Synchronization of activity of rhythm-forming neurons in the respiratory center

The method of determination of the basic parameter of the mathematical model of respiratory centre using temporal characteristics of respiratory neurons has been suggested. The model's behaviour depending on the meaning of this parameter and possibility of respiratory neuron's activity sinchronization have been investigated. The influence of feedback shorting on the mechanico-receptor outline on this process has been described.     

Morphological and functional characteristics of the inspiratory and expiratory formations of the medial and lateral areas of the respiratory center

The density of the reticular and respiratory neurones in the inspiratory and the exspiratory "points" of medial and lateral zones of the medulla oblongata the electrical stimulation of which is accompanied by the maximum inspiratory and exspiratory effects has been studied in the anesthetized cats. The electrophysiological and morphological data allow to relate the structures studied to the respiratory centre and confirm the correct picking out of two functionally heterogeneous zones - the medial and lateral.     

Significance of the corpus callosum in the paired activity of the respiratory center

The asymmetrical reactions of respiratory neurons of the right and left halves of the respiratory center and varied changes in bioelectrical activity of external intercostal muscles on both sides of the chest were discovered in experiments on anesthetized cats in response to successive electrical stimulation of the symmetrical cortical areas of the right and left cerebral hemispheres before and after callosotomy. It was demonstrated that callosotomy increased on both sides of the respiratory center the quantity of neurons responsive to ipsilateral cortical stimulation and determined the character of the asymmetrical reactions of right and left respiratory neurons and intercostal muscles. On the basis of the data obtained it is concluded that the corpus callosum contributes to the functional integration of both halves of the respiratory center.     

Effect of a polarizing current on unit activity in the respiratory center

Single unit activity in the respiratory center in the medulla was recorded in rabbits anesthetized with urethane. The neurons were polarized through the extracellular recording microelectrode by currents of different strength and polarity. In most cases a current in the positive direction (+ to the electrode tip) increased, while a negative current decreased, the firing rate. Most indices of the firing pattern of the respiratory neurons were changed by the action of the polarizing current. The coefficient of phase shift between the pneumogram and unit activity, determined by calculating the cross-correlation function between these two processes, was the most stable index. Since it takes into account the temporal and frequency characteristics of volley activity of the respiratory neurons, this coefficient can serve as a basis for their classification. The dynamics of respiratory neuronal function under subthreshold conditions was revealed by the polarization method. It was shown, in particular, that the shape of the variable component of respiratory unit activity is close to sinusoidal and differs from that suggested by the hypothesis of reciprocal interaction between two groups of neurons.Rostov State University, Rostov-on-Don. Translated from Neirofiziologiya, Vol. 4, No. 3, pp. 280–285, May–June, 1972.     

Electromyographic activity of expiratory muscles in the rat

We examined the participation of expiratory muscles on breathing in the rat. The experiments were performed on 16 male rats in halothane [1.5%] or urethane [1.3 g/kg i.p.] anaesthesia. We recorded the electromyographic [EMG] activity of intercostal and abdominal muscles with a concentric needle electrode during quiet breathing, breathing against increased pressure in the airways and during the expiration reflex. In halothane anaesthesia the EMG expiratory phasic activity was observed only in internal intercostal muscles in 40% of spots examined during quiet breathing and in 58.5% when breathing against increased pressure. The EMG activity during the expiratory reflex was difficult to evaluate. In the abdominal muscles permanent EMG activity was found in 66% of trials. In urethane anaesthesia no phasic expiratory EMG activity was observed in intercostal or abdominal muscles. In abdominal muscles in 9% of trials a permanent activity was found.     

Effects of basolateral amygdalar nuclei on neuronal activity in the medullary respiratory center under hypoxia conditions

The effect of stimulation of the basolateral nuclei of the amygdala (ABL) on the impulse activity of respiratory neurons (RNs) of the rat medulla and the respiratory function was studied in the norm and under conditions of oxygen deficiency. Electrical stimulation of the ABL under conditions of normal atmospheric pressure exerted ambivalent effects on bulbar RNs; both activation and inhibition of these neurons were observed, but inhibitory effects noticeably prevailed. Electrical stimulation of the ABL within an initial phase of hypobaric hypoxia corresponding to ascent to a 4,000 to 5,000 m altitude exerted mostly inhibitory effects on the RN activity (similarly to what was observed under normoxia conditions). Stimulation of these nuclei within a phase of intensive hypoxia (7,500 to 8,000 m) evoked no typical responses of such neurons against the background of hypoxic suppression of their activities. Neirofiziologiya/Neurophysiology, Vol. 38, No. 4, pp. 292–297, July–August, 2006.     

Mechanoreceptor system of the respiratory center and its contribution to respiratory control

The mechanoreceptor system of the respiratory center (RC) includes airway mechanoreceptors together with their conducting pathways and bulbar neuronal structures conveying impulses from mechanoreceptors to the RCV.A. A. Bogomolets Institute of Physiology, Ukrainian Academy of Sciences, Kiev. Translated from Neirofiziologiya, Vol. 24, No. 4, pp. 351–368, May–June, 1992.     

Structural and functional organization of the respiratory center

The main experimental data on the organization of the respiratory center accumulated during the past 200 years are summarized. It is emphasized that the existence of separate, reciprocally interrelated, inspiratory and expiratory centers has never been proved. The notion of multiple respiratory centers in the CNS, including pneumotaxic, apneustic, gasping, and deep-exhalation centers, which allegedly underlie the multiple forms of respiratory movements, is demonstrated to be unjustified. Upon systemic consideration, the evidence in favor of the decisive role of neurons of the pre-Bötzinger complex and preinspiratory neurons in initiating the respiratory rhythm and maintaining rhythm generation in the respiratory center is contradictory and unconvincing. It is assumed that the respiratory center located in the medullary region of the brain of intact animals and humans fulfills the main functions of endogenous self-sustained generation of the respiratory rhythm, chemoregulation, and mechanoregulation in the respiratory system in an integrated manner, according to the general requirements of the body at a given moment.