Vasodilatation in human skin induced by low-amplitude high-frequency vibration.

Vasomotor effects in human skin induced by vibration of low amplitude (10-25 microns) and high frequency (150-250 Hz) have been studied by using skin temperature changes as an approximative measure of variations in skin blood flow. In all tested areas of the body surface, including the face, low-amplitude high-frequency vibration regularly induces vasodilatation. The spatial distribution of the temperature changes induced from different sites of stimulation was studied by infrared thermography. The latencies of the temperature changes, determined by thermistor recordings, were found to vary with site of stimulation and stimulus parameters. The increase in temperature to a given stimulus is greater the lower the prevalent skin temperature, i.e. the increase in blood flow is larger the greater the initial vasomotor tone. The results are in accordance with the view that the vasodilatation is due to a reflex inhibition of pre-existent vasomotor tone in the skin by the afferent inflow from vibration-sensitive mechanoreceptors. High-amplitude vibration (100-200 microns), performed in a few comparative experiments, caused vasoconstriction.

Changes in voluntary muscle strength, somatosensory transmission and skin temperature concomitant with pain relief during autotraction in patients with lumbar and sacral root lesions.

Earlier clinical observations of rapid changes of certain neurological dysfunctions after autotraction treatment of patients with lumbar and sacral root affections have been evaluated by objective registration methods. Isokinetic recordings of maximal voluntary strength showed that in 6 out of 8 patients, weakness of the foot dorsal flexor muscles could be more or less completely restored after one session of autotraction resulting in pain relief. In a group of patients with clinical signs of impaired sensibility, the low or abolished SEP responses to nerve stimulation on the affected side were restituted in 4 out of 5 cases during autotraction. The asymmetric leg skin temperatures in 10 patients with sciatic pain levelled off in the 6 cases obtaining pain relief by the traction. The results suggest a causal relationship between pain relief and restitution of certain neurological deficits.

In vitro studies of frog mucous glands.

The ionic outflow, mainly consisting of Na+ and Cl-, from the mucous glands in an excised nerve-skin preparation of frog has been determined by recording the conductance changes occurring in a fluid layer covering a small area of the skin surface. In the main series of experiments the glands were activated by stimulation of sympathetic nerve fibers in the skin nerve. The relationship between the ionic outflow and the number of nerve volleys was studied over a wide range. The outflow per impulse was found to be fairly constant during the first tens of impulses but diminished gradually with increasing number of stimuli up to a certain maximum value--varying in different preparations--after which the outflow ceased completely. During the initial phase of stimulation the outflow is most likely caused by an ejection of performed secretion due to the contractions of the glandular myoepithelium. The continued outflow in the later stages of the stimulation periods must be due to production of new secretion. Since the glandular epithelium is devoid of nerve terminals a nervous control of the ionic secretion can only be explained by an indirect influence mediated either by transmitter diffusion from the myoepithelial nerve endings or by a close electric coupling between the contractile and the secretory gland cells. Adrenaline and noradrenaline induce ionic outflows which like those evoked by nerve stimulation are inhibited by the beta-adrenoreceptor blocker propranolol, alpha-adrenoreceptor blockers being without effect. A serendipitous finding of tonus changes in the frog skin during nerve stimulation is also described.

In vivo studies of individual mucous glands in the frog.

Individual mucous glands in the toe web were studied in curarized decerebrate frogs using vital microscopy in combination with still or motion photomicrography. By changing the focus position to different levels various structures in the gland could be identified and their changes during glandular activation studied. The first visible effect of nerve stimulation was a contraction of the myoepithelium and probably also structural changes of the secretory epithelium resulting in a narrowing of the glandular lumen. Following this, tricuspid valve opened and secretion was ejected. The latency and time course of the contractile response to nerve stimulation were determined and the influence of the number of stimuli on the duration of the contraction and relaxation phases was analyzed. Comparisons were made with reflex activation of the gland as well as with neurohormonal stimulation. The myoepithelial contraction was found to be under adrenergic control. Of the smooth-muscle stimulants tested only Substance P induced contractions. The time course of the ionic outflow from the toe web was determined by conductance measurements in the fluid surrounding the web and compared with the visually observed phenomena. The initial outflow was concomitant with the phasic myoepithelial contraction but a continued secretion could also be observed and recorded from glands kept in a steady state of contraction by iterative nerve stimulation. The functions of the toe web glands were found to be critically dependent on a maintained circulation in the surrounding capillary network.

Conductance recording of ionic outflow from frog skin glands during nerve stimulation.

A method for continuous recording of the ionic efflux from frog skin glands has been developed which under given experimental conditions provides a convenient index on glandular secretion. A nerve skin preparation from the calf is mounted so that the outside of the skin forms the bottom of a small test compartment with distilled water while the corium side is bathing in Ringer's solution. After determination of the adequate nerve stimulus parameters for discernible gland secretion to occur, the skin nerve was stimulated at 10 Hz during varying periods and chemical control analyses performed of the changes in ionic content of the test compartment solution. The main ionic outflow consisted of Na+ and Cl- in equal amounts, the outflow of other ions during stimulation being negligible. The concomitant conductance changes were measured as variations of absorption in a high-frequency field applied to a conductance probe placed in the test chamber. Determinations of the NaCl outflow based on the conductance changes were in good agreement with the values obtained by chemical analysis. The continuous conductance recordings proved to give approximative information of the quantities and time relations of the glandular secretion, allowing a direct comparison with, e.g., skin potential changes.