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<br />. <br /> <br />! <br />1 .1 <br /> <br />"., <br />.' <br /> <br />r~ ~ <br />(I ':. <br />/) <br />:~ <br /> <br /> <br />,~ ; <br /> <br /> <br />() '7 I 3CJ <br /> <br />552 <br /> <br />/r7~ A Jdvrl\ Sj et /{J <br /> <br />J.l\1\.1~;'. l\ME~. 1'1:'11. :,uc., 1972, NO. 3 <br /> <br />.. <br /> <br />LITERA TURE CITED <br /> <br />ATKINSON, C. E. 1951. Feeding habits of adult <br />shad (Alosa sapidissima) in fresh water. Ecology <br />32: 556--557. <br />CATING, J. P. 1953. Determining age of Atlantic <br />shad from their scales. Fishery Bull. Fish. Wildl. <br />Servo U. S. 54: 187-199. <br />CHITTENDEN, M. E., JR. 1969. Life history and ecol- <br />ogy of the American shad, Alosa sapidissima, in <br />the Delaware River. Ph.D. Thesis, Rutgers Univ., <br />458 p. <br />FREDIN, R. A. 1954. Causes of fluctuations in abun- <br />dance of Connecticut River shad. Fishery Bull. <br />Fish. WildI. Servo U. S. 54: 247-259. <br />JUDY, M. H. 1961. Validity of age determinations <br />from scales of marked American shad. Fishery <br />Bull. Fish. Wildl. Servo U. S. 61: 161-170. <br />LAPOINTE, D. F. 1958. Age and growth of the <br />American shad from the Atlantic coast rivers. <br />Trans. Amer. Fish. Soc. 87: 139-150. <br />LEACH, G. C. 1925. Artificial propagation of shad. <br />Bureau of Fisheries Document 981. Rf^3' U. S. <br />Comm. Fish., 1924. Appendix VIII: 459-.486. <br />LEGGETT, W. C. 1969. Studies on the reproductive <br />biology of the American shad (Alosa sapidissima, <br />Wilson). A comparison of populations from <br />four rivers of the Atlantic / seaboard. Ph.D. <br />Thesis, McGill Univ., 125 p. <br />LEGGETT, W. c., AND R. R. WHITNEY (in press). Wa- <br />ter temperature and the migrations of American <br />shad. Fishery Bulletin (D. S.) 70 (3). <br />LEIM, A. H. 1924. The life history of the shad <br />(Alosa sapidissima, Wilson) with special refer- <br />ence to the factors limiting its abundance. Contr. <br />Can. BioI. Fish. 2: 163-284; <br />MANSUETI, R. R., AND H. KOLB. 1953. A historical <br />review of the shad fisheries of North America. <br />Chesapeake BioI. Lab., Solomons, Maryland, <br />Publ. No. 97. 293 p. <br />Moss, D. D. 1946. Preliminary studies of the shad <br />(Alosa sapidissima) catch in the lower Connecti- <br />cut River, 1944. 11th N. Amer. WildI. Conf. <br />Trans. 230-239. <br />NICHOLS, P. R. 1959. Extreme loss in body weight <br />of an American shad (Alosa sapidissima). Copeia <br />1959: 343-344. . <br />NICHOLS, P. R., AND W. H. MASSMANN. 1963. Abun- <br />dance of shad, York River, Virginia, 1953-1959. <br />Fishery Bull. Fish. Wildl. Servo U. S: 63: 179- <br />187. <br />SYKES, J. E.. 1956. Shad fishery of the Ogeechee <br />River, Georgia in 1954. U. S. Fish. WildI. Servo <br />Fisheries, Spec. ScL Rep. 191: 1-11. <br />SYKES, J. E., AND B. A. LEHMAN. 1957. Past and <br />present Delaware River shad fishery and consid. <br />,erations for its future. U. S. Fish. Wildl. Serv., <br />Res~ Rep. 46. 25 p. <br />TALBOT, G. B. 1954. Factors associated with fluc- <br />tuations in abundance of Hudson River shad. <br />Fishery Bull. Fish. WildI. Servo U. S. 56: 373-': <br />413. <br />W ALBURG, C. H. 1957. Neuse River shad investi. <br />gations. 1953. U. S. Fish. WildI. Servo Fisheries, <br />Spec. ScL Rep. 206. 13 p. <br />W ALBURG, C. H. 1960. Abundance and life history <br />of shad, St. Johns River, Florida. Fishery Bull. <br />Fish. Wildl. Servo U. S. 60: 487-501. <br />WALBURG, C. H., AND J. E. SYKES. 1957. Shad {ish- <br />ery of Chesapeake Bay with special emphasis on <br /> <br />the fishery of Virginia. U. S. Fish. Wildl. Serv., <br />Res. Rep. 48. 26 p. <br /> <br />Department of Biology <br />McGill University <br />Montreal 101, Quebec <br />and <br />Essex Marine Laboratory <br />Essex, Connecticut 06426 <br /> <br />WILLIAM C. LEGGETT <br /> <br />Recovery of Shocked Common <br />Shiner, Notropis cornutus, Re- <br />lated to Electric Energy <br /> <br />Electricity is widely used as a method of <br />fish capture. Past studies have shown that <br />fishes go through a series of responses to in- <br />creased levels of voltage resulting finally in <br />galvanonarcosis, a state of immobilization. <br />Vibert (1963), Halsband (1967), and La- <br />marque (1967) have shown the importance of <br />voltage or voltage drop in causing these re- <br />sponses in fishes. To construct effective <br />electrofishing apparatus, however, considera- <br />tion of electrical parameters in addition to <br />voltage is necessary. The present study, hope- <br />fully, will help to establish a basic energy <br />threshold for electrofishing which could be <br />extrapolated to various sampling situations. <br />Measurements in this study are of the time <br />necessary for fishes to recover from galvano- <br />, narcosis after current is no longer applied. <br /> <br />MATERIALS AND METHODS <br /> <br />Experiments using common shiners,--Ni).: <br />tropis cornutus, were performed under labora- <br />tory conditions at Lake Superior State College. <br />The equipment consiste~ of a direct current <br />laboratory power supply capable of producing <br />up to 180 volts of direct current. A smal1 rec- <br />tangular polyethylene tank approximately 400 <br />X 224 X 160 mmwas used to hold and shock <br />, fish. Two electrodes, consisting of copper <br />screen, were glued to opposite ends of the tank. <br />These electrodes were cut to a length so that <br />each fuUy covered an end of the. tank. The <br />recovery time of narcotized fishes was defined <br />as the period from the last second the current <br />was applied until the fish regained a normal, <br />upright position and was able to swim again. <br />To avoid muscle and nerve fatigue, none o.f <br />the fish shocked . was used more than once. <br /> <br />,. <br /> <br />s <br /> <br />I <br />( <br />f <br /> <br />tl <br />t] <br /> <br />a <br /> <br />p <br />a <br />o <br />l( <br />It <br /> <br />c <br />k <br /> <br />T <br /> <br />(n <br /> <br />I <br />