Department of poultry production Faculty of Animal production
Transcription
Department of poultry production Faculty of Animal production
EFFECT OF LIQUID AMINO ACIDS SUPPLEMENTATION IN DRINKING WATER ON PERFORMANCE OF BROILER CHICKS By Obaie Mobark Babeker Elmbarke B.Sc. (Honours) Animal Production Khartoum University 2001 A thesis submitted to the University of Khartoum in partial fulfillment for the requirement of the Degree of Master of Poultry Science Supervisor Dr. Saadia Abdel - Moniem Abbas Department of poultry production Faculty of Animal production University of Khartoum January – 2006 CHAPTER ONE INTRODUCTION Poultry keeping in Sudan started with rearing of birds, which was concentrated in the country, and rural areas, local type birds were kept in small number to provide eggs and meat where their for the family use. The birds are kept free to forage and are produced with human domestic food residues and local grains. In such type of poultry keeping, production was too low, because of poor management inadequate nutrition and poor genetic constitution of the local birds. The cost of production is negligible. Recently the poultry industry in the Sudan began to develop, but facing many problems. The feeding of poultry represents about 70% of total cost of production, for provision of balanced rations contains all nutrient requirements of birds in adequate quantities, and proper ratios. Protein is an important component in poultry rations, and is derived from different sources such as cakes (groundnut cake nut and sesame), which are used as the main plant protein sources. Incorporation of plant protein sources in poultry ration, would not meet the requirements of certain essential amino acids, which consequently, necessitates the use of animal protein supplements such as fish meal and blood or meat meal. Furthermore, excessive heat treatment during the processing of soybeans meal results in binding and destruction of certain amino acidity, which make them unavailable, Thus adding to the problem associated with the utilization of plant protein in poultry feeding. The inclusion of synthetic amino acids may become a reasonable solution in this respect. High lysine corn is considered as an excellent source of lysine and trytophan which can be used in poultry diets to avoid the poor distribution and precipitation of dietary synthetic amino acids. In (1995) liquid (AA) were sold under various brand names, it is synthesized from vegetable protein, and is stored refrigerated for 3-5 years. It is supplemented in water of feed as its Manu faction, and its an essential (AA) for growth, developments, tissue maintenance and heat stress, The use of liquid (AA) in the diet will also reduce storage cost, loss and will improve mixing and mill environment. The present study was conducted to determine the effect of using liquid amino acids in drinking water on broilers performance fed three types of diets, and compared them with the birds which were not supplemented with liquid amino acids, but fed the same diets, also it measure the quantity of water which were consumed by the birds, and evaporation. CHAPTER TWO LITERATURE REVIEW 2.1 Protein in poultry diet: The proteins form important structural parts of the soft tissues of the animal body such as muscles, connective tissues, collagen, skin, feathers, beak and blood proteins (Scott et al., 1982). In addition proteins are good sources of all essential amino acids (E. A. A.). There are two sources of dietary proteins namely plant and animal proteins. These feed ingredients have some problems associated with antinutritional factors and variability in composition and quality (Rhone, et al., 1995). The same authors also indicated that alternative protein sources such as grains, cakes and legumes are low in some amino acid mainly the essential amino acids, that’s why meat and bone meal or fish meal are added to supplement the essential amino acids in the diets. High dietary protein is known to reduce body fat in broiler chicks (Fisher, 1984), and lipogenesis (Tanaka, et al., 1983). Santoso, et al (1993) used a high dietary protein to minimize abdominal fat and the total body fat without loss of general performance characteristics. However some investigators failed to show compensatory growth and lower body fat at market age when high protein levels were used (Santoso et al; 1995 and Summers et al; 1990). Tanaka and Ohtani (1995) obtained less abdominal fat in chicks when fed high protein levels (25, 30 and 35%) compared with chicks that were fed adlibitum. They also reported liver triglyceride content in chicks fed 21, 30 and 35% C. P. Increasing the dietary protein content in isoenergetic diets will increase carcass protein content and decrease carcass fat content (Holsheimer, 1975, Bedford and Summers, 1985). Decreasing the dietary energy to protein ratio will also increase meat yield and decrease carcass fat content (Salmon et al., 1983). Holsheimer and Veerkamp (1992) found that higher breast meat yield was obtained with normal crude protein levels and high lysine. The last mentioned authors also reported high drum stick yield with low energy and high crude protein diets. They also stated that using high crude protein diets resulted in the lowest skin and fat yields. Bartov and Plavnik (1998) found that relative abdominal fat weight was increased significantly by increasing dietary energy to protein ratio (E:P); and no differences in feed intake and body weight gain were detected up to 42 days of age between broilers fed the diet with low (E/P) ratio and those fed the recommended (E/P) ratio. Also carcass yield was not affected by dietary (E/P) ratio up to 42 days of ages, but at 43 day of age the carcass yield increased significantly by the low (E/P) ratio (Partov and Plavnik, 1998), they concluded that the optimal (E/P) ratio for max breast meat yield particularly at 42 day of age, may be below the NRC (1994) recommended level (135). Diets lower in protein content than recommended by NRC (1994), reduced the yield of meat and increased fattening. The optimal dietary protein level for weight gain is lower than that for feed efficiency (Fancher and Jenson, 1987; Moran et al., (1992). The same findings are true for lysine (Moran and Bilgili 1990; Han and Baker, 1993). Reduced dietary protein level in broiler diets below the recommended level when supplemented with essential amino acids, mainly lysine and methionine, usually support adequate weight gain but increase fattening (Lipshtein et al., 1975, Moran et al., 1992 and Deschepper and Degroote, 1995). Lipshtein et al (1975) reported that reducing crude protein from 20.5% to 17.5% in diets fed to male from 5-9 weeks of age increased carcass fat, although live weight was unchanged, Moran et al (1992) stated that when dietary crude protein was reduced from 23% to 21% or from 20% to 17%, live body weight was not affected, but feed conversion ratio increased. The same authors also reported that when low crude protein was used, abdominal fat was increased. 2.2 Amino acids requirements: The amino acids (AA) requirements for males is higher than that for females (Han and Baker 1993). According to Hurwitz et al (1998), when total dietary amino acids (AA) level is reduced, the requirement for the individual (AA) decrease due to growth retardation resulting from single or multiple (AA) deficiencies. Han and Baker (1994) studied the lysine requirements of both sexes during the period from 3 to 6 week of age. The requirement of lysine in a diet containing 20% crude protein (CP) for maximum weight gain was 0.99% for males and 0.91% for females, and for optimum feed efficiency for males, and females, 1.03 and 0.99 lysine respectively. However, Han and Baker (1991) studied the amino acids requirement of a fast and slow growing broiler chicks fed a diet containing 23% CP and found that the requirement of chicks from 8 to 21 days must not be greater than 1.17% lysine for maximal weight gain and 1.41% lysine for maximum feed efficiency for both strains. These estimates of requirements are substantially higher than 1.1% of the diet estimated by the National Research Council (NRC, 1994) for broilers up to 3 weeks of age and fed a diet containing 23% CP. Moran and Bilgili (1990) reported that 0.85% total lysine was inadequate for broilers 28 to 42 days old chicks, while lysine values used in practice have been escalated to approximately 0.95%(Agriststs 2001). These findings were supported by Acar et al.,(1991), and Bilgili et al.,(1992) in their reports on high breast meat yielding strain given feeds formulated to satisfy NRC (1994) specification. Scott et al., (1982) reported that L– lysine requirement was 5% of the protein only for 1 to 2 weeks of age, then it drops to 4.5% for 2 to 16 weeks of age. These values were equivalent to 1.32 and 1.14% of the diet respectively. Chung et al (1973) determined lysine requirement as follows: 5% of the protein for 1 to 3 weeks of age and 4.1% of the protein for 5 to 7 weeks of age. These were equivalent to 0.94% and 0.7% of the diet, respectively. Titus and Fritz, (1971) suggested that methionine level of 0.31% of the diet is reasonable for both layer and broiler chickens, However, Tileman and Pests, (1968) reported that when a basal diet containing 0.38% methionine was supplemented with 0.2 methionine the weight gain was increased. The lysine and sulfur amino acids requirements have been evaluated extensively, but less information is available on the threonine requirement Waibel et al.,(1996). Threonine may be the third limiting AA, after lysine and methionine in diets for broiler chickens (Han et al., 1992; Fernandez, et al., 1994, and Kidd et al., 1997). The (AA) requirements of poultry and other animals are known to decrease as age increases (NRC, 1994). Broiler chickens commonly increase five fold in weight during the first week of life and 10 fold during the first 2 weeks, that’s why (AA) requirement are very high in these first 2 weeks (Pettit 2001). Cuca and Jensen (1990) estimated the arginine requirements for growth to be from 1.10 to 1.28% of the diet and for maximum feed efficiency from 0.96 to 1.28% of the diets. The NRC (1994) estimated the arginine requirement of broilers 3 weeks of age to be 1.25% of the diet, and for 3-6 weeks to be 1.10%. Many factors can influence the amino acid requirements of chicks at any given growth stage (Baker 1997). This include dietary factors such as protein level, energy level, presence of protease inhibiters, environmental factors, crowding, feeders space and heat or cold stress, genetic factors such as, sex and capacity for leans 2.3 Effect of amino acids supplementation on broiler performance: The supplementation of the amino acids was done to reach the ideal amino acids balance in the diet, without deficiencies or excesses, providing the requirement of all amino acids needed for maintenance and production (Baker and Chung, 1992). According to Penz (1996), amino acids should be added in levels that as close as possible to the requirements of the bird in each production phase and thus, amino acids excesses would be minimized in the diets. Nutritional programs in the Sudan are commonly based on foreign requirement tables such as NRC (1994). It is possible to include amino acids in poultry feed as individual chemical compounds. Lysine and methionine are both available to supplement poultry rations. Methionine may be used either in the form of DL-methionine or as methionine hydroxyl analogue (Austic and Nesheim, 1990). Fritts et al., (2001) studied the relationship of dietary lysine and other essential amino acids in broiler diets, formulated according to NRC (1994) recommendations and used 0.1, 0.2, or 0.3% additions of lysine with other essential amino acids. (EAA) at 100, 110, 120 and 130% of (NRC) recommended levels, and found that there were no significant interaction between the level of lysine and the levels of the other essential amino acids for live performance or carcass characteristics. The final body weight was significantly increased at 21 and 42 days by addition of 0.01% lysine above the NRC level, but not at 56 days. They also reported that dietary lysine level had no significant effect on dressing percentage, breast meat yield, or abdominal fat content. According to Sibbald and Wolynetz (1986) increasing dietary lysine level causes an increase in broiler carcass protein retention and a decrease in fat retention. Park and Austic (2000) reported that chicks received a 5% dietary addition of 11 amino acids consisting of equimolar concentrations of Leucien, valine histidine, alanine, glycine, serine, threonine, lysine, methionine, cystine, and isoleucine had significantly low weight gain and feed consumption and a higher feed conversion ratio than the chicks fed the basal diet. Isoleusine is the fourth limiting amino acid in corn for growth of chicks (Fernandez et al., 1994), but it is less limiting than valine in low protein corn and soybean based diets of broilers (Edmonds et al., 1985; Han et al., 1992 and Fernandez et al., 1994). Threonine may be the third limiting amino acid to methionine and lysine in the diets composed primarly of ground yellow corn and soybean meal, for broiler chickens (Han et al., 1992; Fernandez et al 1994, and Kidd et al., 1997). To achieve optimum broiler performance the dietary crude protein content must provide sufficient levels of EAA to allow a maximum protein and meat synthesis and the demand of the metabolic process other than protein synthesis (Fancher and Jensen 1987). Kim et al (1986) replaced corn by sorghum at different levels, then lysine and methionine were added. When supplementing a 14.4% crude protein diet fed to female broilers from 36 to 63 days with additional methionine and lysine, growth and feed efficiency were equal to that obtained with 18.1% crude protein diet (Lipshtein and Bornstein, 1975). Furthermore, adding the same A. A. to 15.5% crude protein diet resulted in males gaining weight and converting feed efficiency as those receiving a 20.2% diet, (Lipshtein and Bornstein, 1975). Uzu (1983) supplemented a 16% crude protein diet for broilers from 28 to 44 days of age with additional methionine and lysine revealed growth rate equal to that obtained by feeding a 20% C. P diet. Adding methionine and lysine to a 16% C. P diet supported growth from 21 to 65 days comparable to growth of birds fed 19% CP diet, but achieving equal feed efficiency necessitated adding threonine to the low CP. diet (Nakajima et al., 1985). 2.4 Effect of dietary amino acids deficiency and excess on broiler performance: Acar et al (2001) found that excessive dietary (a.a) above the requirement of (NRC) reduced feed intake and, in turn restricted the early rapid growth of broiler. Dietary (a.a) were supplemented to the basal diet to yield a total of 1.57, 2.57 and 3.57% histidine 2.7, 4.3, and 5.9% lysine, 1.66, 2.16 and 2.96% methionine 2.8, 3.8 and 4.8% threonine, and 1.27, 2.27 and 3.27% tryeptophan. Church and Pond (1976) demonstrated that threonine or methionine deficiency, produced fatty liver and lysine deficiency in birds produced abnormal feathering. They also indicated that excess lysine causes growth depression in chicks which can be reversed by addition of arginine, whereas, methionine added to the diet in excess produced growth depression which could not be overcome by supplementation with other amino acids. Thomas et al., (1979), added graded levels of lysine 0.75, 0.90, 1.05, 1.20, 1.80 to broiler diets. They found that the lowest level of lysine (0.75) depressed weight gain and gave the poorest feed conversion; however, the highest level of lysine (1.80%) resulted in no depression in both weight gain and feed efficiency. Holsheimer and Ruesink (1993) reported that levels higher than 1.15% dietary lysine in the starter period (up to 14d of age) resulted in higher breast muscle yield at 49d of age irrespective of dietary lysine level in the range of (1.1 to 1.30%) from 15 to 49d of age. An increase in dietary lysine content will increase protein retention and decrease fat retention (Sibbald and Wolynelz, 1986). As lysine is present in relatively high proportions in poultry muscle ( Roth et al., 1990) it is of interest to know whether an increase in dietary CP, in lysine, or in both is responsible for increased muscle growth. May (1979) reported that feeding chicks 50% of their lysine requirement affect levels of circulating thyroid hormones. Smith (1978) reported that inadequate broiler chicks basal diet supplemented with increasing amount of lysine would impair weight gain and feed utilization, due to toxicity of the amino acids. Behrends and Waibel (1975) studied the methionine and cystine levels in corn-soybean meal, they found that methionine was usually deficient and cystine was in excess of their individual requirements, and they indicated that the deficiency in the total sulphur amino acids in these diets could be corrected by the addition of methionine depend on the amount of utilizable cystine in the dietary protein. Grabber et al., (1971a) stated that cystine can safely provide approximately 55% of the total solid amino acids needs for growth of the chicks. Grabber et al (1971b) found that the maximum cystine replacement value increased with age, and the replacement values where 56, 65 and 67% when gained was the criterion used and 60, 67 and 70% for gain /feed ratio, during the chick, fifth and eighth week of age. Featherston and Rogler (1978) showed that cystine supplementation of diets containing suboptimal levels of methionine and cystine (0.2%) resulted in growth depression. Muller and Ballun (1974) demonstrated that the addition of 0.75 or 1.50% L- leucine to a 10% protein diet drastically reduced egg production and feed consumption and it was concluded that the possibility of a leucine X isoleucine interaction impairing the performance of hens fed practical rations was remote. D' Mello and Lewis (1970) noted that the addition of 1.50% L- leucine to 20% protein corn-groundnut meal diets containing 1.43 and 0.56 % leucine and isoleucine , respectively, depressed chick growth by 3g /chick daily, and the addition of 1.5% L - leucine in a corn-groundnut meal diet containing 20% protein depressed chick gains from 15.9 to 13g / day, and addition of 0.35% DL- valine to the leucine- imbalanced diet increased gain to 15g /day, but the addition of both valine and isoleucine to the imbalanced diet restored gains to 16.9g /day. Bray (1970) showed that excess leucine increased the requirement for isoliosine and valine but had no affect on the requirement for lysine and tryptophan. Bray (1968) showed ample evidence to indicate that the ratio of corn to soybean protein significantly influenced the relative adequacy of essential amino acid in corn –soil diet. Inadequacy of isoleucine may explain the inconsistent and limited response that had been reported when low protein corn–soybean diets were supplemented with various combination of tryptophan, and lysine and methionine. The effect of excess of certain amino acid upon metabolism and dietary requirement for others were studied by Leung, et al., (1968), Kutma and Harper (1962) , they found that excess of leucine increased the requirement of isoleucine. Signs of leucine – induced amino acid deficiency included depression in the plasma concentration of the amino acid, that was first limiting in the diet, and an increase in the plasma level of leucine. Phansalkar, et al., (1970) demonstrated a depression in the level of isoleucine and valine in plasma when leucine was given intravenously. 2.5 Supplementation in the drinking water: According to Baker and Han (1994) and Baker (1997) lysine supplementation of corn- soybean meal diet is a common practice, particularly if the C.P content of the diet is low. The opportunity to lower the protein level of the practical diets has arisen due to the availability of competitively price crystalline amino acids, including (L.lycine Hcl, Dl methionine and L.lysine). All these crystalline amino acids have been available for many years and are assumed to have a bioavailability of 100%. Izquierdo et al., 1988). Recently, change in the procedure for commercial production of L. lysine HCL has allowed for the production of free flowing liquid lysine product ( L. L. P) that contains 60% L lysine free base and is devoid of H CL (Emmert et al., 1999). However Baker (1977) stated that methionine added to water could be degraded to methionine + cystine and may cause severe problems, observed that low levels (not detail) added to the drinking water of growing chicks could decrease water consumption by 50%, no description of the methionine source was given, this reduction could have been due to the odor of methionine (the typical cabbage – like odor). Liquid amino acids easily digested, so they were providing branched chain of amino acids (L- Leucine, L– isoleucine, and L- valine), B – complex vitamins, lipotropic factors, choline, inositol and rich source of energizing complex carbohydrates (glucose polymers) and pure crystalline fructose (Anonymous (a), they also reported that it helps in building muscles tissues, and increase lean muscle mass. So that liquid lysine is an essential AA for growth, development, tissue maintenance and repair, and also Liquid methionine is an essential AA that assists in the breakdown of fat in the liver, arteries that might blood flow to the brain, heart and kidneys, beside that L– Arginine is a semi– essential AA synthesized by the body from ornithine and it produces creatine. L– tyrosine which is used for stress reduction, depression, allergies and headaches. This product is also used for appetite suppression and helps in reducing body fat. L– glutamine regulates the balance between anabolism and catabolism of fat (Billphillips 1998-2005). The synthesized liquid amino acids contain Lysine, Methionine, Alaine, Arginine- Aspartic acids Glutamic acids, Glycine, Histidine Isoleucine, Valine, Tyrosine, threonine serine, proline, phenylalanine and Lucien. (Anonymous (b)). Moreover the same author reported that methionine added to the drinking water of growing chickens could decrease water consumption by 50%. Supplementation of L. lysine. HCL to provide 0.95 and 1.05% total lysine did not increase body weight but improved feed conversion and increased breast muscle yield(Moran and Bilgili(1992). Research concerning the addition of nutrients to drinking water in poultry has been primarily centered around minerals (Kienholz et al., 1965, Shirley, 1970, 1974; Merkly, 1976). Griggs et al.(1971). Administrated several commercial nutrient preparations that contained one or more of the following like amino acids, electrolytes, vitamins, antibiotics, or dextrose in the drinking water of poultry and reported improved early weight gain. Proteins are degraded to small peptides containing 2 – 6 amino acids and some free amino acids. These small peptides are hydrolyzed by peptidases to free amino acids. Amino acids are transported from the luminal small intestine to the mucosal cell. The absorbed amino acids reach the liver and used for synthesis of liver tissues proteins or blood proteins( Scott et al, 1982). Damron et al (1986) studied the effect of liquid methionine source supplied through the water on chick performance. Methionine at 0.05, and 0.075% from the liquid source were added to drinking water and compared with 0.05, and 0.075% methionine supplementation in methionine- deficient basal diet ( dry sources), and found that mortality was not affected by any of the treatments, but water consumption was decreased significantly in the liquid methionine supplemented group. Also Damron (1992) reported that liquid methionine [2-hydroxy4(methyl thio) butanoic; acids HMB] supplied through the drinking water at 0.025and 0.05% compared with levels of 0.03,0.06 or 0.09% in the basal diet of the broiler from 0 to 21 days of age, had no effect on mortality Anderson (1982) reported that, graded levels of L - methionine or water solution of its sodium salt were added at equivalent levels to a broiler diet based on corn, soybean, and poultry by product meals, had no effect on weight gain of broiler. 2.6 Liquid methionine supplementation in the feed: The use of liquid methionine in the feed has many advantages such as improved mixability, reduced power requirement for pelleting, easy storage, elimination of product loss and reduced level of dust in the mill. (Anonymous,(c)). Liquid methionine source in feed reported to give better performance during heat stress, it was reported to be absorbed in the small intestine by the birds via the simple diffusion without the use of energy for transportation across the cell membrane (Swick et. al., 1990., Dibner, 1984). Recent research has shown that DLM absorption is less efficient in birds exposed to h eat stress, and heat stress alters both the mechanisms and rate of DLM absorption (Anonymous, (c)). The absorption of liquid methionine added to the feed was un affected when birds were subjected to heat stress conditions. (Anonymous, (c)), also reported that Liquid methionine digestibility was significantly reduced during heat stress. The birds consuming the liquid methionine in their feed ate more feed and drank more water (Anonymous, (c). Baker (1991) reported that DLM level in excess of the requirement lead to toxicity and caused depression in feed intake, lower growth rate and feed conversion. Swick et al., (1991), and Knight et al., (1994). Reported that birds fed liquid methionine in diets retained a greater percentage of dietary nitrogen when compared to birds fed DLM, as the birds fed liquid methionine ate more feed and drank more water during heat stress experiencing less thermal stress. The liquid methionine in the feed was reported to give better methionine availability for growth and development, the overall performance of broiler, turkeys and layers were reported to be improved by liquid methionine than the dry amino acid (Anonymous, (c)). They also added that liquid methionine when added to the feed acts as mold inhibitor, and it’s better than DLM in dry form. CHAPTER THREE MATERIALS AND METHODS 3.1 Experimental Liquid Amino Acids: Liquid Amino Acids was used in the drinking water at the rate of two ml in one liter of drinking water as recommend by the manufacturers. The consumed water was measured daily to estimate the amount of liquid amino acids consumed by the experimental chicks. The liquid amino acid was purchased from Modern Agricultural Nile Valley Company (Sudan), and its composition of amino acids is presented in Table (1). 3.2 Experimental Diets: A basal diet was formulated from sorghum grain, groundnut meal, sesame meal and other ingredients as shown in table (2). This basal diet ingredients percentage were varied to form three different experimental diets such as follows. Diet (1) contained the basal diet without any supplementation of amino acids. Diet (2) Sorghum + sesame meal + groundnut meal + super concentrate + crystalline amino acids (methionine, and lysine). Diet (3) Sorghum + sesame meal + groundnut meal + crystalline amino acids (methionine, and lysine). Table (1): The composition of liquid amino acids (0.05 mg per 400ml) Amino acids Mg Leucine 0.05 Phenylalanine 0.05 Arginine 0.05 Glycine 0.05 Lysine 0.05 Aspartic acid 0.05 Alanine 0.05 Tyrosine 0.05 2ml of liquid amino acids per 1000 ml water 2ml of liquid amino acids contained 0.00025mg of each amino acids. 0.05 mg = 0.0000125% Table (2): Formulation of the Experimental Diets (%). Ingredients Diet (1) Diet (2) Diet (3) Sorghum 55.80 60.70 55.80 Groundnut meal (GNM) 21.30 15.00 21.30 Sesame meal(SM) 14.00 15.00 15.00 Wheat bran (WB) 3.40 0.40 1.53 Super concentrate (S.C)* ____ 5.00 ____ Dicalcium phosphate 2.60 1.40 2.60 Sodium chloride 0.40 0.33 0.40 Vegetable oil 2.50 2.00 2.56 Lysine ____ 0.04 0.56 Methionine ____ 0.01 0.13 Cystine ____ 0.12 0.11 Total 100 100 100 *Contains unit per kg: Crud protein (400), crude fat (20), crude fiber (20), calcium (100), phosphorous (40), lysine (120), methionine (30), methionine + cystin (32), met. Energy (2, 100 kcal/kg), sodium (26). Vitamin A (200.000), vitamin D (40,000), vitamin E (500), vitamin B1 (15), vitamin B2 (100), vitamin B6 (20), vitamin B12(300), biotin(1000), nicotinic acids (600), folic acids (10), vitamin K3 (30), pantothenic acids (150), choline chloride (5.000), copper (100), manganese (1.200), zinc (800), iron (1.000), iodine (15), cobalt (3), selenium (2), BHT (900), meticlorpindol (2500). The three experimental diets were formulated to meet the requirements of the broiler chicks as recommended by the National Research Council (N.R.C, 1994), as shown in table (3).It can be seen that the diets varied in CP%, metabolizable energy essential amino acids content. Each of these three experimental diets was assigned to 8 pens, where half of the drinkers water was supplemented with liquid amino acids, from day old up to 42 days of the experimental chicks. Table (3): Calculated Composition of the Experimental Diets: Items (%) NRC(1994) Diet (1) Diet (2) Diet (3) Crude protein CP% 23.1 22.6 23.2 Metabolizable energy ME (kcal/kg) 3174.3 3172.0 3172.2 Lysine 0.5 1.1 1.1 Methionine 0.4 0.5 0.5 Cystine 0.3 0.4 0.4 Phenylalanine 0.7 0.9 1.0 Arganine 1.8 1.6 1.8 Glysine 1.0 0.8 1.0 Leucine 1.0 1.6 1.7 Calcium 1.0 1.1 1.0 Phosphorus 0.6 0.5 0.6 3.3 Chemical analysis: proximate analysis of the experimental diets was carried out according to Official Methods of Analysis of Association of Official Analytical Chemists(AOAC,1990); and crude protein was determined by micro-Kjeldhal method. Metapolizable energy values were calculated by the equation of Lodhi(1976). ME(Kcal/kg)=(1.549+0.0102-*CP+0.0275*Ether extract+0.0148*NFE-0.0034*Crude fiber) Table (4): Proximate analysis of the experimental Diets(%): Items Diet (1) Diet (2) Diet (3) Dry matter 96.8 97.3 96.5 Crude protein 24.9 25.1 24.4 Ether extract 4.2 4.4 5.4 Ash 6.5 6.1 5.7 Crude fiber 4.6 5.9 3.8 NFE 56.6 55.8 57.2 2740.52 2731.8 2780.02 ME (kcal/kg) 3.4 Housing and Equipments: The experiment was conducted in an open-sided deep litter house. The house was 18X5 m with a height of 3m. It was constructed using iron posts, zinc sheets roofing, concrete floor and wire mesh in all sides. The wired sides were surrounded by Kenaf, for protection against cold windy spells and solar radiation. The whole house was divided into (24) small pens (one m). Dry wood shavings were used as litter material to a depth of 4 cm. Light was provided for 24 hrs, in the form of natural light supplemented with an artificial light in the evenings. Hundred watt bulbs were used in each pen throughout the experiment to provide light and heat for broodiness. Each pen was supplied with a feeder and a drinker which were raised gradually as the chicks grew bigger. Feed and water were offered adlibitum. 3.5 Experimental birds: One hundred and ninety two one-day old, unsexed commercial broiler chicks (Hubbard) were Purchased from (Ommat Company) in (Egypt) and shipped to the Poultry Unit in the Faculty of Animal Production at Shambat. Chicks arrived on April.4th 2004. Upon arrival, chicks were randomly distributed into 24 pens, (eight chicks per pen). The mean initial weight of the chicks in each pen was approximately similar. The experimental diet were then randomly assigned to the experimental pens with 8 replicates each. Then half of the replicates in each treatment (4reps) received liquid amino acids in drinking water. Concentrate of liquid amino acids was added at 2ml\lit. 3.6 Management and Data Collection: Feed and water were offered ad-libitum. All the birds were given vitamins and minerals in water, and were vaccinated against New castle disease at six days old and against Gumbro at sixteen day old. They were then revaccinated against Gumbro and Newcastle at 22 days and at 30 days, respectively. The chicks were weighed at weekly interval and feed consumption of each group, was calculated at the time of weighing. Ambient temperature was recorded twice a day at early morning and in the afternoon to register low and high temperatures. Water consumption was recorded daily, and water evaporation was estimated using values of evaporation one drinker putted in the middle of the experimental house. The amount evaporated was subtracted from each drinker to arrive at the amount of water drunk in each pen. Then the amount of each amino acids consumed/chick/day was calculated. Mortality was recorded when occurred. 3.7 Carcass evaluation: At the end of the experiment (at 6 weeks of age), one bird was selected at random from each pen, and was slaughtered and used for assessment of carcass and cut percentage. The selected bird was fasted over night, but offered drinking water. Each bird was then weighed and slaughtered by severing the trachea and the carotid arteries, and was allowed to bleed. The bird was then scalded using hot water and was manually plucked, thoroughly washed and left to drain on a wooden table. Evisceration was then carried out by a posterior ventral cut ,and then complete removal of the visceral and thoracic organs was done . The head was then removed close to the base of the skull, and similarly the legs from the hocks joints. Eviscerated carcasses were then weighed to register hot carcass weight, and were kept in the refrigerator for 24 hours at 4c. After that the cold carcasses were weighed, they were then cut into five cuts breast, thigh, drumstick, back and wing. Then the cut parts were weighed individually. After that each cut part was deboned and weighed to estimate at the meat to bone ratio. Also the abdominal fat was dissected from each carcass and weighed. 3.8 Water consumption: Water was added to the drinkers, which were made of metal jar and pan, the capacity of each drinker is about 4 liters. To evaluate the daily water consumption, residual water in the drinkers was measured every 24 hour, using a measuring cylinder. The evaporated water was also measured using the drop in water outside the pens. This amount of evaporated water is then subtracted from each of the drinkers inside the pens. 3.9 Experimental Design and statistical analysis: A complete randomized design was used in this study. The data was subjected to analysis of variance. The significance between treatment means was determined using Duncan Multiple Range test, and correlations for carcass evaluation is made. CHAPTER FOUR RESULTS Table (5) shows the overall performance of the experimental broiler chicks. With respect to body weight gain, chicks fed diet (2) (- ve) gained significantly (P<0.01) higher live weight (1616.26 g), followed by chicks fed diet (3) (-ve) (1222.98 g) and the lowest gain was recorded for chicks in the control group diet (1) (-ve) (590.7 g). Supplementation of these diets with the liquid amino acids solution in the drinking water, however, slightly improved weight gain of chicks. The highest improvement was attained by the chicks fed diet (2) (+ve) ( 1720.58 vs 1616.26 g). The chicks receiving diet (3) with amino acids supplementation recorded reduced lower improvement in body weight gain (1222.98 vs 829.45g), while the chicks reared on the control diet (1) were not affected by liquid amino acids supplementation with respect to body weight gain. The weekly response in body weight gain followed the same pattern (table 7) in the three groups, but with slight better and evident improvement in the chicks receiving diets 2 and 3, more evident as chicks approached the 5th and 6th weeks of age. Feed consumption of chicks fed the experimental diet ( Table 5) was significantly higher (P<0.01) in diet 2 group, followed by diet 3 group, and the lowest feed intake was recorded for chicks on the control diet (1) (3065.9, 1942.9, 1404.68 g respectively). Feed consumption was decreased following liquid amino acid supplementation for the chicks fed diet 2. A significant reduction in feed intake was recorded by the chicks fed diet 3 with liquid amino acid addition. However, there were no significant differences in feed consumption among the chicks fed the control diet (1). The weekly feed intake, Table (6) followed the same pattern as in diet 1, 2 and 3and in response to liquid amino acid supplementation. Feed conversion ratio (FCR) of chicks fed diet (2) (Table 5), was significantly higher (P<0.01) than that of chicks fed diets (3) and (1). Supplementation with liquid amino acid did not improved feed efficiency in all the three diet. The weekly feed conversion ratios on the experimental diets (Table 8) was variable with respect to the three diets through-out the 5th weeks, but became insignificant towards the 6th week of age. Table (5): Overall performance of the experimental broiler chicks. Initial BW Overall feed Overall body Overall (gm) intake (gm) weight gain (gm) FCR -ve 39.00ns 1404.68C 590.70d 1.69b +ve 37.00ns 1350.70c 590.70d 1.65b -ve 37.00ns 3065.96a 1616.26a 2.28a +ve 38.00ns 2836.98a 1720.58a 2.40a Diets Diet (1) grain + cake Diet (2) Grain + cake + Concentrate+ crystalline amino acids Diet (3) Grain + cake + -ve 39.00ns 1942.90b 1222.98b 1.81b Crystalline amino acids +ve 39.00ns 1500.25c 829.45c 1.73b - 39.72 26.62 0.11 N.S ** ** ** ±SEM Level of significant -ve = Without liquid amino acids +ve = With liquid amino acids. A, b, c, d= The column with different superscript differ significantly. ** = P<0.01 N.S = not significant Table (6): The mean weekly feed intake of the experimental broiler chicks (gm/bird). 1st week 2nd week 3rd week 4th Week 5th Week 6 th week Mean -ve 92.5b 125.7b 210.4b 211.4d 328.9b 460.9cd 238.3 +ve 79.3c 97.3b 155.8c 218.4d 359.9b 440.01d 225.13 -ve 99.8a 232.2a 428.1a 625.9a 741.6a 938.1a 510.95 +ve 90.5b 223.2a 405.4a 584.5a 662.9a 920.2a 481.12 -ve 90.5b 126.0b 244.5b 436.2b 368.4b 679.3b 324.03 +ve 90.8b 99.5b 203.9b 284.2c 286.3b 565.8b 250.03 Diets Diet (1) Grain + cake Diet (2) Grain + cake + Concentrate+ crystalline amino acids Diet (3) Grain + cake + crystalline amino acids + SEM Level of significant 0.6612 14.2075 13.9122 ** ** ** 20.1186 51.6249 26.3816 ** ** ** -ve = Without liquid amino acids in water. +ve = With liquid amino acids in water. A, b, c, d= The column with different superscript differ significantly. ** = P<0.01 Table (7): The means weekly body weight gain of the experimental broiler chicks (gm/bird). 1st 2nd 3rd 4th 5th 6th week week Week week week Week -ve 30.2c 44.3c 71.9d 109.0c 179.3cd 256.0bc 115.12 +ve 27.3c 39.2c 67.6d 93.7c 136.9d 165.5c 88.37 -ve 66.9a 175.8a 313.0a 416.3a 396.4a 448.0a 302.73 +ve 60.8a 173.3a 295.7a 389.1a 392.2a 409.5a 286.77 -ve 60.8a 173.3a 295.7a 389.1a 392.2a 409.5a 286.77 +ve 43.5b 71.7b 147.5b 211.2b 275.3b 373.9a 187.18 + SEM 3.60 7.07 8.79 16.90 22.03 46.05 Level of significant ** ** ** ** ** ** Mean Diet (1) Grain + cake Diet (2) Grain + cake + concentrate+ crystalline amino acids Diet (3) Grain + cake + crystalline amino acids -ve = Without liquid amino acids in water +ve = With liquid amino acids in water. A, b, c, d= The column with different superscript differ significantly. ** = P<0.01 Table (8): The means weekly feed conversion ratios of the experimental chicks 1st week 2nd week 3rd Week 4th week 5th week 6 Week Mean -ve 3.1a 2.8b 3.0a 1.9bc 1.9b 2.3ns 2.5 +ve 3.0a 2.6c 2.3b 2.4a 2.7a 2.7ns 2.6 -ve 1.5c 1.3d 1.4c 1.5d 1.9a 2.1ns 1.6 +ve 1.5c 1.3d 1.4c 1.5d 1.7b 2.3ns 1.6 -ve 1.5c 4.0a 2.1b 1.8cd 1.3b 2.1ns 1.6 +ve 2.1b 1.8cd 1.7c 2.1ab 1.3b 1.9ns 1.8 + SEM 0.1572 0.1811 0.1063 0.1162 0.177 0.2602 Level of significant ** ** ** ** ** ** Diet (1) Grain + cake Diet (2) Grain + cake + concentrate + crystalline amino acids Diet (3) Grain + cake + crystalline amino acids -ve = Without liquid amino acids in water +ve = With liquid amino acids in water. A, b, c, d= The column with different superscript differ significantly. ** = P<0.01 Table (9) present the average daily water consumed per ml/bird . It can be seen that water consumption was reduced by about half when liquid amino acids were added compared to consumption. So that the addition of liquid amino acids reduced water consumption. Higher meat percentage was recorded in carcasses cuts of chicks reared on treatment (A), diet (2) of grain + cake + super concentrate + crystalline amino acids followed by treatment (C), of diet (3) grain + cake + crystalline amino acids, and the least meat yield per cuts was recorded in treatment (B), of diet (1) grain+cake. Moreover the addition of liquid amino acids in the drinking water had no significance effects of the performance in all birds group fed the three experimental (Table 10). Table (10): The meat to bone ratio (%): Treatments Parameters Breast meat TA% TD% TB% TE% TC% TF% 29.7 29.2 18.6 18.5 22 21.7 Breast bone 4.9 4.2 5.2 5.6 4.2 4.3 Thighs meat 15.1 15.5 15.2 14.8 11.4 12.8 Thighs bone 2.7 2.2 2.6 2.1 2.2 2.8 Drum sticks meat 13.3 13.7 12.0 10.8 10.4 12.2 Drum sticks bone 2.8 2.9 4.9 4.3 2.6 3.1 Back meat 9.1 9.1 9.2 9.3 7.8 9.6 Back bone 8.4 7.9 9.9 10.1 9.6 14.0 wing meat 7.7 8.1 6.3 5.6 4.5 4.9 Wing bone 4.0 4.3 5.6 6.6 4.2 4 Abdominal fat 2.2 2.5 1.3 1.4 1.5 2.5 TA: Diet (2) Grain + cake +concentrate + TB: Diet (1) Grain + cake. crystalline amino acid. TD: Diet (2) Grain + cake +concentrate + Diet (1) Grain + cake + crystalline amino acid + liquid amino TE: liquid amino acid in water. acid in water. TC: Diet (3) Grain + cake + crystalline TF: Diet (3) Grain + cake + amino acid. crystalline amino acid + liquid amino acid in water. CHAPTER FIVE DISCUSSION Currently, countless amount of work is being carried out to determine the digestibility and availability of amino acids in food and feeds (Nelson, et al., 1986, Parsons, et al., 1986 and Sato et al., 1987). Bioavailability of amino acids is most commonly assessed using chicks, turkey and rat growth assay (Netke and Scott, 1970, Cave and Williams, 1980 and Parson, et al., 1980). Knowledge of amino acids availability in feed ingredients will facilitate formulation of diets with the exact amount of amino acid required to promote animal performance at least cost. Growth has been shown to be positively correlated with the consumption of a limiting nutrients (Giminger, et al., 1957 and Netke, et al., 1969). The trial carried out in this study has an advantage in that it measured the utilization of particular essential amino acids for growth, namely lysine and methionine. A comparison between methods of supplementation of these amino acids for chick was also tested through this study. The data of overall performance revealed that birds fed the diet containing superconcentrate attained significantly (P<0.01) higher body weight gain, followed by the birds fed the diets containing crystalline amino acids. This finding agrees with findings noted by Hurwitz, et al., (1978), and Tilemam and Pesti, (1986 ). On the other hand, addition of liquid amino acids to the diet containing supper concentrate reduced significantly (P<0.01).The weight gain of the experimental birds, which agrees with reported this by Baker , (1997 ). The reduction of body weight gain of the experimental birds fed supper concentrate after the addition of liquid amino acids may be due to the excessive utilization of amino acids above the(NRC) requirements. This suggestion is confirmed by the finding of Acar, et al. (2001). Also Baker (1991) reported that DLM level in excess of the requirement would lead to toxicity and cause depression in feed intake, lower growth rate and reduced feed conversion efficiency. Slight improvement in body weight gain was recorded with addition of liquid amino acid for chicks fed crystalline amino acids. The utilization of liquid amino acids in drinking water has no effect on body weight gain for checks fed on sorghum and cakes only. Feed consumption of chicks fed the experimental diets was significantly higher (P<0.01) with the chicks fed superconcentrate, followed by the chicks fed crystalline amino acids. The lowest feed intake was attained by the chicks fed sorghum and cakes only. This finding agrees with the finding of Scott, et al(1982), who attributed the reduced feed intake to amino acid imbalance. The addition of liquid amino acids numerically reduced the feed consumption of the chicks fed superconcentrate. However, reduction in feed intake was recorded also for chicks fed crystalline amino acids, with liquid amino acids. However, there were no significant difference in feed intake among chicks fed these diets and the sorghum and cakes diet when liquid amino acids was added. These results agreed with the findings of Baker and Hans (1994), and Steven, et al., (1975). The feed conversion ratio of the experimental broiler chicks fed the three experimental diets followed the same pattern as the body weight gain and feed consumption. Moreover, the addition of liquid amino acids in the drinking water has no significant effects in the performance birds fed the three experimental diets. Carcass yield attained the highest value with the diet containing superconcentrate, but was significantly decreased (P<0.01) by the diet containing crystalline amino acids, and it reached its lowest value with the diet formulated from grain and cake only. These results are similar to the findings of Emmert et al., (1999) and Hurwitz et al.,(1998). Amino acids from the liquid source when added to drinking water decreased water consumption by %50. This may be attributed to severe unpleasant odor of liquid amino acids, as was observed by Baker(1977), when added low levels(not detailed) of liquid methionine to the drinking water of chicks, and observed a typical cabbage - like odor. Feed intake was also reduced on addition of liquid amino acids in drinking water as a result of depression of water intake. High cost but good result were found with the diet containing` superconcentrate without addition of liquid amino acids. The addition of amino acids in excess of the requirement may have caused amino acid imbalance. The second least performance was achieved by the diet containing crystalline amino acids, while the diet containing grain and cakes only attained the lowest performance. The poorest performance could be due to deficiency of the critical essential amino acids mainly lysine and methionine. Even the supplementation of liquid amino acids was not enough to overcome these deficiencies because water consumption was reduced drastically. The study suggests that the addition of liquid amino acids is not profitable and did not improve the broiler performance and meat yield beyond that obtained by the diet containing supperconcentrate (amino acids intact protein); and it is of no benefit when added to a basal diet consisting of sorghum+sesame meal+groundnuts, meal as the amino acids deficiency was not corrected by the addition of liquid amino acids. Since it increases the cost, and slight increase in diet contain crystalline amino acids, while it has no significant effect on both body weight, and body weight gain. Conclusion: According to the result of the present studies the following conclusion can be drawn: - Diets containing grain and cake only as a source of protein need to be supplemented with essential amino acids and superconcentrate. - Addition of lysine and methionine until the requirements was not enough so that we must add superconcentrate or increase the rate of the critical amino acids. - Addition of the liquid amino acids to the diet containing crystalline amino acids only give slight improved in weight gain. - Amino acids from the liquid source which were added to the drinking water decreased water consumption about (%50). - Addition of the liquid amino acids is not profitable and did not improved the performance and meat yield, and of no benefit when added to the three type of diets, since it increases the cost. REFERENCES Acar, N. Fatterson, P. H. and Barbato, G. F. (2001). Appetite suppressant activity of supplemental dietary amino acids and subsequent compensatory growth of broiler Poult. Sci. 80: 1215-1222. Acar, N., Moran, E. T., and. Bilgili, S. F (1991). Live performance and carcass yield of male broilers from two commercial strain crosses receiving rations containing lysine below and above the established requirement between six and eight weeks of age, Poult. Sci. 70: 2315-2321. Agristats, (2001). Annual live production. Agristats, Inc. Fort and lysine as partial substitutes for protein in finisher diets Br. Poult. Sci. 16: 189-200. Anderson, JO, Dobson, DC.(1982). Comparison of DL-methionine and its sodium salt in water solution in broiler starter diets with two chlorine levels. Poult. Sci. 61 (11): 2288-90. Annonymus,(a) Amino fuel liquid by Twinlab (320z), (2005), http://supplments 101. com/store/Amino fuel liquid 320z p/twiamino liq 32.htm. Annonymus,(b) liquid feed amino acids, nutritional specialist through latin American Jan (2005). http://www. Aspecialiesinc. com/ingles/aminoacids htm. Annonymus,(b) National Food Nutritional, Association (NNFA) (20022005). Swanson Health products. http://www. Bragg liquid Aminos. Com. Anonymous(c).(2000 -2004 ). Alimet ® feed supplement. COM AOAC (1990). Official methods of analyses. 50. ed. Association of official analytical chemist, Washington. DC. Austic, R. E. and Nesheim, M. C. (1990). Poultry production. 13th ed. by Austic R. E. and Nesheim. M. C., P. 204- 205. Baker, D. H. (1997). Ideal amino acid profiles for swine and poultry and their applications in feed formulation. Bio Kyowa Technol. Rev. 9: 1 - 24. Baker, D. H., (1977). Sulfur in non – ruminant nutrition. Natl. Feed Ingred. Assoc., One corporate place, suite 360, West Des Moines, IA. Baker, D. H., (1991). Amino acid tolerances of Swine and Poultry. NFIA. Nutr. Institute Hand book. Baker, D. H., and Han, Y. (1994). Ideal amino acids profile for chicks during the first three weeks post hatching Poult. Sci. 73: 1441-1447. Baker, D. H., Chung, T. K., (1992). Ideal protein for swine and poultry. Biokowa Publishing conference., St. Louis. P. 1-17. Bartov and Plavnik, (1998). Moderate excess of dietary protein increases breast meat yield of broiler chicks. Bedford, M. R., and Summers, J. D. (1985). Influence of the ratio of essential and non essential amino acids on performance and carcass composition of the broiler chick. Br. Poult. Sci., 26: 483-491 Behrends, B. R., and P. E. Waibel. (1975). Effect of age on the methionine plus cystine requerment of growing turkey. Poult. Sci. 55. 2008 (cited by Saadia). Bilgili, S. F., Moran, E. T, and Acar. N. (1992). Strain – cross response of heavy male broiler to dietary lysine in the finisher feed: Live performance and further processing yield. Poult. Sci. 71: 850858. Billphillips, Eas, (1998-2005). Americas vitamin of nutrition http://store. Yahoo.com/Americas nutrition /twinlglut 501.html. Bray, D. J. (1968). The effect of the ratio of corn to soybean protein in layer diet upon the response to supplemental amino acids. Poult. Sci. 47: 815- 821. Bray, D. J. (1970). The isoleucine and valine nutrition of young laying pullets as influenced by excessive dietary leucine. Poultary. Sci. 49:1334 -1341. Bregendabl, K. Sell. L. L. and Zimmerman. D. R. ( 2002). Effect of low – protein diets on growth performance and body composition of broiler chicks Poults. Sci . 81: 1156-1167. Cave, N. A. and Williams, C. J., (1980). A chick assay for availability of lysine in wheat Poult. Sci. 59: 799-804. Chung, E., Griminger, P., and Fisher, H. (1973). The lysine and sulphur amino acids requirements at two stages of growth in chicks, J. Nutr. 103: 117-122. Church, D. C. and Bond, W. G. (1976). Basic animal nutrition and feeding , USA. By D.C. Church P. 57. Cuca, M., and Jensen, L S (1990). Arginine requirement of starting broiler chicks. Poult. Sci. 69: 1377-1382. Damron B. L. and. Goodson, R. – Williams (1986). Liquid methionine as a drinking water supplement for broiler chicks Poult. Sci. 66: 1001-1006. Damron, B. L., and Flunker, L. K., (1992). 2-Hydroxy-4(methylthio) butanoic acids as a drinking water supplement for broiler chicks. Poult Sci. Nov; 761 (10): 1695-9. Deschepper, K., and Degroote. G. De (1995). Effect of dietary protein, essential and non – essential amino acids on the performance and carcass composition of male broiler chickens. Br. Poult. Sci. 36: 229-245. Dibner, J. J. and Knight, C. D. (1984). J. Nutr. 114:1716-1723. D'Mello, J. P. and Lewis. D. (1970). Amino acid inter action in chick nutrition. 2- inter relation ships between leucine, isoleucine and valine. British Poultry Science. 2: 313- 323. Edmonds, M. S., Parsons, C. M., and D. H. Baker, D. H. (1985). Limiting amino acids in low protein corn – soybean meal diets fed to growing chicks Poult. Sci. 64: 1519-1526. Emmert, J. L, M. Michele, W. Stephanie, D. Carl, M. and Baker, D H. (1999). Bioavailability of lysine from a liquid lysine source in chicks. Poult. Sci. 78: 383-386. Facher, B. I. and Jensen, L. S. (1989). Influence on performance of three to six – week – old broilers of varying dietary protein contents with supplementation of essential amino acids requirements. Poult. Sci., 68: 113-123. Fancher, D. I., and Jenson, L. S. (1987). Influence on performance of three to six weeks cold broilers of varying dietary protein contents with supplementation of essential amino acid requirements Poult. Sci. 68: 113-123. Featherston, W.R., and J. C. Rogler. (1978). Methionine – cystine interrelations in chicks fed diets containing suboptimal levels of methionine. J. Nutr. 108: 1954- 1958. Fernandez, S. R., Aoyagi, S. Han, Y. Parsons C. M and Baker, D. H (1994). Limiting order of amino acids in corn and soy bean meal for growth of the chick Pout. Sci. 73: 1887-1896. Fisher, C., (1984). Fat deposition in broilers. Pages 437- 470 in : Fats in animal nutrition, J. D. Wiseeman, ed Butter worths London, England. Fritts, J. Si., Burnham, D. J. and Waldroup. P. W. (2001). Relationship of dietary lysine level to the concentration of all essential A. A. in broiler diets. Poult. Sci., 80: 1472- 1479. Graber, G., Scott. H. M, Baker, D.H. (1971a). Sulfur amino and nutrition of the growing chick: Effect of age on the capacity of cystine to spare dietary methionine. Poult. Sci. 50: 1450 –1455. Graber., G., Scott, H. M, and D. H. Baker (1971b). Sulfur amino acid nutrition of the growing chick: Effect of age on the dietary methionine requerment. Poult. Sci. 50: 851- 858> Griggs, J. E., Harris, G. C and. Waldroup, P. W. (1971). The use of nutrient solutions for young turkey poults. Poultry Sci. 50: 1581 (Abstr.). Grimiger, P., Scott, H. M. and Forbes, R. M., (1957). Dietary bulk and amino acids requirements. J. Nutr. 62: 61-69. Han, Y. Suzuki, H Parson, C. M. and. Baker, D. H. (1992). Amino acid fortification of low protein corn, soybean meal diet for maximal weight gain and feed efficiency of the chick. Poult. Sci. 71: 1168-1178. Han, Y., and Baker, D. H. (1991). Lysine requirement of fast and slow growing broiler chicks. Poult. Sci. 70: 2108-2114. Han, Y., and Baker. D. H., (1993). Effects of sex, heat stress, body weight and genetic strain on the dietary lysine requirement of broiler chicks. Poult. Sci., 72: 701- 708. Han, Y., and Baker. D. H., (1994). Digestible lysine requirement of mail and female broiler chicks during the period three to six weeks post hatching. Poult. Sci., 73:1739-1745. Holsheimer, J. P. and Veerkamp, C. H. (1992). Effect of dietary energy, protein, and lysine content on performance and yields of two strains of male broiler chicks. Poultry Science, 71: 872-879. Holsheimer, J. P., (1975). The effect of changing energy– protein ratio on carcass composition of broilers. No. 45, Pages 1-10 in: Proceedings of the 2nd European symposium poultry meat, Oosterbeek, the Netherlands. Holsheimer, J. P., and Ruesink, E. W. (1993). Effect on performance carcass composition yield, and financial return of dietary energy and lysine levels in starter and finisher diet fed to broiler. Poultry .Sci. 72: 806 – 815. Hurwitz, S. Sklan, D. Talpaz, H. and Plavnik, I. (1978). The effect of dietary protein level on the lysine and arginine requirements of growing chickens. Poult. Sci. 77: 689-696. Ishibashi, T., and Kametaka, M (1985). Methionine requirements of chickens with various body weight Agric. Biol. Chem. 49: 3493-3500. Izquierdo, O. A., Parsons C. M. and Baker. D. H. (1988). Bioavailability of lysine in L – lysine Hcl. J. Anim. Sci. 66: 2590-2597. Jason, L. Emmert, Michel W. Douglas, Stephanie, D. Boling, Carl M. Parsons, and David H. Baker (1999). Bioavailability of lysine from a liquid lysine source in chicks Poult. Sci. 78: 383-386. Kidd, M. T., Kerr, D. J. Anthony, N. B (1997). Dietary interactions between lysine and threonine in broilers Poult. Sci. 76: 608614. Kienholz, E. W., Enos, H. L and. pherron, T. A. (1965). The effects of some water sources and treatments upon turkey performance. Poult. Sci. 44: 1390. (Abtstr.). Kim, K. S., Han, I. K., and Kwalk, C. H., (1986). The effect of substituting methionine and lysine on the performance of broiler chicks. Korean, J. Anim. Sci. S. 28 (11) 732-735. Klain, G. L., Scott, H. M. and Johnson, B. C (1960). The amino acids requirements of the growing chicks fed a crystalline amino acids diet. Poult. Sci. 39: 39-44. Knight, C. D., and Dibner, J. J. (1994). J. Nutr. 114: 2179 -2186. Kutma, U. S., and A. E. Harper. (1962). Amino acid balance and imbalance. IX. Effect of amino acid imbalance on blood amino acid pattern. Proc. Soc. Exp. Biol. Med. 110: 512- 517. Leung, P. M., Q. R. Roger, and A. W. Harper.(1968). Effect of amino acid imbalance in rats fed ad libtum, internal fed or force fed. J. Nutr.95: 474- 482. Lipshitein, B., Bornstein S., and Bartov, I. (1975). The replacement of some of the soybean meal by the first limiting amino acids in practical broiler diet. 3. Effects of protein concentration and amino acids supplementations in broiler finishing diets and fat deposition in the carcass Br. Poult. Sci. 16: 627-635. Lipshtein, B., and Bornstein, S. (1975). The replacement of some of the soybean meal by the first limiting amino acids in practical broiler diets. 2. Special additions of methionine male and female broiler chicks during the period three to six weeks post hatching. Poult. Sci. 73: 1739-1745. Lodhi,I. N., Singh, D. and Ichponani, J. S.(1976). Variation in nutrient content of feed stuff Rich in protein and Reassessment of the chemical methods for metabolizable energy estimation for poultry. J. Agric. Sci. Camb., 86:293- 303. May, J. D., (1979). Dietary lysine and serum thyroid hormone concentration.Poult. Sci. 58:1084. Merkley, J. W., (1976). Increased bone strength in coopreared broilers provided fluorinated water. Poult. Sci. 55: 1313-1319. Moran, E. T and. Bilgili, S. F. (1990). Processing losses, carcass quality, and meat yields of broiler chickens receiving diets marginally deficient to adequate in lysine prior to marketing. Poult. Sci. 69: 702-710. Moran, E. T., Bushong. R. D., and Bilgiili. S. F., (1992). Reducing crude protein for broilers while satisfying amino acids requirements by least cost formulation: Live performance litter composition and yield of fast food carcass cuts at six weeks. Poultry. Sci., 71: 1687- 1694. Muller, R. D, and S. L. Balluon. (1974). Response to methionine supplementation of leg horn hens fed low proteins cornsoybean meal diets. Poult. Sci. 53: 1463- 1475. Nakajima, T. K,. Kishi, T., Kusubae, H..W., and Kusustani, Y. (1985). Effect of L – threonine and Dl – tryeptophan supplementation to the low protein practical broiler finishing diet, Jpn. Poult. Sci. 22: 10-16. Nelson, T. S., Kirby, L. K. and Halley, J. T., (1986). Digestibility of crystalline amino acids and the amino acids in corn and poultry blend. Nutr. Rep. Int. 43: 903. Netke, S. P., and Scott, H. M., (1970). Estimates of the availability of amino acids in soybean oil meal of determined by chick growing assay; methiodology as applied to lysine. J. Nutr. 100: 281-288. Netke, S. P., Scott, H. M. and Allee, G. L., (1969). Effect of excess amino acids on the utilization of the first limiting amino acid in chick diets. J. Nutr. 99: 75-81. NRC (1984), Nutritional Research Council. Nutrient requirements of poultry. 8th ed. nath. Acad. Sci. Washington, DC. NRC, (1994). Nutrient Requirement of Poultry. 9th Ed. National Academy Press Washington, DC. Park B. C. and Austic. R. E. (2000). Isoleucine imbalance using selected mixtures of imbalancing amino acids in diets of the broiler chicks poultry Sci. 78. 1782-1789. Park, B. C. and Austic, R. E. (2000). Isoleucine imbalance using selected mixtures of imbalancing amino acids in diets of the broiler chicks. Poult. Sci. 79: 1782-1789. Paison, C. M., (1986). Determination of digestible and available amino acids in meat meal using convectional and cuecectomized cockerels or chick growing assays Br. J. Nutr. 56: 227. Paisons, C. M., Potter, L. M. and Shelton, J. R., (1980). Relative lysine potencies of eight analogues in diets of young turkey poultry Sci. 59: 1852-1859. Penz, Jr. Am. OUSO. Do Conceito de proteina ideal para monogastricos. In: Congresso international de zootecnia; porto Alegre, RGS. Anais; Porto A;egre; Farsul%senar, (1996). P. 71-85. Pettit. H., Pesti, G. M. and Bakalli, R. I. (2001). Development of procedures for determining the amino acid requirements of chickens by the indicator amino acid oxidation method. Poult. Sci. 80: 182-186. Phansalkar, S.V., P. M. Norton, L. E. Holt, and S. E. Snyderman. (1970). Amino acid inter relation ships: The effect of a load of leucine on the metabolism of isoleucine. Proc. Soc. Exp. Piol. Med. 134: 262- 263. Rhone,G,A.(1995). Poulnec animal nutrition Meeting the A. A. Requirement of poultry. American Soybean Association (p) No. 083/12/44 (Vol. P. O. 16). Robinson., F. E. Yu, M W. Clandinin. M. T and. Bodnar L (1990). Growth and body composition of broiler chickens in response to different regimes of feed restriction. Poultry. Sci., 69: 20742081. Roth, F. X., Ristic. M. Kreuzer, M. and Maurus, E. M. (1990). Aminosauren zusammensetzungdes Brustfleisches Von Broilers Fleischwirtschaft 70 (5): 608 -612. Salmon, R. E., Classen H. L and Millan, R. K. (1983). Effect of starter and finisher protein on performance, carcass grade, and meat yield of broiler Poult. Sci. 62: 837-845. Santoso, U. K. Tanaka, and S. Ohtani, (1995). Does feed – restriction refeeding program improve growth characteristics and body composition in broiler chicks. Anim. Sci. Tchnol. (JPN) 66: 715. Santoso, U.,K. Tanaka, and S. Ohtani, (1993).Effect of skip day feeding on growth performance and body composition in broilers. Asian. Australian J. Anim. Sci. 6: 451-461. Sato, H., Kobayashi, T. Jones R. W. and easter, R. A., (1987). Tryptophan availability of some feedstuffs determined by pig growth assay. J. Anim. Sci. 64: 191. Scott, M. L., Nesheim, M. C. and Young, R. T. (1982). Nutrition of the chicken. 3rd ed. pages 51-75. Shirley, R. L., (1970). Nutrients in water available to economic animals. Proc. Nutr. Counc. Annu. Am. Feed Manuf. Assoc., Chicago, IL. Shirley, R. L., (1974). Nutrients and toxic substances in water for livestock and poultry. Natl. Acad. Sci., Washington, D. C. Sibbald, I. R., and Wolynets, M. S. (1986). Effect of dietary lysine and feed intake on energy utilization and tissue synthesis by broiler chicks poultry Sci. 65: 98-105. Smith, T. K., and Austic., R. E, (1978). The branched – chain amino acid antagonism in checks. J. Nutr. 108: 1180- 1191. Stevan, S. S. Scott,. M. L. and Nesheim, M. C. (1975). The effect of methionine deficiency on body weight, feed and energy utilization in the chick. Poult. Sci 54 :1184-1188. Summers, J. D., Spratt, D. and Atkinson J. L., (1990). Restricted feeding and compensatory growth for broilers. Poultry. Sci., 64: 1855-1861. Swick, R. A., Cress Well D. C. Dibner J. J and Ivey, F. j (1990). Poultry Sci. 60 (supp1). Swick, R. A., Ivey F.J. and Dibnar,JJ.(1991).Poultry sci.70 (supp1). Tanaka, K., and Ohtani, S. (1995). Early Skip– day feeding of female broiler chicks fed high– protein realimentation diets. Performance and body composition. Poultry. Sci., 74: 494-501. Tanaka, k., Ohtani, S. and Shigeno, K. (1983). Effect of increasing dietary energy on hepatic lipogenesis in growing chickens. 2. Increasing energy by fat or protein supplementation. Poultry. Sci. 62: 452- 458. Thomas, D. P., Twining, P. V., Lossard. Jr Nicholson, J. L. and Rubin, M. (1979). Broiler chick studied with therionine and lysine margiland nutrition confluence for feed manufacturers March 15 and 16. Tilman, P. B. and Pesti, G. M. (1968). The response of female broiler chicks to corn soybean diet supplemented with methionine Poult. Sci. 65: 1741. Titus, H. W. and Fritz, J. C. (1971). The scientific feeding of chickens, 5th ed. The institute of printers and publishing Inc. USA. P. P. 121. Uzu, G., (1983). Broilers feed reduction of the protein level during finishing period. Effect of performance and fattening. (A. E. C. Documant No. 242. Commentary 36000 (France). Waibel, D. M., Fernandez, S. R. Person. C. M. and Baker D. H. (1996). Digestible threonine requirement of broiler chickens during the period three to six and six to eight weeks post hatching Poult. Sci. 75: 1253-1257. Wayne. IN. Woodham, A. A., and Deans, P. S. (1975). Amino acids requirement of growing chickens. Br. Poult. Sci. 16: 269-287. Appendix (B): The total amount of weekly amino acids drunk per bird/mg Diets Total Grain+ cake+ super concentrate+ crystalline 0.00000707 amino acids Grain + cake diet 0.00000707 Grain+ cake + crystalline amino acid 0.00000518 2ml of liquid amino acids per 1000ml water. 2ml of liquid amino acids contained 0.00025 mg of each amino acids. Appendix (C): The average of water evaporation, and temperature day/week. Treatment Week 1 Week 2 Week 3 Week 4 Week 5 Week 6 Temperature (°C) 39.46 39.47 39.46 38.48 38.49 39.51 Evaporation (ml) 0.1-0.2 0.2-0.3 0.2-0.3 0.3-0.4 0.4-0.5 0.4-0.5 Appendix (D) The total amount of individual amino acids intake per bird/mg lysine Phenylalanine Arginine Diet (1) Amino acids in water -ve +ve 7.02 6.80000441 9.83 9.50000441 25.28 24.30000441 14.05 14.05 13.50000441 13.50000441 Diet (2) Diet (3) -ve +ve -ve +ve 33.73 31.2000071 21.37 16.5000052 27.59 25.5300071 19.43 15.0000052 49.06 45.3900071 34.97 27.0000052 24.53 22.6960071 19.43 15.0000052 Diet Diet (1) grain + cake Diet (2) grain + cake + concentrate + crystalline amino acids Diet (3) grain + cake + crystalline amino acids -ve = without liquid amino acids +ve = with liquid amino acids Glysine Leucine 49.06 45.3900071 33.03 25.5000052 List of Tables Table (1): composition of liquid amino acids (each liter contains):----- 20 Table (2): Formulation of the Experimental Diets:------------------------ 22 Table (3): Calculated Composition of the Experimental Diets: --------- 23 Table (4): Proximate analysis of the Experimental Diets:---------------- 24 30 --- Table (5): Overall performance of the experimental broiler Chicks. Table (6): The means weekly feed intake of the experimental broiler chicks (gm).:-------------------------------------------------------------------- 31 Table (7): The means weekly body weight gain of the experimental broiler chicks (gm).: ----------------------------------------------------------- 32 Table (8): The means weekly feed conversion ratios of the experimental: ------------------------------------------------------------------33 Table (9): The Correlation between various measurements of carcass 35 --------------------------------------------------------------------- evaluation.: Table (10) The amount of water (W), and liquid amino acids (LA) consumed per bird/day/ml.:-------------------------------------------------- 37 Table (11): The total amount of amino acids drunk per bird:------------ 38 Table (12): The average of water evaporation, and temperature day/week: ----------------------------------------------------------------------------------39 ABSTRACT The experiment was conducted to determine the effect of liquid amino acids supplemented in the drinking water on the performance of the broiler. One hundred and ninety two chicks were used in this experimental. The chicks were fed three diets, diet (1) contained grain and cake (Sesame and Groundnut meal), diet (2) contained Grain + Cake + supperconcentrat and crystalline amino acids (lysine and methionine), and diet (3) contained Grain + Cake, and crystalline amino acids (lysine and methionine). Chicks fed one of these three diets were divide into two groups, group (1) offered water without liquid amino acids (-ve), group (2)offered water with liquid amino acids (+ve). The result reveled that the liquid amino acids supplemented in water has no significant effect on the general performance of the broiler chicks fed the three diets. Among the three diets, diet (2) attained significantly (P<0.01) the highest feed intake, body weight gain and live body weight, followed by diet (3). Chicks on diet (1) had significantly (P<0.01) the lowest feed intake and bode weight gain. Water consumption of birds on liquid amino acids was reduced about 50% compared with un treated water, and this could have been due to the odor of liquid amino acids (typical cabbage-like odor) which may reduced water appetite, although water is vital factor of metabolism, so the addition of liquid amino acids in the water for the broiler chicks was not profitable, since it increase the cost. Also the rate of evaporation increased, when the temperature was increased. Also there was positive correlation between meat and bone of the carcass when they were evaluated. ﻣﻠﺨﺺ اﻷﻃﺮوﺣﺔ ﺗﻬﺪف هﺬﻩ اﻟﺪراﺳﺔ ﻟﺘﺤﺪﻳﺪ ﺗﺄﺛﻴﺮ اﻻﺣﻤﺎض اﻻﻣﻴﻨﻴﺔ اﻟﺴﺎﺋﻠﺔ اﻟﻤﻀﺎﻓﺔ ﻓﻲ ﻣ ﺎء اﻟ ﺸﺮب ﻋﻠ ﻲ أداء آﺘﺎآﻴﺖ اﻟﻼﺣﻢ .اﺳ ﺘﺨﺪﻣﺖ ﻓ ﻲ ه ﺬﻩ اﻟﺘﺠﺮﺑ ﺔ ﻣﺎﺋ ﺔ وإﺛﻨ ﺎن وﺗ ﺴﻌﻮن آﺘﻜ ﻮت ،وﺗ ﻢ إﻋ ﺪاد ﺛﻼﺛ ﺔ أﻧﻮاع ﻣﻦ اﻟﻌﻼﺋﻖ اﻟﻤﺨﺘﻠﻔﺔ اﻟﺘﺎﻟﻴﺔ :ﻋﻠﻒ ﻣﻜﻮن ﻣﻦ اﻟﺬرة وأﻣﺒﺎز اﻟﺴﻤﺴﻢ واﻟﻔﻮل ،ﻋﻠ ﻒ ﻣﻜ ﻮن ﻣ ﻦ اﻟﺬرة وأﻣﺒﺎز اﻟﺴﻤﺴﻢ واﻟﻔﻮل وﺑﺪرة اﻷﺣﻤﺎض اﻻﻣﻴﺒﻴﺔ )ﻻﻳﺜﻴﻦ وﻣﺜﻴﻮﻧﻴﻦ( واﻟﻤﺮآ ﺰ ﺑﺎﻹﺿ ﺎﻓﺔ اﻟ ﻲ ﻋﻠﻒ ﻣﻜﻮن ﻣﻦ اﻟﺬرة وأﻣﺒﺎز اﻟﺴﻤﺴﻢ واﻟﻔﻮل وﻣﺴﺤﻮق اﻷﺣﻤﺎض اﻷﻣﻴﻨﻴﺔ. ﺗﻢ ﺗﻘﺪﻳﻢ اﻟﻌﻠﻒ ﻟﻜﻞ اﻟﻜﺘﺎآﻴﺖ ﻣﻦ اﻟﺜﻼﺛ ﺔ أﻧ ﻮاع ﻣ ﻦ اﻟﻌﻠﻴﻘ ﺔ ﻋﻠ ﻲ ﻣﺠﻤ ﻮﻋﺘﻴﻦ ،اﻟﻤﺠﻤﻮﻋ ﺔ اﻷوﻟﻲ اﻟﻤﻴﺎة ﺑﺪون اﻷﺣﻤﺎض اﻟﻤﻴﻨﻴﺔ اﻟﺴﺎﺋﻠﺔ ،واﻟﻤﺠﻤﻮﻋﺔ اﻟﺜﺎﻧﻴ ﺔ ﺗ ﻢ ﺗﻘ ﺪﻳﻢ اﻟﻤ ﺎء ﻟﻬ ﺎ وﺑ ﻪ أﺣﻤ ﺎض أﻣﻴﻨﻴ ﺔ ﺳ ﺎﺋﻠﺔ ) وأوﺿ ﺤﺖ اﻟﻨﺘ ﺎﺋﺞ أن إﺿ ﺎﻓﺔ اﻷﺣﻤ ﺎض اﻷﻣﻴﻨﻴ ﺔ اﻟ ﺴﺎﺋﻠﺔ ﻓ ﻲ اﻟﻤ ﺎء ﻟ ﻴﺲ ﻟ ﻪ ﺗ ﺄﺛﻴﺮ ﻣﻌﻨ ﻮي ﻋﻠ ﻲ اﻷداء اﻟﻌ ﺎم ﺑﺎﻟﻨ ﺴﺒﺔ ﻟﻜﺘﺎآﻴ ﺖ اﻻﺣ ﻢ .اﻟﻌﻠ ﻒ اﻟﺜ ﺎﻧﻲ أﻋﻄ ﻲ ﻣﻌﻨﻮﻳﺔﻋﺎﻟﻴ ﺔ ﻻﺳ ﺘﻬﻼك اﻟﻌﻠ ﻒ وﻣﻌ ﺪل اﻟﺰﻳ ﺎدة ﻓ ﻰ اﻟﻮزن،اﻟﻌﻠ ﻒ اﻟﺜﺎﻟ ﺚ اﻟ ﺬى أﻋﻄ ﻰ أﺛ ﺮ ﻣﻌﻨ ﻮى أﻗ ﻞ ﻻﺳ ﺘﻬﻼك اﻟﻌﻠ ﻒ وﻣﻌ ﺪل اﻟﺰﻳ ﺎدة ﻓ ﻰ اﻟ ﻮزن .أﻣ ﺎ اﻟﻌﻠ ﻒ اﻷول ﻓﻘ ﺪأﻋﻄﻰ أﻗ ﻞ أﺛ ﺮ ﻣﻌﻨ ﻮى ﻣﻘﺎرﻧ ﺔ ﺑ ﺎﻟﻌﻠﻒ اﻟﺜ ﺎﻧﻰ واﻟﺜﺎﻟﺚ ﻓﻰ اﺳﺘﻬﻼك اﻟﻌﻠﻒ وﻣﻌﺪل اﻟﺰﻳﺎدة ﻓﻰ اﻟﻮزن . وﻓ ﻰ ﺟﺎﻧ ﺐ اﺧ ﺮ ﻧﺠ ﺪ ان اﻟﻤ ﺎء اﻟﻤ ﻀﺎف اﻟﻴ ﻪ اﻷﺣﻤ ﺎض اﻷﻣﻴﻨﻴ ﺔ اﻟ ﺴﺎﺋﻠﺔ اﻟ ﺬى ﺗ ﺴﺘﻬﻠﻜﻪ اﻟﻜﺘﺎآﻴ ﺖ اﻧﺨﻔ ﻀﺖ ﻧ ﺴﺒﺘﻪ ﺣ ﻮاﻟﻰ %50ﻣﻘﺎرﻧ ﺔ ﺑﺎﻟﻤﺎءاﻟ ﺬى ﻟ ﻢ ﺗ ﻀﺎف اﻟﻴ ﻪ اﻷﺣﻤ ﺎض اﻷﻣﻴﻨﻴ ﺔ اﻟﺴﺎﺋﻠﺔ ،وهﺬا ﻳﻤﻜﻦ أن ﻧﻌﺰوﻩ اﻟﻰ اﻟﺮاﺋﺤﺔ اﻟﻐﻴﺮ ﻣ ﺴﺘﺤﺒﺔ ﻟﻸﺣﻤ ﺎض اﻷﻣﻴﻨﻴ ﺔ اﻟ ﺴﺎﺋﻠﺔ )وه ﻰ ﺗ ﺸﺒﻪ رﺋﺤﺔ اﻟﻘﺮﻧﺒﻴﻂ( ﻓﺘﻘﻠﻞ ﻣﻦ ﺷﻬﻴﺔ اﺳﺘﻬﻼك اﻟﻤﺎء .وﺑﻤﺎ أن اﻟﻤﺎء ﻋﻨﺼﺮ ﺣﻴﻮى ﻓﻰ ﻣﻌﺪل اﻷﻳﺾ ﻓﺎن اﺿ ﺎﻓﺔ اﻷﺣﻤ ﺎض اﻷﻣﻴﻨﻴ ﺔ اﻟ ﺴﺎﺋﻠﺔ ﻓ ﻰ اﻟﻤ ﺎء ﺗ ﺆﺛﺮ ﺳ ﻠﺒﺎ ﻓ ﻰ اﺳ ﺘﻬﻼك اﻟﻜﺘﺎآﻴ ﺖ ﻟﻠﻤ ﺎء ،وﺑﺎﻟﺘ ﺎﻟﻰ ﻻﺟﺪوى ﻣﻦ اﺿﺎﻓﺘﻬﺎ ،ﻻﻧﻬﺎ ﺗﺸﻜﻞ ﺗﻜﻠﻔﺔ اﺿﺎﻓﻴﺔ ﻣﻊ ﺗﻜﻠﻔﺔ اﻟﻌﻼﻳﻖ اﻟﺜﻼث. وﺑﺨﺼﻮص ﻣﻌﺪل ﺗﺒﺨﺮ اﻟﻤﺎء ﻧﺠ ﺪ أﻧ ﻪ ﻳﺰﻳ ﺪ ﺑﺰﻳ ﺎدة درﺟ ﺔ اﻟﺤ ﺮارة .وﻣ ﻦ ﻧﺎﺣﻴ ﺔ أﺧ ﺮى ﻟﻘ ﺪ وﺟﺪ أن هﻨﺎﻟﻚ ﻋﻼﻗﺔ اﻳﺠﺎﺑﻴﺔ ﻓﻰ ﻣﻌﺎﻣﻞ اﻻرﺗﺒﺎط ﺑﻴﻦ اﻟﻠﺤﻢ واﻟﻌﻈﻢ ﻟﻠﺬﺑﻴﺢ . Appendices Appendix (A): The Correlation between various measurements of carcass evaluation. Drum stick meat 0.958** Thigh bone Thigh meat Breast bone Breast meat Cold carcass Hot carcass 0.852** Drum stick bone 0.923** 0.976** 0.965** 0.943** 0.971** 0.994** 0.994** 0.813** 0.826** 0.947** 0.960** 0.968** 0.979** 0.965** 0.986** 0.995** 0.982** 0.814** 0.830** 0.945** 0.959** 0.977** 0.978** 0.964** 0.985** 0.961** 0.992** 0.747** 0.751** 0.942** 0.926** 0.953** 0.963** 0.992** 0.913** 0.956** 0.989** 0.691** 0.715** 0.924** 0.899** 0.929** 0.944** Thigh meat 0.937** 0.924** 0.973** 0.938** 0.751** 0.965** 0.971** 0.974** Thigh bone 0.961** 0.949** 0.964** 0.779** 0.820** 0.938** 0.985** Drum stick meat 0.943** 0.912** 0.937** 0.751** 0.791** 0.928** Drum stick bone 0.915** 0.874** 0.948** 0.708** 0.689** Back meat 0.839** 0.817** 0.753** 0.841** Back bone 0.853** 0.756** 0.717** Wing meat 0.932** 0.964** Wing bone 0.926** Abdominal fat Wing bone Wing meat Back bone Back meat Live weight 0.972** 0.953** 0.966** 0.849** Hot carcass 0.967** 0.961** 0.983** Cold carcass 0.966** 0.961** Breast meat 0.941** Breast bone Abdominal fat Table (9) The amount of daily water consumption bird/ml. Week 1 Week 2 Week 3 Week 4 Week 5 Week 6 Water Water Water Water Water Water Diets Diet (1) - Ve 0.314 0.523 0.601 0.630 0.661 0.680 Grain + cake + Ve 0.312 0.409 0.437 0.441 0.450 0.500 Grain + cake + - Ve 0.319 0.703 1.063 1.413 1.90 2.275 Concentrate + + Ve 0.318 0.409 0.532 0.712 0.97 1.138 - Ve 0.317 0.652 0.792 0.800 0.882 1.329 + Ve 0.315 0.401 0.450 0.490 0.615 0.730 Diet (2) Crystalline AA Diet (3) Grain + cake + Crystalline AA - Ve = Water without liquid amino acid. + Ve = Water with liquid amino acid.