APPENDIX 



PHYSIOLOGIC APPARATUS 



The study of the physical and physiologic properties of muscles and 

 nerves necessitates the employment of some stimulus which, when applied to 

 either tissue, will call forth a contraction of the muscle, or the development of 

 a nerve impulse in the nerve. The most convenient stimulus is electricity, 

 for the reason that, with appropriate apparatus, its intensity and duration 

 can be graduated with the utmost nicety. Moreover, it does not destroy 

 the tissues, as do many chemic, physical, and mechanic stimuli. 



It is, therefore, necessary that the student should have a practical 

 acquaintance with those appliances by means of which electricity is 

 generated, applied and controlled. 



The electric cell is an apparatus composed of different elements, which, 

 by virtue of chemic actions taking place among them, generate and conduct 

 electricity. In its simplest form an electric cell consists of two metals- 

 zinc and copper, or carbon, or platinum, etc., immersed in an exciting fluid, 

 usually dilute sulphuric acid (Fig. 332). 



The zinc element is the one acted on chemically by the sulphuric acid, 

 and at the expense of which the electricity is maintained. It is known as the 

 generating element. *The copper is the collecting and conducting' element. 



With the immersion of these elements in a solution of H 2 SO 4 a chemic 

 action at once takes place between the zinc and the acid, with the formation 

 of zinc sulphate and the liberation of hydrogen, as expressed in the following 

 formula : 



Zn + H 2 S0 4 = ZnS0 4 + H 2 . 



The zinc sulphate passes into the solution, while the hydrogen accu- 

 mulates on the surface of the copper element. 



As all chemic action is accompanied by the development of electricity, 

 it can be shown by appropriate means that this is the case at the surface of 

 the zinc. Such a combination is the means of establishing a difference oj 

 potential between two points] the point of highest potential being in the acid at 

 the surface of the zinc, the point of lowest potential being in the interior of the 

 zinc. So long as the elements remain unconnected there is no movement of 

 electricity, no current. 



If the ends of the elements projecting beyond the fluid are connected by 

 a copper wire, a pathway or circuit is established, and a movement of the 

 electricity takes place. As electricity flows from the point of high to the 

 point of low potential, it follows that inside the cell the current flows in the 

 acid from the zinc to the copper, and outside the cell from the copper to the 

 zinc. Such a current is termed a continuous, a galvanic or a voltaic current. 

 Inasmuch as there is a progressive fall in potential between the highest and 



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