Sympatho-excitatory response to pulmonary chemosensitive spinal afferent activation in anesthetized, vagotomized rats

This review focuses on the neural control of feeding in Aplysia. Its purpose is to highlight distinctive features of the behavior and to describe their neural basis. In a number of molluscs, food is grasped by a radula that protracts, retracts, and hyperretracts. In Aplysia, however, hyperretraction can require afferent activation. Phase-dependent regulation of sensorimotor transmission occurs in this context. Aplysia also open and close the radula, generating egestive as well as ingestive responses. Thus, the feeding network multitasks. It has a modular organization, and behaviors are constructed by combinations of behavior-specific and behavior-independent neurons. When feeding is initially triggered in Aplysia, responses are poorly defined. Motor activity is not properly configured unless responses are repeatedly induced and modulatory neurotransmitters are released from inputs to the central patter generator (CPG). Persistent effects of modulation have interesting consequences for task switching.

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Evidence for glycine, GABAA, and GABAB receptors on rabbit OFF-alpha ganglion cells

Visual Neuroscience ◽

10.1017/s0952523803203072 ◽

2003 ◽

Vol 20 (3) ◽

pp. 285-296 ◽

Cited By ~ 12

Author(s):

THOMAS C. ROTOLO ◽

RAMON F. DACHEUX

Keyword(s):

Ganglion Cells ◽

Gabab Receptors ◽

Direct Inhibition ◽

Light Responses ◽

Retinal Surface ◽

Excitatory Response ◽

Sulforhodamine B ◽

Intact Rabbit ◽

Specific Receptors ◽

Whole Cell Recordings

Inhibitory synaptic transmission via GABA and glycine receptors plays a crucial role in shaping the excitatory response of neurons in the retina. Whole-cell recordings were obtained from ganglion cells in the intact rabbit eyecup preparation to correlate GABA- and glycine-activated currents with the presence of their specific receptors on morphologically identified α ganglion cells. Alpha ganglion cells were chosen based upon their large somata when viewing the retinal surface, and responses to light and dark spots were used to identify OFF-alpha ganglion cells. Light responses were abolished by superfusion of Ringer's containing cobalt to synaptically isolate the cell by blocking all Ca2+-mediated transmitter release. Pressure pulses of GABA and glycine were delivered to an area that encompassed the dendritic field while receptor antagonists were applied through superfusion to characterize the direct inhibition onto the ganglion cell. Physiological results indicated that OFF-α cells did not have any GABAC receptor-activated currents, but did express currents mediated by ionotropic GABAA receptors and metabotropic GABAB receptors that were blocked by their specific antagonists bicuculline and CGP55845, respectively. The amplitudes of strychnine-sensitive glycine-activated currents were always larger than the currents elicited by GABA. Confocal optical sections of physiologically identified, sulforhodamine B-stained cells displayed the localization of glycine and GABAA receptor subunit labeling dispersed over the stained dendrites.

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Monaural inhibition in cat auditory cortex

Journal of Neurophysiology ◽

10.1152/jn.1995.73.5.1876 ◽

1995 ◽

Vol 73 (5) ◽

pp. 1876-1891 ◽

Cited By ~ 187

Author(s):

M. B. Calford ◽

M. N. Semple

Keyword(s):

Auditory Cortex ◽

Lateral Inhibition ◽

Cortical Neurons ◽

Frequency Tuning ◽

Inhibitory Response ◽

Forward Masking ◽

Excitatory Response ◽

Rate Level ◽

Wide Range ◽

Response Area

1. Several studies of auditory cortex have examined the competitive inhibition that can occur when appropriate sounds are presented to each ear. However, most cortical neurons also show both excitation and inhibition in response to presentation of stimuli at one ear alone. The extent of such inhibition has not been described. Forward masking, in which a variable masking stimulus was followed by a fixed probe stimulus (within the excitatory response area), was used to examine the extent of monaural inhibition for neurons in primary auditory cortex of anesthetized cats (barbiturate or barbiturate-ketamine). Both the masking and probe stimuli were 50-ms tone pips presented to the contralateral ear. Most cortical neurons showed significant forward masking at delays beyond which masking effects in the auditory nerve are relatively small compared with those seen in cortical neurons. Analysis was primarily concerned with such components. Standard rate-level functions were also obtained and were examined for nonmonotonicity, an indication of level-dependent monaural inhibition. 2. Consistent with previous reports, a wide range of frequency tuning properties (excitatory response area shapes) was found in cortical neurons. This was matched by a wide range of forward-masking-derived inhibitory response areas. At the most basic level of analysis, these were classified according to the presence of lateral inhibition, i.e., where a probe tone at a neuron's characteristic frequency was masked by tones outside the limits of the excitatory response area. Lateral inhibition was a property of 38% of the sampled neurons. Such neurons represented 77% of those with nonmonotonic rate-level functions, indicating a strong correlation between the two indexes of monaural inhibition; however, the shapes of forward masking inhibitory response areas did not usually correspond with those required to account for the "tuning" of a neuron. In addition, it was found that level-dependent inhibition was not added to by forward masking inhibition. 3. Analysis of the discharges to individual stimulus pair presentations, under conditions of partial masking, revealed that discharges to the probe occurred independently of discharges to the preceding masker. This indicates that even when the masker is within a neuron's excitatory response area, forward masking is not a postdischarge habituation phenomenon. However, for most neurons the degree of masking summed over multiple stimulus presentations appears determined by the same stimulus parameters that determine the probability of response to the masker.(ABSTRACT TRUNCATED AT 400 WORDS)

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Response properties of units in the dorsal cochlear nucleus of unanesthetized decerebrate gerbil

Journal of Neurophysiology ◽

10.1152/jn.1996.75.4.1411 ◽

1996 ◽

Vol 75 (4) ◽

pp. 1411-1431 ◽

Cited By ~ 47

Author(s):

K. A. Davis ◽

J. Ding ◽

T. E. Benson ◽

H. F. Voigt

Keyword(s):

Dorsal Cochlear Nucleus ◽

Type I ◽

Type Ii ◽

Decerebrate Cat ◽

Excitatory Response ◽

Type Iii ◽

Type Iv ◽

Noise Type ◽

Rate Versus ◽

Excitatory Responses

1. The electrophysiological responses of single units in the dorsal cochlear nucleus of unanesthetized decerebrate Mongolian gerbil (Meriones unguiculatus) were recorded. Units were classified according to the response map scheme of Evans and Nelson as modified by Young and Brownell, Young and Voigt, and Shofner and Young. Type II units have a V-shaped excitatory response map similar to typical auditory nerve tuning curves but little or no spontaneous activity (SpAc < 2.5 spikes/s) and little or no response to noise. Type I/III units also have a V-shaped excitatory map and SpAc < 2.5 spikes/s, but have an excitatory response to noise. Type III units have a V-shaped excitatory map with inhibitory sidebands, SpAc > 2.5 spikes/s, and an excitatory response to noise. Type IV-T units typically also have a V-shaped excitatory map with inhibitory sidebands, but have a highly nonmonotonic rate versus level response to best frequency (BF) tones like type IV units, SpAc > 2.5 spikes/s, and an excitatory response to noise. Type IV units have a predominantly inhibitory response map above an island of excitation of BF, SpAc > 2.5 spikes/s, and an excitatory response to noise. We present results for 133 units recorded with glass micropipette electrodes. The purpose of this study was to establish a normative response map data base in this species for ongoing structure/function and correlation studies. 2. The major types of units (type II, type I/III, type III, type IV-T, and type IV) found in decerebrate cat are found in decerebrate gerbil. However, the percentage of type II (7.5%) and type IV (11.3%) units encountered are smaller and the percentage of type III (62.4%) units is larger in decerebrate gerbil than in decerebrate cat. In comparison, Shofner and Young found 18.5% type II units, 30.6% type IV units, and 23.1% type III units using metal electrodes. 3. Two new unit subtypes are described in gerbil: type III-i and type IV-i units. Type III-i units are similar to type III units except that type III-i units are inhibited by low levels of noise and excited by high levels of noise whereas type III units have strictly excitatory responses to noise. Type IV-i units are similar to type IV units except that type IV-i units are excited by low levels of noise and become inhibited by high levels of noise whereas type IV units have strictly excitatory responses to noise. Type III-i units are approximately 30% of the type III population and type IV-i units are approximately 50% of the type IV population. 4. On the basis of the paucity of classic type II units and the reciprocal responses to broadband noise of type III-i and type IV-i units, we postulate that some gerbil type III-i units are the same cell type and have similar synaptic connections as cat type II units. 5. Type II and type I/III units are distinguished from one another on the basis of both their relative noise response, rho, and the normalized slope of the BF tone rate versus level functions beyond the first maximum. Previously, type II units were defined to be those nonspontaneously active units with rho values < 0.3 where rho is defined as the ratio of the maximum noise response minus spontaneous rate to the maximum BF tone response minus spontaneous rate. In the gerbil, the average rho value for type II units is 0.25, although a few values are > 0.3, and the rate-level curves are consistently nonmonotonic with normalized slopes steeper than than -0.007/dB. The average rho value for type I/III units is 0.54, although a few values are < 0.3, and the rate-level curves tend to saturate with slopes shallower than -0.006/dB. In general, the response properties of type II units recorded in gerbil are similar to those recorded in decerebrate cat. 6. In comparison to decerebrate cat, the lower percentage of type IV units recorded in decerebrate gerbil may be due to a species difference (a reduced number of type II units in gerbil) or an electrode bias.

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Cholinergic interneurons in the feeding system of the pond snail lymnaea stagnalis. I. cholinergic receptors on feeding neurons

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.1992.0053 ◽

1992 ◽

Vol 336 (1277) ◽

pp. 157-166 ◽

Cited By ~ 19

Keyword(s):

Synaptic Input ◽

Lymnaea Stagnalis ◽

Cholinergic Receptors ◽

Pond Snail ◽

Feeding System ◽

Inhibitory Receptor ◽

Excitatory Response ◽

Cholinergic Interneurons ◽

Feeding Rhythm ◽

Cholinergic Response

All the identified feeding motoneurons of Lymnaea respond to bath or iontophoretically applied acetylcholine (ACh). Three kinds of receptors (one excitatory, one fast inhibitory and one slow inhibitory) were distinguished pharmacologically. The agonist TMA (tetram ethylam m onium ) activates all three receptors, being weakest at the slow inhibitory receptor. PTMA (phenyltrim ethylam monium ) is less potent than TMA and is ineffective at the slow inhibitory receptor, which is the only receptor sensitive to arecoline. At 0.5 mM the antagonists HMT (hexamethonium) and ATR (atropine) selectively block the excitatory response, while PTMA reduces the response to ACh at all three receptors. d-TC (curare) antagonizes only the fast excitatory and the fast inhibitory responses, but MeXCh (methylxylocholine) blocks the fast excitatory and slow inhibitory responses solely. For each of the feeding motoneurons, the sign of the cholinergic response (excitation or inhibition) is the same as the synaptic input received in the N1 phase of the feeding rhythm .

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GABA and Glycine Inputs Control Discharge Rate within the Excitatory Response Area of Primary-Like and Phase-Locked AVCN Neurons

The Mammalian Cochlear Nuclei ◽

10.1007/978-1-4615-2932-3_19 ◽

1993 ◽

pp. 239-252 ◽

Cited By ~ 14

Author(s):

Donald M. Caspary ◽

Peggy S. Palombi ◽

Patricia M. Backoff ◽

Robert H. Helfert ◽

Paul G. Finlayson

Keyword(s):

Discharge Rate ◽

Excitatory Response ◽

Control Discharge ◽

Response Area

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Influences from laryngeal afferents on expiratory bulbospinal neurons and motoneurons

Journal of Applied Physiology ◽

10.1152/jappl.1988.64.4.1337 ◽

1988 ◽

Vol 64 (4) ◽

pp. 1337-1345 ◽

Cited By ~ 24

Author(s):

J. S. Jodkowski ◽

A. J. Berger

Keyword(s):

Electrical Stimulation ◽

Cold Water ◽

Superior Laryngeal Nerve ◽

Intercostal Nerve ◽

Firing Frequency ◽

Neuronal Responses ◽

Water Infusion ◽

Afferent Activation ◽

Expiratory Neurons ◽

Stimulation Of

The purpose of this study is to analyze the reflex effects of laryngeal afferent activation on respiratory patterns in anesthetized, vagotomized, paralyzed, ventilated cats. We recorded simultaneously from the phrenic nerve, T10 internal intercostal nerve, and single bulbospinal expiratory neurons of the caudal ventral respiratory group (VRG). Laryngeal afferents were activated by electrical stimulation of the superior laryngeal nerve (SLN) or by cold-water infusion into the larynx. Both types of stimuli caused inhibition of phrenic activity and facilitation of internal intercostal nerve activity, indicating expiratory effort. The activity of 46 bulbospinal expiratory cells was depressed during SLN electrical stimulation, and 13 of them were completely inhibited. In 44 of 56 neurons tested, mean firing frequency (FFmean) was decreased in response to cold-water infusion and 8 others responded with increased FFmean; in the remaining 4 neurons, FFmean was unchanged. Possible reasons for different neuronal responses to SLN electrical stimulation and water infusion are discussed. We conclude that bulbospinal expiratory neurons of VRG were not the source of the reflex motoneuronal expiratory-like activity produced by SLN stimulation. Other, not yet identified inputs to spinal expiratory motoneurons are activated during this experimental condition.

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Time-dependent phrenic nerve responses to carotid afferent activation: intact vs. decerebellate rats

AJP Regulatory Integrative and Comparative Physiology ◽

10.1152/ajpregu.1993.265.4.r811 ◽

1993 ◽

Vol 265 (4) ◽

pp. R811-R819 ◽

Cited By ~ 65

Author(s):

F. Hayashi ◽

S. K. Coles ◽

K. B. Bach ◽

G. S. Mitchell ◽

D. R. McCrimmon

Keyword(s):

Phrenic Nerve ◽

Carotid Sinus ◽

Carotid Sinus Nerve ◽

Short Term ◽

Nerve Activity ◽

A Value ◽

Afferent Activation ◽

Term Potentiation ◽

Long Term Facilitation

The objectives were to determine 1) respiratory responses to carotid chemoreceptor inputs in anesthetized rats and 2) whether the cerebellar vermis plays a role in these responses. A carotid sinus nerve was stimulated (20 Hz) with five 2-min trains, each separated by approximately 3 min. During stimulation, respiratory frequency (f), peak amplitude of integrated phrenic nerve activity (integral of Phr), and their product (f x integral of Phr) immediately increased. As stimulation continued, integral of Phr progressively increased to a plateau [short-term potentiation (STP)], but f and f x integral of Phr decreased [short-term depression (STD)] to a value still above control. Upon stimulus termination, integral of Phr progressively decreased but remained above control; f and f x integral of Phr transiently decreased below baseline. After the final stimulation, integral of Phr remained above control for at least 30 min [long-term facilitation (LTF)]. Repeated 5-min episodes of isocapnic hypoxia also elicited STP, STD, and LTF. Vermalectomy lowered the CO2-apneic threshold and eliminated LTF. In conclusion, carotid chemoreceptor activation in rats elicits STP and LTF similar to that in cats; the vermis may play a role in LTF. A new response, STD, was observed.

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Primary Afferent Activation of Thermosensitive TRPV1 Triggers Asynchronous Glutamate Release at Central Neurons

Neuron ◽

10.1016/j.neuron.2010.02.017 ◽

2010 ◽

Vol 65 (5) ◽

pp. 657-669 ◽

Cited By ~ 116

Author(s):

James H. Peters ◽

Stuart J. McDougall ◽

Jessica A. Fawley ◽

Stephen M. Smith ◽

Michael C. Andresen

Keyword(s):

Glutamate Release ◽

Primary Afferent ◽

Central Neurons ◽

Afferent Activation

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