220 INFLUENCE OF TEMPERATURE ON BIOLOGICAL SYSTEMS 



12. HoDGKix, A. L. AND B. Katz. The effect of temperature on the electrical activity 

 of the giant axon of the squid. J. Physiol. 109: 240-249, 1949. 



13. Grundfest, H. Effects of hydrostatic pressures upon the excitability, the recovery 

 and the potential secjuence of frog nerve. Cold Spring Harbor Symp. Quant. Biol. 

 5: 179-187, 1936. 



14. Ebbecke, U. and H. Schaefer. Uber den Einfluss hoher Drucke auf den Aktions- 

 strom von Muskeln und Nerven. Pfliiger's Arch. ge.s Physiol. 236: 678-692, 1935. 



15. Tasaki, I. Nervous Transmission. Springfield, 111.: Thomas, 1953. 



16. Bak, a. a unity gain cathode follower. In preparation. 



17. Tasaki, I. New measurements of the capacity and the resistance of the myelin 

 sheath and the nodal membrane of the isolated frog nerve fiber. Am. J. Phy.^iol. 

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18. Cole, K. S. Rectification and inductance in the squid giant axon. J . Gen. Physiol. 

 25: 29-51, 1941. 



19. Curtis, H. J. and K. S. Cole. Membrane action potentials from the sciuid giant 

 axon. J. Cell. & Comp. Physiol. 15: 147-157, 1940. 



20. HoDGKiN, A. L. AND A. F. Huxley. Resting and action potentials in single nerve 

 fibers. J. Physiol. 104: 176-195, 1945. 



21. HoDGKix, A. L. AND A. F. Huxley and B. K.^tz. Measurement of current-voltage 

 relations in the membrane of the giant axon of Loligo. J. Physiol. 116: 424-448, 

 1952. 



22. Ling, G. and J. W. Woodbury. Effect of temperature on the membrane potential 

 of frog muscle fibers. J. Cell. <& Comp. Physiol. 34: 407^12, 1949. 



23. Coraboeuf, E. and S. Weidmann. Temperature effects upon the electrical activitj^ 

 ■ of Purkinje fibers. Helv. physiol. et pharmacol. acta, 12: 33-41, 1954. In this 



article reference is made to previous literature. 



24. Trautwein, W., U. Gottstein and K. Federschmidt. Der Einfluss der Tempera- 

 tur auf den Aktionsstrom des excidierten Purkinje-Fadens, gemessen mit einer 

 intracellularen Elektrode. Pfliiger's Arch, ges Physiol. 258: 243-260, 1953. 



25. T.\MASHiGE, M. Membrane and sarcoplasm resistance in an isolated frog muscle 

 fiber. Annotationes Zool. Japan. 23: 125-130, 1950. 



26. Del Castillo, J. and X. Machne. Effect of temperature on the passive electrical 

 properties of the muscle fiber membrane. /. Physiol. 120: 431-434, 1953. 



27. HoDLER, J., R. Stampfli .-^nd I. Tasaki. Uber die Wirkung internodaler Abkiihhmg 

 auf die Errgegungsleitung in der isolierten markhaltigen Nervenfaser des Frosches. 

 Pfliiger's Arch. ges. Physiol. 253: 380-385, 1951. 



28. ScHMiTT, 0. H. Electrochemistry in Biology and Medicine. Ed. by T. Shedlovsky. 

 New York: Wiley, 1955. 



29. Tasaki, I. Initiation and abolition of the action potential of a single node of 

 Ranvier. J. Gen. Physiol. 39: 377-395, 1956. 



30. Tasaki, I. and K. Mizuguchi. The clianges in the electric impedance during activity 

 and the effect of alkaloids and polarization upon the bioelectric processes in the 

 myelinated nerve fiber. Biochim. et biophys. acta 3: 484-493, 1949. 



31. Tasaki, I. and W. H. Freygang. The parallelism between the action potential, ac- 

 tion current and membrane resistance at a node of Ranvier. J. Gen. Physiol. 39: 

 211-223, 1955. 



32. HoDLER, J., R. St.Kmpfli and I. Tasaki. Role of potential wave spreading along 

 myelinated nerve fiber in excitation and conduction. Am. J. Physiol. 170: 375- 

 389, 1952. 



33. Johnson, F. H., H. Eyring and M. J. Poliss.\r. The Kinetic Basis of Molecular 

 Biology. New York: Wiley, 1954. 



