Utilization of Different Dietary Lipid and Tocopherol Sources in the Early Life Stages of Freshwater Finfish.

Grayson, John David

January 2020

No description available.

Aquaculture

Nutrition

Fish Production

PUFA

vitamin E

fatty acid ethyl ester

tocopherol

yellow perch

walleye

rainbow trout

My Magnum Opus

Averill, Catherine

16 August 2011

No description available.

Fish Production

Plate Tectonics

Remote Sensing

Robots

Textile Research

Urban Forestry

grief

death

tiny giraffes

Modeling Nearshore Fish Community Responses to Shoreline Types in Lake Erie

Simonson, Martin Albert

January 2017

No description available.

Ecology

Fish Production

Natural Resource Management

Lake Erie

Nearshore Fish

Coastal Management

Great Lakes Fish

Ecological effects of chemicals used in pond culture of catfish and percid fishes

Jacob, Annie Philip

24 June 2008

No description available.

Biology

Ecology

Environmental Science

Fish Production

percid

catfish

plankton

fluridone

copper

Optimizing Larval Fish Survival and Growth through an Analysis of Consumer and Resource Interactions in Percid Culture Ponds

Briland, Ruth

23 August 2010

No description available.

Aquaculture

Ecology

Fish Production

Freshwater Ecology

larval fish ecology

aqucuaculture

walleye

saugeye

The nutritional and genetic effects on body growth, reproduction and molecular mechanisms responsible for muscle growth in yellow perch Perca flavescens

Kwasek, Karolina Anna

24 April 2012

No description available.

Fish Production

yellow perch

lysine

free amino acid

dipeptide

Pept1

muscle

protein

Fish Health and Water Quality in Small Agricultural Ponds in Rural Ohio

Evans, Jeremy Toone

21 July 2022

No description available.

Wildlife Management

Environmental Management

Freshwater Ecology

Fish Production

artificial ponds

management

pond dye

Bluegill

Climate change impacts on production and dynamics of fish populations

Hedström, Per

January 2016

Ongoing climate change is predicted to increase water temperatures and export of terrestrial dissolved matter (TDOM) to aquatic ecosystems influencing ecosystem productivity, food web dynamics and production of top consumers. Ecosystem productivity is mainly determined by the rates of primary production (GPP) in turn controlled by nutrients, light availability and temperature, while temperature alone affect vital rates like consumption and metabolic rates and maintenance requirements of consumers. Increased level of TDOM causes brownification of water which may cause light limitation in algae and decrease GPP and especially so in the benthic habitat. Temperature increase has a been suggested to increase metabolic rates of consumers to larger extent than the corresponding effect on GPP, which suggest reduced top consumer biomass and production with warming. The aim of this thesis was to experimentally study the effects of increased temperature and TDOM on habitat specific and whole ecosystem GPP and fish densities and production. In a replicated large-scale pond experiment encompassing natural food webs of lotic ecosystems I studied population level responses to warming and brownification in the three- spined stickleback (Gasterosteus aculeatus). Results showed overall that warming had no effect on whole ecosystem GPP, likely due to nutrient limitation, while TDOM input decreased benthic GPP but stimulated pelagic GPP. In fish, results first of all suggested that recruitment in sticklebacks over summer was negatively affected by warming as maintenance requirements in relation to GPP increased and thereby increased starvation mortality of young-of-the-year (YOY) sticklebacks. Secondly, brownification increased mortality over winter in YOY as the negative effect on light conditions likely decreased search efficiency and caused lower consumption rates and starvation over winter in sticklebacks. Third, seasonal production of YOY, older, and total stickleback production was negatively affected by warming, while increased TDOM caused decreased YOY and total fish production. The combined effect of the two was intermediate but still negative. Temperature effects on fish production were likely a result of increased energy requirements of fish in relation to resource production and intake rates whereas the negative effect of TDOM likely was a result of decreased benthic resource production. Finally, effects of warming over a three-year period caused total fish density and biomass and abundance of both mature and old fish to decrease, while proportion of young fish increased. The main cause behind the strong negative effects of warming on fish population biomass and changes in population demographic parameters were likely the temperature driven increased energy requirements relative to resource production and cohort competition. The results from this thesis suggest that predicted climate change impacts on lentic aquatic ecosystems will decrease future densities and biomass of fish and negatively affect fish production and especially so in systems dominated by benthic resource production.

Temperature

terrestrial dissolved organic carbon

light extinction

GPP

recruitment

winter mortality

metabolism

cohort competition

fish production

fish biomass

Ecology

Ekologi

Fish meal replacement with soybean meal in yellow perch (Perca flavescens) diets: responses of nutritional programming on growth, transcriptome and isoflavone accumulation

Kemski, Megan Marie

January 2018

No description available.

Food Science

Fish Production

Biochemistry

Biology

Chemistry

The Chinese liver fluke Clonorchis sinensis: an environmental investigation into a foodborne parasite

Klase, Gary L.

06 August 2013

No description available.

Environmental Science

Public Health

Fish Production

Geographic Information Science

Clonorchis sinensis

clonorchiasis

ecological engineering

aquaculture

epidemiology

GIS