Faculty Bibliography

We investigated the conditions under which inhomogeneity in electrical conductivity may significantly modify the magnetic evoked field (MEF) due to primary currents (i.e., neuronal currents) in the brain. In the case of an isolated turtle cerebellum immersed in a large bath of physiological saline, our theoretical analysis showed the cerebellar surface to significantly enhance the MEF due to a primary current, by a factor of as much as two, for experimentally determined values of the conductivities of the cerebellar tissue and saline. A further parametric investigation of the conductivity effect revealed that conductivity boundaries may significantly modify the MEF due to neuronal currents located within 1 mm of a conductivity boundary, as would be the case for active neurons near an edema, an anoxic fringe such as might occur during stroke, or a ventricle in the human head. For a stationary neural source, conductivity boundaries may modify the magnitude of its MEF without affecting its temporal waveform. However, this boundary effect was found to be small for a model geometry locally approximating cortical sources in a sulcus or a fissure, where the boundary effects from adjacent sulcal walls tend to cancel each other

Several improvements in the fabrication and use of carbon fiber voltammetric microelectrodes (CFVMs) are described. These procedures did not involve oxidative treatment, but resulted in sensitivities and selectivities approaching those of treated CFVMs, without the inherent slow response times associated with the latter electrodes. To accomplish this we reduced CFVM noise by (1) improving the adhesive seal between the 8 microns o.d. carbon fiber and the glass insulation using vacuum, (2) snapping rather than cutting or beveling the fiber to be flush with the glass, and (3) using a concentrated electrolyte solution to make electrical contact with the fiber. System noise was reduced by digital smoothing and signal averaging. Selectivity of the CFVMs for dopamine over ascorbate was enhanced to better than 2000:1 by coating with Naflon, a perfluorinated cation exchange polymer, using a low (+0.5 V vs Ag/AgCl) electroplating potential. This low voltage also prevented electrode surface oxidation. To demonstrate the performance of our CFVMs, we used them in conjunction with high-speed cyclic voltammetry to accurately measure the diffusion coefficient of iontophoretically released dopamine at concentrations as low as 35 nM over distances of less than 200 microns in agarose gel

We have not employed a rigid statistical interpretation of the data in this report because, as Botwinick and Arenberg pointed out, the time span of a study (if short enough) and the number of independent observations (if small enough) can affect statistical significance. In the present study, the time span was only 6 years, and the males, as well as the females, were grouped into a single age cohort. These limitations do not allow us to assess true time effects. Nevertheless, we attributed the differences noted between the cross-sectional and longitudinal slopes to a time effect, that is, to a secular trend, over the span of the study. This conclusion was based on the following line of reasoning: First, we assumed that there were no significant cohort effects in the population considered in the present study. This assumption was supported by results from the Baltimore Longitudinal Study of Aging, where no cohort effects were found. (In the Baltimore study, 180 males were followed over a period of 15 years, and the age range covered 40 years.) Second, we documented evidence that the participants in the present study actively limited their cholesterol and fat intake because of their keen awareness of an association between cholesterol intake and coronary heart disease as reported in the lay press over the past 10 years. In the healthy male population considered in the present study, we determined that there was a decrease in daily energy intake of approximately 12 kcal/year. We based this determination on the average of the cross-sectional analysis as we attributed much of the negative effect noted in the longitudinal analysis, as stated above, to a secular trend. Aging had a much lower negative effect on energy intake in the female population, being approximately 4 kcal/year. The decrease in protein intake with age was higher in males (1.1 g/day/year) than in females (0.6 g/day/year). This finding parallels the large negative effect of aging in energy intake noted for males compared with females. The same sex difference was noted for carbohydrate intake between males and females (-0.4 and -0.2 g/day/year, respectively). The cross-sectional findings for fat intake are unremarkable for the males (no change) as well as for the females (only -0.1 g/day/year).(ABSTRACT TRUNCATED AT 250 WORDS)

The performance of a cryogenic system that monitors the extracranial magnetic field simultaneously at 14 positions over the scalp has been evaluated to determine the accuracy with which neuronal activity can be located within the human brain. Initially, measurements were implemented on two model systems, a lucite sphere filled with saline and a model skull. With a magnetic field strength similar to that of a human brain, the measurement and analysis procedures demonstrated a position accuracy better than 3 mm, for a current dipole 3 cm beneath the surface. Subsequently, measurements of the magnetic field pattern appearing 100 ms after the onset of an auditory tone-burst stimulus were obtained in three human subjects. The location of the current dipole representing intracellular ionic current in active neurons of the brain was determined, with 3-mm accuracy, to be within the cortex forming the floor of the Sylvian fissure of the individual subjects, corresponding closely to the Heschl gyrus as determined from magnetic resonance images. With the sensors placed at appropriate positions, the locations of neuronal sources for different tone frequencies could be obtained without moving the recording instrument. Adaptation of activity in human auditory cortex was shown to reveal long-term features with a paradigm that compared response amplitudes for three tones randomly presented

This study evaluated the role of excitatory amino acid (EAA) receptor activation in spreading depression (SD), using the in vitro turtle cerebellum as a model system. SD was triggered by electrical stimulation or by elevated K+ after the cerebellum had been conditioned for at least 30 min with physiological saline in which most of the chloride had been replaced by propionate. SD was recognized as a transient (1-3 min) negative shift of extracellular potential accompanied by depression of evoked potentials (15-30 min) and an increase of extracellular K+ up to 60 mM, which spread across the cerebellum at rates of 1-7 mm/min. SD usually commenced in the granular layer, which apparently contains the 3 major EAA receptor subtypes, quisqualate, kainate and N-methyl-D-aspartate (NMDA), then subsequently spread to the molecular layer, which is largely free of NMDA receptors. Glutamate, aspartate, NMDA, kainate and quisqualate all triggered SD. Kynurenic acid and 2-aminophosphonovaleric acid (APV) inhibited SD under certain conditions further suggesting involvement of EAA receptors. The initiation of SD was blocked by high Mg2+ and facilitated in low extracellular Mg2+, which also eliminated the delay in molecular layer SD onset. Our data suggest that no one EAA receptor subtype is singly responsible for SD

Ion-selective microelectrodes were used to measure extracellular K+ concentrations ([K+]o) and extracellular pH (pHo) in skate cerebellum under resting and stimulated conditions. Consistent with earlier ion analysis of elasmobranch cerebrospinal fluid (CSF), [K+]o was 3.6 +/- 0.1 mM. During parallel fiber activation, [K+]o increased to an upper limit of 12-14 mM with an approximately linear dependence on stimulation frequency (1-20 Hz). Post-stimulus undershoots of 0.1-0.6 mM were seen throughout an animal temperature range of 13-18 degrees C. When stimulation produced spreading depression (SD), [K+]o first increased to about 10 mM, then rose more rapidly to about 30 mM. These observations indicate a K+ ceiling of 10-12 mM in elasmobranchs. This ceiling is the same as that seen in mammals, despite marked differences in CSF composition and osmolality between mammalian and elasmobranch species. Extracellular pH (resting pHo was 7.1-7.3) was also altered during parallel fiber stimulation. An initial alkaline shift and subsequent extracellular acidification were characteristic of the response. These pHo transients were similar to those reported in other preparations, although the alkaline shift was enhanced. This may be attributed to the relatively low buffering capacity of elasmobranch CSF and to summation with a generally smaller acid shift

1. Transmembrane potential (TMP) responses of Purkinje cells (PCs) in isolated turtle cerebellum to externally applied quasi-steady-state electric fields aligned with the dendritic axis were continuously measured using simultaneous intracellular and extracellular recording. TMP was obtained by subtraction of extracellular voltage fields from intracellular potential recorded at the same depth in the cerebellum. 2. The applied field changed the TMP with the polarity and amplitude dependent on the location on the PC membrane. This response at a given location increased linearly with external field up to a threshold level, beyond which active responses appeared. 3. The basic effect on TMP consisted of depolarization in the half of the dendrite towards which the fields were directed, and hyperpolarization in the other half. A pooled TMP depth-profile shows a steady increase in polarization from the middle of the molecular layer towards each end. This profile correlates with that predicted from previously proposed cable models, giving them empirical support for the first time. 4. Active responses were triggered by the field-induced depolarization. Tetrodotoxin (TTX)-sensitive action potentials arose with the primary depolarization in the somatic region. Notched, Ca2+-dependent action potentials arose with primary depolarization in the distal and mid-dendritic regions. 5. A TTX-sensitive voltage plateau was triggered by TMP-depolarization in the proximal region. It in turn activated Na+-spike trains. The frequency of spiking was proportional to the external field. At around 160 spikes/s, the Na+ spikes inactivated, and the TMP level rose to a more depolarized plateau. This latter plateau was also TTX-sensitive. 6. During depolarization of the distal dendritic region, sometimes a Ca2+-dependent plateau was observed. It appears to be associated with a small conductance increase. 7. Field-induced hyperpolarization suppressed local spiking and voltage plateaux, but remote Ca2+ spikes with reduced amplitude appeared in recordings from the proximal region. Similarly, in the distal region, low-amplitude, remote Na+ spikes and a Na+ plateau were observed superimposed on the hyperpolarizing baseline. The Na+ plateau apparently did not contribute to shunting of membrane currents in the distal dendrite. 8. The phase characteristics of the action potentials correlate with the modulation pattern noted in our extracellular study (Chan & Nicholson, 1986). Thus, the extracellular units ('giant spikes') were probably Na+ spikes activated in the soma and spread distally. Occasionally Ca2+ spikes, with a higher threshold, might also be activated to give dual-phase response.(ABSTRACT TRUNCATED AT 400 WORDS)

The neural basis of magnetic evoked fields of the brain was studied with an isolated turtle cerebellum as a model preparation. The turtle cerebellum is a nearly flat tissue with neural processes arranged along three orthogonal axes of symmetry. According to theoretical results, this geometry should enable us to selectively measure the magnetic field due to a subpopulation of nerve cells whose longitudinal axes are perpendicular to the cerebellar surface, by simply placing the cerebellum vertically in the bath so that these cells are horizontal and by measuring the field along the rostrocaudal axis perpendicular to the longitudinal axis of these nerve cells. To elicit neural activity in these cells the dorsal midline was electrically stimulated with a bipolar electrode. Consistent with our expectations, the one-dimensional profile of the field normal to bath surface (Bz) was antisymmetrical along the rostrocaudal axis, implying that the underlying currents were transcortical. Also, the Bz field at a field extremum varied as a cosine of the orientation of the cerebellum when it was rotated about its rostrocaudal axis with the amplitude being zero when the cerebellum was horizontal. The Bz field was dipolar as judged by statistically excellent fits of the dipolar field to the one-dimensional field profile and to the distance function relating the field magnitude at an extremum to measuring distance. This was the case even for the initial component thought to be due to antidromic action currents invading the soma and dendrites of Purkinje cells. We also showed that the dipolar term of the source could be localized within 1 mm of the actual source location in most cases

Slow variations of the magnetic field were recorded in real time during spreading depression (SD) in the isolated turtle cerebellum. The magnetic signal lasted for 2-10 min with the largest amplitude in the first minute. The field strength was of sufficient magnitude to be measured unaveraged at 2-4 cm from the tissue. The directions and time course of the magnetic signal indicated that cerebellar SD is accompanied by current normal to the cerebellar surface. The observations reported here are of clinical interest due to the potential involvement of SD in various neurological disorders, notably head trauma and migraine