Role of catecholaminergic mechanisms in regulating the autogenic periodic motor activity of rat pups

In 1-, 2- to 3-, 7- to 8-, and 10-day old intact and spinal rat puppies, studies have been made of the effect of l-DOPA (100 mg/kg, intraperitoneally) on autogenic periodic motor activity in the gastrocnemius muscle. In 1- to 3-day old pups, strong stimulating effect was observed up to a prolonged continuous activity for 5-10 or even more minutes. This effect decreases with age. Traces of the inhibitory effect are observed at early stages in the form of total decrease of the activity. The inhibitory effect increases with age. In all spinal animals, at the background of a decreased activity, stimulating effect of l-DOPA was predominantly observed. Age peculiarities of the effect of l-DOPA are discussed in relation to ontogenetic development of catecholaminergic innervation in rats. It is suggested that stimulating effect of l-DOPA is associated with its action on the descending noradrenergic system, whereas the inhibitory one is mediated by the brain structures.     

The blood glucose content in newborn rats depending on level and pattern of spontaneous motor activity

Earlier we have shown that administration to newborn rats of the pentose phosphate cycle inhibitor hydroquinone leads to a change in intensity and pattern of spontaneous periodic motor activity (SPMA) characteristic of early stages of development. The most typical was the disappearance of the rest period from the near-minute “activity-rest” cycle and the appearance of uninterrupted motor activity. In several cases, especially after 10 days of development, there was noted an enhancement in the SMPA pattern of the motor activity complexes following in the decasecond rhythm. In this study, on the 3–10-day old rats maintained under conditions of free behavior there was studied the blood glucose content in the animals at various periods of the activity-rest cycle. Apart from the SPMA phase, its composition (pattern) characterizing the maturity level and functional state of spinal motor centers was taken into account. In the 3, 7 and 10-day old rats at the rest period, the glucose concentration was established to differ depending on the motor activity pattern. In the case of the decasecond periodicity, it amounts to 5.7 ± 0.2, 6.3 ± 0.3, and 7.5 ± 0.3 mmol/l, while at the minute one—6.1 ± 0.4, 7.8 ± 0.3, and 7.8 ± 0.1 mmol/l. At the moment of bursts of motor excitation, the glucose concentration falls to 5.2 ± 0.1, 6.1 ± 0.4, and 7.1 ± 0.3 mmol/l at the decasecond and to 5.4 ± 0.5, 6.7 ± 0.2, and 7.6 ± 0.3 mmol/l at the near-minute rhythm (for the 3-, 7-, and 10-day old animals, respectively). The results obtained on the 5-day rat pups differ qualitatively from those observed in other age groups. Thus, the glucose concentration at the rest period amounts to 6.8 ± 0.2 at the decasecond and to 6.7 ± 0.4 mmol/l at the nearminute periodicity. At the period of motor excitation accompanied by the presence of the decasecond activity rhythm, the glucose concentration falls to the level of 6.0 ± 0.2 mmol/l by differing statistically significantly from the observed one in the rest state. In the case of the appearance of the minute rhythm, the glucose concentration amounts to 5.8 ± 0.3 mmol/l. The obtained data indicate that reproduction of the minute and decasecond rhythms recorded in composition of SPMA is accompanied by a change in the blood serum glucose level. The degree of a decrease of its concentration correlates with a certain activity rhythm: at the decasecond one the fall is 9, 13, 3, and 7%, whereas at the minute rhythm—11, 13, 14, and 2% (for the 3-, 5-, 7- and 10-day old rats, respectively). It is to be noted that a certain effect on the activity pattern is produced by the degree of satiety of the rat pups, the gastric emptying being accompanied by an increase in expression of the decasecond rhythm and of brief jerks. Besides, there occur the significant seasonal oscillations of the blood serum glucose concentration in the newborn rat pups—at the summer period it is statistically significantly higher than at the winter—spring period.     

Interconnection between parameters of motor activity and blood glucose concentration in newborn rats at starvation and under glucose load conditions

The study is carried out on the one-, 3-, 5-, 7, and l0-day old free moving or loosely fixed rat pups (P1–10). In satiated and submitted to the 24-h starvation rat pups, parameters of spontaneous periodical motor activity (SPMA) and the blood glucose content were determined. The total glucose level in hungry rat pups was, on average, 1.5–2.5 times lower than in satiated animals. Administration of glucose to hungry rat pups increased 6–11 times its concentration in blood as compared with the animals not obtaining glucose. The glucose administration to the satiated rat pups led to a rise of its level in blood from 2 to 5 times as compared with intact animals, which was 2–3 times less than in the case of hungry animals. Analysis of pattern of motor activity recorded under conditions of the glucose deficit caused by the 24-h starvation of rat pups did not reveal significant changes of ratio of rhythmical components. Introduction of glucose to hungry and to the lesser degree to satiated rat pups led to potentiation of the minute rhythm of activity in all age groups. The exception was the first day after birth when the glucose administration to satiated rat pups promoted an enhancement of the decasecond rhythm and a decrease of the total level of motor activity. Comparison of ontogenetic dynamics of the SPMA parameters and the glucose content in blood of hungry rat pups revealed the clearly expressed regularity absent in the satiated animals: the glucose level in blood was higher during activity than in the state of rest. The performed study has shown that intensity, duration, and, to a degree, pattern of SPMA in the newborn rat pups depend on the level of satiety, and can be significantly changed in the artificially produced hypo- or hyperglycemia. The existing ontogenetic fluctuations in the character of reaction at performance of the glucose tolerance test can be connected both with morphofunctional maturation of the motor system and with immaturity of various chains of carbohydrate metabolism.     

The late prolonged motor discharges during stimulation of the segmentary afferents in rat pups: the effect of L-DOPA

In experiments on 5-30-day rat puppies, under slight urethane narcosis, studies have been made on the late prolonged discharges in extensor muscles evoked by stimulation of contralateral tibial nerve before and after injection of DOPA. Within the first 16 days, the drug completely abolished or significantly reduced late discharges, increasing the spontaneous motor activity. Beginning from the 16th day, periods of potentiation of late discharges were observed. The data obtained are discussed in relation to the development of mechanisms of control of the activity of spinal generators which are responsible for late discharges and spontaneous motor activity.     

Effect of hindbrain structures on autogenous periodic motor activity in the rat pup

Experiments were performed in order to investigate whether the capacity of periodic motor excitation in rats during early postnatal life is the intrinsic feature of immature spinal cord or it is caused by supraspinal input. It was shown that after low spinal cord transection, birsts of periodic activity can still be obtained in m. gastrocnemius but their duration and amplitude are significantly reduced. After brain stem transection at intercollicular level, this type of activity remains unchanged or slightly increased. It was concluded that periodic motor excitation is due to the spinal mechanisms but bulbo-spinal facilitative influences are necessary for normal intensity of autogenic activity.     

The role of the dopamine and noradrenaline systems in regulating autogenic motor activity in rat pups

In experiments on 3-day rat puppies, studies have been made of the effect of a stimulator of noradrenaline receptors--clonidine, and a stimulator of dopamine receptors--apomorphine on autogenic motor activity. It was shown that clonidine injections result in a significant increase of this activity, whereas apomorphine slightly decreases the latter. The data obtained in the present work together with those described earlier for l-DOPA effects, suggest that double regulation of autogenic activity is realized at early stages of ontogenesis. This regulation includes excitatory noradrenergic mechanisms and inhibitory influences which are mediated presumably by dopaminergic systems of the brain.     

Penicillin activates spontaneous motility in chick embryos

The development of the motor reaction to i.v. injection of the sodium salt of penicillin G in a dose of 0.9 x 10(6) I.U./kg egg weight was studied in chick embryos (normal and spinal) from the 11th to the 19th day of incubation. Penicillin first caused standard activation of embryonal motility from the 15th day of incubation, in both normal and spinal embryos. Activation was at first continuous in character (a twofold increase in the frequency of spontaneous movements). In 17- and particularly in 19-day embryos a typical paroxysmal reaction developed, with pronounced intervals of motor rest. The proportion of the spinal component in the penicillin reaction was abut 40% and of the supraspinal component about 60% of total motor activity. In older embryos (after the 15th day of incubation), the motor reaction to penicillin could be effectively modified by the systemic administration of glycine and GABA. It is concluded from the results that penicillin does not activate embryonal motor activity until a given stage of development of the CNS has been attained. It is a developmental phenomenon with a spinal and a supraspinal component, in which central inhibitory mechanisms participate.     

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.     

Development of spontaneous motility in chick embryos. Interaction of reserpine and apomorphine

The effect of apomorphine (1 mg/kg egg weight) on a base of the pre-administration of reserpine (2.5 mg/kg e.w.) 30 min or 2 or 4 hours previously was studied in chick embryos from the 13th to 19th day of incubation. Only the depressant effect of apomorphine was manifested in 13-day embryos. In 15-day embryos summation of the depressant effect of both drugs was recorded for the first time. In 17-day and especially 19-day embryos apomorphine raised the frequency of spontaneous movements high above the level of reserpine-induced depression of motor activity. This activating effect of apomorphine depended upon the supraspinal parts of the CNS, as it disappeared in 17-day embryos after decentralization of the spinal cord (particularly after chronic decapitation). We consider these findings to be further experimental evidence of the participation of catecholaminergic (in particular dopaminergic) central systems in supraspinal control of embryonic motor activity.     

The effect of L-DOPA on potentials of the dorsal surface of the spinal cord evoked by the stimulation of primary afferents in newborn rat pups

In experiments on 5-30-day rat puppies, studies have been made of the effect of L-DOPA (100 mg/kg, intraperitoneally) on the activity of interneurones of the dorsal horn of the spinal cord as revealed from the parameters of potentials of the dorsal surface of the spinal cord. The specific pattern of reaction in 5-day animals is manifested in a succession of inhibitory inhibition and increase in the activity of neurones monosynaptically activated by low-threshold afferents. Both the amplitude and duration of polysynaptic components of the potentials of the dorsal surface are rather high. From the 7th day, deep and stable inhibition is observed which is accompanied by a decrease in the amplitude of all components of the potential of the dorsal surface. At later stages of ontogenesis, a decrease is observed in the inhibitory effect of L-DOPA on the activity of interneurones which monosynaptically contact with low- and especially high-threshold afferents; in contrast to earlier stages, but similar to adult animals, evident inhibition was revealed in the activity of interneurones which have polysynaptic contacts with high-threshold afferents and afferents of flexor reflex. Thus, within the first weeks of postnatal life, basic qualitative changes are observed in the pattern of the reaction of interneurones of the dorsal horn to exogenic catecholamines.     

Change of Parameters of Functioning of the Cardiovascular and Respiratory Systems in Rats of Different Ages under Effects of Low Doses of the Cholinesterase Inhibitor Phosphacol

In the 4-day old rat pups and adult animals there were studied effects of subacute and acute phosphacol intoxication at the doses producing and not producing inhibition of aetylcholinesterase on ECG parameters and respiration rate. Analysis of the heart rhythm variability (HRV) was performed using an original program designed in the Labview media. The frequency diapason of cardiointervals was divided as follows: the high-frequency component (HF)-0.8-2.5 Hz, the low-frequency (LF, waves of the II order)-0.8-0.3 Hz; frequencies lower than 0.3 Hz-VLF (slow waves of the III order). Under the conditions of the subacute intoxication the heart rate frequency in the 4-day old and in adult rats increases by 36% and 13%, respectively, the respiration rate frequency increases by 73% in the newborn and does not change in adult rats. The VHR analysis indicates an increase of the tone of the parasympathetic nervous system. The level of the sympathetic activity somewhat increases in adults, but decreases in the 5-day old rat pups, which leads to an essential shift of the vagosympathetic balance towards predominance of parasympathetic influences. In adult rats, unlike the newborns, the role of the humoral-metabolic factors in regulation of the cardiac rhythm and vasomotor reactions increases significantly. Remarkably, the decrease of the nervous sympathetic effects in the rat pups leads to the positive chronotropic effect and stabilization of the cardiac rhythm. Acute phosphacol intoxication (doses of 0.25 and 1 µg/kg) is studied in the 4-day old rat pups. The low dose of the drug leads to development of a moderate bradycardia without disturbances of the cardiac rhythm. The high phosphacol dose produces pronounced bradycardia; on its background there develops a long-term transitory arrhythmia representing complexes of the heart rhythm, which alternate in the decasecond or nearminute rhythm and are separated by periodicity that is one order slower. We observed such rhythm earlier during activation of central N-cholinoreactive structures and development of bilateral pneumothorax. Results of the present study allow stating the paradoxical heart rhythm not as agonic, non-peculiar to the “living” organism, but as a special form of functioning of cardiac pacemakers due to disturbances of the heart regulatory mechanism.__________Translated from Zhurnal Evolyutsionnoi Biokhimii i Fiziologii, Vol. 41, No. 2, 2005, pp. 160–167.Original Russian Text Copyright © 2005 by Kuznetsov, Goncharov, Glashkina.     

Study of cardiac, respiratory, and motor activities in rat fetuses

Development of the cardiac, respiratory, and motor activities in rat fetuses with preserved placental circulation was studied at the 16th, 18th, and 20th gestation days. The presence of three main movement types has been found: complexes of generalized activity, local movements, and jerks. In development of respiratory function, there is observed a gradual transition from individual inspirations to series of breathing movements and then to formation of periodic breathing episodes. At the studied period, the heart rate has been found to increase. The existence of the slow-wave modulations of the heart rate with a period of 2040 s has been revealed. Analysis of interrelations between the respiratory and motor systems has shown that in the 16-day fetuses, each breathing movement is accompanied by extensor jerk. By the 20th days of embryonic development (E20), uncoupling of the respiratory and motor activities occurs. Comparison of the activity observed in the cardiac and somatomotor systems has shown that at E16, the cardiac rhythm fluctuations do not depend on the motor excitation jerks. In the 18-day fetuses, brief slowing down (decelerations) of the cardiac rhythm appeared during the motor activity jerks, whereas at E20, on the contrary, an increase of frequency (accelerations) of the cardiac rhythm occurred.     

Sensitivity of embryonic spontaneous motility to the GABA agonists baclofen and muscimol

The development of the sensitivity of spontaneous motor activity to the GABA agonists baclofen (10 mg/kg egg weight, systemic administration) and muscimol (0.8 mg/kg e.w., systemic administration) was tested in 11-day to 19-day-old chick embryos. 1) Baclofen already significantly depressed the frequency of spontaneous movements in 11-day embryos; its effect attained the maximum (85% depression of spontaneous motility) in 13-day embryos. After the 15th day of incubation, it reduced spontaneous motor activity by 50-60%. In spinal embryos, baclofen had the same, but a quantitatively more pronounced effect, demonstrated from its direct action on the spinal cord uninfluenced by supraspinal modulation, which began to be manifested after the 15th day of incubation. 2) Muscimol did not begin to inhibit spontaneous motility significantly until the 13th day of incubation. Subsequently, the latent period of its effect shortened, its duration lengthened and, lastly, its quantitative result also increased. 3) A comparison of the effect of GABA (Sedlácek 1978), muscimol and baclofen in 17-day chick embryos showed that the depressive effect increased in the sequence baclofen less than GABA less than muscimol, but that GABA took effect faster than the others. The results testify that the maturation of the individual elements of the GABA-ergic central inhibition system is a complex process.     

Role of L-DOPA in spinal nociceptive reflex activity: higher sensitivity of Aδ versus C fibre-evoked nociceptive reflexes to L-DOPA

The role of L-DOPA in spinal nociceptive reflex activity has been re-evaluated. In high spinal cats, with supraspinal loops being excluded, the onset of reflex facilitation induced by noxious radiant heat is delayed after injection of L-DOPA by 4 to 10 s, i.e. the early component of nociceptive reflex facilitation is blocked, while the late component persisted. Further investigations have shown that the early component of reflex facilitation induced by noxious radiant heat is mediated by Adelta-fibres and the late component by C-fibres. Therefore, it can be assumed that L-DOPA, like opioids, preferentially blocks the transmission in nociceptive reflex pathways from Adelta-fibres.     

The acute and the chronic effects of imipramine on the spontaneous motility in chick embryos

The effect of imipramine on the spontaneous motility and development of chick embryos was studied from the 4th to the 19th day of incubation. On acute administration (a single dose of 12.5 of 25 mg/kg egg weight), imipramine already induced significant depression of spontaneous motility in 11-day embryos--an effect which increased significantly after the 15th day of incubation. The similar effect of imipramine in spinal embryos testifies to its direct action on the spinal cord and draws attention to certain details of the role of supraspinal structures of the CNS in the acute effect of imipramine. The chronic administration of imipramine showed that it had an almost 100% lethal effect from 4th to the 7th day of incubation. Between the 8th and the 10th day it caused longlasting depression of spontaneous motility. When it was administered between the 11th and 16th day of incubation, no significant effect on the development of spontaneous motor activity was found in chick embryos.     

Electrophysiological Properties of Motor Neurons in a Mouse Model of Severe Spinal Muscular Atrophy: In Vitro versus In Vivo Development

We examined the electrophysiological activity of motor neurons from the mouse model of severe spinal muscular atrophy (SMA) using two different methods: whole cell patch clamp of neurons cultured from day 13 embryos; and multi-electrode recording of ventral horns in spinal cord slices from pups on post-natal days 5 and 6. We used the MED64 multi-electrode array to record electrophysiological activity from motor neurons in slices from the lumbar spinal cord of SMA pups and their unaffected littermates. Recording simultaneously from up to 32 sites across the ventral horn, we observed a significant decrease in the number of active neurons in 5–6 day-old SMA pups compared to littermates. Ventral horn activity in control pups is significantly activated by serotonin and depressed by GABA, while these agents had much less effect on SMA slices. In contrast to the large differences observed in spinal cord, neurons cultured from SMA embryos for up to 21 days showed no significant differences in electrophysiological activity compared to littermates. No differences were observed in membrane potential, frequency of spiking and synaptic activity in cells from SMA embryos compared to controls. In addition, we observed no difference in cell survival between cells from SMA embryos and their unaffected littermates. Our results represent the first report on the electrophysiology of SMN-deficient motor neurons, and suggest that motor neuron development in vitro follows a different path than in vivo development, a path in which loss of SMN expression has little effect on motor neuron function and survival.     

Motor Disturbances in Offspring of Female Ambidexter Rats with Psychogenic Trauma

The vital stress experienced by mothers both during and before their pregnancy produced motor disturbances in their offspring. By parameters of the EMG activity of the low extremities, more pronounced motor disturbances are revealed in the young 35-day old rat pups whose mothers were exposed to the acute psychogenic trauma during pregnancy. Asymmetry of the motor disturbances is the most prominent in the 45-day old rat pups born from the mothers exposed to the psychogenic trauma one month before pregnancy. In the process of ontogenetic development the revealed deviations are better compensated in the rat pups of the “neonatal stress” group than in the case of their mothers' preconception psychogenic trauma.     

Thyrotropin-Releasing Hormone Enhances Choline Acetyltransferase and Creatine Kinase in Cultured Spinal Ventral Horn Neurons

The effect of 0.1 mM thyrotropin-releasing hormone (TRH) on ventral horn neurons was investigated in eight experimental sets of tissue cultures established from ventral and dorsal portions of spinal cords of 13-15-day rat embryos. Cultures were treated with TRH from day 1 for 2-5 weeks. TRH-treated ventral spinal cord cultures (VSCC), compared with control VSCC, had more numerous and more healthy-appearing neurons and thicker bundles of long cell processes. In TRH-treated VSCC, choline acetyltransferase (ChAT) activity was greater than 16 times (p less than 0.005) and creatine kinase greater than 3 times (p less than 0.005) that of control VSCC. Morphologic and biochemical parameters of dorsal spinal cord cultures remained unchanged by TRH treatment. Since lower motor neurons are numerous in the ventral spinal cord (and not present in the dorsal cord) and since lower motor neurons are the major ChAT-containing spinal cord cells, our data demonstrating a beneficial effect of TRH on VSCC suggest a tropic effect of TRH on lower motor neurons.     

Sex-dependent differences in parameters of long-term pain caused by inflammatory focus in prenatally stressed newborn rats

In experiments on the 7-day old female and male Long-Evans rat pups, for the first time, there was studied effect of prenatal (immobilization) stress on dynamics of nociceptive behavioral response caused by an inflammatory focus. The nociceptive sensitivity was evaluated for 1 h by the number of the flexion-shaking patterns organized at the spinal level in response to injection of formalin (10%, 10 μl) to the posterior leg sole. Control rat pups were not submitted to any prenatal stress; in these animals the response in the formalin test was found to be represented by one phase. It the prenatally stressed rat pups the studied patterns were organized into two phases characteristic of the definitive type of response. At the period between them (during interphase), the nociceptive behavior was absent. At the second, tonic phase the number of flexion-shakings in the prenatally stressed males was statistically significantly higher than in the prenatally stressed females, which indicates a sensitization of the neurons involved in the tonic pain chains in male individuals. Thus, the data obtained on prenatally stressed animals confirm the previous data about immaturity of the mechanisms mediating the second phase of response in the formalin test in the 7-day old rat pups. An important fact is revealed which indicates that in the prenatally stressed rat pups of the same age the second phase of response is already obvious. Mechanisms underlying the behavioral response caused by the inflammatory focus in the formalin test in the one-week old stressed rat pups are characterized by sexual dimorphism: the pain sensitivity in males at the second phase of response is statistically significantly higher than in females.     

Evidence for a supraspinal analgesic effect with cyclazocine and pentazocine

The antinociceptive effect of the benzomorphan class of opioid analgesics have been difficult to measure utilizing some of the standard animal pain models. This may be due, in part, to the sedative and/or motor effects associated with these drugs. In addition, it has been proposed that the major site of action for drugs with agonist activity at the kappa opiate receptor is exclusively at the spinal level opposed to both spinal and supraspinal as with the mu receptor agonists such as morphine. The present study examines the antinociceptive effect of the mixed agonist-antagonists cyclazocine and pentazocine utilizing electrical stimulation of the midbrain reticular formation (MRF) as the aversive stimulus in the rat. Animals were trained to escape MRF stimulation by turning a cylindrical manipulandum. An escape threshold was determined by varying the current intensity according to a modification of the psychophysical method of limits. In addition to the determination of the escape threshold the response latency and strength of response was also measured. Both cyclazocine (0.25-1.0 mg/kg) and pentazocine (2.5-12.5 mg/kg) raised the escape threshold in a dose-dependent manner without any concomitant change in the response latency or strength of response. These data suggest that the observed threshold elevation is due to a specific antinociceptive effect. Since the aversive stimulation was delivered supraspinally, the data also suggest that there are supraspinal mechanisms mediated by kappa receptors responsible for this analgesic effect.