Your search keyword '"Gilbey, M. P."' showing total 6 results

1. Cutaneous sympathetic motor rhythms during a fever-like response induced by prostaglandin E(1).

Author

Collins DR, Korsak A, and Gilbey MP

Subjects

Action Potentials drug effects, Alprostadil metabolism, Animals, Arteries drug effects, Arteries physiology, Biological Clocks drug effects, Blood Pressure drug effects, Blood Pressure physiology, Body Temperature Regulation drug effects, Body Temperature Regulation physiology, Brain physiology, Efferent Pathways physiology, Fever physiopathology, Heart Rate drug effects, Heart Rate physiology, Hyperthermia, Induced, Male, Periodicity, Rats, Rats, Sprague-Dawley, Respiratory Physiological Phenomena drug effects, Sympathetic Fibers, Postganglionic drug effects, Tail blood supply, Tail innervation, Tail physiology, Vasoconstriction drug effects, Action Potentials physiology, Alprostadil pharmacology, Arteries innervation, Biological Clocks physiology, Fever metabolism, Sympathetic Fibers, Postganglionic physiology, Vasoconstriction physiology

Abstract

Neuronal population discharges within the CNS and in somatic and sympathetic motor nerves often display oscillations. Peripheral oscillations may provide a window into central mechanisms, as they often show coherence with population activity of subsets of central neurones. The reduction in heat loss through the cutaneous circulation during fever may be mediated via sympathetic premotor neurones not utilised during normal temperature regulation. Consequently, here we assessed, in anaesthetised rats, whether the frequency signature of population sympathetic discharge observed in neurones innervating the tail (thermoregulatory) circulation changed during a fever-like response induced by intracerebroventricular injection of prostaglandin E(1). We found that when core temperature was raised to 38.8-40.5 degrees C sympathetic activity was abolished. Following administration of prostaglandin (400 ng or 1 microg per rat), activity was restored to levels seen prior to heating (154+/-53.5%; n=10). Injection of vehicle had no effect (n=7). Prior to heating when most animals were in central apnoea (14/18) two peaks were observed in autospectra of sympathetic activity: one at 0.68-0.93 Hz (T-peak) and another at the frequency of ventilation (2 Hz). Central respiratory drive was recruited during hyperthermia where it was 1:2 locked to the frequency of ventilation and following prostaglandin administration, an additional peak in sympathetic autospectra was seen at this frequency. Time-evolving spectra indicated that this peak resulted from the dynamic locking of the 'T-peak' to central respiratory drive. Our data show that during a fever-like response the dominant oscillations in sympathetic activity controlling a thermoregulatory circulation and their dynamic coupling to respiratory-related inputs are similar to those seen under normal conditions. Therefore, during this fever-like response, the neural substrate(s) underlying the oscillations is not reconfigured and remains capable of sculpturing the pattern of sympathetic neuronal discharge that may be regulated by several descending pathways.

Published

2002

2. Resetting of sympathetic rhythm by somatic afferents causes post-reflex coordination of sympathetic activity in rat.

Author

Staras K, Chang HS, and Gilbey MP

Subjects

Animals, Arteries innervation, Blood Pressure physiology, Electric Stimulation, Neurons, Afferent ultrastructure, Periodicity, Physical Stimulation, Radial Nerve cytology, Rats, Rats, Sprague-Dawley, Tail blood supply, Tail innervation, Neurons, Afferent physiology, Radial Nerve physiology, Reflex physiology, Sympathetic Fibers, Postganglionic physiology, Vasoconstriction physiology

Abstract

1. We have proposed previously that graded synchronous activity is produced by periodic inputs acting on weakly coupled or uncoupled oscillators influencing the discharges of a population of cutaneous vasoconstrictor sympathetic postganglionic neurones (PGNs) in anaesthetized rats. 2. Here we investigated the effects of somatic afferent (superficial radial nerve, RaN) stimulation, on the rhythmic discharges of this population. We recorded (1) at the population level from the ventral collector nerve and (2) from single PGNs focally from the caudal ventral artery of the tail. 3. Following RaN stimulation we observed an excitatory response followed by a period of reduced discharge and subsequent rhythmical discharges seemingly phase-locked to the stimulus. 4. We suggest that the rhythmical discharges following the initial excitatory response (conventional reflex) result from a resetting of sympathetic rhythm generators such that rhythmic PGN activity is synchronized transiently. We also demonstrate that a natural mechanical stimulus can produce a similar pattern of response. 5. Our results support the idea that in sympathetic control, resetting of multiple oscillators driving the rhythmic discharges of a population of PGNs may provide a mechanism for producing a sustained and coordinated response to somatic input.

Published

2001

3. Multiple oscillators, dynamic synchronization and sympathetic control.

Author

Gilbey MP

Subjects

Animals, Arteries physiology, Rats, Respiratory Mechanics physiology, Tail blood supply, Tail physiology, Arteries innervation, Sympathetic Fibers, Postganglionic physiology

Abstract

1. Intermittent bursts of activity are a robust feature of the discharges of sympathetic nerves. There are at least two major mechanisms producing such discharges: (i) phasic inputs influencing sympathetic circuits; and (ii) oscillators embedded within sympathetic networks. The functional significance of patterned and synchronized activity underlying bursts of population activity may reside in their influence on information transfer between excitable cells. At the level of the single neuron, firing pattern appears to be an important determinant of synaptic/neuroeffector function (e.g. the probability of transmitter release, the types of transmitter released, the types of receptor activated and plasticity). Synchronization of inputs at a target favours summation and, therefore, may influence response (short term and long term). 2. In the present paper, I review the work from my laboratory that has focused on furthering understanding of the potential functional importance of pattern and synchrony coding in sympathetic nervous control of cardiovascular function. Because the rat tail artery has been used extensively as a model for studying neuroeffector transmission, in our investigations we have recorded from its sympathetic innervation. 3. In the anaesthetized preparation, under steady state conditions, we have established that the discharges of these sympathetic neurons have a distinct rhythm (frequency approximately 0.8 Hz). This can be detected both at single neuron and population levels. 4. A family of oscillators appears to control their discharge such that under some conditions all neurons do not have the same frequency of rhythmical activity. However, these weakly coupled or uncoupled oscillators can be synchronized dynamically by various inputs, such as central respiratory drive, lung inflation cycle-related inputs and inputs arising from visceral and somatic afferents. 5. The potential functional significance of dynamic synchronization of sympathetic oscillators in relation to sympathetic pattern generation and neuroeffector transmission is discussed.

Published

2001

4. Coherent rhythmic discharges in sympathetic nerves supplying thermoregulatory circulations in the rat.

Author

Smith JE and Gilbey MP

Subjects

Animals, Apnea blood, Apnea physiopathology, Blood Gas Analysis, Linear Models, Male, Membrane Potentials physiology, Neurons cytology, Periodicity, Phrenic Nerve physiology, Rats, Rats, Sprague-Dawley, Tail blood supply, Body Temperature Regulation physiology, Neurons physiology, Sympathetic Fibers, Postganglionic physiology, Tail innervation, Tail physiology

Abstract

1. In anaesthetised rats, activity recorded from sympathetic postganglionic neurones innervating the tail circulation has characteristic rhythmicity (0.4-1.2 Hz). At the population level this rhythmicity can be seen as a peak (T-peak) in autospectra of sympathetic activity recorded from ventral collector nerves (VCNs). 2. Here we investigated whether nerves supplying thermoregulatory circulations share common rhythmic discharges at T-peak frequency. Activity was recorded from nerve pairs consisting of left ventral collector nerve (LVCN) and one of the following: right ventral collector nerve (RVCN), left dorsal collector nerve (DCN), left saphenous nerve (SN) or left renal nerve (RN). 3. During central apnoea, T-peak frequencies in RVCN autospectra were similar to those of simultaneously recorded LVCN and these activities were coherent. Similar observations were made for nerve pairs involving LVCN-DCN and LVCN-SN. In contrast, autospectra of RN activity did not contain T-peaks. 4. In comparison to the peaks in autospectra of RN activity, when the frequency of rhythmic phrenic nerve activity was manipulated T-peaks in VCN, DCN and SN autospectra did not show obligatory 1:1 locking. 5. We conclude that T-peaks are a robust feature of autospectra of sympathetic discharges supplying thermoregulatory circulation but not those influencing the kidney. The high coherence demonstrated between the T-peak discharges is consistent with the view that common/coupled oscillators located within the CNS influence cutaneous vasoconstrictor sympathetic activity.

Published

2000

5. Rhythmic sympathetic discharges and 'escape behaviour'.

Author

Smith JE and Gilbey MP

Subjects

Animals, Male, Rats, Rats, Sprague-Dawley, Escape Reaction physiology, Periodicity, Sympathetic Fibers, Postganglionic physiology

Abstract

The characteristic rhythmical discharges of single postganglionic sympathetic neurones (PSNs) innervating the caudal ventral tail artery (CVA) of anaesthetised rats can still be recorded following the sectioning of afferents arising from the tail and hindquarters. Consequently, we suggest that such rhythmical discharges are neither a 'local sign' sympathetic response nor a sympathetic correlate of 'escape behaviour'., (Copyright 1998 Elsevier Science B.V.)

Published

1998

6. Focally recorded single sympathetic postganglionic neuronal activity supplying rat lateral tail vein.

Author

Johnson CD and Gilbey MP

Subjects

Anesthesia, General, Animals, Carbon Dioxide blood, Electrophysiology, Fever physiopathology, Male, Phrenic Nerve physiology, Rats, Rats, Sprague-Dawley, Respiration, Artificial, Respiratory Mechanics physiology, Vagotomy, Neurons physiology, Sympathetic Fibers, Postganglionic physiology, Tail blood supply, Tail innervation, Veins innervation

Abstract

1. In anaesthetized rats, using a focal recording technique, activity was recorded from single sympathetic postganglionic neurones innervating the lateral tail veins. On-going activity was examined in order to determine whether it had similar or different characteristics to those recorded from the caudal ventral artery in a previous study. 2. Animals were artificially ventilated, vagotomized, paralysed and given a pneumothorax. 3. The discharges of fourteen out of seventeen sympathetic postganglionic neurones were rhythmic. Such units had a mean firing frequency of 1.62 +/- 0. 70 Hz. The mean frequency of the dominant sympathetic rhythm under control conditions was 0.82 +/- 0.05 Hz. 4. The frequency of the dominant sympathetic rhythm was different from that of the phrenic rhythm in nine out of fourteen cases. 5. The mean frequency of the dominant sympathetic rhythm was: (i) not influenced significantly by hypocapnic apnoea, (ii) decreased by hyperthermia, which increased the frequency of the phrenic rhythm, (iii) in all cases different from that of the artificial ventilation cycle. 6. The above characteristics are similar to those recorded from the sympathetic supply to the caudal ventral artery of the same vascular bed under comparable conditions.

Published

1998