Longevity of Bolbophorus damnificus infections in channel catfish

The digenean Bolbophorus damnificus infects commercial channel catfish Ictalurus punctatus, causing mortality, lower feed consumption, and reduced growth in surviving fish. The purpose of this study was to determine the length of time for which B. damnificus prodiplostomulum metacercariae (juvenile trematode stage that infects fish) would remain viable (parasite appearing to be intact or exhibiting movement) in channel catfish. Fish (n = 210) were infected with molecularly confirmed B. damnificus cercariae harvested from naturally infected marsh rams-horn snails Planorbella trivolvis. During the first sampling (at 20 d postinfection), 8.3 +/- 3.6 metacercariae/fish (mean +/- SD) were found in the host muscle and visceral organs. The channel catfish were then acclimated to a water temperature of either 18 degrees C or 28 degrees C. After 11 months, 6.8 +/- 3.5 and 5.9 +/- 3.0 metacercariae/fish were found in groups held at 18 degrees C and 28 degrees C, respectively. The mean number of parasites per fish did not significantly differ between fish held at the two temperatures and did not significantly decline over time at either temperature. Fish examined from 13 to 30 months postinfection all contained viable metacercariae that were morphologically and molecularly identified as B. damnificus. At 18 months, 12 metacercariae (of which 11 were intact and 10 displayed movement) were found in the one fish sampled; at 30 months, the last fish sampled contained three intact metacercariae (one displayed slight movement). Our results indicate that B. damnificus metacercariae can remain viable in channel catfish for at least an 18-30-month production cycle during which they have the potential to affect fish growth; in addition, infected fish may serve as intermediate hosts for these metacercariae for at least 2.5 years postinfection.     

Comparative Susceptibility of Channel Catfish,Blue Catfish,and their Hybrid Cross to Experimental Challenge with Bolbophorus damnificus (Digenea: Bolbophoridae) Cercariae

Abstract

The digenetic trematode Bolbophorus damnificus has been implicated in significant losses in catfish aquaculture since the late 1990s. The complex life cycle sequentially involves the American white pelican Pelecanus erythrorhynchos, the marsh rams horn snail Planorbella trivolvis, and Channel Catfish Ictalurus punctatus. Research supports anecdotal reports from the industry, suggesting that the hybrid of Channel Catfish×Blue Catfish I. furcatus is less susceptible to disease agents that have been historically prohibitive to Channel Catfish production, namely the gram-negative bacteria Edwardsiella ictaluri and Flavobacterium columnare, as well as the myxozoan parasite Henneguya ictaluri. This current research compared the susceptibility of Channel Catfish, Blue Catfish, and their hybrid cross to an experimental challenge by B. damnificus. Fish were exposed to 0, 100, 200, and 400 B. damnificus cercariae per fish, and the numbers of metacercariae per fish were determined 14 d postchallenge. Metacercariae were recovered from all challenged fish. There were no significant differences among fish groups challenged with the same dose, suggesting Channel and Blue Catfish and their hybrid are comparably susceptible to B. damnificus infection. As such, it is recommended that producers raising hybrid catfish remain diligent in controlling populations of the snail intermediate host to prevent production losses attributed to B. damnificus, especially when loafing pelicans have been observed at the aquaculture operation.

Received October 22, 2013; accepted January 5, 2014     

Experimental Induction of Proliferative Gill Disease in Specific-Pathogen-Free Channel Catfish

Abstract

Specific-pathogen-free channel catfish Ictalurus punctatus were exposed to sediment and mud from a pond containing channel catfish with proliferative gill disease. In one experiment, fish were to exposed to mud and sediment for 2 months in water maintained at 19°C. Fish were necropsied weekly, and certain tissues were examined histologically and ultrastructurally. Four trials were conducted with sediment samples from different epizootics of proliferative gill disease. In a second experiment, fish were exposed to sediment for 7 d in water maintained at 16, 19, or 26°C; the fish were then moved to clean water held at 16, 19, or 26°C. Fish were necropsied before transfer to clean water and weekly thereafter for 2 months. Channel catfish held at 19°C developed proliferative gill disease within 2 d of exposure to sediment. Primary cells of a uninucleate myxosporean parasite were present in the gills at the base of lamellae. These developed into plasmodia with numerous secondary cells, and some primary cells disintegrated, releasing their internal secondary cells. Similar development was observed in internal organs 1 week after appearance of the parasite in gills. Complete sporogony did not occur over the 2 months of this study. Plasmodia became necrotic and were not detected after 60 d. In fish exposed to sediment for 7 d at 16, 19, and 21°C, similar organisms were detected, but clinical disease occurred only at 19 and 26°C. Proliferative gill disease may be attributed to extrasporogonic stages of a myxosporean resembling Sphaerospora spp.     

Effect of Temperature and Dissolved Oxygen Concentration on Edwardsiella ictaluri in Experimentally Infected Channel Catfish

Abstract

Channel catfish Ictalurus punctatus were experimentally infected with Edwardsiella ictaluri by immersion exposure. After clinical disease ran its course for 52 d, the surviving fish were exposed to one of the following environmental regimes in troughs: 25°C with aeration, 25°C with no aeration, or variable temperature (18–23°C) with no aeration. After 29 d of exposure to the environmental regimes, various organs and tissues of the fish were assayed to determine the effects of these conditions on E. ictaluri concentrations (colony-forming units/mL of tissue sample). The concentrations of this pathogen were significantly (P < 0.05) higher in all tissues (trunk kidney, liver, head kidney, blood, spleen, gallbladder, muscle, brain, and gonad) 52 d postinfection than 29 d after exposure to any of the environmental regimes (81 d postinfection). Fish exposed to a near-normal concentration of dissolved oxygen (6.4 mg/L) and a constant temperature of 25°C had E. ictaluri concentrations that were significantly (P < 0.01) lower than those offish exposed to a low oxygen concentration (2.6 or 1.8 mg/L) and either a constant or a variable temperature.     

Responses of Blue Catfish and Channel Catfish to Environmental Nitrite

Abstract

In nitrite-exposure experiments, percent methemoglobin, plasma nitrite concentration, and plasma chloride ion concentration were compared between channel catfish Ictalurus punctatus and blue catfish I. furcatus exposed to sublethal levels of nitrite for 48 h at 25°C. In nitrite-recovery experiments, fish exposed to elevated environmental nitrite for 12 h were transferred to freshwater, and blood characteristics were monitored during the 24-h recovery period. Blue catfish appeared to be more resistant to environmental nitrite than channel catfish. Methemoglobin levels (percent of hemoglobin in methemoglobin form) were significantly lower in blue catfish than in channel catfish. Maximum plasma nitrite concentrations were 137 mg NO₂-/L plasma in blue catfish and 164 mg NO₂-/L plasma in channel catfish. Percent methemoglobin and plasma nitrite concentration were closely correlated. Plasma chloride decreased initially with exposure to nitrite but quickly returned to control levels. Blue catfish exposed to nitrite at 10°C required 1 week to recover when placed in nitrite-free water. The methemoglobin reductase enzyme apparently functioned at a slow rate in fish acclimated to cold temperatures.     

Experimental Control of Metacercariae of the Yellow Grub Clinostomum marginatum in Channel Catfish

Abstract

Metacercariae of yellow grub Clinostomum marginatum in the flesh of farm-raised channel catfish Ictalurus punctatus pose a potential marketing problem to fish farmers. Infected fish may not be marketable. Three compounds were tested as possible control agents. Droncit (praziquantel) and Masoten (trichlorfon) were used separately as a bath treatment. Droncit and ivermectin were injected into the musculature to control yellow grub metacercariae. The two treatment rates were 0.65 mg/L plus 15 mg/kg offish as a bath treatment and 25 mg/kg offish as an injected treatment for Droncit. Masoten was treated at a rate of 2 mg/L as a bath treatment and ivermectin (1% solution) was injected at a rate of 0.022 mL/kg. Droncit significantly reduced metacercariae in both bath and injection treatments. Ivermectin also significantly reduced the number of metacercariae, but was not as effective as Droncit. Masoten was ineffective. More study is needed to obtain dosage rates for Droncit and ivermectin that would eliminate yellow grub metacercariae from the flesh of channel catfish.     

Survival and Antibody Response of Channel Catfish,Blue Catfish,and Channel Catfish Female × Blue Catfish Male Hybrids after Exposure to Edwardsiella ictaluri

Abstract

Juvenile Norris strain channel catfish Ictalurus punctatus, blue catfish I. furcatus, and Norris strain channel catfish female × blue catfish male hybrids were challenged with Edwardsiella ictaluri by bath immersion or intraperitoneal injection (high or low dose) in aquaria. Survival (%) after bath immersion was highest for blue catfish (89.5 ± 2.8), intermediate for hybrids (73.8 ± 6.7), and lowest for channel catfish (62.0 ± 4.2). Prechallenge antibody levels to E. ictaluri, measured by enzyme-linked immunosorbent assay, were negative (mean ± SE optical density [OD] = 0.010 ± 0.003). Postchallenge antibody response for blue catfish (OD = 0.132 ± 0.045) was significantly lower than that of channel catfish (OD = 0.350 ± 0.045), whereas the response of the channel × blue catfish F₁ hybrids (OD = 0.263 ± 0.051) was intermediate and not significantly different from either parental species. Intraperitoneal injections of E. ictaluri resulted in significant mortality only in channel catfish (88.3 ± 2.6% survival) and were sublethal to hybrid catfish and blue catfish with 100.0% and 99.3 ± 0.4% survival, respectively. Antibody responses after the injection challenge were significantly different among catfish groups and injection dose with no group × dose interaction. Antibody responses after the injection challenge were consistent with the immersion challenge, and means of high and low challenge doses were lowest in blue catfish (OD = 0.061 ± 0.014), intermediate in hybrids (OD = 0.187 ± 0.014), and highest in channel catfish (OD = 0.272 ± 0.014). For all fish groups combined, the high injection challenge dose resulted in higher antibody levels (OD = 0.206 ± 0.011) than low injection challenge dose (OD = 0.140 ± 0.012). Overall results indicate greater resistance to E. ictaluri and lower antibody response in blue catfish, and show the potential to identify molecular markers linked with disease resistance and introgression of resistance genes from blue catfish into channel catfish.     

Olfactory Organ of Channel Catfish as a Site of Experimental Edwardsiella ictaluri Infection

Abstract

Edwardsiella ictaluri, the causative agent of enteric septicemia of catfish (ESC), is one of the most important pathogens to infect channel catfish Ictalurus punctatus. Although the full pathogenesis of E. ictaluri is unclear, the olfactory organ is thought to be a site of entry. We have examined the effects of applying E. ictaluri directly into the olfactory capsule of channel catfish. Olfactory organs of 30 experimental fish were exposed to E. ictaluri for 1 h (1 mL, 1 × 10⁶ colony-forming units/mL). Live fish were sampled at 1, 24, 48, and 72 h, and days 5 and 14 postinfection, and their olfactory organs were examined by light and electron microscopy. Damage, including loss of sensory cilia and microvilli from the olfactory mucosal surface, was observed at 1 h postinfection. Degeneration of olfactory receptors and supporting cells was evident by 24 h postinfection. The nonsensory region also showed signs of degeneration, such as columnar cells lacking cilia. Electron microscopic immunocytochemistry confirmed the presence of E. ictaluri on the mucosal surface and within the epithelium. Host leukocytes responded to bacteria by migrating through the olfactory epithelium into the interlamellar lumen and phagocytosing organisms, but phagocytosed E. ictaluri did not appear to be destroyed. Our results indicate that during initial stages of infection channel catfish olfactory epithelium is vulnerable, and E. ictaluri can enter the host through the olfactory organ. It is also possible that host phagocytic cells serve as a vehicle for the systemic dissemination of E. ictaluri     

The Effect of High Total Ammonia Concentration on the Survival of Channel Catfish Experimentally Infected with Flavobacterium columnare

Abstract

Ammonia concentrations in water can affect the severity of Flavobacterium columnare infections in fish. Two trials lasting 7 d each were conducted to determine the effect of a single immersion flush treatment of total ammonia nitrogen (TAN; 15 mg/L) on the survival of channel catfish Ictalurus punctatus infected with F. columnare; the chemical was added while the water flowed continuously through the tanks. Both trials consisted of four treatments: (1) no ammonia exposure and no bacterial challenge (control), (2) ammonia exposure only, (3) bacterial challenge only, and (4) both ammonia exposure and bacterial challenge. Two hours after exposure to ammonia, the highest un-ionized ammonia level was 0.43 mg/L. The percent un-ionized ammonia is based on TAN, temperature, and pH. Caudal fins from three fish in each treatment were sampled at 24 h posttreatment to be analyzed by quantitative real-time polymerase chain reaction (qPCR). No significant difference in survival (mean ± SE) was noted between the channel catfish in treatment 1 (95.2 ± 1.2%) and those in treatment 2 (95.6 ± 1.0%); however, survival in both treatments 1 and 2 differed significantly from that in treatments 3 (8.5 ± 4.5%) and 4 (41.8 ± 12.7%). Treatment 4 catfish had significantly higher survival than treatment 3 catfish. Quantitative PCR data showed that treatment 4 fish had significantly less F. columnare (7.6 × 10⁵) than did treatment 3 fish (1.2 × 10⁷), and treatment 2 fish (8.5 × 10³) had significantly less bacteria than did treatment 1 fish (6.9 × 10⁴), indicating that ammonia limited the F. columnare infection. The highest mean concentration of the bacteria (3.9 × 10⁷) was found on moribund fish. The ammonia concentrations tested did not negatively influence fish survival but interfered with the infection process. An in vitro assay was also conducted to evaluate the direct effects of ammonia on F. columnare.

Received September 15, 2010; accepted May 7, 2011     

Attempts to Control Flexibacter columnaris Epizootics in Pond-Reared Channel Catfish by Vaccination

Abstract

Evaluation of bacterins for the immunization of channel catfish Ictalurus punctatus against Flexibacter columnaris was carried out over 5 years. Groups of 60,000–100,000 pondreared channel catfish, weighing an average of 1.5–4.1 g, were vaccinated each year with formalininactivated Flexibacter columnaris bacterins by immersion. Bacterins were prepared from isolates of the preceding year's epizootic. Equal numbers of nonvaccinated channel catfish reared under similar conditions served as controls. Fish were vaccinated during May each year when water temperatures ranged from 16 to 18°C. Data were recorded daily from early June through midSeptember as water temperatures rose to 24–26°C. Deaths were recorded daily, and the number of hours required for antibiotic treatments were monitored. Analysis of the data indicated a general trend toward a beneficial effect of vaccination, particularly for larger fish. Mortality and hours of antibiotic treatment were significantly higher for most control groups than for vaccinated groups.     

Effect of Dietary Lipid Sources on Production of Leukotriene B by Head Kidney of Channel Catfish Held at Different Water Temperatures

Abstract

Separate and combined effects of dietary fatty acids and water temperature on the production of leukotriene B (LTB) by the head kidney of channel catfish Ictalurus punctatus were investigated. Fish were fed semipurified diets containing 7% lipid as beef tallow, corn oil, linseed oil, menhaden oil, or a mixture (1:1:1) of menhaden oil, beef tallow, and corn oil. At 28°C, fish fed corn oil produced the greatest amount of LTB, and fish fed beef tallow produced the least. At 17°C, production of LTB by fish fed the beef tallow diet was again lowest; production of LTB by fish fed the corn oil diet was highest but was not significantly different from that obtained with the mixed-oil or menhaden oil diet. Production of LTB for the other diets was intermediate. This is the first report that the head kidney of channel catfish produces LTB; this production was affected by dietary lipid sources but not by the two water temperatures tested. Production of LTB was not related to weight gain. Moreover, the pattern of LTB production does not explain survival rates of channel catfish observed in a previous experiment in response to pathogen challenge. However, LTB concentration does appear to be roughly proportional to the amount of eicosanoid precursors (arachidonic acid and eicosapentaenoic acid) previously reported for liver phospholipids of channel catfish fed diets containing different amounts of essential fatty acids.     

Transmission of Edwardsiella ictaluri from Infected,Dead to Noninfected Channel Catfish

Abstract

Enteric septicemia of catfish (ESC) was transmitted horizontally from channel catfish Icialurus punctatus that had died from Edwardsiella ictaluri infection to contact channel catfish during 2 d of habitation in a tank. The contact channel catfish became positive for E. ictaluri antibody, became infected with this bacterium, and had signs of ESC and died within 12 d postexposure. Edwardsiella ictaluri was recovered from 24 of the 30 contact channel catfish that died from ESC, as well as from 9 of the 25 tested contact survivors. The cannibalizing of E. ictaluri-infected fish, or the shedding of E. ictaluri from dead fish, or both, were shown to be mechanisms of horizontal transmission of ESC among channel catfish.     

Distribution of Edwardsiella ictaluri in California

Abstract

Wild and domestic populations of channel catfish Ictalurus punctatus were examined to determine the distribution of the disease called enteric septicemia of catfish (ESC) in California. The causative agent of ESC, Edwardsiella ictaluri, was isolated from five separate sites in California. Two of these isolations were from rectal swabs of asymptomatic fish, confirming that a carrier state may exist. Normal-appearing fish with serum antibody titer to E. ictaluri were commonly found in domestic channel catfish populations, suggesting that many fish become infected but recover. Wild channel catfish with antibody to E. ictaluri were also found in major reservoirs and water distribution canals. Edwardsiella ictaluri appears to be widely distributed within California.     

Experimental Infections of Bluegill with the Trematode Ribeiroia ondatrae (Digenea: Cathaemasiidae): Histopathology and Hematological Response

Infections by the digenetic trematode, Ribeiroia ondatrae, cause severe limb malformations in many North American amphibians. Ribeiroia ondatrae also infects fishes as second intermediate hosts, but less is known about the pathology and immune responses initiated in infected fish, even though reports of infected fish date back to early 1900s. To this end, we experimentally exposed juvenile Bluegills Lepomis macrochirus to three doses of R. ondatrae cercariae and monitored the pathology, parasite infection success, and humoral responses over 648 h. All exposed fish became infected with metacercariae, and the average infection load increased with exposure dose. Histologically, infection was associated with acute hemorrhages in the lateral line and local dermis at 36 h, followed by progressive granulomatous inflammation that led to the destruction of encysted metacercariae. Correspondingly, over the course of 648 h we observed an 85% decline in average infection load among hosts, reflecting the host's clearance of the parasite. Infection was not associated with changes in fish growth or survival, but did correlate with leukocytosis and neutrophilia in circulating host blood. Understanding the physiological responses of R. ondatrae in Bluegill will help to clarify the ecological effects of this parasite and provide a foundation for subsequent comparisons into its effects on behavior, individual health, and population dynamics of Bluegill.

Received March 4, 2015; accepted August 9, 2015     

Communications: Specificity of the Channel Catfish Antibody to Edwardsiella ictaluri

Abstract

The specificity of channel catfish Ictalurus punctatus serum antibody to Edwardsiella ictaluri was characterized by microtiter agglutination assay. There was no correlation between antibody titer to Aeromonas hydrophila and antibody titer to E. ictaluri in wild or feral channel catfish. Anti-E. ictaluri antibodies in naturally infected channel catfish were not removed by adsorption by nine other species of bacteria found in the channel catfish intestine and fish ponds. Channel catfish immunized with nine other species of bacteria did not develop substantial antibody titer to E. ictaluri. The antibody response of channel catfish to E. ictaluri is highly specific, and the microtiter agglutination test is a specific indicator of previous exposure to E. ictaluri     

Early Changes in Pigmented Macrophages in Head Kidney of Channel Catfish Infected with Aeromonas hydrophila

Abstract

Channel catfish Ictalurus punctatus with scarified skin were exposed to the bacterial pathogen Aeromonas hydrophila. Systemic infections developed in 80% of the exposed fish, and the remaining exposed fish had infections limited to the cutaneous lesion. Skin of control fish was injured in the same manner as for the exposed fish, but control fish were not exposed to A. hydrophila nor was A. hydrophila recovered from them. None of the fish died during the 3-d experiment, and gross lesions in head kidneys, including changes in the size or relative weight, were not found in infected fish. Macrophage aggregates in head kidney of systemically infected fish increased 68% in mean area, 28% in number, and 111% in total relative volume. Volume of lipofuscin, the predominate pigment found in channel catfish head kidney, in systemically infected fish was about twice that of control fish. Volume of hemosiderin was about four times as great and macrophages containing hemosiderin were about three times as numerous in systemically infected fish as in control fish. The amount of melanin in macrophages did not change in infected fish. Significant differences in macrophage aggregates and pigments were not found between controls and fish with only superficial infections. Microscopic lesions, other than changes in macrophage aggregates and pigments, were not found in the head kidney. Increases in macrophage aggregates, lipofuscin, and hemosiderin in head kidney of channel catfish were useful for quantification of injury caused by a systemic bacterial infection.     

Pathogenesis of Enteric Septicemia of Channel Catfish,Caused by Edwardsiella ictaluri: Bacteriologic and Light and Electron Microscopic Findings

Abstract

To clarify early events in the pathogenesis of enteric septicemia of catfish, 140 channel catfish Ictalurus punctatus (8–10 months old) were each infected with approximately 1.0 × 10⁹ colony-forming units of Edwardsiella ictaluri by intragastric intubation. Fish were sacrificed at 0, 0.25, 0.5, 1, 3, 6, 12, 24, 48, 72, 96, and 120 h postinfection (PI). Multiple tissue samples at all scheduled sampling times were evaluated by gross observation, light and electron microscopy, and immunohistochemical methods. In addition, at each sampling time, stomach, intestine, trunk kidney, and liver were cultured to quantitate bacteria. Trunk kidney cultures were positive by 0.25 h PI, indicating rapid transmucosal passage. In the intestine, E. ictaluri was seen in contact with the brush border at 0.5 h PI. Also at 0.5 h PI, dilated basilar cells with large intracytoplasmic inclusions were observed adjacent to the basement membrane. From 1 to 3 h PI, occasional necrotic enterocytes were seen on tips of intestinal folds. Proprial leukocytes were rare before 24 h PI but common thereafter. Immunoelectron microscopy showed E. ictaluri in vacuoles within phagocytes as early as 24 h PI in the intestinal mucosa. In other tissues, earliest observed microscopic lesions (48 h PI) consisted of bacteria within vacuoles of phagocytic cells contained within blood vessels. Bacteria were also seen within degenerate vacuoles in enterocytes and hepatocytes at 72, 96, and 120 h PI. This study confirms that E. ictaluri can invade channel catfish within 0.25 h PI by crossing the intestinal mucosa and suggests that the bacterium may have invasion and survival strategies similar to those of other enteroinvasive members of the Enterobacteriaceae.     

Decreased Resistance to Edwardsiella ictaluri Infection in Channel Catfish Intraperitoneally Administered an Oil Adjuvant

Abstract

The effects of intraperitoneal injection of squalene, an oil adjuvant, on nonspecific mortality of channel catfish Ictalurus punctatus and on their resistance to experimental Edwardsiella ictaluri infection were studied. Yearling channel catfish were assigned to control (N = 22) or squalene (N = 25) treatment groups, and mortality was monitored for 14 d following treatment. On day 14 both groups were infected with E. ictaluri, the causative agent of enteric septicemia of catfish, and mortality was monitored for an additional 11 d. Before infection, mortality did not differ between groups. After E. ictaluri infection, fish that received squalene were at a substantially higher risk of dying than control fish (relative risk after squalene treatment = 6.86). These results suggest that intraperitoneal administration of squalene, although not directly toxic, decreased resistance to E. ictaluri infection.     

Electron Microscopy of Infection by Saprolegnia spp. in Channel Catfish

Abstract

Saprolegnia sp. isolated from channel catfish Ictalurus punctatus grew slower than S. parasitica on cornmeal agar (CMA). Oogonia in Saprolegnia sp. appeared frequently, whereas oogonia were rarely seen in S. parasitica on CMA. In experimental exposures of injured channel catfish to fungal spores, infections were apparent after 3–4 d, but were most common after 7–9 d. Multiple lesions were usually seen in naturally infected fish, whereas a single lesion appeared at the injured site of experimentally infected fish. No obvious differences were found between lesions caused by S. parasitica and those caused by Saprolegnia sp. Most of the epidermal cells in fungusinfected lesions were necrotic. In some lesions, the epidermis was completely sloughed and the dermis was exposed. Both Saprolegnia parasitica and Saprolegnia sp. penetrated the dermis, causing damage to fibroblasts and collagen lamellae.     

Efficacy of Copper Sulfate for the Treatment of Ichthyophthiriasis in Channel Catfish

Abstract

Ichthyophthirius multifiliis is a protozoan that may infest and significantly damage cultured fish species. The purpose of this study was to measure the efficacy of copper sulfate in treating ichthyophthiriasis. Fingerling channel catfish Ictalurus punctatus exposed to at least 2,000 theronts of I. multifiliis per liter of water developed consistent infestations of I. multifiliis (20 or more trophonts on the dorsal surface of the head of the fish). Infestation was observed in untreated controls at day 5 after exposure and mortality occurred after day 10. Coexposure studies with theronts and different concentrations of copper sulfate revealed that all theronts were killed at concentrations greater than 0.05 mg/L. To determine the effect of copper sulfate in the treatment of ichthyophthiriasis, fish were exposed to the parasite until trophonts were observed (day 5), and they were subsequently treated with copper sulfate. The lowest effective concentration of copper sulfate for treatment of ichthyophthiriasis (i.e., after infestation was observed in the fish) was 0.4 mg/L. To assess the effects of various water quality conditions on copper treatment, total suspended solids (TSS) and pH were varied during treatment of ichthyophthiriasis. Concentration of TSS was inversely correlated to the efficacy of copper sulfate for I. multifiliis infestations, whereas no relationship was observed between pH and efficacy of a single copper sulfate dose. The results indicated that copper sulfate can be used to treat ichthyophthiriasis at concentrations of 0.4 mg/L for at least 5 d under the specific water conditions used in this study (pH, 7.45 ± 0.27; temperature, 20.5 ± 0.7°C; alkalinity, 176.6 ± 28.1 mg/L as CaCO₃) and that efficacy of copper sulfate was affected more by TSS concentration than by pH.