UTILIZATION OF DISTILLER?S DRIED GRAINS WITH SOLUBLE IN 
CATFISH FEEDS 
 
 
Except where reference is made to the work of others, the work described in this 
thesis is my own or was done in collaboration with my advisory committee. This 
thesis does not include proprietary or classified information. 
 
 
Ping Zhou 
 
 
Certificate of Approval: 
 
   
Ronald P. Phelps                                                     D. Allen Davis, Chair    
Associate Professor                                   Associate Professor    
Fisheries and Allied Aquacultures                    Fisheries and Allied Aquacultures 
 
 
       
   
   
Jeffery Terhune                                    George T. Flowers 
Associate Professor                                 Dean 
Fisheries and Allied Aquacultures         Graduate School 
                                                                       
 
 
 
 
 
UTILIZATION OF DISTILLER?S DRIED GRAINS WITH SOLUBLE IN 
CATFISH FEEDS 
 
 
Ping Zhou 
 
 
A Thesis 
Submitted to 
the Graduate School of 
Auburn University 
in Partial Fulfillment of the 
Requirements for the 
Degree of 
 Master of Science 
 
 
 
 
Auburn, Alabama 
August 10, 2009
iii 
 
UTILIZATION OF DISTILLER?S DRIED GRAINS WITH SOLUBLE IN 
CATFISH FEEDS 
 
Ping Zhou 
 
 
 
Permission is granted to Auburn University to make copies of this thesis at its 
discretion, upon request of individuals or institutions at their 
expense. The author reserves all publication rights. 
    
 
 
   
                                                                                  Signature of Author 
   
 
 
                                                                       Date of Graduation 
                                                                     
 
 
 
                             
 
 
iv 
 
VITA 
Ping Zhou was born in August 16, 1970 in China. He received his bachelor 
degree in Medical radiology from Wuhan University, Wuhan, China in 1992. After 
completion of his degree, he worked as a technical radiologist in the Chinese 
Traditional Medical Hospital of Hubei province for four years and as a radiological 
physician for eight more years in the same hospital. He married Ying Si, a plant 
scientist, in 2002 and had his daughter Ariel Zhou in 2003. In 2004, he came to 
Auburn, Alabama, US following his wife and immediately felled in love with this 
nice small town. Consequently, he decided to accompany his wife for more years in 
US. Since the interest of fish, he entered master program under the direction of Dr. D. 
Allen Davis in Fisheries and Allied Aquaculture, Auburn University in 2007. 
  
 
 
v 
 
THESIS ABSTRACT 
UTILIZATION OF DISTILLER?S DRIED GRAINS WITH SOLUBLE IN 
CATFISH FEEDS 
Ping Zhou 
Master of Science, August 10th, 2009 
(B.S., Wuhan University, 2002) 
 
59 Typed Pages 
Directed by Allen Davis 
Feed is generally the largest expenditure in semi-intensive and intensive 
catfish culture operations, and protein is the most expensive component of feeds. 
Efforts to reduce feed costs have resulted in increased use of plant proteins in diet 
formulations as replacements of expensive animal ingredients. Currently, soybean 
meal (SBM) comprises 30 to 40% in commercial grow-out feeds for catfish. 
Replacement of SBM with less expensive protein sources would be beneficial in 
reducing feed costs. Distiller?s dried grains with solubles (DDGS), a co-product of the 
ethanol distillery industry, is less expensive than SBM on a per unit protein basis. In 
2001, the U.S. produced about 3.1 million tons of DDGS. As a result of the recent 
expansion and increase in ethanol production for fuels due to the shortage and rising 
cost of petroleum-based fuel, and to reduce pollution , the production of DDGS in the 
U.S. has been reported to increase to approximately 8 million tons in 2006 (Shurson 
2006).
vi 
 
To evaluate the effects of the dietary levels of DDGS with and without lysine 
supplementation on growth, feed intake, feed efficiency  of  a catfish growth trial, two 
different catfish spices were chosen, channel catfish (Ictalurus punctatus) and hybrid 
catfish (channel catfish ? blue catfish Ictalurus furcatus). Channel catfish were reared 
in earth pond and hybrid catfish in an indoor intensive water reuse system using the 
same formulation of five different feeds. Five diets (diets 1-5) were formulated to 
contain approximately 32% crude protein and 2,900 kcal of digestible energy/kg 
(NRC 1993). The diets were consisted of a basal (control) diet and diets containing 20 
and 30% DDGS, with and without the addition of lysine to the level equal to that of 
the basal diet. The test diets were formulated as partial replacements of a mixture of 
soybean meal (SBM) and corn meal (CM) on an equal protein basis. Lipid levels in all 
diets were maintained constant by the addition of fish oil. Diets were processed into 
floating pellets by a local Feed Mill. 
Based on statistical analysis of the result, there are no significant difference 
among all treatments for the measured parameters in both species including survival 
rate, weight gain, feed intake, FCR, final size etc. Under the reported conditions, 
lysine supplementation may be omitted from theses diet formulations for channel 
catfish reared in earthen pond conditions and hybrid catfish reared in intensive 
system. Consequently, the feed cost in channel catfish production as well as hybrid 
catfish production can be further reduced by omitting the lysine supplementation for 
these formulations. Based on these results further research should focus on challenges 
using higher levels of DDGS as well as the possibility of immune stimulation by 
DDGS. 
vii 
 
ACKNOWLEDGEMENTS 
The author would like to thank his major professor, Dr. D. Allen Davis, for his 
years of patient and helpful direction and support in completing this program. Dr. D. 
Allen Davis gave the author valuable lessons and guidance in the entire process of this 
project. The author would like to thank Dr. Chhorn Lim, Dr. Ronald P. Phelps, and 
Dr. Jeffery Terhune for their help and suggestions in completing this program. Thanks 
are also due to Jessica N. Jacquay, Patricio Paz and Daranee Sookying for their 
assistance to the experiments. Special thanks are also offered for the whole group of 
Dr. Davis? students which are Fabio S. D. da Silva, Waldemar Rossi Junio, Bochao 
Hu, Yan Li. Also Mr. Bill Trimble and Dr. Wenbing Zhang did great contribution for 
making possible the project to be done.  There are still a lot of people did so many 
great jobs in this project and the author even doesn?t know their names. But their 
faces will never be forgotten. 
The author wishes to express his love and gratitude to his wife Ying Si for her 
love and support during the graduate study period. The author also wishes to express 
his appreciation to his loving daughter Ariel Zhou and his mother in law Junlin 
Zhang?s invaluable and continuous support during the course of this program. 
  
viii 
 
Style manual of journal used: Aquaculture Research 
Computer software used: Microsoft Office Word, Microsoft Excel XP, and SAS 
v.9.1.3 
  
 
 
ix 
 
TABLE OF CONTENTS 
LIST OF TABLES ................................................................................................... xi 
I. INTRODUCTION ............................................................................................... 1 
II. UTILIZATION OF CATFISH PRODUCTION DIETS USING HIGH LEVELS 
OF DDGS WITH OR WITHOUT LYSINE SUPPLEMENTS ................................... 9 
   1.ABSTRACT ........................................................................................................ 9 
   2.INTRODUCTION ............................................................................................. 10 
   3.MATERIALS AND METHODS ....................................................................... 11 
      3.1.PONDS ........................................................................................................ 11 
      3.2.DIETS PREPARATION .............................................................................. 12 
      3.3.CULTURE METHODS ............................................................................... 13 
      3.4.HARVESTING AND FINAL DATA COLLECTION ................................. 15 
   4.RESULTS ......................................................................................................... 16 
   5.DISCUSSION.................................................................................................... 17
x 
 
   6.REFERENCES .................................................................................................. 24 
III. GROWTH RESPONSE  AND FEED UTILIZATION OF JUVENILE HYBRID, 
ICTALURUS PUNCTATUS ? I. FURCATUS, USING HIGH LEVELS OF DDGS 
WITH OR WITHOUT LYSINE  SUPPLEMENTS ................................................. 28 
   1.ABSTRACT ...................................................................................................... 28 
   2.INTRODUCTION ............................................................................................. 29 
   3.MATERIALS AND METHODS ....................................................................... 30 
      3.1.DIET PREPARATION ................................................................................ 30 
      3.2.ANIMAL REARING ................................................................................... 31 
      3.3.CALCULATIONS AND STATISTICAL ANALYSIS ................................ 32 
   4.RESULTS ......................................................................................................... 32 
   5.DISCUSSION.................................................................................................... 34 
   6.REFERENCES .................................................................................................. 37 
IV. SUMMARY AND CONCLUSIONS ................................................................. 41 
 
xi 
 
LIST OF TABLES 
 
Table 1. Ingredient and proximate composition of five experimental diets (As is 
basis) ????????????????????????????  14 
Table 2. Amino acid compositions in the experimental diets ???????......  15 
Table 3. Water Quality Criteria for a catfish grow out pond ????????..  18 
Table 4. Growth performance and feed utilization of channel catfish fed on 
experimental Diets ? ????? ????????????????...  19 
Table 5. Whole-body proximate composition of channel catfish fed diets 
containing various levels of distiller?s dried grains with solubles with and 
without lysine supplementation for 150 days ...???????????...  20 
Table 6. Growth performance and feed utilization of juvenile hybrid catfish 
(Ictalurus punctatus ? I. furcatus) fed on experimental diets ?????......  33 
 
 
1 
 
I. INTRODUCTION 
According to the UN Food and Agriculture Organization, aquaculture is 
growing more rapidly than all other animal food-production sectors (FAO 2006). Its 
contribution to global supplies of fish, crustaceans and molluscs increased from 3.9% 
of total production by weight in 1970 to 32% in 2005 and is currently estimated at 
50% of the world supply. This growth is at an average compounded rate of 9.2% per 
year since 1970, compared with only 1.4% for capture fisheries and 2.8% for 
terrestrial farmed-meat production systems. It is remarkable that half of the consumed 
seafood in the world is now farm raised.  
The expansion of aquaculture production has been accompanied by a rapid 
growth of feed production for aquatic species. The challenge facing the aquaculture 
industry is to identify economically viable and environmentally friendly feeds to rear 
fish. Presently, many of our feeds are based on the use of fish meal and fish oil. While 
the supply of fish meal and oil in world supplies cannot be expand, Hence, as the feed 
industry continues to expand so does the demand for marine ingredients. The feeds 
industry has recognized for many years that viable utilization of plant based feedstuffs 
formulated into feeds for the production of cold-, cool- and warm-water aquatic 
species is an essential requirement for future development of aquaculture as well as 
current cost savings. 
Continued growth and intensification of aquaculture production depends upon 
the development of sustainable protein sources that are economical and from 
 
 
2 
 
expandable supplies. There are various plant feedstuffs which currently are or 
potentially may be incorporated into feeds to support the sustainable production of 
various fish species in aquaculture. 
The use of fishmeal in fish feeds varies considerably due to a variety of factors 
including, ingredient costs, nutrient requirements as well as farm requests. Of the 
alternative protein sources, soybean products such as solvent extracted soybean meal 
(SBM) is one of the most important plant based proteins as it has a suitable nutrient 
content and ready supply (Gatlin & Barrows 2007). As compared to fish meal, SBM 
is a relatively inexpensive protein source and there are a number of fish species (e.g. 
carp, tilapia and catfish) whose diets are primarily derived from SBM. Over the years, 
the price of soybean has generally increased. Thus, in diets formulated primarily with 
SBM, to further reduce costs, one has to look at alternatives to reduce the use of SBM 
in the diet. There are some products such as cottonseed meal (CSM) and distiller?s 
dried grains with solubles (DDGS) which can be used as substitute ingredients.  
The use of plant based diets varies considerably from species to species. Farm-
raised channel catfish (Ictalurus punctatus), is the most important aquaculture 
industry in the United States, representing about half the total United States 
aquaculture production. The catfish industry is one that is very mature and 
considerable nutrition work has been conducted with this species resulting in very 
efficient and low cost production diets. In fact, catfish feeds are some of the least 
expensive feeds in the industry as they are primarily based on soybean meal as the 
primary protein source.   
Channel catfish is typically fed a diet comprised primarily of soybean meal 
(SBM), corn, and wheat middlings plus a small amount of animal meal, fat, and 
 
 
3 
 
nutrient supplements (Robinson et al. 2001). Like other animals, catfish do not have 
an absolute protein requirement, but rather have a requirement for indispensable 
amino acids and a certain amount of nonspecific nitrogen for normal growth. Dietary 
protein requirements for catfish have been determined in various studies, and range 
from 24 to 55% (NRC 1993). The wide variation in protein requirements for catfish is 
not surprising because of the different conditions under which the studies were 
conducted and the fact that several factors affect the dietary protein requirement. Fish 
of different size and life stages require different levels of dietary protein for maximum 
growth. Catfish fry raised from swim-up to about 2 to 3 weeks of age require about 
55% protein in the diet for normal growth (Winfree & Stickney 1984). Catfish 
fingerlings raised from about 10 to 25 cm (4 to 10 inches) length require 35% dietary 
protein for maximum growth, while a diet containing 25%-35% protein can be 
adequate for fish grown from 100 to 500g (0.25 to 1.1 pound) (Page & Andrews 
1973). 
Digestible energy of the diet maybe also influences the dietary protein 
requirement. It has been demonstrated that small catfish grow as well on a 27% 
protein diet as on a 38% protein diet when the energy level in the diet is low, but 
when the energy level increases, feed consumption decreases and the low protein diet 
does not support maximum growth (Manfalik 1986).  
Feeding rate may have a profound effect on the dietary protein requirement. 
Minton (1978) reported that weight gain of pond-raised catfish was not different when 
the fish were fed to satiation with 30% and 36% protein diets, but feeding at 
approximately 75% of satiation the fish fed the 36% protein diet gained more weight. 
Similarly, Li and Lovell (1992) reported that a dietary protein concentration of 26% 
 
 
4 
 
was adequate for optimum weight gain when fish were fed as much as they would 
consume, whereas a minimum dietary protein level of 32% was necessary for 
optimum growth when fish were fed at a predetermined maximum level of 60 kg/ha  
(55 pounds/acre) per day. 
Dietary protein requirements for catfish are also influenced by the presence of 
natural food organisms in pond water. Although the natural food organisms are 
abundant in catfish ponds, the contribution to growth is relatively small. Wiang 
(1977) reported that only 2.5% of the protein requirement and 0.8% of the energy 
needed for catfish grown at a moderate density in ponds were obtained from natural 
foods. However, there are indications that natural foods are significant sources of 
micro-nutrients, such as vitamins, minerals, and essential fatty acids (Robinson et al. 
1998).  
Feed is generally the largest expenditure in semi-intensive and intensive 
catfish culture operations, and protein is the most expensive component of feeds. 
Efforts to reduce feed costs have resulted in increased use of plant proteins in diet 
formulations as replacements of expensive animal ingredients. Soybean meal (SBM), 
because of its consistent quality and availability, and high nutritional value, is the 
most commonly used plant ingredient in fish feeds. Currently, SBM comprises 30 to 
40% in commercial grow-out feeds for catfish. Replacement of SBM with less 
expensive protein sources would be further beneficial in reducing feed costs or 
providing alternatives to the feed mill manager. Considerable work has been 
conducted on cotton seed meal, peanut meal as well as DDGS, another cost effective 
alternative. 
 
 
 
5 
 
Distiller?s dried grains with solubles (DDGS), a co-product of the ethanol 
distillery industry, although currently not locally available, may become abundant as 
ethanol plants come on line as a result of new energy policies and an abundant corn 
crop in the southern United States. In 2001, the U.S. produced about 3.1 million tons 
of DDGS. As a result of the recent expansion and increase in ethanol production for 
fuels due to the shortage and rising cost of petroleum-based fuel, and to reduce 
pollution , the production of DDGS in the U.S. were reported to have increased to 
approximately 8 million tons in 2006 (Shurson 2006).  
DDGS has a moderate level of protein (~ 30% crude protein) without the 
presence of antinutritional factors commonly found in most plant protein sources. 
Moreover, the yeast component of DDGS also contains ?-glucan and mannans which 
have been reported to stimulate fish immune responses (Lim 2008). This product has 
been successfully used in commercial catfish feeds and experimental diets at levels of 
15?30% as a replacement for animal proteins and SBM (Webster et al. 1991; 
Robinson et al. 2001). DDGS are highly palatable to catfish but contain about 45% of 
the lysine found in SBM. Research has shown that all the animal protein in catfish 
diets can be replaced with SBM, and a portion of the SBM can be replaced by other 
plant proteins such as DDGS (Robinson & Li 2008). 
Presently, DDGS is widely used as a protein supplement in terrestrial animal 
feeds, but its use in fish feed is limited due to its low content of essential amino acids, 
especially lysine (NRC 1993). Results of earlier studies, however, have shown that 
based on growth performance and feed utilization efficiency, DDGS is a promising 
feed ingredient for several fish species, including rainbow trout (Cheng & Hardy 
2004), channel catfish (Lovell 1980; Tidwell et al. 1990; Webster et al. 1991, 1992a, 
 
 
6 
 
1992b, 1993), and tilapia (Wu et al. 1996; Lim et al. 2007). A recent laboratory study 
by Lim and co-workers (personal communications) showed that, with lysine 
supplementation, DDGS at dietary levels ranging from 10 to 40% can be used in 
catfish feeds as replacements of various levels of a mixture of SBM and corn meal 
without affecting their growth and feed utilization efficiency. Because of the shortage 
of lysine in DDGS, practical feeds used for catfish production containing DDGS will 
most likely require lysine enhancement. 
There have been a number of studies evaluating the use of DDGS in catfish 
feeds. A diet containing 15% DDGS has been reported to provide satisfactory growth 
of channel catfish (Hastings 1967). Lovell (1980) reported that, when used in 
combination with 10% fish meal, up to 30% DDGS can be used in channel catfish 
diets. Webster et al. (1993) also found that 30% DDGS can be used as a replacement 
of a mixture of SBM and CM (corn meal) in channel catfish diets containing 8% fish 
meal. Tidwell et al. (1990) and Webster et al. (1991) found that 40 and 35% DDGS, 
respectively, can be used in catfish diets as substitutes for the combination of SBM 
and CM on an equal protein basis without requiring lysine supplementation. However, 
a diet containing 70% DDGS appeared to be deficient in lysine because 
supplementation of lysine at a level to meet lysine requirement improved the growth 
of catfish (Webster et al. 1991).  In another study, evaluating fixed percentage of 
DDGS (35%) and variable percentages of SBM (35?49%) as a partial or total 
replacement of fish meal in channel catfish diets, Webster et al. (1992a) found that the 
weight gain of fish fed the diet with 0% fish meal, 35% DDGS, and 49% SBM was 
similar to that of the diet with 12% fish meal and 48% SBM. Although, there are a 
number of studies evaluating the use of moderate levels of DDGS in conjunction with 
 
 
7 
 
feed formulations using fish meal, there are few trials evaluating the response using 
the upper limits of DDGS. 
The catfish industry is critical to the economy of a number of states such as 
Mississippi and Alabama. The industry is evaluating a variety of alternatives to make 
them more cost competitive. Reducing the feed costs is just one of the strategies. 
Using other catfish species could be a way to be more economically competitive. At 
least four species of ictalurid catfish and several hybrids have been considered as 
candidates for commercial aquaculture in the USA. Channel catfish Ictalurus 
punctatus and blue catfish I. furcatus are the best two species for aquaculture (Tucker 
& Robinson, 1990; Dunham et al., 1993). Compared with blue catfish, the channel 
catfish has faster growth-to-market size, better tolerance for low oxygen, and superior 
resistance to some diseases (such as columnaris). However, blue catfish has superior 
resistance to certain diseases (such as enteric septicemia of catfish), better carcass 
traits, and easier harvest ability (Dunham & Argue, 2000). Research on hybrids, 
female channel catfish I. punctatus ? male blue catfish I. furcatus (C?B), has 
demonstrated that they exhibit many commercially desirable characteristics. 
Compared to most commercially cultured strains of channel catfish, the C?B hybrid 
exhibits superior characteristics for the following traits: faster growth, tolerance of 
low oxygen, increased resistance to many diseases, tolerance to crowded growth 
conditions in ponds, uniformity in size and shape, higher dress out percentages, 
increased harvest ability by seining, and increased vulnerability to angling (Wolters et 
al., 1996; Masser & Dunham, 1998).  
The use of hybrid catfish has become more and more common in catfish 
industry and the nutrition studies related to hybrid catfish are very limited. It is 
 
 
8 
 
demonstrated that the growth and feed conversion ratio (FCR) were better for C?B 
hybrid fed the 25% protein diet compared to those fed the 45% protein diet (Bosworth 
et al., 1998). 
The economic challenges from lower and lower price of catfish product forced 
today?s catfish industry in the US to reduce the feed cost as more as possible and also 
find more economically competitive species. The use of higher level of DDGS to 
replace SBM without lysine supplementation may be a way to further lower feed cost.  
As discussed, there is considerable interest in the use of DDGS in both 
traditional catfish culture and hybrid catfish culture. Currently, there is considerable 
laboratory work on the use of DDGS in channel catfish feeds. However, there are few 
examples which demonstrate the feasibility of using high levels of DDGS with or 
without lysine supplements under pond production conditions. Consequently, the 
primary objective of this work was to evaluate the response of channel catfish to diets 
containing 20 or 30% DDGS with or without lysine supplements in pond production 
condition. As an alternative species to channel catfish in today?s catfish industry, 
hybrid catfish production has become more and more popular in US. As mentioned 
before, there is limited information on hybrid catfish nutrition and their acceptance of 
practical diet formulations. So the secondary objective of this research was to 
preliminarily evaluate the response of fingerling hybrid catfish to the four mentioned 
diets under controlled laboratory conditions.  
 
 
 
9 
 
II. UTILIZATION OF CATFISH PRODUCTION DIETS USING HIGH LEVELS OF 
DDGS WITH OR WITHOUT LYSINE SUPPLEMENTS 
1. ABSTRACT 
The response of channel catfish to practical diets containing 20% and 30% 
DDGS with and without lysine supplementation was evaluated over a 150 day pond 
trial. Twenty earthen ponds four replicates per treatment were stocked with 650 
juvenile channel catfish. The control diet (Diet-1) contained 35% SBM and 23.7% 
CM was based on the formula of a practical diet for channel catfish. The experimental 
diets included: Diet-1 (basal diet; no DDGS and no lysine supplementation), Diet-2 
(20% DDGS and 0% lysine supplementation), Diet-3 (20% DDGS and 0.10% lysine 
supplementation), Diet-4 (30% DDGS and 0% lysine supplementation) and Diet-5 
(30% DDGS and 0.20% lysine supplementation). There were no significant 
differences among all treatments for the measured parameters including initial weight, 
initial biomass, initial length, final number, final weight, final biomass, final average 
length, weight gain, yield, feed input, survival rate, and FCR. This study indicates that 
diets without lysine supplementation containing 30% DDGS in combination with 
SBM and CM provide good growth and feed utilization in channel catfish pond 
production. 
 
 
10 
 
2. INTRODUCTION 
Feed is generally the largest expenditure in semi-intensive and intensive 
catfish culture operations, and protein is the most expensive component of feeds 
(Robinson & Li, M 2008).  Efforts to reduce feed costs have resulted in increased use 
of plant proteins in diet formulations as replacements of expensive animal ingredients. 
Soybean meal (SBM), because of its low-cost, consistent quality, availability, and 
high nutritional value, is the most commonly used plant based protein source in fish 
feeds. Currently, SBM comprises 30 to 40% of the formulation in commercial grow-
out feeds for catfish. Replacement of SBM with less expensive protein sources would 
be beneficial in reducing feed costs. Distiller?s dried grains with solubles (DDGS), a 
co-product of the ethanol distillery industry, is typically less expensive than SBM on a 
per unit protein basis. In 2001, the U.S. produced about 3.1 million tons of DDGS. As 
a result of the recent expansion and increase in ethanol production for fuels due to the 
shortage and rising cost of petroleum-based fuel, and to reduce pollution , the 
production of DDGS in the U.S. has been reported to approximately 8 million tons in 
2006 (Shurson 2006).  
DDGS has moderate protein content (~ 30% crude protein) without the 
presence of antinutritional factors commonly found in most plant protein sources. At 
present, DDGS is widely used as a protein supplement in terrestrial animal feeds, but 
its use in fish feed is limited due to its low content of essential amino acids, especially 
lysine (NRC 1993). Results of earlier studies, however, have shown that based on 
growth performance and feed utilization efficiency, DDGS is a promising feed 
ingredient for several fish species, including rainbow trout (Cheng and Hardy 2004), 
channel catfish (Lovell 1980; Tidwell et al. 1990; Webster et al. 1991, 1992a, 1992b, 
 
 
11 
 
1993), and tilapia (Wu et al. 1996; Lim et al. In Press). A recent laboratory study by 
Lim and co-workers (personal communications) showed that, with lysine 
supplementation, DDGS at dietary levels ranging from 10 to 40% can be used in 
catfish feeds as replacements of various levels of a mixture of SBM and corn meal 
without affecting their growth and feed utilization efficiency. The cost of feed can be 
further reduced if lysine supplementation can be omitted from the formulation. 
Currently, there is considerable interest in the use of DDGS in commercial 
catfish rations. However, there is limited information on the use of high levels DDGS 
and the need for lysine supplements. Hence, the objective of this study was to 
demonstrate 1) the use of DDGS at high inclusion levels and 2) to determine if lysine 
supplements are required in commercially grow out DDGS containing diets for 
channel catfish. 
3. MATERIALS AND METHODS 
3.1. PONDS  
Twenty rectangular ponds were utilized at the E. W. Shell Fisheries Center, 
North Auburn. The size of each pond is equally 0.04 ha (0.1 acre), and from 0.6-1.2 m 
(2 to 4 feet) in depth with a bottom slope of 0.2 to 0.3 degree. A rectangular catch 
basin is situated in the deep end of the pond and contains a water inlet and tilt down 
screened stand pipe. Each pond has two separate water supply lines for independent 
filling from the catch basin or the shallow end of the pond. Ponds were sun dried for 
one week before stocking.  They were then filled with around 0.6 m (2 feet) of water 
and copper sulfate was applied for 4 days to prevent the aquatic weeds problems. The 
ponds were then drained, dried for two days, filled and quick lime applied to increase
 
 
12 
 
the alkalinity of the water. Ponds were filled from a hillside reservoir receiving runoff 
from the stations water shed. 
3.2. DIETS PREPARATION 
Five experimental diets were formulated to contain 32% protein and 6% lipid. 
The upper limit to dried distiller?s grain with soluble (DDGS) was set at 30% due to 
processing consideration and possible degradation of pellet quality when using higher 
inclusion levels (Lim 2007). The diets consisted of a basal (control) diet and test diets 
containing 20% and 30% DDGS, with and without the addition of lysine. The DDGS 
replaced on an equal protein basis a mixture of SBM and CM. (Table 2). The diets 
were designated as follows: Diet-1 (basal diet; no DDGS and no lysine 
supplementation), Diet-2 (20% DDGS and 0% lysine supplementation), Die-3 (20% 
DDGS and 0.10% lysine supplementation), Diet-4 (30% DDGS and 0% lysine 
supplementation) and Diet-5 (30% DDGS and 0.20% lysine supplementation). Fish 
oil was adjusted to keep lipid constant in all treatments. Because DDGS contains 
lower levels of protein than SBM, a combination of SBM and CM was used to 
maintain the protein level around 32%. Diets were extruded into floating pellets by 
Zeigler Brothers Inc. (Gardners PA, USA) and were transported and stored in plastic 
lined paper bags. A pooled sample from over > 15 bags was collected and the 
proximate composition and amino acids composition of the diets analyzed following 
AOAC (1995) procedures by the New Jersey Feed Laboratory, Inc and are presented 
in Table 1 and 2, respectively.  
 
 
13 
 
 
3.3. CULTURE METHODS 
 Channel catfish (Ictalurus punctatus) juvenile were obtained from a 
commercial fingerling producer in Mississippi. Before juveniles were stocked into 
experimental ponds, a formalin treatment was applied to reduce disease transmission 
in holding troughs. An initial sample of 60 fingerlings was randomly collected for the 
calculation of average initial weight, length, and size distribution. Based on the 
relationship between weight and length, all juveniles were judged as thin (relative 
weight ratio of every fish is less than 1.0). The standard length-weight relationship 
comes from the published values of Tucker & Hargreaves (2004).  
Juveniles were manually sorted into three groups based on length. The range 
for each group was: less than 12.7cm (5 in), 12.7-15.2 cm (5-6 in), larger than 15.2cm 
(7 in). Every group was then evenly stocked into twenty ponds in a rate of 650 fish 
per pond (6500/acre or 16055/ha). During the first five days after stocking, mortalities 
were collected and replaced with similar sized fish.  
Feed was offered once a day in the afternoon. A fixed quantity of feed was 
pre-weighed for each pond which was based on an estimated feed intake. Feed was 
then offered to satiation with daily rations adjusted as needed based on the fishes 
response and the desire not to over feed  The feeding process in this study was:  
1. Pre-weight feed for each pond.  
2. Apply feed to pond slowly and observe the feeding behavior. 
3. Increase or decrease feed inputs based on feeding response. 
 
 
14 
 
Table 1. Ingredient and proximate composition of five experimental diets (As is basis) 
 
Ingredient Diet-1 Diet-2 Diet-3 Diet-4 Diet-5 
 
Soybean meal  32.00 24.00 24.00 20.00 20.00 
DDGS1 0.00 20.00 20.00 30.00 30.00 
Wheat middlings 21.79 16.00 16.00 9.99 9.79 
Corn meal 20.00 15.00 15.00 16.00 16.00 
Cottonseed meal 15.00 14.99 14.89 15.00 15.00 
Poultry by product meal 
67% P 5.60 5.40 5.40 5.40 5.40 
Blood meal 92% P 2.00 2.00 2.00 2.00 2.00 
Fish oil 2.00 1.00 1.00 0.00 0.00 
Dicalcium phosphate 1.00 1.00 1.00 1.00 1.00 
Ca propionate 0.25 0.25 0.25 0.25 0.25 
Vitamin premix2 0.20 0.20 0.20 0.20 0.20 
Mineral premix2 0.10 0.10 0.10 0.10 0.10 
Stay-C 35% active 0.06 0.06 0.06 0.06 0.06 
Lysine 0.00 0.00 0.10 0.00 0.20 
 
Proximate composition (As is basis)3 
Crude protein  35.0 34.2 34.8 35.0 34.0 
Crude lipid  6.8 6.6 6.6 7.1 6.6 
Fiber 5.5 5.7 5.8 5.8 5.9 
Ash 6.3 6.2 6.2 6.1 5.7 
Lys % Protein 5.4 5.0 5.1 4.7 4.8 
Met + Cys % Protein 3.4 3.6 3.5 3.5 3.3 
 
1 DDGS: distiller?s dried grains with solubles. 
2 Vitamin and mineral premixes (DSM Inc., 45 Waterview Boulevard, Parsippany, 
New Jersey 07052-1298). 
3  Analysis conducted by New Jersey Feed Lab Inc 1686 Fifth St Trenton NJ.  08638 
 
 
15 
 
Table 2. Amino acid compositions (g/100g basis) of the experimental diets Analysis 
conducted by New Jersey Feed Lab Inc , Trenton NJ.  USA. 
 
Amino acids  
(% dry diet) Diet-1 Diet-2 Diet-3 Diet-4 Diet-5 
Methionine 0.60 0.62 0.62 0.61 0.58 
Cystine 0.55 0.55 0.55 0.55 0.51 
Lysine 1.81 1.63 1.67 1.58 1.58 
Phenylalanine 1.69 1.65 1.69 1.67 1.67 
Leucine 2.63 2.73 2.85 2.90 3.00 
Isoleucine 1.28 1.22 1.36 1.30 1.29 
Threonine 1.32 1.28 1.28 1.32 1.28 
Valine 1.52 1.48 1.59 1.57 1.50 
Histidine 0.88 0.89 0.87 0.88 0.87 
Arginine 2.56 2.28 2.41 2.31 2.33 
Glycine 1.82 1.71 1.72 1.77 1.68 
Aspartic acid 3.61 3.34 3.35 3.33 3.22 
Serine 1.77 1.71 1.68 1.72 1.66 
Glutamic acid  6.49 6.54 6.19 6.59 6.36 
Proline 1.81 1.95 1.91 2.08 1.97 
Hydroxyproline 0.20 0.22 0.23 0.23 0.24 
Alanine 2.07 2.00 2.19 2.31 2.04 
Tyrosine 0.84 0.87 0.90 0.86 0.89 
Total 33.45 32.67 33.06 33.58 32.67 
 
 
 
Water temperature and DO concentrations were monitored twice daily (at 
about 06:00 and 17:00 h) using an YSI model 55 DO meter (YSI Incorporated). Water 
sample were collected every two weeks for total ammonia nitrogen analysis and pH 
was checked every week using pH test strips. Morning DO levels of ponds were 
maintained above 3 ppm by using 0.5-hp floating vertical pump aerators. 
3.4. HARVESTING AND FINAL DATA COLLECTION 
The fish were cultured from May 22, 2008 to October 21, 2008 with feed 
being offered over 150 days. Prior to harvest, the water level was lowered to 2 feet for 
all ponds. The harvest process included group weighing of the fish with 40 fish 
 
 
16 
 
randomly sampled for the determination of individual weights and lengths. Fish were 
first removed by seining the ponds then by drain harvesting with the fish concentrated 
into the catch basin. After harvest, five fish from each pond was collected for 
determination of whole-body proximate composition (AOAC 1990). The collected 
data including: final number, final weight, final biomass, final average length, weight 
gain, and yield. Survival was in percentage basis. FCR was the ratio of feed input over 
yield.  
The collected data was then analyzed for statistical differences using SAS 
(Statistic Analysis Systems, SAS Institute, Inc., Cary, NC, 2008). Data was analyzed 
by one-way analysis of variance and Student-Nuewman-Keuls test to determine 
significance (P < 0.05) difference between means. 
4. RESULTS 
Overall means (? 95% confidence interval) for water quality parameter were: 
temperature, 26.5 ? 0.2oC; dissolved oxygen, 4.84 ? 0.06 ppm; pH, 7.8 ? 0.3; total 
ammonia nitrogen, 0.24?0.03 ppm; (ranged from 0 to 1.48 ppm). These values are 
within acceptable water quality criteria (Table 3) for channel catfish grow out pond 
provided by Craig S. Tucker (Tucker 2004).  
Initial biomass, initial weight, final biomass, final weight, net yield, final 
number, survival, weight gain, feed consumption, and FCR are summarized in table 4.  
Survival rate ranges from 62% to 85%. The numerically lowest survival rate was 
found in diet 2 which is 20% DDGS diet without lysine supplementation. The highest 
survival rate was found in diet 5 which is 30% DDGS diet with 0.2% lysine 
supplementation. Percent weight gain (WG) ranges from 243.9% to 397.5%.  The 
 
 
17 
 
lowest number of WGR was found in diet 2 which is 20% DDGS diet without lysine 
supplementation and the highest number of WGR was found in diet 3which is 20% 
DDGS diet with 0.1% lysine supplementation. FCR ranges from 1.5 to 2.2. The 
lowest FCR was found in diet 3 (20% DDGS + 0.1% lysine) and the highest FCR was 
found in diet 2 (20% DDGS + 0% lysine). There are no significant differences were 
found in recorded parameter among all diets including initial number, initial weight, 
initial size, final number, final weight, final size, survival rate, weight gain and final 
relative weight.  
The whole-body proximate composition analysis of sample in harvest is given 
in table 5. There was no significant difference among the tested parameters. 
5. DISCUSSION 
Dietary protein requirements for catfish have been determined in various 
studies, and range from 24 to 55% (NRC 1993). As mentioned before, factors that can 
influent the protein requirements for catfish were concluded as: 1) Different size and 
life stages. 2) The digestible energy content of the diet. And 3) Feeding rate. Li and  
Lovell (1992) reported that a dietary protein concentration of 26% was adequate for 
optimum weight gain when fish were fed as much as they would consume, whereas a 
minimum dietary protein level of 32% was necessary for optimum growth when fish 
were fed at a predetermined maximum level of 60 kg/ha (55 pounds/acre) per day. In 
present study, all diets were maintained to have a protein level around 32%. This 
protein level was chosen as it is currently used by the commercial industry in 
Alabama.    
 
 
 
18 
 
Table 3. Acceptable Water Quality Criteria for a catfish grow out pond (Tucker & 
Hargreaves 2004).  
 
___________________________________________________________ 
 
 1.  Temperature range 200C-350C, ideal range: 250C-320C 
 2.  Low CO2 , less than 5 ppm, no more than 20 ppm 
 3.  Morning O2 - more than 3 ppm  less than 1 ppm lethal 
 4.  Nitrogen (gas) 
   100% saturation acceptable 
   supersaturation problems 
 5.  Suspended solids- < 2000 ppm 
 6.  pH- 6.5-9.0 
 7.  Alkalinity and hardness 50 mg to 250 mg/L Ca as CaCO3  
 8.  Salinity : lower than 12ppt 
 9.  Iron- less than 0.1 ppm 
 10.  Pesticides/pollution free 
___________________________________________________________ 
 
 
In order to reduce the cost of production diets for catfish, one could either 
reduce the level of protein, which is not favorable by many producers, or one could 
switch to a lower cost protein source. DDGS is one of the choices which are the lower 
cost protein source. DDGS has moderate protein content (~30% crude protein) 
without the presence of antinutritional factors commonly found in most plant protein 
sources. At present, DDGS is widely used as a protein supplement in terrestrial 
animal feeds, but its use in fish feed is limited due to its low content of essential 
amino acids, especially lysine (NRC 1993). Results of earlier studies, however, have 
shown that based on growth performance and feed utilization efficiency, DDGS is a 
promising feed ingredient for several fish species, including rainbow trout (Cheng & 
Hardy 2004), channel catfish (Lovell 1980; Tidwell et al. 1990; Webster et al. 1991, 
1992a, 1992b, 1993), and tilapia (Wu et al. 1996; Lim et al. 2008). 
  
 
 
19 
 
Table 4. Growth performance and feed utilization of channel catfish fed on 
experimental diets. (Statistic Analysis Systems, SAS Institute, Inc., Cary, NC, 
2008). 
 
 
 IBio: Initial Biomass (kg) 
IW: Average Initial Weight (g) 
FBio: Final Biomass (kg) 
Yield: FBio*10*2.47acre/hectare (kg/ha) 
NetY:(Fbio ? Ibio) *10*2.47acre/hectare(kg/ha) 
FNum: Final Number 
Sur:Average Percent Survival (%) 
FW: Average Final Weight (kg) 
NYP: Net yield per pond = FBio- IBio (kg) 
WG: Weight gain = 100 ? (final weight ? initial weight) / initial weight (%) 
MRW: Mean relative weight: Mean relative weight of 40 fish per pond. 
FC: Average Feed Consumption per pond (kg) 
FCR: Feed conversion ratio = feed offered (kg) / weight gained (kg) 
PSE: Pooled standard Error= ???/? 
 Diet-1 Diet-2 Diet-3 Diet-4 Diet-5 PSE P-value 
IBio(kg) 56.3 56.9 55.7 56.3 55.9 0.67 0.787 
IW(g) 86.7 87.5 85.7 86.7 86.1 1.03 0.786 
FBio(kg) 236.3 229.2 251.8 234.0 233.4 9.64 0.535 
Yield(kg/ha) 5838 5661 6220 5779 5766 238.1 0.535 
NetY(kg/ha) 4446 4255 4844 4388 4383 231.7 0.472 
FNum 477.0 476.8 523.0 476.5 499.8 22.36 0.512 
Sur(%) 73.5 73.2 80.2 73.3 77.0 0.035 0.548 
FW (g)  498.8 481.7 482.2 491.4 468.6 17.78 0.799 
NYP(kg) 180.0 172.3 196.1 177.7 177.5 9.38 0.472 
WG (%)  319.5 302.8 351.8 315.5 317.0 15.4 0.30 
 MRW 1.16 1.11 1.11 1.10 1.13 0.019 0.148 
FC(kg) 310.5 327.7 327.1 332.2 333.2 7.6 0.27 
FCR 1.7 1.9 1.7 1.9 1.9 0.077 0.151 
 
 
20 
 
Table 5. Whole-body proximate composition of channel catfish fed diets containing 
various levels of distiller?s dried grains with solubles with and without lysine 
supplementation for 150 days. 
 
diet Moisture (%) 
Percent wet weight basis (%) 
Lipid Ash Protein 
1 74.85 6.11 1.18 17.75 
2 75.46 5.26 1.15 17.60 
3 74.89 5.82 1.17 17.54 
4 75.53 5.44 1.18 17.53 
5 74.51 6.35 1.18 17.83 
PSE 0.577 0.573 0.023 0.23 
 p-value 0.689 0.653 0.791 0.85 
 
 
The present study was conducted over a 150 days of culture resulting in a final 
biomass of around 5550 kg/ha (5000 lbs/acre). These numbers are typically 
acceptable in the southern US (Tucker 2004). Results of the present study suggest that 
utilization of high levels (20% and 30%) of DDGS in production diets for catfish is 
acceptable. Under the conditions of this study, there were no differences in net yield, 
final weight and FCR for fish reared on a typical catfish feed or one containing 20% 
and 30% DDGS. These results are supported by a number of other studies with 
various fish species and under variety of culture conditions. 
Wu et al. (1996), in a study to evaluate the growth response of Nile tilapia 
(Oreochromis niloticus) fry fed all-plant protein diets, reported that in diets containing 
32, 36, and 40% crude protein, incorporation of 16?49% DDGS resulted in good WG, 
FER, and PER. A diet containing 15% DDGS has been reported to provid
 
 
21 
 
satisfactory growth of channel catfish (Hastings 1967). Lovell (1980) reported that, 
when used in combination with 10% fish meal, up to 30% DDGS has been used in 
channel catfish diets under pond conditions. Webster et al. (1993) also found that 30% 
DDGS can be used as a replacement of a mixture of SBM and corn meal  in channel 
catfish diets containing 8% fish meal when the fish are reared in cages culture 
conditions. Tidwell et al. (1990) and Webster et al. (1991) found that 40 and 35% 
DDGS, respectively, can be used in catfish diets as substitutes for the combination of 
SBM and CM on an equal protein basis without requiring lysine supplementation. In 
the same study, Webster also reported that a diet containing 70% DDGS appeared to 
be deficient in lysine because supplementation of lysine at a level to meet lysine 
requirement improved the growth of catfish. In a laboratory study of Nile tilapia 
(Oreochromis niloticus), Lim et al. (2007) reported that increasing dietary levels of 
DDGS to 40% without addition of lysine significantly reduced WG and PER compare 
to those obtained with diets containing lower DDGS levels (0, 10, and 20%). FCR of 
this diet (40% DDGS) was also significantly lower than that of the control diet.  
Lysine is generally considered to be the first limiting amino acid for catfish. If 
feeds are formulated to meet a minimum lysine requirement, the requirements for all 
other amino acids are met or exceeded if traditional feed ingredients are used. Lysine 
will likely be the only supplemental amino acid needed in commercial catfish feeds 
(Tucker and Hargreaves 2004). Lysine requirement of juvenile channel catfish for 
optimum growth was reported as 5.1% of total protein (NRC 1993). Lysine levels of 
the test diets are presented in table 2 in diet percentage basis. Converting these values 
to percentage of dietary protein, the diets lysine percentages of total protein are: diet 
1, 5.41%; diet 2, 4.99%; diet 3, 5.05%; diet 4, 4.71%; diet 5, 4.84%.  So diet 4 and 
 
 
22 
 
diet 5 likely have the higher risks to show lysine deficiency. In the present study, 
signs of a dietary lysine deficiency were not evident.  
There are several possible reasons that a deficiency was not observed. One 
possible explanation is that the fermentation process can improve the digestibility of 
plant protein sources; thus, improving the availability of lysine. Ingledew (1999) 
estimated that 3.9% of the total biomass of DDGS was yeast, with 5.3% of the protein 
content of this product being contributed by yeast protein. Yeasts are rich in protein, 
B-complex vitamins and ?-glucans. Therefore, effects of the micronutrients and some 
other components of DDGS should be taken into account when it is used as dietary 
protein source. Another reason could be that DDGS improved the palatability of feed 
and fish can eat more thus improving daily intake which would over shadow a minor 
deficiency.  
 In the present study, as well as those of  Tidwell et al. (1990) and Webster et 
al. (1991) it was demonstrated that high levels of DDGS  can be used in catfish diets 
as substitutes for the combination of SBM and CM on an equal protein basis without 
requiring lysine supplementation. In addition to growth and production not being 
influence by the shifts in protein sources there were no differences in proximate 
composition of the fish.  As table 5 shows, whole-body proximate composition was 
not affected by dietary levels of DDGS and lysine supplementation. The lower protein 
content of fish fed the 30% DDGS diet without lysine may be related to smaller size 
of sampled fish that had less flesh. Webster et al. (1992b) reported significantly lower 
protein content of dressed carcass of catfish fed a diet with 90% DDGS without added 
lysine than in fish fed the 55% DDGS diet. However, no significant differences were 
observed among carcass proximate composition of catfish fed diets containing 0, 10, 
 
 
23 
 
20, and 30% DDGS (Webster et al. 1993). However, there were significantly lower 
protein content of dressed carcass of catfish fed a diet with 90% DDGS without added 
lysine than in fish fed the 55% DDGS diet.  If the channel catfish industry is going to 
reduce costs, they must optimize commercial feed formulations. Hence, when feed 
prices warrant the use of DDGS there appears to be no reason not to use up to 30% 
DDGS in practical diets. As this ingredient is low in lysine, levels of this nutrient 
should be adjusted if needed.  
  
 
 
24 
 
6. REFERENCES 
 
Association of Official Analytical Chemists (AOAC), 1995. Official methods of 
analysis of official analytical chemists international, 16th ed. Association of 
analytical chemists, Arlington, VA.. 
Cheng, Z.J., & Hardy, R.W., 2004. Nutritional value of diets containing distiller?s 
dried grain with solubles for rainbow trout, Oncorhynchus mykiss. Journal of 
Applied Aquaculture, 15:101-113. 
Dunham, R.A., & Argue, B.J., 2000. Reproduction among channel catfish, blue 
catfish, and their F1 and F2 hybrids. Transactions of the American Fisheries 
Society, 129:222?231. 
Dunham, R.A., et al., 1993. Comparison of culture traits of channel catfish, Ictalurus 
punctatus, and blue catfish, I. furcatus. Journal of Applied Aquaculture 3:257?
267. 
Hastings, W. H.  1967.  The Hungarian People's Republic. Fish feed technology. A 
report prepared for the Development of Fish Culture Research Project 
Harding, D.E., et al., 1977. Sulfur amino acid requirement of channel catfish: L-
methionine and L-cystine. Journal of Nutrition, 107: 2031-2035. 
Ingledew, W. M., 1999. Yeast ? could you base business on this bug? Pages 27?47 in 
T. P. Lyons and K. A. Jacques, editors. Under the microscope ? focal points for 
the new millennium ? biotechnology in the feed industry. Proceedings of 
Alltech?s 15th Annual Symposium. Nottingham University Press, Nottingham, 
UK. 
 
 
 
 
25 
 
Li, M. & Lovell, R. T. 1992. Comparison of satiate feeding and restricted feeding of    
channel catfish with various concentrations of dietary protein in production 
ponds. Aquaculture. 103 (2), 165-175. 
Lim, C. et al., 2007. Growth Response and Resistance to Streptococcus iniae of Nile 
 tilapia, Oreochromis niloticus, Fed Diets Containing Distiller? Dried Grains with 
 Solubles. Journal of World Aquaculture Society. 38 (2), 231-237. 
Lim, C. et al., 2008.  Effect of distillers dried grains with solubles-incorporated  diets 
on growth, immune function and disease resistance in Nile tilapia (Oreochromis  
niloticus L.) Aquaculture Research. 39 (12), 1351-1353.      
Mangalik, A. 1986. Dietary energy requirements of channel catfish DISS. ABST. 
INT. PT. B - SCI. & ENG. 47 (2), 139.  
Jimmy W. et al., 1975.  The Effects of Frequency of Feeding on Culture of Catfish. 
Transactions of the American Fisheries Society. 104 (2), 317-321. 
Robinson, E.H, et al., 1998.Effect of reduction of supplementary dietary vitamins on 
the stress response of channel catfish ictalurus punctatus. Journal of the World 
Aquaculture Society. 29 (3), 319-324.  
Robinson, E.H, & Li, M.H., 2001. Evaluation of Corn Gluten Feed as a Dietary 
Ingredient for Pond-Raised Channel Catfish Ictalurus punctatus. Journal of the 
World Aquaculture Society. 32 (1), 68-71. 
 Robinson, E.H., & Li, M.H., 2008. Replacement of Soybean Meal in Channel 
Catfish, Ictalurus punctatus, Diets with Cottonseed Meal and Distiller?s Dried 
Grains with Solubles. Journal of the World Aquaculture Society, 39(2): 521-527. 
 
 
 
 
26 
 
Robinson, E.H et al., 1980. Re-evaluation of the lysine requirement and lysine 
utilization by fingerling channel catfish. Journal of Nutrition.  110: 2313-2316. 
Shurson, J., 2006. Diversity in DDGS and other corn co-products. What?s good for 
monogastrics - or not! Feed Management, 57 (2): 14-17. 
Storebakken, T., et al., 2000. Soy products as fat and protein sources in fish feeds for 
intensive aquaculture. In: Drackley, J.K. (Ed.), Soy in Animal Nutrition. Fed. 
Anim. Sci. Soc., Savoy, IL, USA, pp. 127?170. 
Teshima, S., & Kanazawa, A., 1988. Nutritive value of methionine-enriched soy 
plastein for Oreochromis niloticus fry. In: Pullin, R.S.V., Bhukaswan, T., 
Tonguthai, K., Maclean, J.L. (Eds), 2nd Intl. Symp. on Tilapia in Aquaculture, 
ICLARM Conf. Proc. No. 15, Manila, Philippines. pp. 393?399. 
Tidwell, J.H., et al., 1990. Evaluation of distillers grains with solubles in prepared 
channel catfish diets. Transactions of Kentucky Academy of Science, 52:135-
138. 
Tucker, C.S., & Robinson, E.H., 1990. Channel catfish farming handbook. Van 
Nostrand Reinhold, New York, New York, USA. 
Tucker, C. S., et al., 2004. Biology and culture of channel catfish.  London : Elsevier, 
Amsterdam. 
Viola, S., & Arieli, Y., 1983. Nutrition studies with tilapia Sarotherodon: 1. 
Replacement of fishmeal by soybean meal in feeds for intensive tilapia culture. 
Bamidgeh 35: 9?17. 
Webster, C.D., et al., 1992. Use of soybean meal and distillers grains with solubles as 
partial or total replacement of fish meal in diets for channel catfish, Ictalurus 
punctatus. Aquaculture, 106:301?309. 
 
 
27 
 
Webster, C.D., Tidwell et al., 1993. Growth, body composition, and organolepitic 
evaluation of channel catfish fed diets containing different percentages of 
distillers? grains with solubles. The Progressive Fish-Culturist, 55: 95-100. 
Webster, C.D., et al., 1991. Evaluation of distillers? grains with solubles as a protein 
source in diets for channel catfish. Aquaculture, 96:179?190. 
Winfree, R.A., & Stickney, R.R., 1984. Formulation and processing of hatchery diets 
for channel catfish.  Aquaculture. 41 (4): 311-323.        
Wolters, W.R., et al., 1996. Survival and antibody response of channel catfish, blue 
catfish, and channel catfish female ? blue catfish male hybrids after exposure to 
Edwardsiella ictaluri. Journal of Aquatic Animal Health, 8: 249-254. 
Wu, Y.V., et al., 1996. Effects of diets containing various levels  of protein and 
ethanol co-products from corn on growth of tilapia fry. Journal of Agricultural 
Food Chemistry, 44: 1491-1493 
 
 
28 
 
III. GROWTH    RESPONSE  AND FEED UTILIZATION OF JUVENILE HYBRID 
CATFISH, I. PUNCTATUS ? I. FURCATUS, USING HIGH LEVELS OF DDGS 
WITH OR WITHOUT LYSINE  SUPPLEMENTS 
1. ABSTRACT 
A feeding trial was conducted in aquaria with juvenile hybrid catfish, channel 
catfish Ictalurus punctatus ? blue catfish I. furcatus (C ? B), to evaluate the distiller?s 
dried grains with solubles (DDGS) as a replacement for a combination of soybean 
meal (SBM) and corn meal (CM). Twenty-five 75 l glass aquaria were stocked with 
30 juvenile hybrid catfish (initial weight: 1.16-1.25 g) per aquarium. The control diet 
(Diet-1) contained 35% SBM and 23.7% CM was based on the formula of a practical 
diet for channel catfish. The list of the experimental diets was as follows: Diet-1 
(basal diet; no DDGS and no lysine supplementation), Diet-2 (20% DDGS and 0% 
lysine supplementation), Diet-3 (20% DDGS and 0.10% lysine supplementation), 
Diet-4 (30% DDGS and 0% lysine supplementation) and Diet-5 (30% DDGS and 
0.20% lysine supplementation). Fish were restricted-fed at a rate equaling 5-10% of 
wet body weight twice daily for 8 weeks. There were no significant differences in 
final weight, final biomass, percentage weight gain (WG) among the all treatments. 
The lowest feed conversion ratio (FCR) was found in Diet-4. This study indicates that 
diets without lysine supplementation containing 30% DDGS in combination with 
SBM and CM provide good growth and feed utilization in juvenile C ? B hybrid 
catfish. 
 
 
29 
 
2. INTRODUCTION 
Efforts to reduce feed costs have resulted in increased use of plant proteins in 
diet formulations as replacements of expensive animal ingredients, especially fish 
meal. Because of its high protein content, high digestibility, relatively well-balanced 
amino acid profile, reasonable price, and steady supply, solvent extracted de-hydrated 
soybean meal (SBM) is widely used as a cost-effective feed ingredient for many 
aquaculture animals (Storebakken et al., 2000). However, other plant protein sources 
often cost less than SBM, thus replacing SBM with less expensive plant protein 
sources would be beneficial in reducing feed costs. 
Distiller?s dried grains with solubles (DDGS) is a co-product of the ethanol 
distillery industry. As a result of the recent expansion and increase in ethanol 
production for fuels, and to reduce pollution, the production of DDGS in the USA has 
been reported to increase to approximately 8 million tons in 2006 (Shurson, 2006). It 
has moderate protein content (~ 30% crude protein) without the presence of anti-
nutritional factors commonly found in most plant protein sources. Results of earlier 
studies have shown that based on growth performance and feed utilization efficiency, 
DDGS is a promising feed ingredient for several fish species, including rainbow trout 
(Cheng and Hardy, 2004), tilapia (Wu et al., 1996), and channel catfish (Lovell, 1980; 
Tidwell et al., 1990; Webster et al., 1991; 1992; 1993).  
    At least four species of ictalurid catfish have been considered as candidates 
for commercial aquaculture in the USA. Channel catfish Ictalurus punctatus and blue 
catfish I. furcatus are the most popular two species for aquaculture (Tucker and 
Robinson, 1990; Dunham et al., 1993). Compared with blue catfish, the channel 
catfish has faster growth-to-market size, better tolerance for low oxygen, and superior 
 
 
30 
 
resistance to some diseases (such as columnaris). However, blue catfish has superior 
resistance to certain diseases (such as enteric septicemia of catfish), better carcass 
traits, and easier harvest ability (Dunham and Argue, 2000). Research on hybrids, 
female channel catfish I. punctatus ? male blue catfish I. furcatus (C?B), has 
demonstrated that they exhibit many commercially desirable characteristics. 
Compared to most commercially cultured strains of channel catfish, the C?B hybrid 
exhibits superior characteristics for the following traits: faster growth, tolerance of 
low oxygen, increased resistance to many diseases, tolerance to crowded growth 
conditions in ponds, uniformity in size and shape, higher dress out percentages, 
increased harvest ability by seining, and increased vulnerability to angling (Wolters et 
al., 1996; Masser and Dunham, 1998). The published data on the nutrition of C?B 
hybrid was limited. It is demonstrated that the growth and feed conversion ratio 
(FCR) were better for C?B hybrid fed the 25% protein diet compared to those fed the 
45% protein diet (Bosworth et al., 1998). The objective of this study is to investigate 
the growth response and feed utilization of juvenile C?B hybrid catfish fed diets 
containing high level of DDGS as a replacement of a combination of SBM and corn 
meal (CM). 
3. MATERIALS AND METHODS 
3.1. DIET PREPARATION 
Because lack of the basic data of nutrient requirements for hybrid catfish (C ? 
B), a practical diet formula for channel catfish I. punctatus was used as the basal 
(control) diet in present study. Five isonitrogenous experimental diets were 
formulated to contain 32% protein and 6% lipid. The upper limit to DDGS was set at 
 
 
31 
 
30% due to processing consideration and possible degradation of pellet quality when 
using higher inclusion levels. The diets consisted of a basal (control) diet and diets 
containing 20% and 30% DDGS, with and without the addition of lysine, as partial 
replacements of a mixture of SBM and CM on an equal protein basis (Table 1). The 
list of these diets was as follows: Diet-1 (basal diet; no DDGS and no lysine 
supplementation), Diet-2 (20% DDGS and 0% lysine supplementation), Die-3 (20% 
DDGS and 0.10% lysine supplementation), Diet-4 (30% DDGS and 0% lysine 
supplementation) and Diet-5 (30% DDGS and 0.20% lysine supplementation). Fish 
oil was added to keep lipid constant in all treatments. Diets were extruded into 
floating pellets by Zeigler Brothers Inc. (Gardners PA, USA). The proximate 
composition and amino acids composition of the diets were analyzed following 
AOAC (1995) procedures by the New Jersey Feed Laboratory, Inc and are presented 
in Table 1and 2, respectively. 
3.2. ANIMAL REARING 
Juvenile C?B hybrids were obtained from a mix of spawning. Prior to the start 
of the feeding trial, fish were acclimated to the experimental conditions and fed the 
basal diet for 3 weeks in an indoor re-circulated water system. Fish with an average 
weight of 1.16-1.25 g were randomly stocked into twenty-five 75 l glass aquaria at a 
density of 30 fish per aquarium. Aquaria were supplied with flow-through 
dechlorinated tap water with continuous aeration to maintain the dissolved oxygen 
level above saturation. Fish in quintuplicate aquaria were randomly assigned to each 
of the five experimental diets and were restricted-fed at a rate equaling 5-10% of wet 
body weight twice daily (between 07:00-08:00 h and 14:00?15:00 h) for 8 weeks. 
Fish in each aquarium were group weighed and counted every two weeks. During the 
 
 
32 
 
feeding trial, water temperature was maintained at 24-29 oC, salinity less than 5, pH 
7.2-8.5. Dissolved oxygen was not less than 5 mg/l, and there were negligible levels 
of free ammonia and nitrite. 
3.3. CALCULATIONS AND STATISTICAL ANALYSIS 
At the termination of the 8-week feeding trial, fish in each glass aquarium were 
weighed (each replicate was group weighted) and counted.  
Growth and feed utilization were expressed as follows: 
Weight gain (WG, %) = 100 ? (final weight ? initial weight) / initial weight 
Feed conversion ratio (FCR) = feed offered (g) / weight gain (g) 
Protein efficiency ratio (PER) = weight gain (g) / protein offered (g) 
The Statistical Analysis System (V8.01 SAS Inst. Inc., Cary, NC, USA) was 
used for all statistical evaluations. All data were analyzed using one-way analysis of 
variance (ANOVA), followed by the Duncan test. The level of significance was set at 
P<0.05. 
4. RESULTS 
The proximate analyses of amino acids compositions of experimental diets were 
confirmed by an analysis and are presented in table 2. Lysine levels ranged from 
1.58% to 1.81% of the diet (dry weight basis), and methionine ranged from 0.58% to 
0.62%. 
At the conclusion of the eight week growth trial, survival ranged from 97.3% to 
100.0% had no significant differences among the dietary treatments (Table 6). 
Compared with those in Diet-1 (control) and Diet-2 (20% DDGS, 0% lysine 
supplementation), hybrids fed Diet-4 and Diet-5 with 30% DDGS regardless of lysine 
 
 
33 
 
supplementation had the significant higher final body weight (8.39 g and 8.67 g, 
respectively). Although there were no significant differences in WG among Diet-3 
(20% DDGS, 0.10% lysine supplementation), Diet-4 and Diet-5, they were all 
significant higher than those in Diet-1. Furthermore, the highest value of WG 
(643.2%) was found in Diet-5.  
 
Table 6. Growth performance and feed utilization of juvenile hybrid catfish (Ictalurus 
punctatus ? I. furcatus) fed on experimental diets.  
 
Item 
Experimental diets 
1PSE P value 
Diet-1 Diet-2 Diet-3 Diet-4 Diet-5 
Survival (%) 100 100 98 97 98 0.42 0.174 
Initial weight(g) 1.25 1.17 1.18 1.16 1.17 0.02 0.600 
Final weight(g) 7.42a 7.54ab 8.21bc 8.39c 8.67c 0.14 0.006 
2WG (%) 501a 547ab 598b 624b 643b 16.34 0.021 
3FCR 2.07c 1.97bc 1.78ab 1.73a 1.74a 0.04 0.009 
4PER 1.40a 1.49ab 1.62bc 1.66bc 1.69c 0.03 0.007 
 
1PSE = Pooled Standard Error of Mean 
2WG: Weight gain = 100 ? (final weight ? initial weight) / initial weight 
3FCR: Feed conversion ratio = feed offered (g) / weight gain (g) 
4PER: Protein efficiency ratio = weight gain (g) / protein offered (g) 
 
There were no significant differences in FCR between Diet-4 and Diet-5 
regardless of lysine supplementation. However, both had significant lower FCR than 
Diet-1 and Diet-2. Furthermore, the lowest FCR (1.73) was found in Diet-4 with 30% 
DDGS and 0% lysine supplementation. Regardless of lysine supplementation, 30% 
DDGS in diet leaded to significant higher PER than control. The highest value (1.69) 
of PER was found in Diet-5 with 30% DDGS and 0.20% lysine supplementation. 
 
 
34 
 
5. DISCUSSION 
All treatment groups have a growth rate higher than 500% within the eight week 
rearing period. This is an acceptable result for controlled laboratory conditions 
according to the Reference of Fingerling catfish Health and Production Practices in 
the United States (USDA, 2003).  
Most of the published data about hybrid catfish I. punctatus ? I. furcatus (C ? B) 
focus on spawning, reproduction and disease resistance (e.g., Wolters et al., 1996; 
Dunham and Argue, 2000; Phelps et al., 2007). Limited information on nutrition of 
this hybrid is available. Bosworth et al. (1998) fed diets containing 25% and 45% 
protein to C ? B hybrid for 10 weeks and found that hybrids fed the lower protein diet 
had better growth and feed efficiency than those fed the high protein diet. Because 
lack of the basic data of nutrient requirements for C ? B hybrid, in present study, a 
practical diet for channel catfish I. punctatus was used as the basal (control) diet. It is 
interesting, in present study, that diet of DDGS up to 30% in diet as a replacement of 
a combination of SBM and CM regardless of lysine addition improved the growth of 
C ? B hybrids. This is in general agreement with previous studies, which showed that 
up to 30-35% DDGS could be used to partially replace SBM in channel catfish diets 
(Webster et al., 1991; 1992; 1993; Robinson and Li, 2008). Furthermore, in present 
study, the control diet with 32% soybean meal and 20% corn meal had the poorest 
growth. The WG in this treatment was significantly lower than those in Diet-3, Diet-4 
and Diet-5 with DDGS supplementation (Table 6). Concentrations of lysine (1.58-
1.81%) and methionine (0.58-0.62%) in these five experimental diets (Table 2) met 
the requirements of channel catfish (lysine, ~1.5%, Robinson et al., 1980; methionine, 
 
 
35 
 
~0.56%, Harding et al., 1977). The results implied that lysine and methionine were 
not the limiting amino acids in diets containing DDGS used for C ? B catfish.  
The lowest FCR in the current study was found in Diet-4 with 30% DDGS and 
no lysine supplementation. At the same time, Diet-4 had the highest PER statistically 
the same as Diet-5 with 30% DDGS and 0.20% lysine supplementation. It appears 
that replacement of dietary SBM and CM with DDGS at an up to 30% level improved 
the SBM and CM control diet. These results are in general agreement with the results 
in research of channel catfish (Robinson and Li, 2008). In that experiment, FCR was 
significantly lower for fish fed the SBM + DDGS diet compared to those fed a SBM 
control diet. However, this has not been seen in previous studies (Webster et al., 1991; 
1992; 1993; Robinson and Li, 2005). Robinson and Li (Robison & Li, 2008) ascribed 
this difference to the underestimation of digestible energy for DDGS. Meanwhile, 
poor palatability of the high SBM (73.75%) supplemented diet could be another 
reason (Bosworth et al., 1998). At this time, in present study, we are unable to 
determine the reason for increases of PER and decreases of FCR caused by DDGS in 
C?B hybrid diets. Ingledew (1999) estimated that 3.9% of the total biomass of DDGS 
was yeast, with 5.3% of the protein content of DDGS being contributed by yeast 
protein. Yeasts are rich in protein, B-complex vitamins and ?-glucans. Therefore, 
fermentation could increase the digestibility of plant dietary protein sources. 
Comparative studies on the digestibility of some dietary protein sources, such as 
DDGS, SBM, CM and CSM, are needed to improve the feed formula for C?B hybrid.   
 
 
36 
 
In conclusion, combination with SBM and CM, DDGS appears to be a suitable 
ingredient for use in C?B hybrids diets at least at levels up to 30% without lysine 
supplementation. This is supported by experiments with tilapia. Viola and Arieli 
(1983) and Teshima and Kanazawa (1988) both reported that supplementing tilapia 
diets with crystalline EAA did not improve fish performance. It is suggested that 
future research should evaluate the nutritional influence of higher levels of inclusion 
in combination with processing studies to evaluate the potential negative effects of 
DDGS on pellet stability. 
 
 
37 
 
6. REFERENCES 
Association of Official Analytical Chemists (AOAC), 1995. Official methods of 
analysis of official analytical chemists international, 16th ed. Association of 
analytical chemists, Arlington, VA. 
Bosworth, B.G., et al., 1998. Growth, feed conversion, fillet proximate composition 
and resistance to Edwardsiella ictaluri of channel catfish, Ictalurus punctatus 
(Rafinesque), blue catfish, Ictalurus furcatus (Lesueur), and their reciprocal F1 
hybrids fed 25% and 45% protein diets. Aquaculture Research, 29: 251?257. 
Cheng, Z.J., & Hardy, R.W., 2004. Nutritional value of diets containing distiller?s 
dried grain with solubles for rainbow trout, Oncorhynchus mykiss. Journal of 
Applied Aquaculture, 15:101-113. 
Dunham, R.A., & Argue, B.J., 2000. Reproduction among channel catfish, blue 
catfish, and their F1 and F2 hybrids. Transactions of the American Fisheries 
Society, 129:222?231. 
Dunham, R.A., et al., 1993. Comparison of culture traits of channel catfish, Ictalurus 
punctatus, and blue catfish, I. furcatus. Journal of Applied Aquaculture 3:257?
267. 
Harding, D.E., et al., 1977. Sulfur amino acid requirement of channel catfish: L-
methionine and L-cystine. Journal of Nutrition. 107: 2031-2035. 
Ingledew,W. M., 1999. Yeast ? could you base business on this bug? Pages 27?47 in 
T. P. Lyons and K. A. Jacques, editors. Under the microscope ? focal points for 
the new millennium ? biotechnology in the feed industry. Proceedings of 
Alltech?s 15th Annual Symposium. Nottingham University Press, Nottingham, 
UK. 
 
 
38 
 
Masser, M., & Dunham, R., 1998. Production of Hybrid Catfish. Southern Regional 
Aquaculture Center Publication, 190: 1-5. 
Phelps, R.P., et al., 2007. Effects of temperature on the induced spawning of channel 
catfish and the production of channel ? blue catfish hybrid fry. Aquaculture, 273: 
80-86. 
Robinson, E.H., & Li, M.H., 2005. A summary of catfish nutrition research conducted 
under a cooperative agreement between MAFES and Delta Western Research 
Center. Bulletin 1144. Mississippi Agricultural and Forestry Experiment Station, 
Mississippi State, Mississippi, USA. 
Robinson, E.H., & Li, M.H., 2008. Replacement of Soybean Meal in Channel Catfish, 
Ictalurus punctatus, Diets with Cottonseed Meal and Distiller?s Dried Grains 
with Solubles. Journal of the World Aquaculture Society, 39: 521-527. 
Robinson, E.H., et al., 1980. Re-evaluation of the lysine requirement and lysine 
utilization by fingerling channel catfish. Journal of Nutrition. 110: 2313-2316. 
Shurson, J., 2006. Diversity in DDGS and other corn co-products. What?s good for 
monogastrics - or not! Feed Management, 57 (2): 14-17. 
Skrede, G., et al., 2002. Lactic acid fermentation of wheat and barley whole meal 
flours improves digestibility of nutrients and energy in Atlantic salmon (Salmo 
salar L.) diets. Aquaculture, 210: 305?321. 
Storebakken, T., et al., 2000. Soy products as fat and protein sources in fish feeds for 
intensive aquaculture. In: Drackley, J.K. (Ed.), Soy in Animal Nutrition. Fed. 
Anim. Sci. Soc., Savoy, IL, USA, pp. 127?170. 
Teshima, S., & Kanazawa, A., 1988. Nutritive value of methionine-enriched soy 
plastein for Oreochromis niloticus fry. In: Pullin, R.S.V., Bhukaswan, T., 
 
 
39 
 
Tonguthai, K., Maclean, J.L. (Eds), 2nd Intl. Symp. on Tilapia in Aquaculture, 
ICLARM Conf. Proc. No. 15, Manila, Philippines. pp. 393?399. 
Tidwell, J.H., et al., 1990. Evaluation of distillers grains with solubles in prepared 
channel catfish diets. Transactions of Kentucky Academy of Science, 52:135-
138. 
Tucker, C.S., & Robinson, E.H., 1990. Channel catfish farming handbook. Van 
Nostrand Reinhold, New York, New York, USA. 
Tucker, C. S., et al., 2004. Biology and culture of channel catfish.  Amsterdam; 
London : Elsevier,  
Viola, S., & Arieli, Y., 1983. Nutrition studies with tilapia Sarotherodon: 1. 
Replacement of fishmeal by soybean meal in feeds for intensive tilapia culture. 
Bamidgeh 35: 9?17. 
Webster, C.D., et al., 1992. Use of soybean meal and distillers grains with solubles as 
partial or total replacement of fish meal in diets for channel catfish, Ictalurus 
punctatus. Aquaculture, 106:301?309. 
Webster, C.D., et al., 1993. Growth, body composition, and organolepitic evaluation 
of channel catfish fed diets containing different percentages of distillers? grains 
with solubles. The Progressive Fish-Culturist, 55: 95-100. 
Webster, C.D., et al., 1991. Evaluation of distillers? grains with solubles as a protein 
source in diets for channel catfish. Aquaculture, 96:179?190.Wolters, W.R., et 
al., 1996. Survival and antibody response of channel catfish, blue catfish, and 
channel catfish female ? blue catfish male hybrids after exposure to 
Edwardsiella ictaluri. Journal of Aquatic Animal Health, 8: 249-254.  
 
 
40 
 
Wu, Y.V., et al., 1996. Effects of diets containing various levels of protein and 
ethanol co-products from corn on growth of tilapia fry. Journal of Agricultural 
Food Chemistry, 44: 1491-1493. 
 
 
41 
 
IV. SUMMARY AND CONCLUSIONS 
 
Aquaculture has become a very important industry around world. Its 
contribution to global supplies of fish, crustaceans and molluscs increased from 3.9% 
of total production by weight in 1970 to over 50% in present (FAO. 2006). It is 
remarkable that half of fish consumed in the world is now farm raised. Catfish 
farming has grown rapidly over the last 50 years. The expansion of aquaculture 
production has been accompanied by rapid growth of feed production. Presently, the 
commercial ration of catfish is largely based on SBM and CM. Under the influence of 
the expansion of biofuel industry, the prices of the common feed ingredients such as 
soybean and corn have gone up rapidly. A cheaper protein source to replace soybean 
meal and corn meal becomes more desirable. Reducing feed costs without influent 
fish optimal fish growth goes up to the top of concern list.  
Distiller?s dried grains with solubles (DDGS) is one of the alternatives to 
replace SBM and CM. Distiller?s dried grains with solubles (DDGS) is less expensive 
than SBM on a per unit protein basis, but its use in fish feed is limited due to its low 
content of essential amino acids, especially lysine (NRC 1993). The cost of feed can 
be further reduced if lysine supplementation can be omitted from the formulation. So 
the purpose of our study was set as to evaluate the effect of the dietary levels of 
DDGS with and without lysine supplementation on growth, feed intake, and feed 
efficiency of catfish. The reported research evaluated DDGS substitution
 
 
42 
 
 in commercial catfish rations under pond productions as well as controlled aquaria 
studies. 
Under our conditions, results from pond studies indicated that 30% DDGS 
containing feed without lysine supplementation can be used in channel catfish 
production in pond condition. 
Although channel catfish is the most important species in catfish industry, 
researches on hybrids, female channel catfish I. punctatus ? male blue catfish I. 
furcatus (C?B), have demonstrated that they exhibit many commercially desirable 
characteristics. Hybrid catfish has become a more and more important strain that is 
gaining commercial acceptance. However, little information is available on the 
nutrition requirement of this hybrid catfish. In order to confirm the results from 
previous study on channel catfish as well as to test certain DDGS level in hybrid 
catfish growth trial, a study of hybrid catfish growth trial using DDGS with and 
without lysine supplementation in aquaria was conducted. 
The results from hybrid catfish study (table 6) showed that there were some 
significant differences among all treatments which are final weight, weight gain, FCR 
and protein efficiency ratio. This study indicates that diets without lysine 
supplementation containing 30% DDGS in combination with SBM and CM provide 
good growth and feed utilization in juvenile C ? B hybrid catfish. Based on our 
results from both studies, a DDGS level up to 30% without lysine supplementation 
can be used in channel catfish and hybrid catfish diets. Further research may focus on 
 
 
43 
 
challenging higher percentage of DDGS in catfish feed. The percentage of DDGS can 
be recommended as 30% and 40% with and without lysine supplementation.  
 
 
44 
 
CUMULATIVE BIBLIOGRAPHY 
 
Association of Official Analytical Chemists (AOAC), 1995. Official methods of 
analysis of official analytical chemists international, 16th ed. Association of 
analytical chemists, Arlington, VA. 
Bosworth, B.G. et al., 1998. Growth, feed conversion, fillet proximate composition 
and resistance to Edwardsiella ictaluri of channel catfish, Ictalurus punctatus 
(Rafinesque), blue catfish, Ictalurus furcatus (Lesueur), and their reciprocal F1 
hybrids fed 25% and 45% protein diets. Aquaculture Research, 29: 251?257. 
Cheng, Z.J., & Hardy, R.W., 2004. Nutritional value of diets containing distiller?s 
dried grain with solubles for rainbow trout, Oncorhynchus mykiss. Journal of 
Applied Aquaculture, 15:101-113. 
Dunham, R.A., & Argue, B.J., 2000. Reproduction among channel catfish, blue 
catfish, and their F1 and F2 hybrids. Transactions of the American Fisheries 
Society, 129:222?231. 
Dunham, R.A., et al., 1993. Comparison of culture traits of channel catfish, Ictalurus 
punctatus, and blue catfish, I. furcatus. Journal of Applied Aquaculture 3:257?
267. 
Hastings, W.H.  1967.  The Hungarian People's Republic. Fish feed technology. A      
report prepared for the Development of Fish Culture Research Project Q1 01582. 
Harding, D.E., et al., 1977. Sulfur amino acid requirement of channel catfish: L-
methionine and L-cystine. Journal of Nutrition, 107: 2031-2035.  
 
 
45 
 
Ingledew, W. M., 1999. Yeast ? could you base business on this bug? Pages 27?47 in 
T. P. Lyons and K. A. Jacques, editors. Under the microscope ? focal points for 
the new millennium ? biotechnology in the feed industry. Proceedings of 
Alltech?s 15th Annual Symposium. Nottingham University Press, Nottingham, 
UK. 
Li, M.H., & Lovell, R.T., 1992. Comparison of satiate feeding and restricted feeding 
of channel catfish with various concentrations of dietary protein in production 
ponds.  Aquaculture. 103 (2): 165-175. 
Lim, C. et al., 2007. Growth Response and Resistance to Streptococcus iniae of Nile 
Tilapia, Oreochromis niloticus, Fed Diets Containing Distiller? Dried Grains 
with Solubles. Journal of World Aquaculture Society. 38 (2): 231-237. 
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growth, immune function and disease resistance in Nile tilapia (Oreochromis  
niloticus L.) Aquaculture Research. 39 (12): 1351-1353. 
Mangalik, A. 1986.  Dietary energy requirements of channel catfish DISS. ABST. 
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Masser, M., & Dunham, R., 1998. Production of Hybrid Catfish. Southern Regional 
Aquaculture Center Publication, 190: 1-5. 
Jimmy, W., et al., 1973.  The Effects of Frequency of Feeding on Culture of Catfish.  
Transactions of the American Fisheries Society. 104 (2): 317-321. 
Phelps, R.P., et al., 2007. Effects of temperature on the induced spawning of channel 
catfish and the production of channel ? blue catfish hybrid fry. Aquaculture, 273: 
80-86. 
 
 
 
46 
 
Robinson, E.H., et al., 1998. Effect of reduction of supplementary dietary vitamins on 
the stress response of channel catfish ictalurus punctatus  Journal of the World 
Aquaculture Society. 29 (3): 319-324.  
Robinson, E.H, & Li, M.H., 2001. Evaluation of Corn Gluten Feed as a Dietary 
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World Aquaculture Society. 32 (1): 68-71. 
Robinson, E.H., & Li, M.H., 2005. A summary of catfish nutrition research conducted 
under a cooperative agreement between MAFES and Delta Western Research 
Center. Bulletin 1144. Mississippi Agricultural and Forestry Experiment Station, 
Mississippi State, Mississippi, USA. 
Robinson, E.H., & Li, M.H., 2008. Replacement of Soybean Meal in Channel Catfish, 
Ictalurus punctatus, Diets with Cottonseed Meal and Distiller?s Dried Grains 
with Solubles. Journal of the World Aquaculture Society, 39: 521-527. 
Robinson, E.H., et al., 1980. Re-evaluation of the lysine requirement and lysine 
utilization by fingerling channel catfish. Journal of Nutrition. 110: 2313-2316. 
Shurson, J., 2006. Diversity in DDGS and other corn co-products. What?s good for 
monogastrics - or not! Feed Management, 57 (2): 14-17. 
Skrede, G., et al., 2002. Lactic acid fermentation of wheat and barley whole meal 
flours improves digestibility of nutrients and energy in Atlantic salmon (Salmo 
salar L.) diets. Aquaculture, 210: 305?321.  
 
 
47 
 
Steeby, J.A. 2002. Sediment accumulation, organic carbon content, and oxygen 
demand in commercial channel catfish (Ictalurus punctatus) ponds.Dissertation 
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Storebakken, T., et al., 2000. Soy products as fat and protein sources in fish feeds for 
intensive aquaculture. In: Drackley, J.K. (Ed.), Soy in Animal Nutrition. Fed. 
Anim. Sci. Soc., Savoy, IL, USA, pp. 127?170. 
Teshima, S., & Kanazawa, A., 1988. Nutritive value of methionine-enriched soy 
plastein for Oreochromis niloticus fry. In: Pullin, R.S.V., Bhukaswan, T., 
Tonguthai, K., Maclean, J.L. (Eds), 2nd Intl. Symp. on Tilapia in Aquaculture, 
15: 393-399. 
Tidwell, J.H., et al., 1990. Evaluation of distillers grains with solubles in prepared 
channel catfish diets. Transactions of Kentucky Academy of Science, 52:135-
138. 
Tucker, C.S., Robinson, E.H., 1990. Channel catfish farming handbook. Van 
Nostrand Reinhold, New York, New York, USA. 
Tucker, C. S., et al., 2004. Biology and culture of channel catfish. Amsterdam ; 
London : Elsevier.  
Viola, S., & Arieli, Y., 1983. Nutrition studies with tilapia Sarotherodon: 1. 
Replacement of fishmeal by soybean meal in feeds for intensive tilapia culture. 
Bamidgeh 35: 9?17. 
Webster, C.D., et al., 1992. Use of soybean meal and distillers grains with solubles as 
partial or total replacement of fish meal in diets for channel catfish, Ictalurus 
punctatus. Aquaculture, 106:301?309. 
 
 
48 
 
Webster, C.D., et al., 1993. Growth, body composition, and organolepitic evaluation 
of channel catfish fed diets containing different percentages of distillers? grains 
with solubles. The Progressive Fish-Culturist, 55: 95-100. 
Webster, C.D., et al., 1991. Evaluation of distillers? grains with solubles as a protein 
source in diets for channel catfish. Aquaculture, 96:179?190. 
Winfree and Stickney 1984. Formulation and processing of hatchery diets for channel 
catfish. Aquaculture. 41 (4): 311-323. 
Wolters, W.R., et al., 1996. Survival and antibody response of channel catfish, blue 
catfish, and channel catfish female ? blue catfish male hybrids after exposure to 
Edwardsiella ictaluri. Journal of Aquatic Animal Health, 8: 249-254. 
Wu, Y.V., et al., 1996. Effects of diets containing various levels of protein and 
ethanol co-products from corn on growth of tilapia fry. Journal of Agricultural 
Food Chemistry, 44: 1491-1493.