Faculty Bibliography

Dopamine reaches targets in the outer retina of the clawed frog (Xenopus laevis) by diffusion from a network of dopaminergic cells and processes located predominantly at the junction of inner nuclear and inner plexiform layers. We obtained values for the steady-state release, uptake, and extracellular concentration of dopamine in the retina by a combination of HPLC (with electrochemical detection), scintillation spectroscopy, and fast-scan cyclic voltammetry. Vitreal concentrations of dopamine varied from 564 +/- 109 nM in light-adapted eyes near the time of subjective dawn to 156 +/- 12 nM in dark-adapted eyes. The data are consistent with a simple model for steady-state dopamine diffusion from an appropriately sited thin-sheet source. This model was used to generate a profile of extracellular dopamine concentration as a function of retinal depth. The model predicted an increase in the dopamine concentration from the vitreous to the layer of dopaminergic cells, remaining constant from that layer to the distal tips of the photoreceptors. This prediction was borne out by comparing fast-scan voltammetric measures of dopamine at the distal tips of the receptors with the vitreal concentrations determined by HPLC using electrochemical detection

The organic calcium channel blocker verapamil has been demonstrated to block epileptic activity in various experimental models both in vitro and in vivo. The drug, however, does not pass the blood-brain barrier, so that both the oral route and intravenous administration of the drug are ruled out for antiepileptic treatment. The present investigations analyzed the effects of verapamil applied epicortically in experimental models of interictal penicillin-induced and ictal pentylenetetrazol-induced epileptic activity in rats. Such epicortical application of verapamil was ineffective in suppressing either interictal or ictal epileptic activity. To test whether this lack of effect was due to poor penetration of the substance into the cortical tissue, the diffusion characteristics of verapamil were studied in agar and in gray matter by pressure microejection and an appropriate verapamil-selective microelectrode. The diffusion could be described fully by a diffusion coefficient D (5.08 x 10(-6) cm2 x s-1), tortuosity lambda (1.51) and concentration-dependent uptake, k' (2.23 x 10(-3) s-1). Using these values, the depth-dependent concentration gradient resulting from superfusion of the substance was calculated for agar and brain. In concentration measurements done in brain tissue, however, verapamil could not be detected in cortical layers deeper than 150 microns, which did not agree with the theoretical prediction. This observation may indicate a diffusion barrier at the interface between superfusing fluid and tissue. The results indicate that epicortical administration of verapamil is not efficacious in treatment of epilepsy

1. Measurements of extracellular diffusion properties were made in three orthogonal axes of the molecular and granular layers of the isolated turtle cerebellum with the use of iontophoresis of tetramethylammonium (TMA+) combined with ion-selective microelectrodes. 2. Diffusion in the extracellular space of the molecular layer was anisotropic, that is, there was a different value for the tortuosity factor, lambda i, associated with each axis of that layer. The x- and y-axes lay in the plane parallel to the pial surface of this lissencephalic cerebellum with the x-axis in the direction of the parallel fibers. The z-axis was perpendicular this plane. The tortuosity values were lambda x = 1.44 +/- 0.01, lambda y = 1.95 +/- 0.02, and lambda z = 1.58 +/- 0.01 (mean +/- SE). By contrast, the granular layer was isotropic with a single tortuosity value, lambda Gr = 1.77 +/- 0.01. 3. These data confirm the applicability of appropriately extended Fickian equations to describe diffusion in anisotropic porous media, including brain tissue. 4. Heterogeneity between the molecular and granular layer was revealed by a striking difference in extracellular volume fraction, alpha, for each layer. In the molecular layer alpha = 0.31 +/- 0.01, whereas in the granular layer alpha = 0.22 +/- 0.01. 5. Volume fraction and tortuosity affected the time course and amplitude of extracellular TMA+ concentration after iontophoresis. This was modeled by the use of the average parameters determined experimentally, and the nonspherical pattern of diffusion in the molecular layer was compared with the spherical distribution in the granular layer and agarose gel by computing isoconcentration ellipsoids. 6. One functional consequence of these results was demonstrated by measuring local changes in [K+]o and [Ca2+]o after microiontophoresis of a cerebellar transmitter, glutamate. The ratios of ion shifts in the x- and y-axes in the granular layer were close to unity, with a ratio of 1.04 +/- 0.08 for the rise in [K+]o and 1.03 +/- 0.17 for the decrease in [Ca2+]o. In contrast, ion shifts in the molecular layer had an x:y ratio of 1.44 +/- 0.14 for the rise in [K+]o and 2.10 +/- 0.42 for the decrease in [Ca2+]o. 7. These data demonstrate that the structure of cellular aggregates can channel the migration of substances in the extracellular microenvironment, and this could be a mechanism for volume transmission of chemical signals. For example, the preferred diffusion direction of glutamate along the parallel fibers would help constrain an incoming excitatory stimulus to stay 'on-beam.'

The construction and application of liquid-membrane ion-selective microelectrodes (ISM) are described. Recommendations are provided for the selection of appropriate cocktails containing neutral carriers to form the liquid membrane to sense K+, Ca2+, H+ and Na+. The use of charged carriers to sense Cl- and the cation tetramethylammonium (TMA+) is discussed. A detailed protocol is given for constructing double-barreled electrodes (ion-sensor and reference barrel) with tips of 1 micron diameter or more for extracellular ion measurements. The primary results obtained with ISMs in the brain cell microenvironment are briefly surveyed. The theoretical basis for measuring diffusion properties of extracellular space is described. Such measurements enable the estimation of volume fraction (proportion of tissue that is extracellular space) and tortuosity (hindrance of diffusion due to cellular obstructions). A method is given for using TMA+ ISMs in combination with iontophoresis or pressure ejection of TMA+ from a nearby micropipette to measure diffusion properties

The tetramethylammonium (TMA+) method for measuring the volume fraction and tortuosity of brain extracellular space is presented in detail. The temporal and spatial distribution of TMA+ in the extracellular space following iontophoresis or pressure microinjection is described by suitable equations and illustrated with graphs. By fitting the equations to the concentration versus time data obtained from measurements with ion-selective micropipettes, the volume fraction and tortuosity can be measured. In addition, the concentration-dependent uptake of TMA+ can be estimated from the given equations. The final section of the paper derives simple numerical estimates of TMA+ loss from the extracellular space by this mechanism

1. Regulation of brain extracellular and intracellular water content, regarded as volume, and electrolytes in response to 90 min of hypernatremia has been studied in the cerebral cortex of rats under urethane anaesthetic. 2. Total tissue electrolytes and water were partitioned between extracellular and intracellular compartments based on measurements made in two series of experiments. In one, tissue samples were collected and analysed for total water, Na+, K+ and Cl-. In the other, tissue extracellular volume fraction, [Na+] and [K+] were measured in situ using ion-selective microelectrodes. 3. Osmotically induced water loss from cerebral cortex was less than that predicted for ideal osmotic behaviour, revealing a degree of volume regulation, and this regulation was associated with net tissue uptake of Na+, Cl- and K+. 4. Total water content was 3.77 g H2O (g dry weight)-1 in control cortex and this decreased by 7% after 30 min of hypernatremia and then remained relatively stable at this value. Control extracellular water content, based on an extracellular volume fraction of 0.18, was 0.88 g H2O (g dry weight)-1. Control intracellular water content, estimated as the difference between total and extracellular water contents, was 2.89 g H2O (g dry weight)-1. After 30 min of hypernatremia, extracellular water content decreased by an average of 27% but intracellular water did not change. This indicates selective regulation of cell volume. By 90 min the extracellular water content had decreased by 47% and the loss in extracellular water content appeared to be accompanied by a roughly equivalent increase in intracellular water content. The intracellular volume increase, however, was not statistically significant. The tortuosity of the extracellular space averaged 1.57 and increased to 1.65 during the hypernatremia. 5. Brain extracellular fluid and plasma [Na+] were roughly equal in control tissue. Both increased by 30 mu equiv (g H2O)-1 as a result of the hypernatremia, although extracellular [Na+] lagged behind the plasma value during much of the first 60 min of hypernatremia. Extracellular [K+] was homeostatically regulated at 3 mu equiv (g H2O)-1 independent of changes in plasma electrolytes. 6. Estimates of extracellular and intracellular ion content (mu equiv (g dry weight)-1) indicate that extracellular Na+, Cl- and K+ content decreased during hypernatremia, by 32, 21 and 42% respectively, whereas intracellular ion content increased by 100, 169 and 5% respectively. 7. It is concluded that during acute hypernatremia the extracellular space decreases in volume through the loss of water and electrolytes while the intracellular compartment maintains its water content and gains electrolytes.(ABSTRACT TRUNCATED AT 400 WORDS)

The tissue volume required to produce a penicillin-induced interictal discharge in the local EEG was estimated. A pair of microelectrodes were lowered into the motor cortex of anaesthetised and artificially ventilated rats. One double-barrelled electrode was used to release tetramethylammonium (TMA+) by iontophoresis or to pressure eject a solution containing penicillin (PEN-) and TMA+ concentration. The extracellular distribution of PEN- was defined using diffusion analysis of the TMA+. From these data the spatial distribution of PEN- was estimated at the times of first interictal spikes in the EEG. The critical mass of active nerve cells was calculated from the threshold concentration of PEN- needed to elicit paroxysmal depolarisation shifts in neocortical slices and found to lie within a tissue sphere with a radius of ca. 150 microns

1. Diffusion properties of submerged, superfused slices from the rat neostriatum were measured by quantitative analysis of concentration-time profiles of tetramethylammonium (TMA+) introduced by iontophoresis. TMA+ was sensed at an ion-selective microelectrode (ISM) positioned 100-150 microns from the source pipette. Slice viability was assessed from the extracellular field potentials evoked by intrastriatal electrical stimulation. 2. Under normoxic conditions the extracellular volume fraction (alpha) was 0.21 (range 0.18-0.24), and the tortuosity (lambda) was 1.54, in slices with good field potentials. In slices with poor field potentials, alpha was 0.09-0.16. Extraction of correct alpha and lambda in the slice required evaluation of nonspecific uptake, k', which was 1 x 10(-2) s-1. 3. Slices were made hypoxic by superfusing physiological saline equilibrated with 95% N2-5% CO2 for 10-30 min. Synaptic components of field potentials were inhibited after 3-4 min in hypoxic media. In some experiments extracellular K+ concentration [( K+]o) was monitored with ISMs. During hypoxia, [K+]o rose from an average baseline of 5.1 mM to 7-10 mM. After reoxygenation, [K+]o transiently fell below the original level. 4. The average value for alpha during hypoxia was 0.13 (a 38% decrease), which was significantly different from control (P less than 0.001) and increased progressively during hypoxic exposure. In contrast, tortuosity and k' were unchanged by this treatment. 5. These data represent the first characterization of the diffusion properties of the rat striatal slice and of changes in extracellular volume fraction during hypoxia in a brain slice preparation.(ABSTRACT TRUNCATED AT 250 WORDS)

An external electric field applied parallel to longitudinal axis of neurons selectively depolarizes either end and thereby activates voltage-sensitive conductance changes in a large population of neurons. Here, we characterized such population responses in the in vitro turtle cerebellum. The responses were recorded and analyzed using a multimodal approach: the magnetic evoked field was measured using a Superconducting Quantum Interference Device (SQ

Ion-selective microelectrodes can be used to evaluate the characteristics and laminar distribution of excitatory amino acid agonist-induced K+ and Ca2+ shifts in the extracellular environment of brain cells. This report describes the pattern of K+ increases and Ca2+ decreases elicited by glutamate and aspartate at 100 microns intervals in the isolated turtle cerebellum. These responses were compared to ion shifts evoked by kainate, quisqualate and N-methyl-D-aspartate. Glutamate and aspartate produced indistinguishable laminar patterns of ion shifts, with the greatest [K+]o and [Ca2+]o shifts in the granular layer. The average maximum granular and molecular layer increases in [K+]o were, respectively, 130% and 24% larger than the increase in the Purkinje cell layer. Kainate-induced increases in [K+]o also followed this granular greater than molecular greater than Purkinje cell layer pattern; however, the corresponding [Ca2+]o decreases were smaller and more variable. Quisqualate-evoked ion shifts in the molecular layer closely mimicked the shape of glutamate- and aspartate-induced responses. In the granular layer, however, quisqualate caused little ion change during iontophoresis followed by large [K+]o and [Ca+]o shifts after the end of the pulse. The minimal ion shifts induced during quisqualate application in the granular layer gave this agonist the distinction of being the only agent tested to have its greatest direct effect in the molecular layer. N-Methyl-D-aspartate caused large, two-phase [K+]o and [Ca2+]o shifts in the granular layer, only small [K+]o rises in the Purkinje cell and ventral molecular layers, and no response in the dorsal molecular layer. The lack of similarity between glutamate- and aspartate-induced ion shifts in the granular layer and those of any one agonist demonstrate the mixed agonist action of glutamate and aspartate in the cerebellum. These studies provide new information about the dynamics of excitatory amino acid receptor activation that is complementary to autoradiographic receptor mapping data and to single cell electrophysiological studies