GENERAL PHYSIOLOGY OF MUSCLE AXJ> NERVE 



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fall of thedensityofthe current in thesecondary coil is very ruiml.an.l this rapi.!.!..!.!.!,..-!,.. 

 in density of the current causes the induction shock to be a very effective irritant Tin- 1 .- 

 ing induction shock, as we call that which is produced by breaking tin- primary current, i, 

 found to act more vigorously than the making shock, which is the iwcix- ..I 1 what i> t;.m,l 

 with direct battery currents. The cause of this lies in the nature of the apparatus At tin- 

 moment that the current begins to flow into the primary coil, it induces not only a cm 

 in the secondary coil, but also currents in the coils of wire of the primary coil. T 

 extra induced currents in the primary coil have the opposite direction to the batten cur- 

 rent and tend to oppose its entrance, and thereby to prevent it from immediately gain- 

 ing its full intensity. This delay affects the development of the induced current in tin- 

 secondary coil, causing it to be weaker and to have a slower rise and fall of int<-n>ity than 

 would otherwise be the case. When the primary current is broken, on the other hand, 

 there is no opposition to its cessation, and the current induced in the secondary coil i> 

 intense and has a rapid rise and fall. These differences are illustrated in Figure 1 



To accurately test the effect of the making and breaking induction shocks. 

 it is necessary to record the reaction of the nerve ; this can be done by record- 

 ing the extent to which the corresponding muscle contracts in response to the 

 stimulus which it receives from the nerve. In such an experiment it is 

 customary to use what is known as a nerve-muscle preparation. The gas- 

 trocnemius muscle and sciatic nerve of a frog, for instance, are carefully 

 dissected out, the attachment of the muscle to the femur being preserved, and 

 the bone being cut through at such a point that a sufficiently long piece of 

 it shall be left to fasten in a clamp, and so support the muscle (see Fig. 13). 



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FIG. 13 Method of recording muscular contraction. 



The simplest method of recording the extent of the muscular contract., 

 is to connect the muscle by means of a fine thread with a light lever, a 

 the point of the lever rest against a smooth surface covered with * 

 when the muscle contracts it shall draw up the lever and trace a h 

 responding length upon the blackened surface. The combination o 



