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Notes: Summary Fibronectin is a glycoprotein belonging to the opsonic system and able to mediate phagocytosis by the reticuloendothelial system (RES). Severe intoxications are often followed by a diminished capacity of RES-clearance. Patients with severe drug intoxications have lower concentrations of fibronectin in plasma than healthy persons. Charcoal hemoperfusion lowers plasma fibronectin by an average of 4.7 mg/dl. Initial values below 15 mg/dl did not undergo a significant decrease in the case of hemoperfusion. Regarding these findings, determination of plasma fibronectin seems a useful parameter for monitoring RES function during treatment of drug-intoxicated patients by hemoperfusion.

Notes: Summary The effects of hypocalcemia induced by excision of the parathyroid glands upon the function of spinal motoneurones and peripheral receptors were investigated in decerebrate cats. 1. In hypocalcemic convulsions the motoneurones show extraordinary high frequency discharges. 2. Both alpha and gamma motoneurones often exhibit double discharges, “doublets”. 3. The peripheral receptors, for example those in muscle spindles, have bursts of high frequency impulses “multiplets”; these are obtained with and without efferent muscle innervation. 4. The relation of this hypocalcemic excitation of the receptors to the changes in perception, spinal reflexes, and the neural control of respiration is discussed.

Notes: Summary The effects of pre- and/or intercollicular decerebration on the activity and responsiveness of individual Renshaw cells were studied in 15 adult cats under continuous light anesthesia. It was found that decerebration either had no effect on the spontaneous activity of Renshaw cells and their response to antidromic stimulation, or it enhanced activity, provided that the blood pressure was prevented from falling below critical values. Spontaneous activity showed the more pronounced increase, particularly after intercollicular decerebration. Severing of the ipsilateral dorsal roots had no noticeable effect on the Renshaw cell behaviour. Concomitant with the release of extensor a-motoneurones following decerebration — as indicated by an augmentation in the amplitude of monosynaptic reflexes — the Renshaw cell response to orthodromic stimulation was enhanced. The phasic response of Renshaw cells, elicited by muscular ramp stretch, was also more pronounced after decerebration. Thus judging by the experimental results obtained in anesthetized animals, any decrease in Renshaw cell activity would not seem to be a primary cause of decerebrate rigidity.

Notes: Summary 1. The red nucleus region was stereotaxically stimulated with short trains of high-frequency alternating current pulses in anaesthetized cats. The effects were studied, in contralateral lumbar segments, on the responses of microrecorded individual Renshaw cells (RCs) to antidromic or orthodromic test shocks of ventral root or muscle nerve fibres. Monosynaptic reflexes (MRs) of their motoneurone pools were recorded from one of the cut lumbar ventral roots. Averages of 10–20 replicate test responses of the RC (converted into instantaneous frequency curves, IFCs) and of the MR shapes were computed and graphically displayed. 2. Orthodromic (afferent) test shocks induced simultaneously MRs as well as responses of a RC belonging to the same motor pool. From their paired records at systematically varied shock strengths, whole “linkage characteristics” of the relation between the two events could be obtained, representing the functional linkage from the motoraxon collaterals to the RC under study. The overall result of rubral conditioning was a change in the course of the characteristic, which indicated a reduction of this linkage (= relative inhibition of the RC against its recurrent input). 3. Sequential trials with test shocks of constant, submaximal strength were performed with 45 individual RCs. The clearest results were obtained with RC responses to antidromic ventral root shocks: 65% of the RCs were partially inhibited by rubral conditioning. Interposed minor facilitory subcomponents could be seen in the course of inhibited IFCs. Mixed sequences of manifest inhibitory/facilitory effects were observed in 11%; reversed sequences (facilitory/inhibitory) did not occur. A pure but weak facilitation was found in only one case, paralleled by an increase of the MR. RCs belonging to either extensor or flexor motor pools were affected about equally. A little over 20% of the tested RCs remained uninfluenced by rubral stimulation. 4. The MRs, induced by constant, submaximal, orthodromic test shocks, were usually enhanced with only few exceptions, by rubral stimulation. The effects on the orthodromic RC responses were mainly inhibitory, but could be more or less masked by the concurrent increase of the MR, providing a stronger recurrent input to the RC. Such inhibition could be uncovered, however, by observing the above described linkage change. 5. Variation of several parameters of rubral conditioning (train duration, timing of train with respect to test shock, strength of train) modified the inhibitory effects on antidromic RC responses to a certain extent without changing their principal character. Higher conditioning strengths frequently induced mass discharges of previously silent motoneurones, but at the same time an increased inhibition of the concurrent RC responses. 6. Spontaneous RC activity (in the absence of test stimuli) occurred infrequently and was weak and interrupted by silent periods. When this persisted long enough for testing repeated rubral stimulation, a strong initial inhibition lasting up to several hundred ms was found, sometimes followed by some oscillations of the average discharge rate. 7. The predominant combination of concurrent effects of the conditioning, namely, inhibition of RCs and facilitation of motoneurones, indicated independent (and mostly divergent) control of the two target neurones by the red nucleus. It is concluded that in this way the RCs can be flexibly and transiently decoupled to some degree from their recurrent motoneuronal input.

Notes: Summary Successive motor unit (MU) twitches often do not sum linearly. Also, muscle spindle (MS) afferents may react nonlinearly to MU contractions occurring at short intervals. Little data is presently available on the interactions between two (or more) MUs regarding their effects on tension output and MS responses. We have studied these effects in cat Mm. gastrocnemius medialis (MG), soleus and semitendinosus. In adult anaesthetized cats, MUs of the muscle under study were electrically stimulated via their ventral root axons with random sequences of brief pulses having mean rates between 6 and 12 pulses per second. Isometric tension fluctuations were recorded from the muscle under study, and discharge patterns of MS afferents (Ia and group II) were recorded from dorsal root filaments. A crosscorrelation analysis was performed to display linear and nonlinear effects evoked by selected time constellations of MU activations. 1) 18 (67%) of 27 MG MUs showed marked potentiation of the second of two twitches in response to pairs of stimuli separated by 5 to about 25 ms. The remainder of these and 16 of the soleus MUs did not exhibit conspicuous nonlinearities. — 2) MS responses to such pairs of MU activations usually showed a prolonged spindle pause. — 3) About 28% of 36pairs of MG MUs produced twitch tension less than expected for linear summation if activated nearly simultaneously. — 4) If two MUs both produced a spindle pause and possibly a relaxation discharge in an MS afferent, the near-synchronous activation of the units produced respective discharge variations that were less than expected for linear summation. If one MU produced an early discharge, contraction of another MU would often prevent it. — These results are discussed in regard to mechanisms of tremor suppression.

Notes: Summary The effects of prolonged training of adult monkeys subjected to random, brief perturbations of alternating elbow flexions and extensions were studied over a period of four years. The training was intensive at first, for about one year, and then irregular, with long pauses, during the following three years. As a consequence of the prolonged training with the brief perturbations, the M2 component of the electromyographic (EMG) response of the biceps and triceps muscles became gradually smaller, and finally disappeared. The M1 component, on the other hand, progressively increased in amplitude and continued to do so after the loss of the M2, until it finally dominated the EMG response. The training had similar effects on the response of the biceps muscle to longer perturbations, but, only under certain conditions, did it affect the triceps muscle response. All changes occurred at earlier stages of the training in the flexor than in the extensor muscle. These observations demonstrate a long-term functional plasticity of the sensorimotor system of adult animals and suggest a growing role for fast segmental mechanisms in the reaction to external disturbances as motor learning progresses. Changes at various levels of the stretch reflex system could underlie the enlargement of the M1 component, while the lack of the M2 component should, at least partially, reflect a reduced cortical effect on αmotoneurones and/or changes in spinal systems processing afferent information.

Notes: Summary a) Renshaw cells (RC) were recorded during ramp stretch of the GS muscle. In 90% of the analysed cells, the frequency and duration of the phasic response were enhanced by increases in both the length and rate of stretch. b) The tonic response, which was observed in about 30% of the analysed cells, increased at higher stretch lengths. c) After application of the cholinergic blocking agent mecamylamine or after severance of the GS nerve, the Renshaw stretch response was abolished. d) The results lend some support to the hypothesis that RCs are triggered predominantly by large phasic motoneurones. The smaller tonic motoneurones seem to provide some supporting background input to the RCs.

Notes: Summary The effects of ramp stretches applied to triceps surae muscle on the discharge patterns of single Ia inhibitory interneurones, monosynaptically invaded from various nerves, were studied in either decerebrate or anesthetized cats. Interneurones which received direct excitatory Ia input from the stretched muscle exhibited augmented activity both during the dynamic and static phase of stretch, which was, however, interrupted by a transient inhibitory influence during the dynamic phase of stretch. The influences on Ia inhibitory interneurones, monosynaptically invaded from hamstring or tibial nerve, were exclusively inhibitory. These stretch-induced inhibitions were better demonstrable in decerebrate than in anesthetized preparations. The timing of the discharge patterns of additionally recorded Renshaw cells during stretch, and the disappearance or reduction of the above described inhibitory effects after administration of DHE, strongly support the idea that these inhibitory actions are caused by Renshaw inhibition. In Ia inhibitory interneurones, monosynaptically activated from the antagonistic peroneal nerve, stretch induced also pronounced inhibitory effects, which were most probably caused by mutual inhibition between Ia inhibitory interneurones. The suppression of agonistic Ia inhibitory interneurone activity below the tonic resting activity corresponded to an enhancement of the monosynaptic reflex amplitude of the antagonistic motoneurone pool. The findings suggest that normal orthodromic activation of Renshaw cells, and consequently the recurrent inhibition of the Ia inhibitory interneurones, is predominantly linked with rapid phasic, rather than slow tonic, motoneuronal firing. The functional role of this mechanism for the performance of rapidly alternating movements and the damping of ballistic agonist contractions is discussed.