Vestibulospinal and reticulospinal interactions in the activation of back muscle EMG in the rat.

The effects of electrical stimulation of the lateral vestibular nucleus (LVN) and medullary reticular formation (RF) on electromyographic activity in axial muscles medial longissimus (ML) and lateral longissimus (LL) in the rat were studied. Long trains (150-500 ms) at 200-330 Hz and 20-100 microA were sufficient to activate ML and LL at latencies of 20-100 ms from the beginning of the train. Results of stimulation at 200-330 Hz to RF or LVN showed that muscle units were activated at a fixed latency from any effective pulse in the stimulus train. Using high frequency (1 kHz) trains of 3-6 pulses to LVN, EMG activity was detected at minimum latencies of 3.5-6 ms. When conduction times from the medulla to the spinal cord, and the spinal cord to the muscle are subtracted, this latency range is consistent with monosynaptic activation. In many cases, muscle units were recruited in order of size, with both RF and LVN stimulation. Combined stimulation of LVN and RF sites in n. gigantocellularis led to EMG activity in ML and LL at currents which were insufficient to evoke activity when presented singly. When stimulation of one site (300-400 ms train) was just sufficient to evoke a response, a shorter, overlapping train (100-150 ms) to the other site led to a higher rate of muscle activity that continued through the end of the long train, even after the short train had ended. In all cases, the effect of RF facilitating LVN was similar to the effect of LVN facilitating RF. The evidence for convergence between these two systems in the medulla and the spinal cord is discussed.

Electrical stimulation of the midbrain central gray facilitates reticulospinal activation of axial muscle EMG.

EMG responses were recorded from axial muscles transversospinalis, medial longissimus, and lateral longissimus in urethane-anesthetized rats during combined electrical stimulation of the reticular formation and midbrain central gray. Central gray stimulation facilitated reticular formation-evoked EMG activity in the back muscles of the rat. Electrical stimulation of the central gray lowered the threshold for reticulospinal activation of axial muscles and could maintain firing in these muscles after the end of a reticular formation train. Units were recruited in order of size from small to large. In only one case, central gray stimulation activated axial muscles directly without reticular formation stimulation. The central gray may be important in relaying hypothalamic influences to the reticular formation, which has direct access to the axial muscles responsible for lordosis behavior.

Axial electromyogram and intervertebral length gauge responses during lordosis behavior in rats.

Electromyogram activity from transversospinalis (TS) and lateral longissimus (LL) muscles was recorded concomitant with resistance changes of an intervertebral length gauge during manually elicited lordosis performance. Subjects were estrogen-treated ovariectomized rats. The EMG activity was evoked by manual stimulation of the cutaneous fields contacted by the male rat during mounting. During bilateral palpation of flanks at 2/s, time-locked bursts of EMG activity or more generalized EMG activation was recorded. The EMG response was accompanied by continuous and cumulative length gauge shortening, reflecting progressive rump elevation. The earliest recorded length gauge response had a latency of 10 ms from the first flank stimulus in a sequence of repetitive palpations. Perineal pressure recruited motor units in both the TS and LL which fired at high frequency. The latencies of EMG responses from the TS tended to be briefer than those from the LL; 24/35 TS responses were within 50 ms of the onset of perineal pressure. During some lordoses, the EMG response in both muscles was substantially briefer than the duration of the pressure stimulus and of the length gauge response. Activation of axial muscles during postural adjustments, standing, turning, and other behaviors is also reported. These data represent the first analysis of axial EMG and vertebral length gauge recordings during an endocrine-dependent mammalian behavior.

Brain stem reticular influences on lumbar axial muscle activity. I. Effective sites.

Lumbar axial muscle responses to electrical stimulation of the brain stem reticular formation were used to characterize reticular influences on these muscles. Electromyographic recordings were obtained from the transversospinalis, medial longissimus, and lateral longissimus systems in the urethan-anesthetized rat. Ipsilateral stimulation of the pontomedullary reticular formation evoked excitatory responses in these muscles. Trains of pulses were required, but currents as low as 15 microA were effective. Contralateral reticular stimulation with currents similar to those that elicited activation during ipsilateral stimulation at the same brain stem levels could inhibit lumbar electromyographic activity. The results suggest that the motoneurons innervating the lumbar axial musculature in the rat receive strong reticulospinal influences that could be important for postural maintenance and the expression of certain behaviors.

Brain stem reticular influences on lumbar axial muscle activity. II. Temporal aspects.

Epaxial muscle electromyographic (EMG) responses to electrical stimulation of the pontomedullary reticular formation were analyzed for temporal patterns in the urethan-anesthetized rat. Recordings were obtained from the transversospinalis, medial longissimus, and lateral longissimus groups of back muscles. In response to a series of repetitive stimulus trains, the latency of muscle activation decreased with successive trains. Typically a 10-fold decrease in latency required eight to nine stimulus trains (5 trains/s, 25 pulses/train) with currents of 25-30 microA. Individual pulses within long stimulus trains evoked muscle spike potentials at low probability but with short latencies (population range 4-7 ms). The results suggest that whereas influences on lumbar axial musculature from brain stem reticular formation were not powerful enough to evoke muscle spikes with single-pulse stimulation at currents applied in this study, they can yield short, relatively fixed EMG onset latencies in response to individual pulses within stimulus trains once a potentiation phenomenon has occurred.

The effects of stimulation of substantia innominata and sensory receiving areas of the forebrain upon the activity of neurons within the amygdala of the anesthetized cat.

The present study investigated the response characteristics of individual neurons in the amygdala following stimulation of the substantia innominata (SI), and compared these responses with those elicited by stimulation of insular and temporal polar cortices and the lateral olfactory tract (LOT). Recordings were made from single units within the medial, central, basal, and lateral amygdaloid nuclei of anesthetized, male cats. Stimulating electrodes were located in the SI, LOT, and sylvian cortex (SG). Unit responses were classified as either excitation or inhibition. Excitatory responses were further divided into fixed latency excitation (FLE) and variable latency excitation (VLE) based on the variability of the onset latency of the response. The majority of responses to SI stimulation were of the FLE type, implying a direct orthodromic, monosynaptic activation of amygdaloid units. Proportionally more FLE responses were recorded laterally, especially in the magnocellular basal nucleus, compared to VLE responses which were more common in the medial and central nuclei. SI stimulation consistently affected the activity of many more units than did SG or LOT stimulation. The onset latencies of the population of cells exhibiting excitatory responses elicited by SI stimulation were distributed bimodally, and this may reflect a dual projection pathway of amygdaloid afferents from this basal forebrain region. This correlates with anatomical descriptions indicating that SI projections to amygdala pass via the ventral amygdalofugal pathway as well as in the stria terminalis. Excitatory onset latencies of responses to SI stimulation were the shortest in the lateral and magnocellular basal nuclei and the longest in the parvocellular basal nucleus. Amygdaloid units exhibited convergent input from the stimulus sites. A clear topographical distribution of units was not demonstrated. The data suggests that units receiving a convergent input were rarely driven monosynaptically by more than one stimulus site. The basal nucleus contained the smallest fraction of units exhibiting a convergent input. A small population of antidromic responses was recorded and indicates that within the system studied the caudal aspect of the basal nucleus is a major source of amygdaloid efferents. Antidromically driven units did not exhibit transynaptic responses following stimulation of any of the test sites.