V.Aimradha (1999) Feed Formulation for Fish and Poultry using Hideflesh lrom Tanneries

FEED FORMULATION FOR

FISH AND POULTRY

3.1 INTRODUCTION

Fish and poultry are the major animal protein sources for human consumption and their feed conversion efficiencies are higher than those of other

organisms. However the success of rearing fish and poultry depends upon the

feed given. The feed should be prepared based on the precise knowledge of their

nutritional requirements so that the optimum growth can be achieved in a given

time. The balanced diet to be given to these organisms should contain nutrients

such as protein, carbohydrate, lipid, vitamins and minerals to meet basal energy

requirements and also to ensure healthy growth. Of all the components of the

formulated feed, protein plays an important role in the feed. It is also a costly

component. The percentage of protein in the feed should be neither more nor

less than the optimum required for the organisms. A number of experiments

have been carried out by various researchers to optimize the percentage of protein

required for fish (Mohanty et ai, 1990 and Ogino and Saito, 1970) and for poultry (Jackson et ai, 1982 and Baghel and Pradhan, 1989a).

The quality of any protein depends upon its aminoacid configuration.

Plant protein sources, though comparatively less expensive than animal protein

sources, may not provide all the aminoacids required by the fish and the poultry.

When supplemented by animal protein sources, they can provide the required

amount of essential aminoacids and other growth promoting substances.

In the feed of fish and poultry the main source of animal protein is

fishmeal, which not only supplies the appropriate aminoacids but also acts as feed

attractant besides being highly palatable. Since the demand for fishmeal is high.

its cost is steadily increasing. There is also general a scarcity of good quality

fishmeal due to its being used in other animal husbandly activities. To meet the

heavy demand, many non-conventional sources have been exploited by many

workers. Some such products are blood powder meal (Luzier et al., 1995), animal wastes (Belal et al., 1995), industrial wastes (Kumar et al., 1977 and Samanta el al., 1991) animal by-products (Lee and Yang, 1975) slaughter house wastes (Nandeesha et al., 1986) soldier fly larvae (Bondari and Sheppard, 1987) and rat meal (Aquino, 1987)

In the present study hidefleshings (free from hair) from the tanneries have been processed and used as animal protein source in the feed of fish and poultry

substituting the fishmeal at various percentages.

Besides protein, the animals also require other nutrients like carbohydrates

and lipids. It is well known that supplements of carbohydrates or lipids have a

sparing effect on dietary protein being used as energy source in higher animals.

Proper balance between dietaiy protein and non-protein energy is important for the

efficient utilisation of the protem. Hence, in the diet offish and poultry, besides

54

oil cakes and fishmeal (protein source), grains like wheat, corn, bajra and sorgham have been incorporated as source of energy.

In the present study feed was prepared in the form of pellets for the fish

and in the form of mash for the broilers. The feed was compounded by

incorporating the different raw materials in required quantity taking care of the

nutritional need of the experimental animals.

3.2 REVIEW OF LITERATURE

The success of the performance of the rearing organisms depends upon the

type of feed given to them. The feed should contain not only all the nutrients

required for normal growth in the right proportion but also the required quantity of

aminoacids and fatty acids. Excess of protein in the diet will be excreted along

with other nitrogenous matters or stored as abdominal fats.

Murai el al. (1985) observed that, in carp, the requirement of energy was much lower than that in rainbow trout and that enhancement of digestible energy

with supplemental lipids showed no improvement in the growth, feed conversion

and protein utilisation in carp. They recommended 5 percent lipid

supplementation in feed as the dietary protein level was mainly responsible for the

performance of carp at a level less than 33 percent.

Evaluation of different grains as basic ingredient in 25 percent protein feed

for carp and tilapia (Viola and Arieli, 1982) showed an average daily gain of 2.55g and 2.53 g respectively.

55

Local feeds like leftover rice, barley, wheat, fish offal and blood meal were

mixed by Asgah and Bedawi (1984) to get three feeds containing 53, 43, and 33 percent protein and on feeding carp with them, they obtained the highest

biological value in 43 percent protein feed, with increased protein (73.5 percent) and aminoacid contents in the flesh.

Low cost ingredients like soybean meal, copra cake, corn, rice bran, napier

and carpet grass meals were tested for their digestibility in grass carp (Law, 1986). The experiment showed that copra cake and rice bran were poorly digested

whereas corn meal, soybean meal, napier and carpet grass meal showed better

digestion coefficients.

Jayaram and Sherty (1980) studied the effect of three pelleted feeds incoiporating peanut oil cake, silk worm pupae and fishmeal as sources of protein

on rohu, catla and carp. Silk worm pupae and fishmeal diets showed conversion

ratios of 2.5 and 2.6 for carp.

The digestibility and aminoacid availability of soybean, poultry meat meal

blend based diets for Oreochromis niloticus(L) fingerlings was tested by Sadiku and Jauncey (1995). The fingerlings were fed with 25:75, 50:50 and 75:25 percent of soyflour and poultry meat meal. The best lipid digestibility and aminoacid

availability values were obtained in the 75:25 soyflour and poultry meat meal

blend and the best protein digestibility was observed with 25:75 percent soyflour

and poultry meat meal blend. They concluded that protein and lipid of diets

containing more soyflour seemed to be more digestible than those of poultry meat

meal while the reverse was the case of ash.

Papoustsoglou and Papoustsoglou (1978) compared the body composition of tiouts in three different types of diets. They prepared two types of dry pellets

and one mixed diet. After a feeding trial of 25 weeks, when the fish carcass was

analysed for body composition, the ash content remained constant in all the

experimental fish. They also observed that with the increase of age and body

weight the percentage of protein and water decreased but the fat content increased.

The apparent digestibility of protein, fat, carbohydrate and energy in three

feed ingredients namely wheat, barley and corn for Cyprimis carpio using chromic

oxide as a dietary marker was studied by Degani el ah (1997). Each experimental diet consisted of a mixture of the test ingredient and 50 percent of basal diet.

They observed that die apparent digestibility of wheat meal is significantly higher

than that of barley and corn meal.

The effects of particle size and frequency of feeding on survival and growth

of juvenile gilthead seabream were investigated by Goldan et al..(!997). The effect of dry food particle size and frequency of feeding were investigated with all

treatments being supplemented equally with artemia. Growth was affected by

particle size but not by the frequency of feeding. Frequency of feeding had

significant effect on growth rate when artemia as a sole source of food was tested.

Continuous feeding resulted in a seven fold higher mean weight than in the case of

periodic feeding.

Hassan and Macintosh (1992) investigated under laboratory conditions the optimum feed particle size of an inert diet for common carp fiy ranging from 15 to

466mg body weight and 13 to 31mm total length. Speed of consumption of

standard quantity of feed was used as a measurement of feeding preference for

different particle size ranges. It was observed by them that carp of this size range

preferred feed particle size suitable for their mouth size, on the basis of ingestion

time and feeding behaviour. Particle size in the ranges of 125-300, 300-500, 300-

790 and 500-1000um diameter were found to be most appropriate for carp fry

weighing 15-23mg, 46-97mg, 105-209mg and 210-466mg respectively.

Smith et al. (1995) used pellets of different shapes and sizes for salmon. Both diameter and length of pellets affected the feeding time, because salmons

take longer time to capture small pellets. Though longer pellets were initially

captured by them, finally they were rejected and only the smaller pellets were ingested.

The growth and feed intake responses of broilers to diets of two different

protein contents were analysed by Shariatmadari and Forbes (1993). The protein concentrations were 65, 115, 172, 225 and 280g protein/kg. In one group of birds

the choice of two protein levels of 65 and 280g protein/kg was given. The results

showed that there was a linear increase in protein deposition with dietary protein

content upto 280g protein/kg. When choice of diets was offered the birds

preferred an intake closer to their requirements.

Baghel and Pradhan (1988a) observed the effect of the dietary protein and energy level on weight gain, processing loss and meat yield of broilers. They used

energy levels of 2800, 3000 and 3200 kcal/kg with different protein levels i.e. 20.

22, 23 and 25 percent for starters (0-4 weeks) and 10, 18, 19 and 21 percent for finishers (5-8 weeks). Observation showed that diets with 25-24-21 percent of proteins and metabolisable energy of 2800 kcal/kg are suitable for the starters,

growers and finishers.

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The protein levels in broiler rations was studied for 12 weeks

(Krishnappa et al., 1978). The percentage of protein levels were 16, 18, 20, 22 and 24. They observed that higher protein levels gave higher weight gains upto

the fifth week whereas, from 6-12 weeks, weight gains were not different between

different ration groups and they have recommended 24 and 21 percent protein in

the rations of starters and finishers respectively.

The effect of dietary energy and protein on the carcass composition of

broilers in different phases of growth was observed by Baghel and Pradhan

(1989b). They used 20, 22, 23 and 25 percent of protein for the starter (0-3 weeks), 18, 20, 22 and 24 percent of protein for the grower (4-5 weeks) and, 16, 18,19 and 21 percent of protein for the finisher (6-8 weeks) feeds and the energy levels were 2800, 3000 and 3200kcal/kg respectively. The results showed that

birds fed with lower energy diet contained higher proportion of moisture and

protein and lower proportion of fat and energy in their carcass flesh, whereas the

levels of energy reduced the carcass moisture in the finisher stage.

Chawla et al. (1978) studied the influence of climatic conditions on energy requirements of poultry. When pullets were fed on feed with metabolisable

energy level of 2000, 2400, 2700 and 3000 kcal/kg, they did not show variation in

growth both during winter and summer seasons. They also observed that the daily

requirement of energy was 175 and 215 kcal/kg in summer and winter respectively

and they have recommended 2900-3000- kcal/kg of energy for pullets for both the

seasons.

Moran et al. (1992) reduced the dietary protein level from 23 percent to 20 percent in the starter (0 to 3 weeks) and from 20 percent to 17 percent in the

59

finisher feeds (3 to 6 weeks) of broilers while satisfying the ammoacid requirement. In a trial of eight weeks they observed that the live body weight was

not affected though the feed conversion increased from the third week to sixth

week. However, processing of the birds showed fat in the abdominal cavity when

low crude protein was fed. The weight of the breast muscle also decreased and the

results showed that reduced, level of protein in the feed produced adverse effects

on the live performance.

Growth performance of broilers fed at different levels of energy in the

ration i.e. 2800, 3000 and 3200 kcal/kg fortified with crystalline ammoacid of

methionine and lysine was observed by Baghel and Pradhan (1988b). Energy level showed a significant influence on dressed weight of flesh. The broilers

which received 3000 kcal/kg energy showed significant increase in dressed weight

than those that received the feeds of the other two energy levels. However higher

energy level in the feed resulted in fat deposition on the visceral organs.

Adekunmisi and Robbins (1987) conducted experiments on broilers to study the effect of dietary electrolyte balance, dietaiy crude protein level and

photoperiod on growth performance. Increasing the electrolyte balance (Na+K and CI) from 200meg/kg to 350meg/kg improved the weight gain and feed consumption of chicks fed on high protein (28 percent) diets but depressed weight gain and feed consumption of chicks fed on low protein (14 percent) diets. The results showed that electrolyte balance, that provides for optimum growth,

depended upon dietary crude protein and neither photoperiod nor sex affected the

protein- electrolyte balance interaction.

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The sulphur aminoacid requirement for cross breed broiler chicks was

studied by Prasad et a/.(1978). Broilers were fed on ration containing two levels of protein (20 and 23 percent) and two levels of energy (2800 and 3100 kcal/kg). Deficiency in methionine in the calculated value of aminoacid was supplemented

from 0.86 to 1 percent. At 3100 kcal/kg energy level six percent tallow was added

to the ration. Supplementation of methionine to fat containing diets improved the

nitrogen retention at both levels of protein. The authors observed that the dietary-

energy level and total sulphur aminoacid levels appreciably influenced the

nitrogen retention in the birds.

Tyagi and Singh (1996) studied the effect of dietery crude fibre levels ( 4.8. 6.0, 7.5 and 9.0 percent) in broiler. Dieteiy crude fibre has no significant influence on the feed conversion, percentage eviscerated carcass yield, gizzard weight and

plasma and meat cholesterol level but had significant effect (P

Research shows that long and thin pellets are much preferred by fish to

other shapes like round or flat. Hence, in the present study the fish feed was

prepared in the form of long and thin pellets.

The different raw materials used for the preparation of fish feed are wheat,

rice bran, peanut oil cake, soybean meal and fishmeal. To prepare the fishmeal.

diy fish were purchased from the local market, washed and dried in hot air oven at

60C to constant weight and then powdered.

All the other feed components were cleaned, powdered and passed through

425 urn sieve separately and analysed for protein (micro kjeldhal), fat (soxhlet), ash (muffle furnace), carbohydrate (differential method) and calorific value (Bomb calorimeter), as described in the previous chapter.

One control and two types of isoproteinaceous experimental feeds (40 percent protein) were compounded. In the first type of experimental feeds. fishmeal was replaced by hideflesh powder on weight basis at 20, 40, 60, 80 and

100 percent levels. In the second type of experimental feeds, the fishmeal was

replaced by hideflesh on protein basis at 20, 40, 60, 80 and 100 percent levels.

Thus eleven feeds were prepared (viz. one control feed (feed-1) and 10 experimental feeds (feeds 2-11)).

The feed components were thoroughly mixed and made into hard dough

with sufficient quantity of water. This dough was pressure cooked at 15 Ib/sq.inch

for 15 minutes. Commercially available Supplevite M (mixture of vitamins and minerals) was added to the dough and extruded in the form of noodles using an extruder having 1mm dia perforations. The pellets were dried at room

62

temperature and then in hot air oven at 60C for 6h and were stored in air tight containers till use (Raj, 1978).

Physicochemica! analysis of the fish feed pellets

The feed pellets were, measured for its diameter using a screw gauge. The

zero error and the least count of the gauge were measured. The pellet was held

vertically between the studs using the ratchet. The reading of the pitch scale and

the head scale were noted and the diameter was calculated using die formula:

Reading of the pitch scale + reading of the head scale X least count + zero

correction.

Pellet stability was tested by keeping one gram of pellet in a wire gauze and

immersing it in water for one hour. The wet material with gauze was removed

without much disturbance and dried to a constant weight. All the 11 feed pellets

(one control and ten experimental) were separately pulverised, passed through 425 Micron sieve and analysed for protein, fat, ash, carbohydrate and energy values.

Preparation of feed for broiler

In India the feed for poultry is generally presentead in the form of mash.

Hence in the present study the feed was prepared in the form of mash for the

broilers.

As indicated earlier two types of feeds were compounded for two types of

feeding experiments. In one type of feed fishmeal was replaced by hidefiesh

powder on weight basis and in another type of feed fishmeal was replaced by

63

hideflesh on protein basis. For each type of feed a starter (for 0-4 weeks) and a finisher (for 5-7 weeks) set of feeds with a protein level of 24 and 21 percent respectively were prepared.

For the first type of experiment a control feed (feed 12) and five experimental starter feeds (feeds 13 to 17) were compounded by replacing fishmeal with hideflesh powder at 20, 40, 60, 80 and 100 percent on weight basis.

In the same way 21 percent isoproteinaceous finisher feed were prepared with a

control feed (feed 18) and five experimental feeds (feeds 19 to 23).

In the second type of feeds five 24 percent isoproteinaceous starter feeds

were compounded (feeds 24 to 28) replacing fishmeal protein by hideflesh protein and five 21 percent isoproteinaceous finisher feeds were compounded for finisher

birds (feeds 29 to 33). Feeds 12 and 18 seived as control for this experiment also.

The other components used for compounding the feed were com (Zea mays), bajra (Eleulsive coracana), sorgham (Sorgham vulgarae), peanut oil cake {Arachis hypogea), sesame (Sesamum orientate) oil cake, fishmeal and commercially available vitamin mix and mineral mix. The grains and oil cakes

were analysed for their proximal composition, i.e protein, fat, ash, carbohydrate,

moisture and energy values. The raw materials were cleaned,sun dried and stored

separately in airtight containers till use.

Each week the feed was prepared afresh. The required quantities of the

ingredients were separately broken into coarse particles and used for the

preparation of the feed mash. First the coarse particles of grains were mixed well

and then the particles of the oil cakes were added followed by the fishmeal or

64

hideflesh powder. All the ingredients were thoroughly mixed and then the vitamin

mix and mineral mix were added. It is now mixed thoroughly and then stored in

containers. All the feeds were separately analysed for their proximal

composition.

3.4 RESULTS

All the components used in the preparation of feeds for fish were analysed

for the proximate composition (Table 12). Fishmeal is the usual source of animal protein in fish feeds. Wheat flour and rice bran act as energy source. Wheat

flour, in addition, serves as a binder also. The energy values of the various feed

ingredients ranged from 3583 to 4401 cal/g.

Table 12 Proximate composition of the various ingredients used in the formulation of feed for Cyprinus carpio var. communis fingeriings

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Broiler feed components

All the components used in the feeds for broilers (starter feeds and finisher feeds) were analysed for their proximate composition and the results are given in Table 13. The grains contained high level of carbohydrates. The mineral level

was high in fishmeai. High percentage of fat was observed in sesame oil cake.

Table 13 Proximate composition of various components used in the feed

mash of broilers

Proximate composition offish feeds

The fish feeds (control and experimental) were prepared in the form of isoproteinacious pellets containing 40 percent of protein. The components used in

the control and experimental feeds are given in Table 14 and proximate

66

composition of the control and five experimental feeds (feeds 1 to 6) are given in figure 15 and 16. In the first set of experimental feeds the fishmeal was replaced

by hideflesh on weight basis at 20, 40, 60, 80 and 100 percent levels.

Table 14 Percentage composition of control and five experimental feeds for C.carpio var.communis (0.3610.03g) incorporated with hideflesh powder replacing fishmeal on weight basis at different percentages.

Figure 16 Proximate composition of the five experimental feeds (feeds 2 to 6) for CCarpio var.communis (0.361Q.03g) incorporated with hidefJesh powder replacing fish meal on weight basis at different percentages

Feed 2 Feed 3

Proton 40.9%

Carbohydrate 40.3%

3973 cl/g

Moisture 4.5% / 3 %

6.8%

Proten 403%

Feed 4

Carbohydrate

3877 cal/g

Moisture 34%

Feed 5

Protein 403%

Carbohydrate 43.0%

3913 cal/g

Moisture 5.0%

Carbohydrate 43.6%

3915cal/K

Moisture

Feed 6

Carbohydrate 443%

3966 cal/g

Moisture 5.1%

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The components of the second type of experimental feeds (feeds 7 to 11) in which fishmeal was replaced by hideflesh powder on protein basis at 20, 40, 60.

80 and 100 percent levels is given in Table 15 and the proximate composition of

the feed pellets is given in figure 17.

Table 15 Percentage composition of five experimental feeds for Cyprinus carpio var. communis (0.3610.03g) incorporated with hideflesh powder replacing the fishmeal on protein basis at different percentages

69

Figure 17 Proximate composition of five experimental feeds for Cyprinus varpio var. communis (Q.36103g) incorporated with hidefiesh powder replacing the fish meal on protein basis at different percentages

The pellet stability and the diameter of the pellets of feeds 1 to 6 and feeds

7 to 11 are given in Table 16 and 17 respectively. The stability of the pellets

ranged from 90 to 95 percent and the size of the feed pellets did not vary much.

Proximate composition of the broiler starter feeds

The percentage composition of the control feed (feed 12) and five experimental feeds (feeds 13 to 17) used for stater broiler are given in Table 18 and the proximal composition of the same is given in figure 18 and 19. In the

experimental feeds, fishmeal was replaced by hideflesh on weight basis at 20, 40.

60, 80 and 100 percent levels. As the broilers require energy -rich feed, care was

taken to incorporate grains like corn, bajra and jowar at a high percentage.

Table 18 Percentage composition of control (feed 12) and five experimental feeds (feeds 13 to 17) used for starter broilers (35.50.03g) incorporating hideflesh powder replacing fishmeal on weight basis at different percentages

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Figure 18 Proximate composition of control feed (Feed 12) used for starter broilers (35.50.03g)

Figure 19 Proximate composition of five experimental feeds used for starter

broilers (35.50.03 g) incorporating hideflesh powder replacing the fishmeal on weight basis at different percentages

The mineral mix used in the feed contains the following minerals. The composition of the Supplevite M has already been given.

Mineral Mix (250 g) contain copper - 312 mg, iodine - 0.156 g, cobalt - 45 mg, DL methionate -1.92 g. magnesium -2.114 mg, L. lysine-4.400 g, iron - 979 mg. calcium - 30 g. zinc-2.13 mg, pho.sphorus -8.25g.

The percentage composition of finisher feeds i.e. control feed mash (feed 18) and five experimental feed mashes (feeds 19 to 23) incorporating hideflesh powder on weight basis is given in Table 3.8. The proximate composition of the

same is given in figure 20 and 21. In the fisnisher feeds too, fishmeal was

replaced by hideflesh powder at 20, 40, 60, 80 and 100 percent levels. All the

feeds were isoproteinaceous.

Table 19 Percentage composition of control (feed 18) and five experimental feeds (feeds 19 to 23) used for finisher broilers incorporated with hideflesh powder replacing fishmeal on weight basis at different percentages

Figure 20 Proximate composition of tSie control feed (feedl8) used for finisher broilers

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figure 21 Proximate composition of the five experimental feeds (feeds 19 to 23) for finisher broilers incorporating hideflesh powder replacing the fish meal on weight

basis at different percentages feed incorporated with hideflesh powder on

protein basis

Composition of the broiler starter feed incorporating hideflesh powder on

protein basis

The percentage composition of the five experimental broiler starter feeds

(feeds 24 to 28) is given in Table 20 and their proximate composition is given in figure 22. All the feed mashes were isoproteinaceous and, in the experimental

feeds, fishmeal was replaced by hideflesh powder on protein basis at 20, 40, 60.

30 and 100 percent levels.

Table 20 Percentage composition of five experimental feeds (feeds 24 to 28) used or starter broilers (35.50.03g) incorporated with hideflesh powder replacing fishmeal on protein basis at different percentages

Hideflesh powder

Fishmeal

Peanut oil cake

Corn

Bajra Jowar

Sesame oil cake

Mineral mix

1.24

8.00

28.76

42.00

5.00

5.00

8.00

2.00

2.47

6.00

28.53

43.00

5.00

5.00

8.00

2.00

3.70

4.00

28.30

44.00

5.00

5.00

8.00

2.00

4.94

2.00

28.06

. 45.00

5.00

5.00

8.00

2.00

6.17

0.00

27.83

46.00

5.00

5.00

8.00

2.00

Supplied Supplevite M : at the dosage of lkg/200kg

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Figure 22 Proximate composition of five experimental feeds (feeds 24 to 28) used for starter broilers (35.50.03g) incorporated with hideflesh powder replacing the fishmeal on protein basis at different percentages

The percentage composition of five finisher experimental feeds are given

in Table 21 and the proximate composition of the same (feeds 29 to 33) is given in figure 23. All the feeds are isoproteinaceous and the fishmeal is replaced by

hideflesh powder on protein basis at 20. 40, 60, 80 and 100 percent level.

Table 21 Percentage composition of five experimental feeds used for finisher broilers incorporatied with hideflesh powder replacing fishmeal on protein basis at different percentages

Figure 23 Proximate composition of five experimental feeds (feeds 29-33) used for finisher broilers incorporating hidefiesh powder replacing the fishmeal on protein

basis at different percentages

3.5 DISCUSSION

The ingredients used in fish and broiler feeds are locally available and quite

inexpensive. Peanut oil cake is commonly used in animal feed as a source of

vegetable protein and it is available throughout the year. The aminoacid profile of

peanut cake shows that it is rich in arginine and the limiting aminoacids are

tiyptophan, methionine and lysine. However, in the compounded feed, the lack of

certain aminoacids is taken care of by incorporating certain ingredients which are

rich in those limiting aminoacids.

in poultry feed formulation, the percentage of the usual components

incorporated are as per the ISI (1992) recommendations. The inclusion of sesame oil cake in the diet compensates the lack of limiting aminoacids in the peanut oil

cake. Corn is commonly used in the diet of poultry as an energy source

(Stevenson and Jackson, 1981, Ahmed et al, 1996 and Isarakul and Weewipat 1991) and, besides corn, the feeds also contain small millets which are locally available.

In fish feed, wheat flour is used as energy source besides rice bran. Kim et

al. (1984), Belal et al. (1995) and Desilva and Gunasekera (1989) have used wheat flour in the feed for fish not only as energy source but also as a binder. The other

binding substances like gum arabic and algin are physiologically active and hence

they are considered to have growth inhibiting effects. So wheat flour was used in

the present study as a binder and as a source of energy.

The energy need of fish is much less compared to that of warm blooded

animals. Fish need energy mainly to maintain position and for movement.

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Because of ammonia excretion the use of energy is highly minimized. However

insufficient or excess energy results in reduced growth rate. Fish primarily eat to

satisfy their energy needs and excess energy reduce the intake as high energy feed

satisfy the energy requirement in less quantity. Peanut oil cake is commonly used

a fish feed (Raj, 1989 and Daniel and Sahayaraj, 1990) as vegetable source of protein and fishmeal as animal source of protein.

The dietary protein requirement of fish differs from fish to fish. Several

experiments have been earned out by a number of scientists to optimise the

protein requirement for various species of fish. It has been observed that the

dietary protein requirement of Salmo gairdneri was 45 percent (Higuera et ah. 988), of Cyprimts carpio was 40 percent (Capper et a/., 1982 and Kim and Oh. 985), of C.mrigala was 40 percent (Swamy et al., 1988), of catla and rohu were 5 percent (Jayaram and Sherry, 1980 and Mohanty el al., 1990), of Oreochromis nilolicus was 34 to 36 percent (Desilva and Gunasekera, 1989) . Ogino and Saito 1970) reported that the optimum utilisation of protein by carp was obtained when fed on diets containing 35 to 40 percent of protein. For the present study the

protein level for the compounded feed for Cyprimis carpio var. communis was

fixed at 40 percent level.

Feed is given to fish in various forms like mash, capsules, grains, pellets

c. However supplying the feed for fish in the form of pellets is the common

practice. Dry pellets are easy to prepare, store, transport, handle and distribute.

ley can also be easily protected from fungi and insects. Pelleted diet for fish

culture was used by a number of workers (Raj, 1978; Raj and Kutty, 1984; Raj. 94; and, Daniel and Sahayaraj, 1990). In pelleted feeds desirable protein percentage can easily be calculated (Ali, 1980). Locally available ingredients can

easily be incorporated in the feed to reduce the cost of the feed. Conventional and

non-conventional ingredients like weeds and grasses (Raj, 1984), wild leaves (Raj. 1994) wild seeds (Daniel and Raj, 1992) hideflesh powder (Raj and Kandasamy. 1 991) and Anuradha et al.(1998) are some of the ingredients normally used in the

feed for aquaculture.

Buoyancy of the particles and water stability depend on the density of the

particles. By grinding the particles to uniform size loss of the contents can be

avoided (Ghittino, 1972) and all this in turn, depends upon the processing techniques and the selection of the ingredients. Keeping this in view the raw

materials used for the pellet preparation in the present study were selected.

processed, powdered and sieved in 420 micron sieve and then used for

compounding the feed.

To maximise the feed utilisation among the rearing organisms, their

feeding behaviour should be taken into account. In aquaculture operation the size

a n d the shape of the feed pellets play a role in eliciting responses from animals

w h i c h capture them. The physical attributes of the pellets namely length, texture,

density, colour, flavour etc. not only affect the ability of the fish to capture but

a l s o stimulate the fish to eat them. The size and shape of the pellets are likely to

be important at each stage of the feeding sequence by influencing their

detectability, attractiveness and ease of capture (Stradmeyer et ai., 1988). Smith et ctl. (1995) observed in salmon that though long pellets tended to ellicit rapid response, they were more likely to be rejected than short pellets. Tabacheck ( 1988) observed the pellet size optimal for growth is relative to the fish size w h i c h is determined by the length of the fish and the size of their mouth.

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The texture and hardness of the pellets also play an important role in

motivating the fish to eat them. Soft pellets are readily accepted by the fish

irrespective of their length (Knights, 1985 and Meatus, 1990).

In the present study the length of the pellets used for the carp ranged from

1.2 to 1.5 mm. There was no distinct difference in the diameter and stability of

the pellets.

The stability of the feed pellets depends on the ingredient composition,

nature of the ingredients, their processing method, moisture content etc. Higher fat

content affects the gelatinization and reduces the pellet stability. Winfree and

Stickney (1984) have reported that vegetable proteins increase the stability. In the present study the stability of the feed pellets ranged from 95 to 97 percent. The

difference may be due to the increase in the percentage of hideflesh.

Raj and Kutty (1979) have observed a feed stability of 96.9, 93.0 and 95.8 percent in dry feed pellets of lmm diameter incorporating 60 percent (Jfiricidiu metadata, Albizzia lebbeck and Enteralobium saman seed kernel powder

respectively. Venugopal and Kesavanath (1984) observed a feed stability of 92.8. 91.9 and 87.7 in the pellets incorporated with fishmeal, colocassia leaf and fish

silage. They also observed that increase in moisture, in turn, altered the stability

of the feed pellets.

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Broiler feed

The nutritional requirements of broilers should be met appropriately so that

optimum growth will be achived in the least time. A number of studies have been

carried out by different scientists to optimize the protein requirement of the

broilers (Lepstein et ai, 1975; Fancher and Jensen, 1989 and Shariatmadari and Forbes, 1993). They have recommeded 24 percent of protein for the starter birds (0 to 4 weeks) and 21 percent for the finisher birds (5 to 7 weeks).

In broiler diets the ratio between protein and energy is an important factor.

If the dietary protein is decreased, the abdominal fat deposition may increase as

the bird increases its feed intake in an attempt to maintain its protein requirement

(Bradford and Gous, 1991). As growth progresses the protein requirement decreases and the requirement of energy for maintenance increases and this is

reflected in commercial poultry production by stepwise decrease in the protein

content of the diets given to the birds. Kaufman et al. (1978) have observed a gradual reduction in protein intake of broilers as they grow from 4 to 9 weeks.

Morris and Njuru (1990) showed that higher dietary protein content is necessary for maximal protein deposition in the carcass.

In the present study the starter birds were fed with feeds containing 24

percent protein and the finisher birds with feeds containing 21 percent protein.

Unlike fish, broilers require lipids and carbohydrates for their energy

needs. Birds try to consume more amount of feed to satisfy their energy

requirements. The energy in the ration is mainly contributed by fats and

carbohydrates and the primary function of the protein in the diet is facilitating

86

tissue protein formation whereas fat and carbohydiate serve as source of energy

for maintenance, growth and production. It has been observed that efficiency of

feed utilisation improves with the increase in the dietary energy level. The

optimum level of energy is observed where the breakdown of protein as a source

of energy is minimum without affecting growth rate.

Marked increase in the energy level of the feed decreases the feed

consumption (Chawla et a/., 1978). In broilers, high energy level in the feed is related to excess of fat deposition in visceral organs (Jackson et ai., 1982; Salmon et al., 1983 and Lepstein et al., 1975). Hence, in the feed formulation for the broilers, the energy content of the feed have to be checked. Works carried out by

Summers et al. (1965) has recommended a metabolisable energy level of 3500 cal/g for commercial broilers. In the present study the energy level in all the

given feed mash range from 3500 to 4100cal/g.

In the feed mash of the broilers, grains like maize, bajra and sorgham have been incorporated as energy sources and oil cakes like peanut oil cake and sesame

oil cake are used as vegetable protein sources and fishmeal is the only animal

protein source. Attempts have been made by a number of workers to use plant

protein sources replacing the fishmeal without much success, as fishmeal

contains essential aminoacids, essential fatty acids and minerals which are

essentialfor proper growth of the birds.

Replacement of fishmeal by other animal protein sources like meat meal

(Sethi et a/., 1991), hydrolysed feathermeal (Baker et a/., 1981) and hydrolysed leather meal (Waldroup et al., 1970) has proved that these substances could be

87

incorporated in broiler feeds only upto certain percentages and not to replace the fishmeal completely.

Feed for broilers is prepared afiesh each week in the form of mash as the starter birds prefer fresh feed.

In the present study processed hideflesh powder was incorporated in the

diet of fish and poultry at various percentages replacing the fishmeal on weight

basis and on protein basis so that the cost of the feed could be reduced and that the

tannery wastes could be usefully utilised.

88

BIBLIOGRAPHY

Adekunmisi.A.A. and Robbins.K.R.. 1987.

Effects of dietan' curde protein, electrolyte

balance and photoperiod on growtli of broiler

chickens.Poulty Science, 66:229-305.

Ahmed.M. Jayaprasad.I.A. and Prabakaran.R.

1996. Effect of processed cage layer droppings

in the diet on the performance of broiler. Indian

J. Poult. Sci.. 31(1) : 29-32.

Ali. S.A.. 1980. Feed formulation method in

Mannual of Research Methods for Fish and

shell fish nutrition. CMFRI, special publication.

No.8:98.

Anuradha.V. 1997. Jayalakshmi.G and Daniel.

T.. 1997. Evaluation and suitability of hideflesh

as a compound in the feed for fresh water fish

culture. Abstracts. National Workshop on Fish

and Prawn feeds. 2-3,Sep. Bhubancshwar.

Asgah.N.A.A. and Bedawi.R.M.. 1984.

Efficiency of local feeds for the common carp

(Cyphmis carpio) in Saudhi Arabia. Aquacultnrc. 40: 363-365.

Aquino.R.R.. 1987. Growtli performance of

broilers fed with rat. shrimp and fishmeal as

protein source. Proc. 4th AAAP Animal Science

Congress. Asian-Australian Association of

Animal Production Soc, New Zealand. P-207.

Baghel.R.P.S. and Pradhan.K.. 1988a. Effect of

dietan' energy and protein levels on live weight.

meat yield and processing losses in broilers.

Indian Vet. J.. 65 : 607-610.

Baghcl.R.P.S. and Pradhan.K. 1988b. Influence

of dietan energy and protein levels on the body

weight gain, feed efficiency and retention of

lysine, methionine and cystine in broilers.

Inidan Vet. J.65 (10) 895-902.

Baghel.R.P.S. and Pradhan.K.. 1989a. Carcass

traits, organ weights and bone:meat ratios of the

broilers influenced by energy and protein level

at fixed level of limiting aminoacids during hot

season. Indian Journal of Animal Science.

59(1): 189-195.

Baghel.R.P.S. and Pradhan.K.. 1989b. Energy.

protein and limiting aminoacid requirement of

broilers in their different phases of growth

during hot humid season. Indian J. Ani. Sci..

59(11): 1467-1473.

Bakcr.HLD.. Blitenhal.R.C. Bocbel.K.P,

Czamecki.G.L.. Southcn.L.L. and Willcs.G.M.

1981. Protein aminoacid evaluation of steam

processed feather meal. Poultry Science.

60:1865-1872

89

Belal.ffiH. Al-Owaiferi.A. Al-Dosari.M.. 1995.

Replacing fishmeal with chicken offal silage in

commercial Oreochromis niloticus (L) feed. Aquacultnre Research, 26: 855-858.

Bondari.K. and Sheppard.D.C. 1987. Soldier

fly, Hermertia illucens L. larvae as feed for

channel catfish, Ictalurus punctatus

(Rafinesque) and blue tilabia Oreochromis aureus (S). Aquacult. fish. Mgmt.. 18: 209-220

Bradford.M.V. and Gous.R.M.. 1991. The

response of growing pigs to a choice of diets

difference in protein content. Animal

Production. 52:185-192.

Cappcr.B.S.. WoodJ.F. and Jackson.A.J.,1982.

The feeding value for carp of two types of

mustard seed cake from Nepal. Aquaculturc.

(29) 373-377,

Chawla.J.S.. Chauhan.T.R.. Lodlii.G.N. and

Ichhponani. J.S.. 1978. Influence of climatic

conditions on protein and energy requirements

of poultry : Energy requirement of egg type

replacement pullets in winter and summer.

Indian J. Anim.Sci.. 48(5): 388-394.

Daniel.T. and SahayarajA. 1990. Evaluation of Leucaena kucocephala seed kernel as a

protein suppliment for Sarotherodon

mossambica (Peters). The Indian Zoologists. 14 (1&2) 155-157.

Daniel.T and Raj, S.P., 1992. Observation on the utilisation of Bauhinia purpurea as

alternative protein source in fish feed. Proc. of

Ilth National Symposium on Life Sciences.

Mysore. 9-11th October, p.29.

Degani.G.. Yehuda.Y., Viola.S.. Degani.G..

1997. The digestibility of nutrient sources for

common carp, Cyprimis carpio (L) Aquaculturc Research. 28:575-580.

Desilva.S.S. and Gunasekera.R.M., 1989.

Effect of dietary protein level and amount of

plant ingredient (Phaseo/us aureus) incorporated into the diets on consumption,

growth performance and carcass composition in

Oreochromis niloticus (L) fry. Aquaculturc. 80: 121-133.

Fancher.B. and Jenscn.L.S.. 1989. Influence

on performance of three to six week old broilers

of varying dietary protein contents with

supplimentation of essential aminoacid

requirements. Poultry Science. 68: 113-123.

Ghittino.P.. 1972. Fish nutrition. J.E. Halvcr

edition. Academic press. Newyork and London,

550-571.

Goldan.O.. Popper.D. and Karplus.I.. 1997.

Management of size variation in Juvenile

gilthead sea bream (Sparus aurata) 1: particle size and frequency of feeding dry and live food.

Aquaculture. 152 : 181-190 .

90

Hassan.M.R. and MacIntosh.DJ., 1992.

Optimum food particle size in relation to body

size of common carp, Cyprinus carpio L. fry.

Aquacult and Fish. Mangt., 23 : 167-173.

Higuera.M. Gallego.G.M., Sanz.A..

Cardenete.B. Suarez,MD. and Moyano.F.J..

1988. Evaluation of lupin seed meal as an

alternative protein source in the feed of rainbow

trout (Salmo gairdneri) Aquaculture, 71: 37-50.

Isarakul.C.B. and Weewipat,T.S..1991. Effect

of different levels of sunflower seed in broiler

rations. Poultry Science, 70:2284-2294.

ISI.1992 Indian Standard Specification for

broiler feeds. Indian Standard Institute. New

Delhi.

Jackson.S.. Summcrs.J.D. and Leason.S., 1982.

Effect of dietary protein and energy on broiler

performance and production cost. Poultry

Science, 61: 2232-2240.

Jayaram.M.G. and Shetty.H.P.C, 1980.

Infucncc of different diets on llic proximate

body composition of Catla cat/a, Labeo rohita

and C.carpio. Mysore J.Agric.Sci.. 14:381-384.

Krishnappa.K.. Shanmugasundaram.S. and

Subramaniam.M. 1978. A study on protein

levels in broiler ration . Cherion. Tamil Nadu. J.

on Vet. Sci. 7 (2): 136-141.

KaufmanX.W., Coilier.G. and Squibb.R.L..

1978. Selection of an adequate protein

carbohydrate ratio by domestic chicks.

Physiology and Behaviour, 20: 339-344.

Kim.I.B.. Lee.S.H. and Kang.S.J.. 1984. On the

efficiency of soybean meal as a protein source

substitute in fish feed for common carp. Bull.

Korea Fish. Soc. 17 (1): 55-60.

Kim.I.B. and OIU.K.. 1985. The effect of

phosphorus supplimentation of 40 percent

soybean meal sustituted diet for common carp.

Bull.Korea Fish.Soe.. 18 (5): 491-495.

Knights.B.. 1985, Feeding behaviour and fish

culture. Nutrition and feeding in fish.

Academic Press. London. 223-241.

Kumar.M.C.R., Sreemanarayana and Roa.K.P..

1977. Effect of feeding industrial by-products

on the growth of chicks. Poultry Guide. 45-48.

Law.A.T.. 1986. Digestibility of low cost

ingredients in pelleted feed by grass car}) (Ctenopharyngodon idella) Aquaculture. 51: 97-103.

Lcpstein.B.. Bornstein S. and Bartov.J.. 1975

The replacement of some of the soybean meal

by the first limiting aminoacids in practical

diets.3. Effects of protein concentration and

arninoacid supplimentation in broiler finisher

diets on fat deposition in the carcass. British

Poult. Science. 16:627-635.

91

Lee.K.J. and Bai.S.C, 1984. Haemoglobin

powder as dietary fishmeal replacer in juvenile Japanese eel, Anguilla japonica. Aquaculture Hangaster. 29: 211-217.

Lee,R.K. and YangXF., 1975. Sim dried

chicken droppings as feed for broilers. Journal

of Taiwan Livestock Research, 8: 27-32.

Luzier.J.M. Summerfelt.R.C. and Ketola.H.G..

1995. Partial replacement of fishmeal with

spray dried blood powder to reduce phosphorus

concentrations in diets for juvenile rainbow trout. Oncorhynchus mykiss. Aquaculture

Research. 26:577-587.

Mearns.KJ.. 1990. The behavioural approach

in identifying feeding stimulants for fish and its

application in aquaculture. E.Kjorsvik (Editor) Application of behaviour studies in aquaculture.

Proccdings from the minisyniposium on

ethology in aquaculture. 22nd Oct.

1989. Norwegian Society for Aquculture

Research, Bergen. 69-74.

Mohanty.S.N.. Swamy,D.N. and Tinipadii.S.D..

1990. Growth as nutritional indices and carcass

composition of Indian Major carps, catla. rohu and mrigal fed to dietary protein levels.

Aquaculture Hangaster. 35: 211-217.

MoranJr.E.T.. Bushong,R.D. and Bilgili.S..

1992. Reducing dietary crude protein for

broilers while satisfying aminoacid

requirements by least cost formulation live

performance, litter composition and yeild of fasl

food carcass cuts at six weeks. Poultry Science

71:1687-1694.

Morris.T.R. and Njuru.D.M, 1990. Proteinl requirement of fast and slow growing chicks

British Poult. ScL 31:803-809.

Murai.T.. Akiyama.T.. Tckeuchi.T..

WatanabcT. and Nose.T. 1985. Effects of

dietary protein and lipid levels on performance

and carcass composition of fingerling carp.

Bull. Jap.Soc. Sci. Fish.. 54 (4):605-608.

Nakanuira.N. and Kasahara.S., 1956. A study

on the phenomenon of the tobi koi or shoot

carp.2. on the effect of particle size and quantity

of the food. Bull. Jap. Soc. Sci. Fish.. 21:1033-

1024.

Nandeesha.M.C, Devaraj.K.V. and Sudhakara.N.G.. 1986. Growth response of four

species of carps to different protein sources iu

pelleted feeds.J.L.Maclean. L.B.Dizon and

L.V.Hosillos (eds) The first Asian Fisheries forum. Asian Fisheries Society. Manila.

Philippines. 603-608.

92

Ogmo.C. and Saito.K., 1970. Protein nutrition

in fish. Utilisation of dietary protein by young

carp. Bull. Jap. Soc. Sci. Fish.. 36:250-254.

Papoustsoglou.S.E. and Papoustsoglou.E.P..

1978. Comparative studies on body composition

of rainbow trout (Salmo gairdneri R.) in relation to type of diet and growth rate. Aquaculture, 13

:235-243

Prasad.A.. Sadagopan.V.R., Rao.P.V. and

Panda.B.. 1978. Studies on the sulphur amino

acid requirement of cross-bred broiler chicks.

Indian J. Anim.Sci.. 48 (5): 384-387.

Raj.S.P., 1978. Formulataion of pelleted feeds and feeding trials with common carp. J.lnland

Fish. Soc, India. 9: 45-52 .

Raj.S.P.. 1984 Feed conversion efficiency and growth rate of grass carp Ctenopheryodon idclla

(Val) fed with some weeds and grasses in composite fish culture system. Geobios. 11: 53-

55.

Raj.S.P.. 1989. Evaluation of clitoria leaf as protein suppliment in the feed of Cyprinus

carpio var. communis. J. Ecobiol..l(3) 195-202.

Raj.S.P. and Kandasamy.D.. 1991. Hidefleshings as a protein source in the feed of

Penaeus indicus. Proc. of the II Asian Fish

Forum

Raj,S.P. 1994. Pelleted feed formulation, by incorporating wild leaves for die fingerlings of

rohu (Labeo rohita) Bio Resources Technol..265-267

Raj.S.P. and Kutty.M.N., 1984. Food conversion efficiency and nitrogen balance in

Chrhinus mrigala fingerlings fed on three

pelleted feeds compounded with wild legumes

J.Indian Inst.ScL 65(C): 59-64.

Sadiku.S.O.E. and Jaunccy.K.. 1995

Digestibility, apparent aminoacid availability

and waste generation potential of soybean

flounpouitry meat meal blend based diets for

tilapia, Orcochromis niioticus (L) fingerlings. Aquaculture Research. 26:651-657

Salmon.R.E. Classcn.H.L. and Mc Millan. R.K..

1983. Effect of starter, finisher protein on

performance, carcass grade and meat yield of

broiler. Poultry Sci.. 62: 837-845.

Samanta.G.. Chakraborty.N. and Mandai.L.

1991. Feeding value of penicillin and

tetracycline waste products in broiler diets.

Poultry Guide. 12:51-53.

Sethi.A.P.S.. Sikka.S.S.. Nagra.S.S. and

Chawia.J.S., 1991. Nutritional evaluation of

meat meal for poultry. Indian J. Poult. Sci.

26(4): 217-220.

93

Shariatmadan.F. and Forbes. J.M., 1993.

Growth and food intake responses to diets

containing two concentrations of protein in

broiler and layer stains of chickens. British

Poultry Science. 34:959-970.

Smith. I.P.. Metcalfe.N.B. and Huntingford,

F.A.. 1995. The effects of- food pellet

dimensions on feeding responses by Atlantic

salmon (Salmo salar L.) in a marine net pen. Aquaculiure, 130: 167-175.

Stradmeycr.L., Metcalfe.N.B. and ThorpeJ.E..

1988. Effect of food pellet shape and texture on

the feeding responses of juvenile Atlantic salmon. Aquaculturc. 73:217-228.

Stcvcnscn.M.H. and Jackson.N.. 1981. The

nutritional value of dried skim milk in broiler

diets. J.Sci. Food Agric. 32:79-86.

Summcrs.J.D.. Slingcr.S.J. and Ashton. G.C..

1965. The effect of dietary energy and potein

on carcass composition with a note on method

for estimating carcass composition. Poultry

Science. 44: 501-509.

Swainy.D.N.. Mohantay.S.N. and Tripathi.S.D..

1988. Growth of mirgal fingerlings fed on

fishmeal based formulated diets. Proceedings

of the first Indian fisheries forum. Asian

fisheries Society. Indian branch. Mangalore.

Dec.4-8-1987. 81-83.

Tabachek.J.L.. 1988. The effect of feed particle size on growth and feed efficiency of Arctic charr (Salvelinus alpinus). Aquaculture. 71: 319-330.

TyagiJ.S. and Singh.R.A., 1996. Effect of

dietary crude fibre levels and season on the

performance of broilers. Indian J. Poult. Sci..

31(1): 33-37.

Venugopai.M.N. and Kesavanath.P.. 1984

Influence of supplementary feeds on the

biochemical composition of flesh of fresh water

carps. Cat/a catla (Ham), Cirrhinux inrigala (Ham) and Cyprinus carpio (Lam). Indian J.Anim.ScL 54 (6) 555-559.

Viola.S. and Arieli.Y.. 1982. Nutrition studies

with a high protein pellet for carp and

Sarathorodon sp. Bamidgeh. 34 (2): 39-46.

Virk.R.S.. Lodhi.G.N. and Ichhponani.J.S..

1978. Influence of climatic conditions on

protein and energy requirements of broiler

starter in winter and summer. Indian J. Aniin.

Sci.. 48(1): 36-41.

Waldroup.P.W.. Hillard.C.M. Abbot.W.W. and

Luthcr.L.W.. 1970. Hydrolysed leather meal in

broiler diets. Poultry Science. 49:1259-1263.

Winfree.R.A. and Stickney.R.R.. 1984 Formulation and processing of hatchery diets for channel cat fish. Aquaculture. 41:311-323.

94