Electrical activity in the chemoreceptors of the blowfly. II. Responses to electrical stimulation

An analysis of the various parts of the electrical responses to the chemical and electrical stimulation of a single labellar chemosensory hair of the blowfly, Phormia regina, indicates that the recording conditions for the spike potentials approximate the intracellular recordings made in other types of sense cells. The large positive resting potential probably arises from the basement membrane of the hypodermal cells and neurilemma rather than from the neurons at the base of the chemosensory hair. The responses to polarizing currents passed through single chemosensory hairs support this analysis. The behavioral responses to similar polarizing currents are shown to result from the action of the current on the neurons at the bases of the adjacent chemosensory hairs. The reported neural interaction of the two chemosensory neurons associated with the chemosensory hair is probably due to the physical-chemical attributes of the stimulating solution rather than to any real neural interaction. Observations on the latency of the initial nerve impulse in response to chemical stimulation indicate that the chemosensory neurons are normally free from spontaneous spike activity.     

A system designed for the study of cell activity under electrical stimulation

Summary Indium tin oxide electrodes have been used to investigate in vitro effects of steady electric fields on rat bone marrow stromal cells. At voltages <0.8V, no medium decomposition takes place and an electrical double layer is formed at the electrodes. At the anode, the attachment of cells is enhanced but their proliferation is suppressed. Cell proliferation is resumed on removal of the field.     

Electrophysiological responses of olfactory bulb neurons to odour stimuli in the frog. A comparison with receptor cells

Extracellular recordings were performed from olfactory bulbneurons in the frog. The odour stimuli were the same as thosepreviously used for studying the receptor cells in the sameanimal species and were delivered at similar concentrations(Revial et al., 1982). The general properties of the neuronresponses are presented and discussed with reference to homologousproperties of olfactory receptor cells. The response rates elicitedby different stimuli from the bulbar neurons were found to behighly correlated with those elicited from receptor cells. Theindividual cell selectivity was better in the bulb than in theolfactory epithelium. The olfactory bulb neurons seemed to improvethe discrimination between stimuli (enantiomers) poorly distinguishedby the receptor cells. Reducing odor concentration caused therate of suppressive response to decrease faster than that ofexcitatory ones, suggesting that the manifestations of inhibitoryprocesses in some neurons requires a high level of excitationin others.     

Olfactory neuron-specific expression of NeuroD in mouse and human nasal mucosa

Human olfactory neuroepithelium (OE) is situated within the olfactory cleft of the nasal cavity and has the characteristic property of continually regenerating neurons during the lifetime of the individual. This regenerative ability of OE provides a unique model for neuronal differentiation, but little is known about the structure and biology of human olfactory mucosa. Thus, to better understand neurogenesis in human OE, we studied the expression of olfactory marker protein (OMP), TrkB and NeuroD in human nasal biopsies and autopsy specimens and compared these data with those obtained from normal and regenerating mouse OE. We show that NeuroD and TrkB are coordinately expressed in human OE. Thus, by using these markers we have been able to extend the known boundaries of the human OE to include the inferior middle turbinate. In normal mouse OE, TrkB and OMP expression overlap in cells closest to the superficial layer, but TrkB is expressed more strongly in the lower region of this layer. In contrast, NeuroD expression is more basally restricted in a region just above the globose basal cells. These characteristic expression patterns of OMP, TrkB and NeuroD were also observed in the regenerating mouse OE induced by axotomy. These results support a role of NeuroD and brain-derived neurotrophic actor (BDNF), the preferred ligand for TrkB, in the maintenance of the olfactory neuroepithelium in humans and mice.     

Evoked potentials in the frog medulla to electrical stimulation of the glossopharyngeal nerve

Evoked potentials in the frog medulla to stimulation of the glossopharyngeal nerve appear on the ipsilateral side in a zone of limited area. They are recorded at depths not exceeding 2000 µ. Depending on their form the surface evoked potentials are divided into two groups, negative and positive—negative, differing from each other in their parameters and properties. During insertion of the microelectrode the phase of the negative potential is changed. The principal slow components of the responses reflect postsynaptic processes. The first fast wave of the evoked potential is regarded as the presynaptic component. Differences in the properties of the evoked potential recorded at different points are determined by the neuromorphological heterogeneity of the structures of the primary center.     

Responses of neurons of the frog nucleus isthmi to optic nerve stimulation

Responses of single units in the region of the nucleus isthmi were investigated in frogs immobilized with diplacin by means of extracellular capillary liquid microelectrodes. The neurons of this region were not spontaneously active and, after electrical stimulation of the contralateral optic nerve with a single pulse, they gave a single spike discharge with a minimal latent period of 20–110 msec. On increasing the strength of stimulation from threshold to maximal these latent periods were significantly reduced, indicating marked development of summation processes in the corresponding neuronal pathway. Only 14% of the neurons (7 of 57) discharged in response to stimuli exciting myelinated but not exciting unmyelinated optic fibers. All neurons were characterized by instability of the latent period of the evoked discharge; consequently, they were not excited antidromically. The possible functional role of the nucleus isthmi region in the Anura is discussed.A. N. Severtsov Institute of Evolutionary Morphology and Ecology of Animals, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 9, No. 1, pp. 33–40, January–February, 1977.     

Responses of a teratological crustacean limb to electrical stimulation

Summary An anomalous walking limb of the common lobster, in which a supernumerary movable double daetylus is present, is described. The extra digit induces its musculature from the normal flexor and the latter loses its ability to respond to stimulation through the nerve. The excitability of the normal extensor becomes that characteristic of the flexor     

Effects of electrical stimulation of the human olfactory mucosa

Electrical stimulation of the human olfactory mucosa was performed by means of an electrode attached to a rhinoscope . Stimulation of the nasal mucosa did not evoke smell sensations, but suppressed smell sensations of presented odorants. When electrical stimulation followed the exposure to an odorant within a certain interval, the stimulus recalled the already faded sensation of the preceding odorant. Electrical stimulation without prior natural stimulation produced unpleasant sensations in 3 patients with a history of temporal lobe seizures and olfactory auras , but not in patients with primary, generalized or focal epilepsy.     

Chemo-somatosensory event-related potentials in response to repetitive painful chemical stimulation of the nasal mucosa

The aim of the study was to investigate how chemo-somatosensory event-related potentials (CSSERPs) and pain ratings are modified by repetitive painful stimulation of the nasal mucosa (58% v/v CO₂, 200 msec duration). Twenty-two subjects performed 3 experiments during which trains of stimuli were applied. The interstimulus interval (ISI) between stimuli was constant for each experiment, but varied between experiments (8, 4, and 2 sec). CSSERPs were obtained from positions (Fz, C3, Cz, C4, and Pz). The subjects not only rated the overall perceived intensities but also reported the quality of the stimuli. At an ISI of 8 sec estimates decreased and only stinging sensations were reported. In contrast, at an interval of 2 sec estimates increased being accompanied by the buildup of burning pain. This phenomenon was interpreted in terms of the superposition of first (sharp and stinging pain: Aδ fibers) and second pain (dull and burning pain: C fibers), respectively. However, given the special circumstances of short ISIs CSSERP amplitudes decreased the more the shorter the ISI was. In line with previous investigations it is hypothesised that CSSERPs predominantly reflect nociceptive information transmitted via Aδ fibers.     

Responses of rabbit visual cortical neurons to intracortical electrical stimulation

Responses of rabbit visual cortical neurons to single and repetitive intracortical electrical stimulation were investigated. The stimulating electrode was located 0.7–1.2 mm away from the recording electrode. Response thresholds to single stimulation were as a rule 150–180 µA, whereas to series of stimuli they were 30–60 µA. The latent period to the first spike averaged 5–15 msec but the probability of the initial discharge was very low, namely 3–6%. With an increase in current intensity the duration of the initial inhibitory pause was increased in half of the neurons responding to it, whereas in the rest it was unchanged. After presentation of series of stimuli spontaneous activity was enhanced for a short time (4–6 sec). In about half of the cells the same kinds of discharge dynamics were observed in response to repetitive stimulation (frequency 0.25 Hz) as in responses to light, but more neurons with sensitization of discharge and fewer "habituating" neurons took part in responses to electrical stimulation. It is postulated that stimulation of a given point of the visual cortex evokes excitation of a local neuron hypercolumn and inhibition of neighboring cell columns.M. V. Lomonosov Moscow State University. Translated from Neirofiziologiya, Vol. 15, No. 4, pp. 412–419, July–August, 1983.     

Olfactory rhythm in the electrical activity of the human amygdaloid nucleus

Summated electrical activity of the human amygdaloid nucleus was investigated in the neurosurgical clinic by chronically implanted electrodes. It was found that odoriferous stimulation of this structure produced bursts of rapid rhythm (20–30 cps, 30–50 µV). The quasisinusoidal waves of olfactory rhythm consist of sinusoidal components which are more pronounced within the 20–30-Hz frequency range. Spindling of 1–3 sec duration occurs at the end of inhalation and the beginning of exhalation in time with breathing. During monorhinal breathing this activity, whose amplitude depends on degree of olfactory stimulation, can only be recorded ipsilaterally. Room air also activates the amygdaloid nucleus, but less strongly than odoriferous substances: No characteristic odor-dependent differences were discovered in the frequency range of the olfactory rhythm within a 20–30-Hz band.Institute of Physiology, Kiev State University, Kiev. Translated from Neirofiziologiya, Vol. 18, No. 1, pp. 61–69, January–February, 1986.     

Olfactory receptor cell responses of pigeon to some odors

A preparation has been developed in the pigeon which allows recording of the electrical activity from an olfactory nerve twig containing the nonmyelinated axons of a small group of olfactory receptor cells. The pigeon's response to n-amylacetate is vigorous and stable, like that of other air-breathing animals. Responses in the olfactory receptor cells in the pigeon increased in magnitude with increase in the odor concentration. An olfactory nerve twig produced a different magnitude of responses to the various odor stimuli. When an odor stimulation was applied to the olfactory mucosa, the two different olfactory nerve twigs which were separated from the same olfactory nerve bundle produced a different magnitude of responses. The differences may be dependent on several factors.     

Electrical activity in the chemoreceptors of the blowfly. I. Responses to chemical and mechanical stimulation

The electrical responses of the neurons associated with the various types of chemosensory hairs of the blowfly, Phormia regina Meigen, following stimulation by chemical and mechanical means have been studied. The singly innervated chemosensory hairs on the ovipositor, maxillary palpi, and antennae respond vigorously to chemical stimulation, but not to mechanical stimulation. The triply innervated chemosensory hairs on the labellum, tarsus, and wing have two neurons which respond only to chemical stimuli. The third neuron responds only to mechanical stimulation. The differential responses of the two chemosensory neurons to various chemical stimuli following the removal of the tip of the hair suggest that the structures responsible for chemoreception are located throughout the distal processes of these neurons. The response of the third neuron to mechanical stimulation is similar to the response recorded from the neuron associated with one type of tactile hair which responds to motion and not to steady deformation. Recordings have been made from the neurons associated with purely tactile hairs using the cut hair as an extension of the micropipette. The mechanosensory neuron of the wing chemosensory hair is capable of responding at the rate of at least 600 impulses per sec. and may serve to indicate changes in air flow over the wing surfaces during flight to enable the fly to correct the wing camber and attack angle.