Summing responses of cat soleus muscle spindles to combined static and dynamic fusimotor stimulation

This is a study of the summation of responses of primary endings of muscle spindles to combined static and dynamic fusimotor stimulation in the soleus muscle of the anaesthetised cat. Summation, expressed as a summation coefficient, K, was measured under a variety of conditions including (1) at several, fixed muscle lengths using steady rates of stimulation, (2) using ramp-shaped increases in stimulation rates, (3) during passive stretches after muscle conditioning, and (4) during combined stretch plus stimulation. The predominant effect observed was occlusion, that is, the combined response was less than the sum of the two individual responses. The calculated mean K value for responses at fixed length was 0.156 (±0.005 S.E.M.). It was hypothesised that summation arose from electrotonic spread of generator current between the afferent terminals, either directly, or as a result of mechanical interactions between the contracting intrafusal fibres. Summation for responses from pairs of static fusimotor fibres gave a larger mean K value, 0.340 (±0.020 S.E.M.). These findings were interpreted in terms of a model of the muscle spindle where responses to dynamic fusimotor stimulation arise at one impulse generating site, and static fusimotor responses arise at another.     

Summation of responses of cat muscle spindles to combined static and dynamic fusimotor stimulation

This is a study of the process of interaction between the responses of muscle spindles to stimulation of two fusimotor fibres. Combined stimulation of a static and a dynamic fusimotor fibre supplying the same muscle spindle in the soleus muscle of the anaesthetised cat gave a response which was larger than from stimulating each fibre separately, but less than their sum. A similar summation process was observed with pairs of static fusimotor fibres. The mean summation coefficient for the responses to stimulation of 14 pairs of static fusimotor fibres was 0.29 (range 0.14–0.52; S.D. 0.09), while for 42 static:dynamic pairs it was 0.30 (range 0.07–0.89; S.D. 0.20). Mechanisms considered for the summation process were probabilistic mixing of impulse traffic from two or more impulse generators within the terminals of the primary ending of the spindle, the spread of generator current from one encoding site to another and mechanical interactions between contracting intrafusal fibres. In an experiment where single static and dynamic fusimotor fibres were stimulated together, and then stimulation of the static fibre stopped, the size of the continuing dynamic response was larger than when the dynamic fibre had been stimulated alone. This finding suggested some kind of mechanical interaction between the contracting intrafusal fibres and implies that static and dynamic fusimotor effects within a spindle cannot be considered to be entirely independent of one another.     

The responses of muscle spindles to small, slow movements in passive muscle and during fusimotor activity

We have previously shown that movement detection thresholds at the human elbow joint were less than a degree of joint rotation in the passive limb but were higher if they were measured while subjects co-contracted elbow muscles [A.K. Wise, J.E. Gregory, U. Proske, J. Physiol., 508 (1998) 325-330]. Here we report observations on the responses of muscle spindles of the soleus muscle of the anaesthetised cat to determine their ability to signal small length changes in the passive muscle and during a contraction, under conditions resembling those of the human experiments. After appropriate conditioning of the muscle to control for history effects, primary endings of muscle spindles showed thresholds to ramp stretch at 20 micrometers s-1 of between less than 5 micrometers and 15 micrometers, which translates to 0.05 degrees -0.15 degrees of human elbow joint rotation. Thresholds were much higher following conditioning to introduce slack in the muscle. Since during a voluntary contraction there is likely to be alpha:gamma co-activation, responses of spindles were also recorded during slow stretches (100 micrometers at 20 micrometers s-1) during static fusimotor stimulation, dynamic fusimotor stimulation, combined fusimotor stimulation and fusimotor plus skeletomotor stimulation. Invariably, responses to passive stretch were larger than during motor stimulation. It is concluded that spindles are sensitive enough to signal fractions of a degree of elbow joint rotation and that the rise in threshold observed during a voluntary contraction may be accounted for by the actions of fusimotor and skeletomotor axons on spindle stretch responses.     

Miniature end-plate potentials in the frog muscle spindle

Spontaneous miniature end-plate potentials (m.e.p.p.s) were recorded from the intrafusal muscle fibers in the muscle spindles isolated from the frog sartorius and semitendinosus muscles by means of microelectrode (intracellularly) and across a vaseline gap made transversely on the intrafusal bundle (extracellularly). The latter method was available to record simultaneously the m.e.p.p.s and the afferent terminal activities, of which the latter was easily distinguishable from the former by concomitant occurrence with the axonal responses. Simple type spindles in the sartorius muscle have a restricted end-plate region along the intrafusal bundle on either side of the capsule, while complex type spindles in the semitendinosus muscle are innervated by plural regions which are found on both sides of the capsule in most preparations. Application of 2× hypertonic Ringer's solutions with NaCl or sucrose induced an increase in the rate of the m.e.p.p.s preceding a decrease in the rate of afferent discharges from the spindle.     

Modification of sensory-terminal responses and membrane structure of frog muscle spindle by collagenase

A preparation of decapsulated muscle spindles with intact sensory innervation has been developed to allow direct access to the sensory terminal for the application of drugs or to alter the extracellular ionic composition. Muscle spindles were isolated from semitendinosus muscles of the frog Rana catesbeiana, and were incubated in a calcium-free Ringer's solution containing 0.2% collagenase. Following optimal incubation at 34 degrees C for 30 min the response pattern of the spindles during stretch could not be distinguished from that of intact spindles, although the duration of individual afferent spikes was prolonged about 4 times normal. The spikes disappeared immediately after the Ringer's solution was replaced with an isotonic choline chloride solution, in contrast to those of intact spindles which remained for 30 min after the replacement. Electron microscopy showed that the outer and inner capsules were partially disrupted. No significant change was observed in the size or packing density of intramembrane particles in freeze-fracture replicas of spindles decapsulated under optimum conditions. More prolonged treatment with the enzyme resulted in abolition of the static component of the response during stretch, and also in an aggregation of the particles, whose size decreased and packing density increased.