Effects of baroreceptor activation on spontaneous activity in the sweat glands and nictitating membrane of the cat

Functional morphology of the nictitating membrane in the domestic cat

Morphological differences between the corneal and palpebral surfaces of the nictitating membrane of the domestic cat were examined using histology, histochemistry and the scanning electron microscope. Both surfaces are covered by one or two layers of epithelial cells. The epithelium contains numerous goblet cells, particularly on the palpebral side. These cells revealed binding sites for six lectins as well as positive PAS reactivity, and alcianophilia at both pH 2.5 and pH 3.5. Numerous lymph follicles located on the corneal side make the epithelium look like lymphoepithelial tissue. Accumulations of lymphatic tissue may also be found on the palpebral side. Scanning electron micrographs showed microvilli on the epithelial surfaces. The function of the cat nictitating membrane is discussed on the basis of our findings and those of other authors. Movements of the nictitating membrane alternate between active and passive phases of gliding. The membrane as a whole effectively protects the nasal portion of the bulb from dust, dehydration and pathogens.

Evidence for two distinct sympathoinhibitory bulbo-spinal systems

Yohimbine hydrochloride (0.5 mg/kg, i.v.) caused a long-lasting potentiation of electrodermal (sympathetic-cholinergic) reflexes in intact anaesthetized and decerebrate unanaesthetized cats. Transection of the cervical spinal cord also resulted in an increased amplitude of the sudomotor reflex in unanaesthetized decerebrate preparations. Depletion of monoamines in the CNS by pretreatment with reserpine (5 mg/kg, i.p.) and alpha-methyl-p-tyrosine (2 X 300 mg/kg, i.p.) reduced the concentrations of norepinephrine, dopamine and serotonin to less than 93% of control levels in the thoracic spinal cord. In monoamine-depleted preparations, yohimbine no longer facilitated the reflex amplitude whereas the effect of spinal transection was not altered. These results suggest that there are two distinct sympathoinhibitory systems in the lower brain stem that converge on spinal sympathetic neurons, one of which is monoaminergic and one of which is not. Evidence for the baroreceptor-independent nature of these descending inhibitory systems is discussed.

Phase relations between carotid pressure and ongoing electrocortical activity

The behavioral significance of changes in the cardiovascular system has been a major source of controversy in psychophysiology. In view of this, it is surprising that so few studies have examined the relationship between cardiac events and electrocortical (EEG) activity in human subjects. In the present study, this relationship was examined by comparing phase, amplitude and frequency of EEG activity sampled during systolic and diastolic pressure recorded from the carotid artery of resting subjects. The results indicated that rhythmic oscillations of the EEG (particularly those in the alpha range) were time-locked to the carotid pressure wave, and EEG samples taken during systolic and diastolic pressure were distinctly out of phase. In addition, EEG activity sampled during systolic pressure was comprised of slower frequencies than EEG activity sampled during diastolic pressure. It was suggested that the relationship between cardiac events and behavior may be mediated in part by influences of the cardiovascular system on electrocortical rhythms.

Aortic baroreceptor reflex pathway: a functional mapping using [3H]2-deoxyglucose autoradiography in the rat

The organization of pathways within the central nervous system which are activated by aortic baroreceptor input was studied in the urethane anesthetized rat using the 2-deoxyglucose method. [3H]2-deoxyglucose was administered i.v. while either the aortic nerve was electrically stimulated or aortic baroreceptors were physiologically activated by pulse increases in arterial pressure in animals with bilateral denervation of the carotid sinus. Autoradiographs of transverse sections of the central nervous system were developed and analyzed for changes in metabolic activity in discrete regions compared to control animals, as indicated by the density of the photographic emulsion. Electrical stimulation of the aortic nerve resulted in all animals in an increase in the uptake of deoxyglucose in a number of sites throughout the central nervous system, primarily ipsilateral to the site of stimulation. In the brainstem, structures previously implicated in cardiovascular reflexes were labeled. These included the nucleus of the solitary tract, the solitary tract, the dorsal motor nucleus of the vagus, and the nucleus ambiguus. In addition, the inferior olivary nucleus, the parabrachial nuclei and the ventrolateral reticular formation showed increased labeling. In the hypothalamus, increased labeling was observed only in the paraventricular and supraoptic nuclei.

Cardiac rhythmicity of skin sympathetic activity recorded from peripheral nerves in man

In previous microelectrode recordings of sympathetic impulse activity in human peripheral nerves a marked cardiac rhythmicity has been found in the spontaneous firing of vasoconstrictor neurones supplying the vascular bed of skeletal muscles. Evidence has been presented that this rhythmicity depends on a potent baroreflex control of these neurones which are significantly involved in blood pressure regulation. In contrast, no cardiac rhythmicity has previously been seen in the spontaneous firing of sympathetic fibres supplying vessels and sweat glands in the human skin. The present study shows that when strong sudomotor activity is induced in skin nerves by a rise in ambient temperature, the sudomotor impulses tend to occur in volleys time-locked to the cardiac cycle. A similar cardiac rhythmicity is not exhibited by the skin vasoconstrictor fibres which can be activated by lowering of the ambient temperature. Induced falls in blood pressure do not produce any baroreflex modulations of the sudomotor outflow, suggesting that the cardiac rhythmicity of the sudomotor impulses is mot dependent on the action of this reflex.

Organization of the sympathetic innervation supplying the hairless skin of the cat's paw

The sympathetic outflow supplying the hairless skin of the cat's hind paw has been analyzed in brain-intact and chronic low spinal animals. For this purpose the activity of postganglionic axons in fascicles of the medial plantar nerve which innervate the central pad and the respective responses of the target organs (transient skin potentials, skin temperature) have been recorded. (1) Blood vessels and sweat glands in the hairless skin of the cat's hind paw are under efferent control of vasoconstrictor neurons, sudomotor neurons, and possibly vasodilatator neurons. (2) Vasoconstrictor neurons are largely under inhibitory control of various afferent input systems from the body surface and from the internal milieu, and sudomotor neurons under excitatory control in brain-intact as well as in chronic spinal cats. (3) The basic neuronal network or "machinery" for the this reciprocal organization is probably located in the spinal cord. (4) Effects of anesthetics on the sudomotor reflexes indicate that this spinal neuronal organization is controlled in a complex manner by descending spinal systems from the brain stem. (5) The existence of vasodilatator neurons, a third efferent control system supplying the hairless skin, which can only be activated by spinal cord warming in brain-intact as well as in chronic spinal cats is not very well established. Neurons with this property are rare and it is unclear whether they course through the sympathetic trunk or dorsal roots or through both. The axons of these neurons are unmyelinated. (6) The organization of the neuronal control of vessels and sweat glands in the hairless skin may be a paradigmatic model for studying the respective neuronal organization in the spinal cord and its descending control.

The mechanisms of differential control in the sympathetic system studied by hypothalamic stimulation

In an attempt to study the mechanisms of differential action observed in the autonomic nervous system, response patterns evoked in two sympathetic nerves by stimulation of the hypothalamus were investigated. Recordings were made from inferior cardiac and vertebral nerves (mainly vasoconstrictors of the forearm muscles), both originating from stellate ganglia, in chloralose anesthetized cats. Repetitive stimulation of various hypothalamic regions produced 4 types of responses often in single preparations: (1) a response in which differential action between cardiac and vertebral nerves was characterized by an increase in vertebral nerve activity and a decrease in cardiac nerve discharges; (2) a response in which the activities of these two nerves were opposite to that described above; (3) a generalized response of the two nerves; both vertebral and cardiac nerve activity being greatly augmented. This response was accompanied by a great increase in forearm blood flow and could be classified as a part of "defense reaction"; and (4) another type of generalized response in which augmented activity of both nerves was accompanied by a decrease in muscle blood flow. Stimulation of the same hypothalamic area with a single or a short train of pulses evoked in sympathetic neurons an excitation of a short duration, followed by a long-lasting "silent period". The magnitude and duration of these two phases of responses of cardiac and vertebral nerves differed, depending on the site of stimulation. Stimulation of certain hypothalamic points could affect discharges of the left and the right cardiac nerves differently in some animals. The mechanism of differential control in the sympathetic system and some conditions which alter this pattern was discussed.