Interrelations of the Autogenic Somatomotor Excitation of the Cardiac Activity in Developing Rats

In developing rats aged from newborns to 1.5 months, regularities were studied of the heart rate fluctuations associated with periodic bursts of the endogenous somatomotor excitation characteristic of early stages of postnatal ontogenesis of immature born animals. It has been established that decelerations predominate on the background of the motor bursts for the first week of life, whereas accelerations, since the beginning of the 3rd week. The heart rhythm changes can precede or lag behind the beginning of the motor excitation, which allows judging about the existence of two mechanisms of the interaction: about the heart reaction to motor activity and about the central drivers acting simultaneously on the both systems. Experiments with chronic desympathization and block of -adrenoreceptors indicate a participation of the sympathetic nervous system in formation of the motor-cardiac interaction.     

Cardiac,respiratory, and motor activity in norm and after activation of catecholaminergic systems in newborn rat pups

Study of parameters of the cardiac, respiratory, and motor activity (MA) was carried out on newborn rat pups for the first day after birth (P0) and at the 14th day of postnatal development (P14) after change of the activity levels of dopaminergic and noradrenergic systems. To provide an excessive level of catecholamines, the animals were administered individually with L-DOPA (25–100 mg/kg) and with the indirect adrenomimetic isoamine (3 and 10 mg/kg). Additionally there were studied effects of L-DOPA and isoamine after blockade of D1 and D2 dopamine receptors (antagonists SCH-23390 and sulpirid). The L-DOPA administration produced a dose-dependent MA enhancement with its subsequent possible conversion into the continuous generalized activity. At P0 the release of monoamines was accompanied by development of weak bradycardia. There was noted a tendency for acceleration of respiration at administration of the low dose both of L-DOPA and of isoamine and for its deceleration at high doses. At P14 the L-DOPA administration was accompanied by deceleration of the heart rate (HR) by 8% and by acceleration of respiration rate (RR) by 26%. The isoamine administration produced an insignificant decrease of HR and an increase of RR by 8% at the low dose and by 21% at the high dose of the agent. At the blockade of D1 receptors, RR remained close to the background values, while at the blockade of D2 receptors it decreased insignificantly. Blockade of D1 and D2 receptors did not cause significant HR changes. Analysis of the HR variability has shown that both after L-DOPA administration and at blockade of dopamine receptors no unidirectional reaction was observed: in 80% of rat pups the portion of nerve mechanisms of HR regulation increased, while in the rest-of sympathetic and humoral factors at a decrease of parasympathetic effects. In all rat pups the isoamine administration was accompanied by a shift of the specter power into the higher frequency area; in 60% of the animals there were enhanced sympathetic effects. At P14 in rat pups after administration both of L-DOPA and of isoamine, the sympathetic nervous effects were predominant. Thus, at P0 both at release of endogenous catecholamines and at their excessive concentration in rat pups there occurs a qualitative change of character of the catecholaminergic effects on functional activity of excitable structures, particularly of those connected with regulation of respiration.     

Secondary Rhythms of Cardiac Activity in Rat Ontogeny

Endogenous periodic oscillations of the heart beat rate are described in rat pups aged 3–4, 7–8, 10–11, 13–14, 21–22 days and 1.5 month after birth. These oscillations have all characteristic features established earlier for the secondary rhythms of endogenous contractile activity in the wall of various regions of the gastrointestinal tract and for bursts of spontaneous somatomotor excitation in the early postnatal ontogeny of rats: a multi-stage organization, inconstancy, irregularity of components. In frequency spectra of secondary oscillations of the heart rate obtained by means of fast Fourier transform of R–R intervals of the periodogram, age-related changes of the spectral frequency power are demonstrated in 4 ranges, 0.01–0.03, 0.03–0.1, 0.1–1.0, and 1.0–2.5 Hz, which correspond to the about-one-minute, decasecond, and about-one-second waves of the heart rhythm oscillations and to sinus arrhythmia. It is shown that the dominating frequencies of the secondary rhythms in each range do not have regular age-related changes, which is characteristic of all endogenous secondary rhythms.     

Effect of change in levels of motor activity and innervation on basic and secondary rhythms of rat heart beatings and respiration in ontogenesis

Changes in the heart basic rhythm, its rhythmical variations on periodograms, and level of spontaneous motor activity were studied on offspring of white rats from newborn to 3-week age at transition from the state of active wakefulness to narcosis as well as under conditions of blockade of M-cholinoreceptors with atropine. It is shown that the endogenous rhythmical activity can be regulated not only by a change in frequency of basic rhythms, but also by action on all parameters and properties of their rhythmical variations and secondary rhythms. The changes in power of the heart secondary rhythms exceed considerably the frequency oscillations of basic rhythms during blockade of cholinergic innervation or a change in the motor activity level that affects both the basic rhythm circulation and respiration and their variations—secondary rhythms. The atropine blockade of M-cholinoreceptors at the studied ages changes the heart contraction rhythm within the limits of 10% of bradycardia in newborns to tachycardia in the 3-week old animals. At the same time, power of the cardiac rhythm secondary oscillations changes several times. These data indicate that the cholinergic mechanisms play the key role in formation of the secondary rhythms and their correlation with motor activity.     

Effect of change in levels of motor activity and innervation on basic and secondary rhythms of rat heart rate and respiration in ontogenesis

Changes in the heart basic rhythm, its rhythmical variations on periodograms, and level of spontaneos motor activity were studied on offspring of white rats from newborn to 3-week age at transition from the state of active wakefulness to narcosis as well as under conditions of blockade of M-cholinoreceptors with atropine. It is shown that the endogenous rhythmical activity can be regulated not only by a change in frequency of basic rhythms, but also by action on all parameters and properties of their rhythmical variations and secondary rhythms. The changes in power of the heart secondary rhythms exceed considerably the frequency oscillations of basic rhythms during blockade of cholinergic innervation or a change in the motor activity level that affects both the basic rhythm circulation and respiration and their variations--secondary rhythms. The atropine blockade of M-cholinoreceptors at the studied ages changes the heart beating rhythm within the limits of 10% of bradicardia in newborns to tachycardia in the 3-week old animals. At the same time, power of the cardiac rhythm secondary oscillations changes several times. These data indicate that the cholinergic mechanisms play the key role in formation of the secondary rhythms and their correlation with motor activity.     

Role of sympathetic and parasympathetic mechanisms in formation of secondary cardiac rhythms in rats ontogenesis

In progeny of Wistar rats aged from birth to 3 week, there was studied participation of sympathetic and parasympathetic mechanisms in regulation of cardiac rhythm and its rhythmic oscillations (secondary cardiac rhythms), whose spectral composition was analyzed using rapid Fourier transformation. Consequences, which changed in the process of development, of blockade of -adrenoreceptors by propranolol, of -adrenoreceptors by phentolamine, and of muscarinic cholinoreceptors by atropine as well as of chronic desympathization by guanethidine (isobarine). It was found that due to heterochronia in establishment of functions of sympathetic and parasympathetic nervous systems, reactions to blockade of adreno- and cholinoreceptors for the first 3 weeks of postnatal ontogenesis changed not only quantitatively, but also qualitatively. Blockade of adrenoreceptors in newborn animals leads to an increase of power of the rhythm oscillations in all low-frequency diapasons. The baroreflex function of parasympathetic innervation is well expressed as early as in newborns. Tonic function with respect to frequency of heart rate and power of oscillations in the high-frequency diapason becomes evident only by the 3-week age.Translated from Zhurnal Evolyutsionnoi Biokhimii i Fiziologii, Vol. 41, No. 1, 2005, pp. 69–75.Original Russian Text Copyright © 2005 by Bursian, Sizonov, Semenova, Kulaev, Timofeeva, Polyakova, Dmitrieva.     

Action of novocain on cardiac and somatomotor autorhythmical functions in early postnatal ontogenesis in rats

In conscious rat pups aged 2–3, 10–11, and 22–23 postnatal days, it has been shown that intraperitoneal administration of 0.5% Novocain at a dose of 25 mg/kg body mass leads to phasic changes of the level of spontaneous periodic motor activity—from increased at once after the administration to depression and subsequent restoration. They are accompanied by the cardiac rhythm fluctuations that change with age their direction on the background of an increased motor activity from brady to tachycardia. All the changes are the most pronounced in newborns. At comparison of the results with the afferent impulsation level fluctuations recorded under the same conditions in the peripheral vagus segment, it is suggested that the revealed reactions are associated with changes of the interoceptive afferentation flow. The conclusion is made that at early stages of ontogenesis, interoception plays an important role in regulation of autorhythmical functions and that this role decreases with age.