization and controls the extent of the cell surface where the transfer can take place. An increase in the number of pulses enhances the rate of permeabilization. The pulse duration parameter is shown to be crucial for the penetration of macromolecules into Chinese hamster ovary cells under conditions where cell viability is preserved. Cumulative effects are observed when repeated pulses are applied. At a constant number of pulses/pulse duration product, transfer of molecules is strongly affected by the time between pulses. The resealing process appears to be first-order with a decay time linearly related to the pulse duration. Transfer of macromolecules to the cytoplasm can take place only if they are present during the pulse. No direct transfer is observed with a postpulse addition. The mechanism of transfer of macromolecules into cells by electric field treatment is much more complex than the simple diffusion of small molecules through the electropermeabilized plasma membrane.     

Resetting of the hamster circadian system by dark pulses

Circadian rhythms of animals are reset by exposure to light as well as dark; however, although the parameters of photic entrainment are well characterized, the phase-shifting actions of dark pulses are poorly understood. Here, we determined the tonic and phasic effects of short (0.25 h), moderate (3 h), and long (6-9 h) duration dark pulses on the wheel-running rhythms of hamsters in constant light. Moderate- and long-duration dark pulses phase dependently reset behavioral rhythms, and the magnitude of these phase shifts increased as a function of the duration of the dark pulse. In contrast, the 0.25-h dark pulses failed to evoke consistent effects at any circadian phase tested. Interestingly, moderate- and long-dark pulses elevated locomotor activity (wheel-running) on the day of treatment. This induced wheel-running was highly correlated with phase shift magnitude when the pulse was given during the subjective day. This, together with the finding that animals pulsed during the subjective day are behaviorally active throughout the pulse, suggests that both locomotor activity and behavioral activation play an important role in the phase-resetting actions of dark pulses. We also found that the robustness of the wheel-running rhythm was weakened, and the amount of wheel-running decreased on the days after exposure to dark pulses; these effects were dependent on pulse duration. In summary, similarly to light, the resetting actions of dark pulses are dependent on both circadian phase and stimulus duration. However, dark pulses appear more complex stimuli, with both photic and nonphotic resetting properties.     

Early stage shape change of human erythrocytes after application of electric field pulses.

Erythrocytes which receive electric field pulses are subject to poration, fusion and shape changes due to electrodynamic forces, aminophospholipid perturbation and influences on the normal flip-flop process. The shape change characteristics of cells suspended in different media were analysed after application of rectangular electric field pulses from t=11-44 micros and from E=4-8 kV/cm. Albumin is shown to decelerate the echinocyte shape change within the first few seconds after pulse application. The addition of fluoride and vanadate accelerates the shape change due to their inhibiting influence on the aminophospholipid translocase. For both the duration of the field pulse and its field strength, there exist lower threshold values under which no early stage shape change is observable. The activation energy calculated from the dissipative influence of the electric field alone is smaller than expected, indicating the electrodynamic influence on the flip-flop process. Cell shapes were additionally analysed by contour tracing to focus on the echinocyte spicule distribution after pulse application. This image analysis revealed that, with an increase of both pulse duration and field strength, the shape change velocity and the shape change intensity increase.     

Human erythrocyte electrofusion kinetics monitored by aqueous contents mixing.

The kinetics of electrically induced fusion of human erythrocyte ghosts were monitored by the Tb/DPA and ANTS/DPX fluorescence fusion assays. Ghosts were aligned by dielectrophoresis using a 3-MHz 350-V/cm alternating field and were fused by single 15- or 50-microseconds electric field pulses of amplitude 2.5-5.0 kV/cm. Fusion was detected immediately after the pulse. The peak fluorescence change due to fusion was always obtained within 7 s of pulse application, and was highest for a 5.0 kV/cm 15-microseconds pulse. Probe leakage was measured separately and became apparent only 2-3 s after the initiation of fusion. Increasing pulse amplitudes produced higher fusion yields but produced more leakage from the fusion products. 50-microseconds pulses produced less fusion, resulting from a disruption of the dielectrophoretic alignment by fluid turbulence immediately after pulse application. Probe leakage was observed only when pulse application was preceded by dielectrophoresis, suggesting that close membrane positioning allows for additional membrane destabilization caused by the high field pulse. The fluorescence kinetics are interpreted using a simplified model depicting three major types of events: (a) fusion without observable leakage, (b) fusion followed by probe leakage, and (c) contact-related leakage from ghosts which do not undergo contents mixing.