Impulse activity of the bulbar cardiovascular neurons during myocardial ischemia and stimulation of the cortical sensorimotor zone

In acute experiments on cats performed under nembutal anesthesia the stimulation of sensorimotor zone in cerebral hemisphere cortex changed the impulse activity of interneurons of bulbar cardiovascular centre and not of the afferent neurons. The analysis of the activity of afferent neurons and interneurons has shown a decrease in coordination between the reaction of these cells to the development of ischemic myocardial lesions during the cortex stimulation. In these conditions bulbar cardiovascular neurons could both increase and decrease the impulse activity. These changes seem to be the reason for the growing incidence of idioventricular ischemic arrhythmias during cortical stimulation.     

Participation of the cardiovascular neurons of the bulbar cardiovascular center in the adaptive reactions of the circulatory system during changes in the composition of inspired air

The experiments performed on rabbits have shown that with the inhalation of various gas mixtures the impulse activity of cardiovascular neurons in bulbar cardiovascular centre is changed. The most active are inserted cardiovascular neurons that are highly sensitive to O2 shortage and CO2 excess. It is believed that the experiments on Hering nerve severing indicate the possible development of reflex effects on hemodynamics during changes in inhaled gas composition produced from sinocarotid reflexogenic zone not only through bulbar respiratory neurons, but also through a system of inserted neurons of bulbar cardiovascular centre.     

Hemodynamic changes in post-suspension rats during gradual hemorrhage

We examined the changes of hemodynamic parameters in nembutal-anesthetized rats during gradual hemorrhage (2 ml/100 g body weight during 30 min). In control rats blood pressure began to decline starting from 3rd min of bleeding and from 5th min it was accompanied by cardiac deceleration. Hindlimb vascular resistance was only slightly increased up to 15th min (by 20-30%) and then began to grow drastically. Less prominent changes of hemodynamics were observed in post-suspension rats. The results indicate that when activity of sympathetic nervous system is blunted with anesthetic post-suspension rats demonstrate higher hemodynamic stability during acute hemorrhage.     

Analysis of the effects of electrical stimulation of certain limbic structures

It has been established that stimulation of the structures of the limbic system (hippocampus, amygdaloid complex, septum) and the medial nucleic of the thalamus of rabbits in conditions of free behavior elicits four basic types of behavioral reactions: arousal, orientation-investigatory, aggressive-defensive and various epileptiform (convulsive) reactions. Activation of behavior, i.e., arousal and the orientation-investigatory reaction, constantly appear on stimulation of the unspecific thalamic nuclei. The aggressive-defense reaction is elicited by stimulating the nuclei of the amygdaloid complex of the ventral part of the hippocampus and the ventromedial nuclei of the thalamus. The epileptiform reactions are most readily reproduced on stimulation of the amygdaloid complex and the ventral part of the hippocampus. The threshold for the appearance of discharges of the aftereffect is very low. The latter are more sustained on stimulation of the basolateral part of the amygdala and the ventral part of the hippocampus. In rabbits as compared with higher animals the discharges on stimulation rapidly spread not only to the limbic system but also to the reticular formation and the neocortex.Kharkov Medical Institute. Translated from Neirofiziologiya, Vol. 1, No. 2, pp. 194–201, September–October, 1969.     

Biomechanics of human quadriceps muscles during electrical stimulation

The quadriceps muscles of neurologically intact and spinal cord injured (SCI) human subjects were stimulated with constant current pulses. Up to three, separately adjustable stimulating electrodes over the motor points for vastus medialis (VM), vastus lateralis (VL) and rectus femoris (RF) muscles were used to maximize torque generation while minimizing discomfort. The torque generated by stimulation increased as the knee was slowly flexed to about 1 rad (50-60 degrees) and decreased beyond that point (a 'negative slope' on a torque-angle curve). Despite this region of negative slope the force generated by small oscillations remained positively correlated to the angle changes. When the knee was slowly extended again from a flexed position, the torque continued to decline and therefore showed a large degree of 'hysteresis'. Of the three heads studied, only stimulation of RF muscle generally produced this behavior. VL and VM had torques that increased monotonically with knee flexion over the range studied. The torques generated with electrical stimulation of normal subjects represented up to about 30% of maximum voluntary contraction. When subjects generated similar torques voluntarily, the negative slope region and substantial hysteresis were not observed. Thus, SCI subjects may be adversely affected by hysteresis during electrically-induced transitions from sitting to standing and vice versa, while normal subjects are not.     

Mathematical models for fatigue minimization during functional electrical stimulation

We previously reported the development of a force- and fatigue-model system that predicted accurately forces during repetitive fatiguing activation of human skeletal muscles using brief duration (six-pulse) stimulation trains. The model system was tested in the present study using force responses produced by longer duration stimulation trains, containing up to 50 pulses. Our results showed that our model successfully predicted the peak forces produced when the muscle was repetitively activated with stimulation trains of frequencies ranging from 20 to 40 Hz, train durations ranging from 0.5 to 1 s, and varied pulse patterns. The predicted peak forces throughout each protocol matched the experimental peak forces with r² values above 0.9 and predicted successfully the forces at the end of each protocol with <15% error for all protocols tested. The success of our model system further supports its potential use for the design of optimal stimulation patterns for individual users during functional electrical stimulation.     

Epinephrine infusion enhances muscle glycogenolysis during prolonged electrical stimulation

To determine the effects of epinephrine (EPI) infusion on muscle glycogenolysis and force production, the quadriceps muscles of both legs in six subjects were intermittently stimulated for 30 min. Contractions lasted 1.6 s (20 Hz) and were separated by 1.6 s of rest. EPI was infused (approximately 0.14 micrograms.kg body wt-1.min-1) in one leg during the last 15 min and the vastus lateralis was biopsied at rest (control leg only) and after 15, 18 (EPI leg only), and 30 min of stimulation. EPI infusion doubled the mole fraction of phosphorylase a (22.5 +/- 4.1 to 44.8 +/- 9.0%) and glycogenolysis (2.16 +/- 0.72 to 5.45 +/- 0.81 mmol glucosyl U.kg dry muscle wt-1.min-1) during stimulation. Muscle glucose 6-phosphate increased from 3.04 +/- 0.17 to 6.43 +/- 0.20 mmol/kg dry muscle wt, and lactate increased from 25.8 +/- 4.4 to 34.3 +/- 4.6 mmol/kg after 3 min of EPI infusion. Isometric force production was unaltered by EPI infusion. These results demonstrate a strong glycogenolytic effect of EPI infusion during prolonged electrical stimulation and suggest that the extra pyruvate formed was converted mainly to lactate. Exclusive anaerobic metabolism of the extra substrate would provide only a 10% increase in total ATP production, possibly accounting for the lack of improvement in force production. We suggest that the decrease in force production during prolonged electrical stimulation is related to decreased excitation of the contractile mechanism rather than inhibition of cross-bridge turnover caused by a shortage of energy or accumulation of hyproducts.     

The capacitive function of the spleen during electrical stimulation of the structures of the ventral section of the medulla oblongata

In acute experiments on cats under perfusion with constant blood expenditure of hemodynamically isolated spleen the authors studied the reactions of its vessels in the electrical stimulation of ventral brainstem. It was shown that the stimulation of the rostral zone of these structures increased vein outflow from the spleen. It was shown the deterioration of the parametres which characterize a capacitance function of the spleen by stimulation of a causal depressor zone of the brainstem by means of the current of threshold size and its increase by irritation of the brain structures with a 2 threshold current size. There have been made a supposition has been made about the participation of the pointed structures of the brain in the regulation of a vasomotion tonus of the spleen vessels.     

Behavioural and cardiovascular responses to electrical stimulation of the medulla oblongata of the cat

Effects of stimulation of the nucleus tractus solitarii, the dorsal motor nucleus of the vagus, the nucleus reticularis paramedianus, and the nucleus cuneatus were studied in free-moving cats. Stimulation of the medullary nuclei that are known to be involved in the central nervous control of cardiovascular functions might activate preprogrammed motor responses such as licking and sniffing, and induce complex behavioural response patterns such as sleep or flight reaction. Moreover, both lever-pressing for rewarding brain stimulation, and eating in food deprived cats might be modulated by these stimulations. In a shuttle box the cats showed no tendency toward shuttling during stimulation, except the stimulation of the nucleus reticularis paramedianus which produced aversion. The cardiovascular and respiratory effects varied parallel with the behavioural responses. It is concluded that the medullary nuclei related to visceral functions are capable of affecting somatomotor behaviour either directly on the motor system, or by inducing complex response patterns in which somatomotor and visceral responses are integrated.     

Altered excitability of rat cutaneous mechanoreceptors during transcranial electrical stimulation

Functional aspects of high, medium, and low threshold mechanoreceptor units were investigated in acute experiments under hexanol-induced anesthesia during transcranial electrical stimulation (TES). It was found that low and medium threshold receptor units ceased responding to mechanical stimulation 1 and 5 min respectively after the start of TES. Firing ended by 18–20 min of TES in high threshold units responding to mechanical stimuli produced by a needle. No significant alteration in parameters of response were produced by TES after prior i.p. or intracutaneous injection of naloxone. Potential mechanisms of TES action are discussed. It is suggested that changes produced in the function of cutaneous mechanoreceptors by TES may be put down to endogenous opioids acting on the receptors.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 22, No. 4, pp. 495–500, July–August, 1990.     

Serotonin-mediated cardiovascular responses to electrical stimulation of the raphe nuclei in the rat.

The dorsal and median raphe nuclei in rats were electrically stimulated and blood pressure and heart rate were recorded. Stimulation of each raphe nucleus caused an increase in blood pressure without affecting heart rate. The size of the increase in blood pressure depended upon the stimulus-intensity.Significant increases were already obtained with 5 sec. trains of 0.3 msec., 200 μA stimuli given at a frequency of 50 Hz. The increases in blood pressure could be obtained with electrodes within the raphe nuclei.Pretreating rats with para-chlorophenylalanine (pCPA, 100 mg/kg.day for 3 days) significantly diminished the increases in blood pressure obtained during electrical stimulation of the median raphe nucleus. However, similar pretreatment did not affect blood pressure rises induced by dorsal raphe stimulation.These data are discussed in relation to the role of central serotoninergic mechanisms in cardiovascular control.