[From the U.S. Government Printing Office, www.gpo.gov]
A SYNTHESIS OF WATER QUALITY AND
CONTAMINANTS DATA FOR YELLOW
PERCH, PERCA FLAVESCENS
FINAL DRAFT Sep 1989
COASTAL ZONE
INFORIvIATION Cr,-NTER
SH
171
S96
1989
�
(71 5%
FINAL DRAFT
A SYNTHESIS OF WATER QUALITY AND CONTAMINANTS DATA FOR
YELLOW PERCH, PERCA FLAVESCE.NS
Steven A. Fischer
-Lenwood W. Hall, Jr.
and
John A. Sullivan
-The Johns Hopkins University
Applied Physics Laboratory
Aquatic Ecology Section
Shady Side, Maryland
COASTAL ZONE
'NFORMATION CENTEF,
September, 1989
Preparation of this report was funded by the Coastal Resources
Division, Tidewater Administration, Maryland Department of Natural
Resourcesi through a CZM Program Implementation Grant from the
Office of ocean and Coastal Resource Management, NOAA.
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INTRODUCTION
The unique physical, chemical and biological parameters of
the Chesapeake Bay create a suitable environment for numerous
fish species. The abundance and distribution of resident and
migratory f ish species which utilize the Bay, as well as the
recruitment potential of estuarine-reared oceanic fish species,
are influenced by variables such as climate, reproductive
potential, parasites, disease, natural population cycles, food
availability and suitable habitat. overharvesting of commercial
and recreational f ish@ species and habitat destruction (water
quality and contaminants) are 'the primary factors resulting in
dramatic and prolonged fish stock declines (Wohlfarth, 1986;
Setzler-Hamilton, 1987; Speir, 1987). Habitat degradation
resulting from adverse water quality and chemical contaminants
have been suspected recently of reducing several Chesapeake Bay
fish species populations (Hendrey, 1987; Klauda and Bender,
1987).
The extent and degree of spawning and nursery habitat
degradation resulting from deleterious contaminant and water
quality conditions within the Chesapeake Bay and related
tributaries are major considerations when attempting to manage
particular fish species. Populations of anadromous and resident
fish species, including the yellow perch (Perca flavescens), have
recently declined within the Chesapeake Bay (Hendrey, 1987;
Klauda and Bender, 1987). Due to such drastically low yellow
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perch stocks in the Chesapeake Bay, the state of Maryland
instituted a partial ban effective in 1989. The ban prevents the
collection of yellow perch by any method from 11 river systems
around the Bay. The new regulation also prohibits the sale of
yellow perch during the entire month of February. In addition, a
creel limit of 5 yellow perch per person per day with a minimum
length limit of 216 mm was implemented.
Yellow perch are residents of the Bay and spawn within the
poorly buffered coastal plain freshwater tributaries. Yellow
perch eggs and larvae are exposed to potentially detrimental
acidic pulses. More definitive data concerning water quality and
contaminant effects on the early life history stages of yellow
perch are required if adequate management plans are to be
implemented. Synthesis of the data can also be used to identify
suitable habitat requirements.
This document was developed to provide a compilation and
review of both water quality and contaminants data on various
life stages of yellow perch. Data contained in this document
will be useful in the Toxics Reduction Strategy for the
Chesapeake Bay Program effort. A life history and ecology
section on yeliow perch will be prepared by other investigators
and merged with this document to provide a complete review of the
species.
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TOXIC WATER-QUALITY COI@DITIONS
Toxic water quality conditions adversely affecting various
life stages of yellow perch are presented in Table .1. Each
parameter is discussed separately in the following sections.
Temperature
Temperature effects on yellow perch embryos, larvae,
juveniles and adults were evaluated in 19 different studies.
Hokanson (1977a) reported that yellow perch require increased
temperatures during early ontogenetic development. Hokanson and
Kleiner (1974) and Hokanson (1977b) indicated minimum and maximum
median tolerance limits (TLSO) for yellow perch egg stages were
6.8 and 19.9 C, respectively. Hatching varied from 2 d at 18.2 C
to 30.5 d at 3.3 C according to Hokanson and Kleiner (1974).
Hardy (1978) indicated that hatching occurred in 11 - 13 d at 15
C in freZ:@water, wh---)e 13 - 15 d were required at 1.55 C in 5.8 ppt
salinity.
Yellow perch larvae exhibited a temperature preference of
21.7 - 24.3 C when acclimated at 20 - 25 C (Ross et al. 1977).
Hale and Carlson (1972) reported a 63% survival rate for larvae
fed at 20 - 21 C, which is similar to the preference range
reported by Ross et al. (1977). A temperature tolerance range of
10 - 30 C for feeding larvae was reported by Hokan'son (1977b),
while Hubbs (1971) reported that larvae fed when temperatures
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were as low as 9.5 C. Significant mortality to larvae,
acclimated between 13.5 - 17 C, occurred only as a result of a 15
C temperature increase in an experiment designed to simulate
primary entrainment with pressure-temperature shock (PSE&G,
01
1978). They also reported no significant difference in mortality
between control and treatment groups when larvae, acclimated at
16.5 C, were exposed to test temperatures of 19.0 - 24.5 C for
0.5 - 4 h.
McCauley and Read (1973) and Cherry et al. (1977) reported
juvenile yellow perch selected a temperature range of 19 - 23 C
when acclimated at 24 C and 15 - 24 C, respectively. Neill and
Magnuson (1974) reported young-of-the-year (YOY) pe-rch selecteda
similar temDerature (23 C) during a laboratory thermal
preference experiment. Reynolds and Casterlin (1979) reported
that age-0 yellow perch exhibited a diel rhythum of preferred
temperature, with a predawn minimum of 16.7 C and a dusk maximum
of 23.8 C. Optimum growth conditions for juvenile yellow perch
were approximately equal to the preferred temperature (22 C) with
16 h of light (Huh et al., 1976). Conversely, McCormick (1976)
reported significantly greater growth rates at 26 - 30 C when
held at constant temperatures. He also reported little to no
growth at 8 C and total mortality within 7 d at 34 C. Growth of
juvenile yellow perch occurred within a temperature range of 6 -
31 C (Hokanson, 1977b). Barans and Tubb (1973) collected YOY and
adult yellow perch seasonally to compare temperature preference
ranges between the two life stages. They reported that YOY
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yellow perch selected temperature ranges 4 C greater than those
selected by adults during spring, summer, and fall, but YOY
selected a temperature range 2 C lower than adults during the
winter. Hokanson and Kleiner (1974) also reported the juvenile
stage was more thermally tolerant than the adult stage..
Hokanson and Kleiner (1974) reported that 24.7 C was the
physiological optimum temperature for adult yellow perch. Ross
and Siniff (1982) reported that adult yellow perch preferred a
median temmerature of 6.3 C when exposed to a winter thermal
effluent of 0 - '15 C. This winter temperature preference differs
from that of Barans and Tubb (1973) who collected adult yellow
perch during the winte.--- in the range of 12 - 16 C. Meldrim and
Gift (1971) reported that adult perch acclimated at 15 C (6 ppt
salinity) and 25 C (freshwater) preferred 23.5 C and 22.5 C,
respectively. Thermal avoidance tests were also conducted by
Meldrim and Gift (1971). Two groups of adult yellow perch
acclimated at 25 C and different light levels avoided
temperatures greatr--r than 33 C. PSE&G (1978) reported a similar
avoidance range (31 - 34 C) when acclimated at 25 C in
freshwater. PSE&G (1978) data also indicated that saltwater
increased the upper avoidance temperature in adult yellow perch.
Avoidance temperatures of 14 - 18 C and 27 C were reported when
adult yellow perch were acclimated at 6 C in freshwater and
saltwater (1.5 ppt salinity) environments, respectively. Two
investigators reported that rheotactic responses were the cause
of behavioral changes exhibited by adult yellow perch
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encountering heated thermal effluent (Kelso, 1976; MacLean,
1982).
salinity
Salinity effects on yellow perch eggst larvae, YOY and
adults were evaluated in four studies. Muncy (1962) reported
that spawning occurred in freshwater and in brackish areas with
less than 2.5 ppt salinity. Hatching success of yellow perch
eggs decreased with increased salinity ranging from 0 - 11.7 ppt
(Muncy, 1962). He also reported a 2 d hatching delay in
saltwater (5.8 ppt) versus freshwater at 15 C. Muncy (1962) also
reported hatching success ranged from 65 - 42% when salinity
conditions varied from 0 - 2.43 ppt.
Klauda et al. (1988) conducted a preliminary salinity
tolerance laboratory experiment of 8 and 26 d old yellow perch
larvae. Mortality estimates for 8 and 26 d old larvae at 3 ppt
salinity were 40% and 28%, respectively. Mortality estimates for
8 and 26 d old larvae at 6 ppt salinity were 25% and 18%,
respectively. Neither age-group survived longer than 48 h in 12
and 24 ppt salinity.
Muncy (1962) reported that YOY perch were collected in
salinities ranging from 0.5 - 9.5 ppt. Seine hauls from the
Severn River (Annapolis, MD) indicated that YOY yellow perch were
most abundant in 5 - 7 ppt salinity (Muncy 1962).
Actual field data represents the only salinity information
regarding adult yellow perch since no laboratory salinity
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preference experiments have been conducted. Driver and Garside
(1966) and Muncy (1962) both reported that adult yellow perch
inhabit salinities ranging from 0.0 - 10.3 ppt, while Hardy
(1978) reported that adult yellow perch were collected from
waters with salinities up to 15 ppt.
Dissolved Oxygen
The effects of low dissolved oxygen (D.O.) on larval and
juvenile yellow'perch were examined in two studies. Petit
(1973) reported a lethal D.O. concentration of 0.84 mg 02/L for
yellow perch larvae at 23 C. This D.O. concentration was not
lethal for YOY tested at 15.1 C, which may have been the result
of a lowered metabolic rate. Carlson et al. (1980) indicated
that growth of juvenile yellow perch was not significantly
affected when mean D.O. concentrations were > 3.5 mg 02/L, while
growth was significantly reduced when D.O. concentrations were <
2.0 mg 02/L.
IDH
Eight studies were conducted to evaluate the effects of pH
on various life history stages of yellow perch. Yellow perch
eggs were exposed to four pH levels (5.0 - 7.0) an'd five nominal
aluminum concentrations (0 - 400 ug/L) during a series of flow-
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through experiments (janicki and Greening, 1988). They reported
that mean egg mortality (62%) was significantly greater at pH 5.0
with no aluminum during a 15 d exposure than in the less acidic
test conditions (40 -45%). The addition of aluminum did not
significantly influence mortality rates.
Klauda et al. (1988) reported that yellow perch larvae could
tolerate 12 - 24 h acidic pulses of pH 5.0. These investigators
also reported that 17 d old feeding larvae were more sensitive to
acid pulses of pH 4.0 than were pre@-feeding larvae. They
concluded that yellow perch is a relatively acid tolerant
species that can sustain reproducing populations when mean pH is
5.0. Correll et al. (1987) indicated that significant
differences in the survival of newly hatched (12 h old) yellow
perch larvae existed between pH 5 and 7 even though greater than
50% of the larvae survived at pH 5.0. The addition of 100 ug/L
of nominal inorganic monomeric aluminum at pH 5.0 reduced
survival of yellow perch larvae. from > 50% (pH 5.0 with no
aluminum) to 5% (Swenson et al. 1989). Klauda (1989) proposed
that critical acidic conditions for early life history stages of
yellow perch occur between pH 4.5 - 5.5, and includes inorganic
monomeric aluminum concentrations between 50 - 150 ug/L with
dissolved calcium levels at least 2 mg/L.
The acid tolerance of YOY and adult yellow perch collected
from lakes with ambient pH > 6.0 was tested under laboratory
conditions (Rahel and Magnuson, 1983). It was reported that both
YOY and adults survived longer than 10 d at pH 3.05 in 19 C
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water. Lyons (1982) examined blood sodium concentrations in
adult yellow perch from a naturally acidic (pH 4.6) and a
naturally alkaline lake (pH 7.9). He reported that exposure to
lethal acidity (ph 3.2) for 48 h resulted in significant but
similar decreases in plasma sodium levels in both populations.
Factors other than significant decreases in blood sodium levels
were assumed responsible for mortality in the yellow perch
populations. Rahel (1983) reported that adult yellow perch from
acidic lakes (pH 4.5) survived longer than adults from alkaline
lakes (pH 7.6) when exposed to pH 3.2 for 21 d. This suggests
possible genetic adaptations to low pH conditions. The survival
of adult yellow perch at pH 10.4 was similar for organisms
previously exposed to acidic and alkaline lakes (Rahel, 1983).
Susnended Sediment
Several studies designed to evaluate the effects of
suszended solids an yellow perch eggs and larvae in the
Chesapeake Bay have been conducted. Schubel and Wang (1973)
reported fine-grained suspended sediment in concentrations <500
mg/L had no significant effect on hatching success of yellow
perch eggs. However, they did report a 6 - 12 h delay in
hatching at 100 and 500 mg/L suspensions. Schubel et al. (1973)
conducted additional tests and reported that a 1000 mg/L
suspension significantly reduced hatching success 'of yellow perch
eggs. Conversely, Auld and Schubel (1974) exposed eggs to the
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same conditions and found no significant reduction in hatching
success.
Minimal information exists concerning the effect of
suspended solids on yellow perch larvae. survival was
significantly reduced when yellow perch larvae were exposed for
96 h to concentrations of suspended solids > 500 mg/L (Auld and
Schubel, 1974).
TOXICITY TO SINGLE CHEMICALS
Acute toxicity data for larval and juvenile yellow perch
exposed to 56 single chemicals are presented in Tables 2 and 3,
respectively. The majority of the acute toxicity research for
yellow perch was conducted at the Columbia National Fisherids
Research Laboratory (Mayer and Ellersieck, 1986).
The deleterious effects of total residual chlorine (TRC) to
yellow perch larvae were greatly enhanced in saltwater versus
freshwater. PSE&G (1978) reported 50% mortality when larvae were
exposed to 0.55 mg/L TRC for 0.5 h in 3.5 ppt salinity at 16 C.
Seegert et al. (1977) reported a 24 h LC50 value of 4.0 mg/L TRC
when larvae were exposed for 0.5 h in a freshwater environment
at 15 C. The acute toxicity of one inorganic compound on yellow
perch larvae was investigated by Fung and Bewick (1980). They
reported 1 h LC50 values of 1.55 and 0.046 mg/L hydrogen sulfide
at 10 and 20 C, respectively. Acute toxicity datd for larvae
exposed to 42 organic compounds are presented in Table 2. The
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most toxic substances (expressed as 96 h LC501s) were the
pesticides Antimycin A (0. 040 ug/L) , S-bioallethrin (7.8 ug/L)
DDT (9. 0 ug/L) and toxaphene (12 ug/L) (Mauck et al., 1976; Mayer
and Ellersieck, 1986).
Toxicity data for yellow perch juveniles were available from
six studies (Table 3). Brooks and Seegert (1977) reported 24 h
LC50 values of TRC for YOY yellow perch were inversely related to
temperature. A study by Marking and Olsen (1975) indicated 3-
trifluoromethyl-4-nitrophenol (TFM) was more toxic to juvenile
yellow perch than to older age-0 yellow perch. Toxicity data
from three inorganic compounds (hydrogen cyanide, hydrogen
sulfide and potassium permanganate) are list-ad in 7able 3.
Hydrogen sulfide was the most toxic to juvenile yellow perch
with a 96 h LC50 value of 8 ug/L (Fung and Bewick, 1980). Acute
toxicity data for juveniles exposed to 7 organic compounds are
presented in Table 3. The most toxic chemicals (expressed as 96
h LC50's) were RU-11679 (0.06 ug/L), endrin (0.15 ug/L) and
resmethri.n. (0.51 ug/L) (Mayer and Ellersieck, 1986).
TOXICITY'TO CHEMICAL MIX=ES
One acute toxicity chemical mixture experiment was conducted
with juvenile yellow perch., Seeyle et al. (1988) graphically
presented 24 h LC25 values for numerous combinations of the
piscicides TFX and Bayer-73 at 33 different alkalinities (40 -
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200 mg/L CaC03)- Juvenile yellow perch sensitivity to TFM and
mixtures of TFM and Bayer-73 decreased as alkalinity increased.
IN-SITU STUDIES
Four in-situ contaminant studies have been conducted with
yellow perch eggs, larvae, YOY and adults (Table 4). Schofield
and Driscoll (1987) reported that only 3.8% of the yellow perch
eggs collected in a near-neutral lake.(pH 6.6), with 0 - 30 ug/L
total monomeric aluminum, hatched when placed in an acidic lake
(PH 5.0 with 190 - 230 ug/L total monomeric aluminum) . Hatching
success for eggs spawned and hatched in the neutral lake was
86.2%. A hatching success rate of 43.5% was reported for eggs
deDosited and hatched in the acidic lake (PH 5.0) (Schofield and
Driscoll, 1987). Similar to Rahel (1983), Schofield and Driscoll
(1987) concluded that yellow perch exhibited genetic adaptation
to acid stress. In-situ tests.were also conducted in two
Maryland coastal plain streams by Janicki and Greening (1988).
They reported an 8.4% egg mortality rate as PH decreased to 6.0
and total monomeric aluminum peaked at 55 ug/L during a 4 d storm
event in Mattawoman Creek. In Bacon Ridge Creek, egg mortality
rates ranged from 0.3 - 50.0% as pH decreased to 6.4 and total
monomeric aluminum peaked at 20 ug/L. Janicki and Greening
(1988) did not offer any suggestions as to why higher
mortalities were observed in the less acidic system, although
Klauda (1989) suggested that suspended sediments, turbulence, and
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current velocity may have affected the mortality rates.
Greening et al. (1989) reported that yellow perch eggs were
relatively insensitive to chemical changes during four storm
events in the same two streams studied by Janicki and Greening
(1988). They recorded egg mortality rates of 0 - 23.7% in
Mattawoman Creek at pH minimums of 5.8 - 6.0, dissolved calcium
concentrations of 3.1 - 5.6 mg/L, and total monomeric aluminum
maxima of 69 ug/L. Mortality rates ranged from 2.5 - 12.5 % in
Bacon Ridge Creek as pH ranged from 5.8 - 6.0, dissolved calcium
concentrat" ions were 5.7 - 8.2 mg/L, and total monomeric aluminum
peaked at 52 ug/L.
Greening e"-* al. (1988) also examined mor-tality rates of
larval yellow perch. They reported that larvae were more
sensitive than eggs when exposed to acidic storm events.
Mortality rates for yellow perch larvae in Mattawoman Creek
ranged from 51.5 - 100% as pH minima ranged from 5.8 - 6.3, with
total monmeric aluminum maxima at 69 ug/L and dissolved calcium
between 3.1 - 7.3 mg/L. At Bacon Ridge Creek, a 92.3% larval
mortality rate was recorded at a pH minima of 5.8, with total
monomeric aluminum of 52 ug/L and dissolved calcium between 5.7
8.2 mg/L.
Schofield and Driscoll (1987) reported a 72% survival rate
when YOY perch were transferred from a neutral lake (pH 6.9) to
an acidic lake (pH 4.6) for a 28 d in-situ experiment. They
concluded that non-native species (yellow perch) exhibited
greater acid tolerance than native cyprinids.
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Adult yellow perch were placed into wire' mesh cages in the
Hudson River (below a suspected contaminant source) for 14 d to
show the rapid bioaccumulation of the polychlorinated biphenyl
(PCB), Aroclor 1016 (Skea et al., 1979). Control groups were
located upstream of the suspected contaminant source. The PCB
concentration was calculated daily from the river water below
the contaminant source. Concentrations of Aroclor 1016 found
within the exposed adult yellow perch were greater than 10,000
times the concentrations present in the water.
CONCLUSIONS
1. Yellow perch populations within the Chesapeake Bay have 01
declined in recent years. Spawning occurs in poorly buffered
coastal plain freshwater tributaries of the Chesapeake Bay.
Eggs and larve are thus exposed to potentially deleterious
acidic pulses.
2. Hatching occurred in 2 d at 18.2 C, while 30.5 d were
required at 3.3 C. Median thermal tolerance limits for
yellow perch eggs were 7 20 C. Feeding larvae tolerated a
temperature range of 10 30 C, while 20 - 24 C appears to be
the optimum range. optimum growth conditions for juveniles
occurred at 22 C with 16 h of light. A diel temperature
preferenda was reported for age-O yellow perch; maximun
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preferred temperature occurred at dusk. The physiological
optimum temperature for adult yellow perch is 24.7 C.
3. Spawning occurs in freshwater and brackish water with less
than 2.5 ppt salinity. Hatching success of yellow perch
decreased as salinity increased from 0 - 2.4 ppt salinity.
Larvae survived for 72 h at salinities < 6 ppt, but no
survival was observed after 48 h exposure to salinities > 12
ppt. Adults have been collected in salinities ranging from 0
15 ppt.
4. A dissolved oxygen (D.O.) concentration of 0.84 mg/L was
lethal to larval yellow perch exposed at 23 C, but was not
lethal after exposure at 15 C. Growth of age-O yellow perch
was significantly reduced when D.O. concentrations were < 2.0
mg/L.
5. Yellow perch is considered a relatively acid tolerant
species, however, the data suggests adults can survive and
spawn in acidic waters that are potentially detrimental to
fertilized eggs. Mortality of yellow perch eggs was
significantly greater at pH 5.0 than at other less acidic
conditions. Larvae tolerated a 12 - 24 h exposure to an acid
pulse of > pH 5.0, while survival decreased from > 50% to 5%
with the addition of 100 ug/L aluminum at pH 5.0. A proposed
critical acidic condition exists for early life stages of
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yellow perch exposed to pH 4.5 - 5.5, with inorganic
monomeric aluminum concentrations between 50 - 150 ug/L and
dissolved calcium levels at least 2 mg/L. Adult yellow perch
collected from naturally acidic waters (pH 4.5) exhibit a
possible genetic adaptation to low pH conditions over adults
from alkaline lakes (pH 7.6).
6. Concentrations of 100 - 500 mg/L suspended solids caused a 6
- 12 h delay in hatching of yellow perch eggs. Survival of
larvae was significantly reduced when exposed for 96 h to
concentrations > 500 mg/L suspended solids.
7. Acute toxicity data for larval yellow perch exposed to 44
single chemicals indicated that the pesticides Antimycin- A,
S-bioallethrin, DDT and toxaphene were most toxic. Toxicity
data for juveniles exnosed to 13 single chemicals indicated
the insecticides RU-11679, endrin, and resmethrin were most
toxic.
8. An inverse relationship existed between alkalinity and the
sensitivity of juvenile yellow perch to 3-trifluoromethyl-4-
nitrophenol (TFM) and mixtures of TFM and Bayer-73.
9. Field studies revealed that less than 50% of the eggs hatched
from a yellow perch population indigenous to an acidic lake
(pH 5.0). In-situ tests also indicated that yellow perch
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larvae are more sensitive than egg stages when exposed to
critical acidic storm events.
10. An in-situ experiment demonstrated the rapid (14 d)
bioaccumulation of the PCB Aroclor 1016 in adult yellow perch
from the Hudson River.
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Marking, L. L. and Bills, T. D. Toxicity of potassium
permanganate to fish and its effectiveness for detoxifying
antimycin. Trans. Am. Fish. Soc. 104:579-583; 1975.
Marking, L. L. and Olson, L. E. Toxicity of the lampricide 3-
trifluoromethyl-4-nitrophenol (TFM) to nontarget fish in
20
�
static tests. Investigations in Fish Control No. 60; U.S.
Fish Wildl. Serv.; Washington, DC; 1975.
Mauck, W. L.; Olson, L. E. and Marking, L. L. Toxicity of
natural pyrethrins and five pyrethroids to fish. Arch.
Environm. Contam. Toxicol. 4:18-29; 1976.
Mayer, F. L. and Ellerseick, M. R. Manual of acute toxicity.
U.S. Fish Wildl. Serv., Res. Publ. 160; 1986, 506 p.
McCauley, R. W. and Read, L. A. A. Temperature selection by
juvenile and adult yellow perch (Perca flavescens)
acclimated'to 24 C. J. Fish. Res. Board Can. 30:1253-1255;
1973.
McCormick, J. H. Temperature effects on young yellow perch,
Perca flavescens. EPA-600/3-76-057, U.S. Environ. Protect.
Agency, Duluth, MN; 1976, 25 p.
Meldrim, J. W. and Gift, J. J. Temperature preference, avoidance
and shock exmeriments with estuarine fishes. Ichtyological
Associates, Inc., Bull. 7. Middletown, DE; 1971, 75 p.
Muncy, R. J. Life history of yellow perch in Severn River.
Ches. Sci. 3:143-159; 1962.
Neill, W. H. and Magnuson, J. J. Distributional ecology and
behavioral.thermoregulation of fishes in relation to heated
effluent from a power plant at Lake Monona, Wisconsin.
Trans. Am. Fish. Soc. 106:663-710; 1974.
Olson, L. E. Dinitramine: residues in and toxicity to
freshwater fish. J. Agr. Food Chem. 23:437;'1975.
21
�
Petit, G. D. Effects of dissolved oxygen on survival and
behavior of selected f ishes of western Lake Erie. Ohio
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Newark, NJ; 1978.
Rahel, F. J. Population differences in acid tolerance between
yellow perch, Perca flavescens, from naturally acidic and
alkaline lakes. Can. J. Zool. 61:147-152; 1983.
Rahel, F. J. and Magnuson, J. J. Low pH and the absence of fish
species in naturally acidic Wisconsin lakes: inferences for
cultural acidification. Can. j. Fish. Aquat. Sci. 40:3-9;
1983.
Reynolds, W. W. and Casterlin, M. E. Behavioral thermoregulation
and locomotor activity of Perca flavescens. Can. J. Zool.
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91:406-410; 1977.
Ross, M. J. and Siniff, D. B. Temperatures selected in a power
plant thermal effluent by yellow perch (Perca flavescens) in
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Schofield, C. L. and Driscoll, C. T. Fish species distribution
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of the Moose River basin. Biogeochem.. 3:63-85; 1987.
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Schubel, J. R.; Auld, A. H. and Schmidt, G. M. Effects of
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Southeast. Assoc. Game Fish Comm. 27:689-694; 1973.
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sediment on the hatching success of Perca flavescens (yellow
perch), Morone americana (white perch), Morone saxatilis
(striped bass), and Alosa pseudcharencrus (alewife) eggs.
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Biofouling Control Procedures Technology and Ecological
Effects, Marcel Dekker, Inc., New York, NY; 1977, p. 91-100.
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Guide for determining application rates of lampricides for
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1016 in Hudson River fish. Bull. Environm. Contam. Toxi@ol.
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and Eaton, J. G. Experimental acidification of Little Rock
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1989.
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Sci. 43:1298-1306; 1986.
24
�
Table I. Toxic water quality parameters adversely affecting various life stages of yellow
perch.
Parameter Life Stage Data Reference
Temperature Egg Tolerance range of 7 - 20C Hokanson, 1977
Temperature Egg LC50 range of 6..8 - 19.9C Hokanson and
Kleiner, 1974
Temperature Larvae Primary entrainment was PSE&G, 1978
simulated. Significant
mortality occurred only
as the result of a 15C
temperature increase when
acclimated between 13.5 - 17C.
Ln Temperature Larvae A preference range of 21.7 - Ross et al,
24.3C was reported when 1977
acclimated between 20 - 25C.
Temperature Larvae No significant difference PSE&G, 1978
occurred in mortality
between controls and
expe'rimental treatments
when exposed to a 2.5 - 8.OC
temperature increase for
0.5 - 411. Acclimation was
16.5C.
Temperature Larvae 63% survival occurred during Hale and
a feeding study after 3 weeks Carlson, 1972
at 20 - 21C.
�
Table 1. (Continued)
Parameter Life Stage Data Reference
Temperature Larvae At 12.5C three of seven groups Hubbs, 1971
fed, while one of nine fed at
9.5C.
Temperature Larvae Tolerance range for feeding Hokanson, 1977
larvae was 10 30C.
Temperature Juvenile Temperature preference ranged Cherry et al,
from 19.2 - 22.4C when 1977
acclimated at 15, 18, 21, and
24C.
Temperature Juvenile Growth tolerance range was Hokanson, 1977
6 - 31C.
Temperature Juvenile A temperature range of 20 - McCauley and
23.3C was selected when Road, 1973
acclimated at 24.
Temperature Juvenile Greatest weight gain occurred Huh et al,
at 22C with 16h of light. 1976
Data suggests photoperiod
influences growth much more
than temperature.
Temperature Age-O Diel preferred temperatures Reynolds
of 16.7C (predawn) and and Casterlin,
23.8C (dusk) were exhibited 1979
when acclimated at 20C.
�
Table 1. (Continued)
Parameter Life Stage Data Reference
Temperature Age-O and Fish were collected seasonally Hokanson and
Adults from Lake Erie. Age-0 fish Kleiner,
preferred temperatures 4C or 1974
greater than those preferred
by adults during spring,
summer and fall, but preferred
water 2C lower than adults
during winter.
Temperature Adults A temperature of 6.3C was Ross and
perferred when exposed to a Siniff,
winter thermal plume 1982
considting of a 0 - 15C
thermal gradient.
Temperature Adults Selected a temperature range McCauley
of 17.6 - 20.1C when and Reed,
acclimated to 24C. 1973
Temperature. Adults Preferred 23.5C when Meldrim and
acclimated at 15C in 6 ppt Gift, 1971
salinity. Preferred 22.5C
when acclimated at 25C in
freshwater.
Similar avoidance temperatures
(33.3 - 33.9C) were selected
when acclimated at 25C but
different light levels (2 and
20 ft. - candles).
�
Table 1. (Continued)
Parameter Life Stage Data Reference
Temperature Adults Fish acclimated in freshwater PSE&G, 1978
to 25C avoided areas 31 - 34C,
while those acclimated to 6C
avoided 14 - 18C. Fish
acclimated to 6C in 1.5 ppt
salinity avoided.27C.
Salinity Egg Hatching success was: Muncy, 1962
65-68% in freshwater
56% in 0.47 2.43 ppt salinity
42% in 0.1 0.94 ppt salinity
55% in 5.8 ppt salinity
0% in 11.7 ppt salinity
tI3 Salinity Larvae. 8 and 26d, old larvae were Klauda at al,
CO exposed to 3, 6, 12 and 24 1988
ppt salinity for 72h. No
survival occurred in either
group after 48h exposure in
12 - 24 ppt salinity. Mortality
for Od old larvae ranged from
40 - 25% after 72h exposure to
3 - 6 ppt salinity. Mortality of
26d old larvae ranged from 28 -
18% after 72h exposure to 3 - 6
ppt salinity.
�
Table 1. (Continued)
Parameter Life Stage Data Reference
Dissolved Oxygen Juvenile Exposed for 67d to five Carlson et al,
concentrations of 1980
dissolved oxygen (2.0 - 6.5
mg/L). Growth was not
reduced when mean constant
dissolved oxygen level was
@-- 3.5mg/L. Growth was not
affected at fluctuations of
1.4 - 3.8 mg/L.
Dissolved Oxygen Age-0 Fish at 22.95C were exposed Petit, 1973
to disolved oxygen concentrations
between 1 - 5 mg/L. At 5 mg/L
opercular movements increased;
4 mg/L there was loss of normal
coloration; 2 mg/L cessation of
feeding; loss of equilibrium at
1 mg/L. Lethal level occurred
at 0.895 mg/L for individuals
and 0.839 mg/L for groups of four.
No lethal level found when
acclimated at,15.1C.
pH Egg Exposed to p1l 5, 5.5, 6 and 7 Janicki and
and nominal aluminum (0 - 400 Greening,
pg/L). 62% mortality after 1988
15d exposure to pH 5.0 with
no altii-inum. Mortality in
less acidic conditions (40
45%) was significantly less
than at p1l 5.0. Addition
of aluminum did not significantly
affect mortality. Temp = 12 - 15C.
�
Table 1. (Continued)
Parameter Life Stage Data Reference
P11 Larvae At p1l 5.0 with 100 Mg/L Swenson et al,
aluminum (Al) survival 1989
declined significantly to
5% compared to > 50% survival
in the other pil 5.0 treatments.
The addition of 100 pg/L Al at
p1l 4.5 resulted in total
mortality.
pH Larvae 17d old feeding larvae were Klauda et al,
more sensitive to acid 1988
pulses of p1l 4.0 than pre-
feeding larvae. Mean
mortalities of feeding
larvae during a 12h pulse
were 98% at pil 4, 4% at
pH 5 and 8% at p1l 6. Mean
mortalities of pre-feeding
larvae during a 12h pulse
were 22% at pli 4, 2% at pil 5
and 0% at pff 6.
Pulse durations did not affect
larval mortality at p1l 5 or 6.
pit Larvae >50% survival occurred at p1l Correll et al,
5.0. significant difference 1987
in survival occurred between
pil 5 and 7, while both
significantly reduced overall
survivability.
�
Table 1. (Continued)
Parameter Life Stage Data Reference
pit Adult Exposure to lethal-acidity Lyons, 1982
(pit 3.2) for 48h resulted in
significant but similar
decreases in blood plasma
sodium levels in both
populations. Fish were
from a naturally acidic
lake (pit 4.6) and a naturally
alkaline lake (pit 7.9).
pH Adult Fish from acidic lakes (pit 4.5) Rahel, 1983
survived longer than fish from
alkaline lakes (pit 7.6) when
exposed to pit 3.2 at 18 - 20C
Li in a laboratory. Acclimation to
sublethal pit (4.6) for 21d did not
affect acid tolerance. Suscepti-
bility to lethal high pH (10.4)
was shnilar for acidic and
alkalini-.! acclimated fish.
pit Adult Survived longer than 10d in a Rahel and
lab experiment at pit 3.05 and Magnuson,
19C. Collected from wild in 1983
lakes with ambient pit > 6.0.
Suspended Solids Egg Exposures of 50, 100, 500 Schubel et al,
and 1000 mg/L were used. @1973
A significant decrease in
hatching success occurred
when exposed to 1000 mg/L
�
Table 1. (Continued)
Parameter Life Stage Data Reference
Suspended Solids Egg Hatching success was not Sdwbel and Wang,
affected by concentrations 1973
:5 500 mg/L. A 6 - 12h
hatching delay occurred
at 100 and 500 ing/L
suspensions.
Suspended Solids Egg Exposures of 50, 100, 500 Auld and
and 1000 mg/L were used. Schubel,
No significant reduction in 1974
hatching success was reported.
Suspended Solids Larval Suspensions ?-- 500 mg/L Auld and
significantly reduced survival Schubel,
when exposed for 96h. 1974
�
Table 2. Toxicity data for yellow perch larvae exposed to various single chemicals. All
studies were static unless otherwise noted. (FT flow through)
Water Quality
Water Temp. Hardness
chemical Type (CO) PH (mg/L) Data References
(CaC03)
Acephate (Insecticide) Fresh Mayer and
94% Tech material 12 7.5 42 96h LC50 > 50000 jug/L Ellersieck,
75% Wettable powder 12 7.5 42 96h LC50 > 100000 pg/L 1986
75% Wettable powder 12 6.5 42 96h LC50 > 100000 pg/L
75% Wettable powder 12 9.0 42 96h LC50 > 100000 pg/L
75% Wettable powder 12 8.0 12 96h LC50 > 100000 pg/L
75% Wettable powder 12 8.0 44 96h LC50 > 100000 pg/L
75% Wettable powder 12 8.0 300 96h LC50 > 100000 pg/L
Aninocarb (Herbicide) Fresh
98% Tech 12 7.5 40 96h LC50 = 6400 Ag/L
98% Tech 12 7.5 40 96h LC50 = 230 pg/L
17% Oil soluble 12 7.5 40 96h LC50 = 11700 jjg/L
98% Tech 7 7.5 40 96h LC50 = 5600 pg/L
98% Tech 12 7.5 40 96h LC50 - 4700 Mg/L
98% Tech 17 7.5 40 96h LC50 = 1700 pg/L
98% Tech 22 6.5 40 96h LC50 - 6400 pg/L
98% Tech 12 7.5 40 96h LC50 - 7000 pg/L
98% Tech 12 8.5 40 96h LC50 = 1430 pg/L
98% Tech 12 9.0 40 96h LC50 = 425 pg/L
98% Tech 12 8.0 40 96h LC50 = 5400 pg/L
98t Tech 12 8.0 40 96h LC50 = 6200 pg/L
98% Tech 12 8.0 1.60 96h LC50 = 7400 pg/L
98% Tech 12 8.0 280 96h LC50 = 5600 Mg/L
Antimycin A (Piscicide) Fresh
95.5% Tech 12 7.4 44 96h LC50 0.040 gg/L
�
Table 2. (Continued)
Water Quality
Chemical Water Temp. Hardness
Type (C-) P11 (mg/L) Data References
(CaCO 3)
Azinphos-methyl
(Insecticide) Fresh
93t Tech 16 7.1 44 96h LC50 = 15 Ag/L
93% Tech 7 7.5 44 96h LC50 - 40 Ag/L
93% Tech 17 7.5 44 96h'LC50 = 5.6 pg/L
93% Tech 22 7.5 44 96h LC50 = 2.4 Ag/L
93% Tech 12 6.5 44 96h LC50 = 17 Ag/L
93% Tech 12 7.5 44 96h LC50 = 29 jig/L
93% Tech 12 8.5 44 96h LC50 = 8.5 Ag/L
93% Tech 12 9.0 44 96h LC50 = 29 Mg/L
93% Tech 12 B.0 12 96h LC50 = 18 Mg/L
93% Tech 12 8.0 44 96h LC50 = 36 Ag/L
93% Tech
12 8.0 170 96h LC50 = 11 Ag/L
93% Tech 12 8.0 300 9 611 LC50 = 27 Ag/L
93% Tech (FT) 12 7.5 314 96h LC50 = 6.5 Mg/L
Captan (Fungicide) Fresh
90% (FT) 17 7.5 314 96h LC50 = 120 pg/L-
Carbaryl, (Insecticide) Fresh
99.5% Tech 18 7.1 40 96h LC50 = 745 pg/L
99.5% Tech 12 7.5 42 96h LC50 = 5100 pg/L
99.5% Tech 7 7.5 42 96h LC50 = 13900 pg/L
99.5% Tech 12 7.5 42 96h LC50 = 5400 pg/L
99.5% Tech 17 7.5 42 .96h LC50 = 3400 pg/L
99.5% Tech 22 7.5 42 96h LC50 = 1200 pg/L
99.5% Tech 12 6.5 42 96h LC50 = 4000 pg/L
99.5% Tec 12 7.5 42 96h LC50 = 4200 pg/L
99.5% Tech 12 8.5 42 96h LC50 = 480 Ag/L
99.5% Tech 12 9.0 42 96h LC50 = 350 Ag/L
99.5% Tech 12 .8.0 42 9 6h LC50 = 3BOO pg/L
99.5% Tech 12 8.0 170 96h LC50 = 5000 Mg/L
99.5% Tech 12 8.0 300 96h LC50 = 3750 jig/L
�
Table 2. (Continued)
Water Quality
Water Temp. flardness
Chemical Type (C*) P11 (mg/L) Data References
(CaC03)
Carbaryl (Insecticide) Fresh
99% Tech 12 7.5 44 96h LC50 = 240 Ag/L
99% Tech 12 9.5 42 96h LC50 = 120 pg/L
99% Tech 12 7.5 44 96h.LC50 - 400 pg/L
Chlordane (Insecticide) Fresh
100% Tech (FT) 12 7.1 44 96h LC50 = 9.6 Mg/L
DDT (Insecticide) Fresh,
99% Tech 18 7.1 44 96h LC50 = 9.0 pg/L
Diflubenzuron (Insecticide) Fresh 12 7.4 44 96h LC50 > 50000 Mg/L
Lj 95% Tech 12 7.4 40 96h LC50 > 25000 Ag/L
V1 95% Tech
Dimethrin (Insecticide) Fresh
100% Tech 12 7.5 44 96h LC50 - 28 Mg/L
Dinitramine (Herbicide) Fresh
99.2% Tech 12 7.5 44 96h LC50 = 1000 pg/L
99.2% Tech (FT) 12 7.5 314 96h LC50 = 780 pg/L
Diquat (Herbicide) Fresh
35.3% Liquid Concentrate 12 7.5 44 96h LCSO = 60000 pg/L
35.3% Liquid Concentrate 12 9.5 44 96h LC50 = 23500 pg/L
�
Table 2. (Continued)
Water Quality
Water Temp. Hardness
Chemical Type (CO) PH (mg/L) Data References
(CaCO 3)
Fenitrothion (Insecticide) Fresh
95% Tech 12 7.5 40 96h LC50 = 5800 pg/L
40% Wettable Powder 12 7.5 42 96h LC50 = 2700 pg/L
40% Wettable Powder 12 7.5 42 96h LC50 = 4700 Mg/L
40% Wettable Powder 7 7.5 42 96h LC50 = 2600 Ag/L
40% Wettable Powder 12 7.5 42 96h LC50 = 3500 Mg/L
40% Wettable Powder 17 7.5 42 96h LC50 = 3000 pg/L
40% Wettable Powder 12 6.5 42 96h LC50 = 4800 Mg/L
40% Wettable Powder 12 7.5 42 96h LC50 - 2900 pg/L
40% Wettable Powder .12 8.5 42 96h LC50 - 3500 pg/L
40% Wettable Powder 12 9.0 42 96h LC50 = 3200 pg/L
40% Wettable Powder 12 8.0 44 96h LC50 = 3900 pg/L
40% Wettable Powder 12 8.0 170 96h LC50 - 2000 pg/L
40% Wettable Powder 12 8.0 300 96h LC50 = 3700 pg/L
Fenthion (Insecticide) Fresh
46% spray concentrate 18 7.1 44 96h LC50 = 1650 pg/L
Folpet (Fungicide) Fresh
88% Tech 12 7.5 44 96h LC50 = 177 pg/L
Houghto - Safe 1120
(Hydraulic fluid)
100% liquid 12 7.5 314 96h LC50 = 500 pg/L
�
Table 2. (Continued)
Water Quality
Water Temp. Hardness
chemical Type (CO) P11 (mg/L) Data References
(CaCO,)
Leptophos (Insecticide) Fresh
87.2% Tech 12 7.4 44 96h LC50 = 2000 Mg/L
87.2% Tech 12 7.4 44 96h LC50 = 1320 Mg/L
87.2% Tech 7 7.4 44 96h LC50 = 3750 pg/L
87.2% Tech 12 7.4 44 96h*LC50 < 500 pg/L
87.2% Tech 22 7.4 44 96h LC50 < 25 Mg/L
87.2% Tech 12 9.0 44 96h LC50 = 680 pg/L
87.2% Tech 12 8.5 44 96h LC50 = 150 pg/L
87.2% Tech 12 7.5 44 96h LC50 = 690 jig/L
87.2% Tech 12 6.5 44 96h LC50 - 140 pg/L
87.2% Tech 12 8.0 12 96h LC50 = 270 pg/L
87.2% Tech 12 8.0 44 96h LC50 = 2500 gg/L
87.2% Tech 12 8.0 170 96h LC50 - 950 pg/L
87.2% Tech 12 8.0 300 96h LC50 - 880 fig/L
87.2% Tech 12 8.0 44 96h LC50 - 2050 14g/L
87.2% Tech (FT) 12 7.6 314 96h LC50 = 7.0 pg/L
Malathion (Insecticide) Fresh
95% Tech 18 7.1 44 96h LC50 - 263 Mg/L
Methoxychlor (Insecticide) Fresh
98% Tech 12 7.5 40 96h LC50 = 30.0 14g/L
50% Granular 12 7.5 40 96h LC50 = 17.5 jig/L
98% Tech 12 7.5 42 96h LC50 > 50 pg/L
98% Tech (FT) 12 7.5 314 .96h LC50 > 20 pg/L
Methyl Parathion
(Insecticide) Fresh
90% Tech 18 7.1 44 96h LC50 3060 pg/L
�
Table 2. (Continued)
Water Quality
Water Temp. Hardness
Chemical Type (CO) PH (mg/L) Data References
(CaC03)
Mexacarbate (Insecticide) Fresh
90% Tech 12 7.5 44 96h LC50 - 16200 gg/L
90% Tech 17 7.5 44 96h LC50 = 16900 gg/L
90% Tech (FT) 12 7.5 314 96h LC50 = 8300 pg/L
Mirex (Insecticide) Fresh
98% Tech 15 7.4 40 96h LC50 > 100000 gg/L
Paroil 1032 (Plasticizer) Fresh
100% liquid (FT) 12 7.5 314 96h LC50 > 5000 pg/L
Paroil, 10@B (Plasticizer) Fresh
Li 100% liquid (FT) 12 7.5 314 96h LC50 > 10000 gg/L
Paroil 160 (Coolant) Fresh
100% liquid (FT) 12 7.5 314 96h LC50 > 10700 gg/L
PCB Arochlor (Industrial) Fresh
1016 100% Tech 12 7.4 44 96h LC50 = 240 Mg/L
1242 100% Tech (FT) 17 7.6 314 96h LC50 > 150 Mg/L
1248 100% Tech (FT) 17 7.6 314 96h LC50 > 100 pg/L
1254 100% Tech (FT) 17 7.6 314 96h LC50 > 150 pg/L
1260 100% Tech (FT) 17 7.6 314 96h LC50 > 200 pg/L
Phthalate Dibutyl
(Plasticizer) Fresh
1001 liquid (FT) 12 7.6 314 96h LC50 350 gg/L
Pydraul 50E
(Hydraulic fluid) Fresh
100% liquid (FT) 12 7.8 300 96h LC50 540 gg/L
�
Table 2. (Continued)
Water Quality
Water Temp. Hardness
Chemical Type (CO) P11 (mg/L) Data References
(CaC03)
S-Bioallethrin
(Insecticide) Fresh
98% Tech 12 7.5 44 96h LC50 m 7.8 Ag/L
Toxaphene (Insecticide) Fresh
100% Tech 18 7.4 44 9 611 LC50 = 12 Mg/L
Trichlorfon (Insecticide) Fresh
98% Tech 12 7.5 40 96h LC50 > 10000 gg/L
Tricresyl Phosphate
(Industrial) Fresh
100% Tech (FT) 12 7.4 242 96h LC50 = 500 pg/L
Xylenol Dimethylamino
(metabolite) Fresh
99% Tech 12 7.5 44 96h LC50 = 3400 gg/L
99% Tech 12 9.5 44 96h LC50 - 100 gg/L
Dinitramine (lierbicide) Fresh 12 7.5 42 96h LC50 = 1000 gg/L Olson et al,
1975
Pyrethrum, extract Fresh Mauck et al,
20% (FT) 12 96h LC50 = 44.5 gg/L 1976
Dimethrin Fresh
96% Tech 12 96h LC50 = 28 jig/L
d-Trans allethrin Fresh
90% Tech (FT) 12 96h LC50 = 9.9 pg/L
RU-11679 Fresh 12 96h LC50 = 0.06 pg/L
�
Table 2. (Continued)
Water Quality
Water Temp. 11ardness
Chemical Type (CO) PH (mg/L) Data References
(CaCO,)
S-bioallethrin Fresh 12 96h LC50 = 7.8 pg/L
SBP-1382 Fresh
89t Tech (FT) 12 96h LC50 = 0.5 Mg/L
Total Residual saline 16 Approximately 50t PSE&G, 1978
Chlorine (TRC) (3.50/oo) mortality after
0.5h exposure to
550 pg/L TRC. No
survival after 0.5h
exposure to 2300 pg/L
TRC.
46 TRC Fresh 10 24h LC50 = 7700 pg/L Seegert
0 15 24h LC50 = 4000 pg/L et-al, 1977
20 96h LC50 = 1100 Mg/L
25 96h LC50 = 1100 pg/L
Hydrogen Sulfide Fresh 10 7.5 96h LC50 = 2 Mg/L Fung and
20 8.0 96h LCSO < 2 Mg/L Bewick,
1980
1111 MINE 0 1 IN@ 11 11 1 1 1 1
�
Table 3. Toxicity data for juvenilq yellow perch exposed to various single chemicals.
All studies were static unless otherwise noted. (FT = flow through)
Water Quality
Water Temp. Hardness
chemical Type (CO) P11 (mg/L) Data References
(CaCO 3)
Carbaryl (Insecticide) Fresh Mayer and
99.5% Tech (FT) 12 7.5 314 96h-LC50 = 1420 Ag/L Ellersieck,
1986
D-trans Allethrin
(Insecticide) Fresh
90% Tech (FT) 12 7.5 314 96h LC50 = 9.9 pg/L
Endrin (Insecticide) Fresh
99A Tech (FT.) 12 7.6 314 96h LC50 = 0.15 pg/L
Phoxim (Insecticide) Fresh
89% Tech 12 7.5 44 96h LC50 - 605 pg/L
89% Tech 17 7.5 44 96h LC50 = 563 pg/L
89% Tech (FT) 12 7.5 314. 96h LC50 = 710 jig/L
Pyrethrum (Insecticide) Fresh
20% liquid (FT) 12 7.6 314 96h LC50 = 33 pg/L
Resmethrin (Insecticide) Fresh
84% Tech (FT) 12 7.6 314 96h LC50 = 0.51 pg/L
RU-11679 (Insecticide) Fresh
96W Tech (FT) 12 7.6 314 96h LC50 = 0.06 jug/L
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Table 3. (Continued)
Water Quality
Water Temp. Hardness
Chemical Type (CO) P11 (mg/L) Data References
(CaC03)
TRC Fresh Effects of one 0.5h Brooks and
exposure Seegert,
10 24h LC50 - 6000 Mg/L 1977
15 24h'LC50 - 3900 Ag/L
20 24h LC50 = 1100 pg/L
.25 24h LC50 = 1000 Mg/L
30 24h LC50 = 700 pg/L
Effects of three
5 min. exposures
3 h apart
10 24h LC50 = 22600 pg/L
20 24h LC50 - 9000 Mg/L
Hydrogen Sulfide Fresh 10 7.5 96h LC50 - 36 Mg/L Fung and
20 8.0 96h LC50 = 8 Mg/L Bewick,
1980
Hydrogen Cyanide Fresh 15 96h LC50 = 90.4 pg/L Smith, 1978
(HCN) 21 96h LC50 = 108 Ag/L
An inverse relationship
existed between organism
sensitivity to HCH and
dissolved oxygen
concentration at 21C.
Potassium Permanganate Fresh 12 7.5 44 96h LC50 = 2830 pg/L Marking and
Bills, 1975
3-trifluoromethyl- Fresh 12 96h LC50 = 9400 pg/L Marking and
4-nitrophenol (TFM) (FT) 12 96h LC50 = 4400 pg/L Olsen, 1975.
M mill I II I
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Table 4. In-situ water quality and contaminant studies conducted with various life stages
of yellow perch.
Parameter Life @7tiqe Data Reference
PH Egg Temp = 10.3 - 10.9.C. Schofield and
Poor hatching success occurred Driscoll,
as a result of alterations in 1987
egg membrane structure inhibiting
process. This suggests possible
genetic adaptation to acid
stress.
Mortality rates:
Egg Source
Incubation Moose Mos
Site __Lpff 5. 0) (01 6. 6)
Moose 43.5% 3.8
Moss 77.0% 86.2
PH YOY YOY were transferred from an Schofield and
alkaline lake (pH 6.9) to an Driscoll,
acidic lake (PH 4.6) where 1987
cages were monitored for 28 d.
72% survival rate was recorded..
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Table 4. (Continued)
Parameter Life Stage Data Reference
pH and Aluminum Egg Mattawoman_free%: Janicki and
(Al) egg mortality = 8.4% Greening,
P11 minima = 5-8 7 6.0 1988
Total monomeric Al maxima 55 Ag/L
Dissolved calcium @-- 4.8 mg/L
Bacon Ridge Creek:
egg mortality = 50%
p1l minima = 5.8 - 6.0
Total monomeric Al maxima = 52 Mg/L
Dissolved calcium = 5.7 - 8.2 mg/L
pH and Al Larvae Mattawoman Creek: Greening et
Larval mortality - 51.5 - 100% al., 1989
p1l minima - 5.8 - 6.3
Total monomeric Al maxima - 69 Mg/L
Dissolved calcium 3.1 - 7.3 mg/L
Bacon-Rid e Creek:
Larval mortality = 92.3%
p1l minima = 5.8
Total monomeric Al maxima = 52 pg/L
Dissolved calcium 5.7 mg/L
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-M @M AM. IM 'M ''M -'M. M M
Table 4. (Continued)
Parameter Life Stage Data Reference
Archlor 1016 (PCB) Adult Fish were collected from a nearby Skea et al.,
nearby lake and.exposed for 14d 1979
to Hudson River water. Fish had
bioacctimulated 1.8 jig/g of Arochlor
101(,. ,Iiile controls (up river)
had residues < 0.02 pg/g. Perch
bioaccumulated approximately
10400 times the concentration
present within the water (0.17 Mg/L).
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