Influences of dietary crude protein and stocking density on growth performance and body measurements of ostrich chicks

MAHROSE, KHALID M.; EL-HACK, MOHAMED E. ABD; AMER, SHYMAA A.

doi:10.1590/0001-3765201920180479

Abstract

Abstract: Thirty-six African Black ostrich chicks were used to investigate the effects of dietary crude protein (CP) levels (180, 210 and 240 g/kg), stocking density (4.5 and 3 m²/bird) and their interactions. A factorial arrangement was used to examine the impact of treatments on growth performance and body measurements of ostrich chicks during 2 to 10 weeks of the age. Results indicated that factors studied did not change growth performance traits. The highest value of protein efficiency ratio was observed in ostrich chicks fed diet contained 240 g/kg diet. Birds fed diet contained 240 g CP /kg diet and kept at stocking density of 3 m² per bird had numerically the highest protein efficiency ratio. Shank girth and tibiotarsus length decreased with increasing dietary CP level. Stocking density did not change values of body measurements, except tibiotarsus length at 6 weeks of age, which increased in birds kept at the lower density than the higher. Body height at 10 weeks of age was significantly affected by the interactions between dietary CP and stocking density. In conclusion, results affirmed that ostrich chicks can grow on diets containing low levels of CP (180-210 g/kg). Our results provide a comprehensive set of morphometric data for ostrich chicks as affected by the factors studied.

Key words
Crude Protein; stocking density; growth; body measurements; ostrich

INTRODUCTION

The fast increase in human population caused a continuous need for the increment of food resources, especially high-protein products like meat. This has increased per capita consumption of chicken, and thus, commercial farming has expanded to ostrich and it is increasing rapidly (LaudadioLAUDADIO V and TUFARELLI V. 2011. Influence of substituting dietary soybean meal for dehulled-micronized lupin (Lupinus albus cv. Multitalia) on early phase laying hens production and egg quality. Livest Sci 140: 184-188. and Tufarelli 2011, BouyehBOUYEH M, SEIDAVI AR, MOHAMMADI H, SAHOO A, LAUDADIO V and TUFARELLI V. 2017. Effect of climate region and stocking density on ostrich (Struthio camelus) productive performances. Reprod Domest Anim 52(1): 44-48. et al. 2017). Recent interest in ostrich farming has led to an increase in the demand for information about this bird and how to manage it in the commercial farms (MinkaMINKA N. 2004. Evaluation of the performance of farmed ostrich chicks to juvenile age in Northern Nigeria. Nigerian J Anim Sci 6: 1. 2004, CooperCOOPER RG, MAHROSE KM, EL-SHAFEI M and MARAI IF. 2008. Ostrich (Struthio camelus) production in Egypt. Tropic Anim Health Prod 40: 349-55. et al. 2008, El-SaftyEL-SAFTY S and MAHROSE KM. 2009. Evaluation of some phenotypic, physiological and egg quality traits of african black neck ostrich under arid desert conditions of Libya. Inter J Poult Sci 8: 553-558. and MahroseMAHROSE K, ELSAYED M, BASUONY H and GOUDA N. 2016. Effects of exposing ostrich eggs to doses of gamma radiation on hatchability, growth performance, and some blood biochemicals of hatched chicks. Environ Sci Poll Res 23: 23017-23022. 2009, Mahrose et al. 2016). To maximize profit, the ostrich industry must focus on increasing chick survivability, maximizing growth and reducing costs associated with feeding (CornettoCORNETTO T, ANGEL R and ESTEVEZ I. 2003. Influence of stocking density and dietary energy on ostrich (Struthio camelus) performance. Inter J Poult Sci 2: 102-106. et al. 2003, Bouyeh et al. 2017). The factors affecting growth in ostriches are similar to those affecting other avian species and include diet, rearing environment, genetic potential, management and health status. Literature on ostrich nutrition and available space is limited, particularly those pertaining to the early-life stage (IjiIJI P. 2005. Anatomy and digestive physiology of the neonatal ostrich (Struthio camelus) in relation to nutritional requirements. Recent Adv Anim Nutr 15: 165-170. 2005, Mahrose et al. 2015MAHROSE KM, ATTIA A, ISMAIL I, ABOU-KASSEM D and ABD EL-HACK ME. 2015. Growth performance and certain body measurements of ostrich chicks as affected by dietary protein levels during 2-9 weeks of age. Open Vet J 5: 98-102., SigoloSIGOLO S, ZOHRABI Z, GALLO A, SEIDAVI A and PRANDINI A. 2017. Effect of a low crude protein diet supplemented with different levels of threonine on growth performance, carcass traits, blood parameters, and immune responses of growing broilers. Poult Sci 96(8): 2751-2760. et al. 2017, Vahabi-AsilVAHABI-ASIL O, BOUYEH M, QOTBI A, KADIM IT, SEIDAVI A, CENTODUCATI G, LAUDADIO V and TUFARELLI V. 2017. Effects of a prebiotic on growth performance, blood parameters and immunity response of turkeys fed low protein diets. European Poult Sci 81: 1-12. et al. 2017).

Stocking density needed by ostrich chicks depends on the type of housing. Semi-intensive rearing of birds is the most widely used method and even during intensive keeping of ostriches in controlled environment houses it is advisable to let them out to minimize occurrence of leg problems (du PreezDU PREEZ J. 1991. Ostrich nutrition and management. In: Farrel DJ (Ed), Recent Advances in Animal Nutrition in Australia. University of New England, Armidale, Australia, p. 278-291. 1991). The aforementioned author added that the values of stocking density of broilers should not be directly applied to ostrich chicks. Providing adequate space to ostrich chicks could help diminish stress and consequently lead to improving survivability and growth rate (Cornetto et al. 2003). Ostrich chicks are raised under a wide range of stocking densities, ranging from 16 to 40 m² per bird (VerwoerdVERWOERD DJ. 1999. Rearing environments around the world. The ostrich: Biology, production and health, p. 191-216. 1999).

However, the development of ostrich industry is hampered by inadequate knowledge of nutritional requirements of this species, particularly those pertaining to the early-life stage (Iji 2005). Nutrition is an important part of poultry and ratite management. So, knowledge of nutrient needs during the various stages of growth, development and production of the ostrich is vital (CooperCOOPER RG. 2004. Ostrich (Struthio camelus) chick and grower nutrition. Anim Sci J 75: 487-490. et al. 2005). Nutrition of ostrich chicks must be correct, as they are most vulnerable up to the age of 3 months (Cooper 2004COOPER RG, ERLWANGER K and MAHROZE KM. 2005. Nutrition of ostrich (Struthio camelus var. domesticus) breeder birds. Anim Sci J 76: 5-10.). In order to increase profitability of ostriches, determination of nutrient requirements of ostriches is essential (CilliersCILLIERS S. 1998. Feedstuff evaluation, metabolisable energy and amino acid requirements for maintenance and growth in ostriches. 2. International Scientific Ratite Congress. Ratites in a competitive world, Oudtshoorn (South Africa), 21-25 Sep 1998. Dept. of Agriculture Western Cape. (Unpublished). et al. 1998). The inclusion of protein in feeds needs to be optimized for optimum performance as well as to minimize wastage (AhmedAHMED E, AZAHAN E and NORAZIAH M. 2011. Evaluation of dietary protein intake by growing ostriches. Asian J Poult Sci 5: 102-106. et al. 2011). Ostriches require rations with high protein content, which is an essential nutrient for optimum growth and development (Cooper 2004). Feeding costs are the largest expense in an ostrich production system, and protein is one of the most expensive components of the diet (CarstensCARSTENS P, SHARIFI A, BRAND T and HOFFMAN L. 2014. The growth response of ostrich (Struthio camelus var. domesticus) chicks fed on diets with three different dietary protein and amino acid concentrations. Br Poult Sci 55: 510-517. et al. 2014). Diverse recommendations concerning the protein content in starter diets (14.6-22% CP) of ostriches have been reported. Most ratite growers feed diets that contain 17-24% crude protein during brooding and growing (Cilliers 1998CILLIERS S, HAYES J, CHWALIBOG A, SALES J and DU PREEZ J. 1998. Determination of energy, protein and amino acid requirements for maintenance and growth in ostriches. Anim Feed Sci Technol 72: 283-293.). The protein deficiency, caused by either one or more limiting amino acids or an overall inadequate consumption of protein, will result in decreases in parameters such as growth rate, N retention, feed consumption and utilization (RedaREDA FM, ASHOUR EA, ALAGAWANY M and ABD EL-HACK ME. 2015. Effects of dietary protein, energy and lysine intake on growth performance and carcass characteristics of growing Japanese quails. Asian J Poult Sci 9(3): 155-164. et al. 2015). However, an over-consumption of protein results in the catabolism of amino acids through deamination and excretion as uric acid, which is both energetically and economically inefficient or in severe cases, ammonia toxicity (AlagawanyALAGAWANY M, ABD EL-HACK ME, ARIF M and ASHOUR EA. 2016a. Individual and combined effects of crude protein, methionine, and probiotic levels on laying hen productive performance and nitrogen pollution in the manure. Environ Sci Pollu Res 23(22): 22906-22913. et al. 2016a, bALAGAWANY M, ABD EL-HACK ME, FARAG MR, TIWARI R, SACHAN S, KARTHIK K and DHAMA K. 2016b. Positive and negative impacts of dietary protein levels in laying hens. Asian J Anim Sci 10: 165-174.). It is essential to try to meet the requirement of poultry as closely as possible in order to maximize production and profitability (Alagawany et al. 2014ALAGAWANY M, ABD EL-HACK ME, LAUDADIO V and TUFARELLI V. 2014. Effect of low-protein diets with crystalline amino acid supplementation on egg production, blood parameters and nitrogen balance in laying Japanese quails. Avian Biol Res 7(4): 235-243., RehmanREHMAN ZU, KAMRAN J, ABD EL-HACK ME, ALAGAWANY M, BHATTI SA, AHMAD G, SALEEM A, ULLAH Z, YAMEEN RMK and DING C. 2018. Influence of low-protein and low-amino acid diets with different sources of protease on performance, carcasses and nitrogen retention of broiler chickens. Anim Prod Sc 58(9): 1625-1631. et al. 2018).

The present study aimed at investigating the effects of stocking density and dietary crude protein levels on growth performance and body measurements of ostrich chicks during 2-10 weeks of age.

MATERIALS AND METHODS

The present work was carried out at the Ostrich farm, Faculty of Agriculture, Zagazig University, Zagazig city, Egypt. All experimental procedures were carried out according to the Local Experimental Animal Care Committee, and approved by the ethics of the institutional committee of the Department of Poultry, Faculty of Agriculture, Zagazig University, Zagazig, Egypt.

BIRDS, EXPERIMENTAL DESIGN AND DIETS

Thirty-six African Black unsexed ostrich chicks were allotted into 6 groups (6 chicks per group; each group had three sub-groups of equal numbers; 2 birds each) in factorial arrangement (3×2) to investigate the influences of 3 dietary protein levels (180, 210 and 240 g/kg) and 2 levels of stocking density (4.5 and 3 m² per bird) on growth performance (body weight, body weight gain, feed consumption, feed conversion ratio and protein efficiency ratio) of ostrich chicks during 2 to 10 weeks of age. In addition, body measurements (body height, neck length, neck diameter, thoracic girth, phalanges length, tarsometatarsus length, tarsometatarsus girth, tibiotarsus length and tibiotarsus girth) were measured at 6 and 10 weeks of age. Ingredients and composition of experimental diets of ostrich chicks are found in Table I. All diets were isocaloric.

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TABLE I
Ingredients and calculated analysis of ostrich chick diets.(g/kg as fed basis)

MANAGEMENT

Unsexed ostrich chicks of 2 weeks of age were randomly divided into 6 groups (of equal average body weight). Each chick was identified by shank tag. Chicks were kept indoors until 4 weeks of age and after that, they were allowed to practice outdoors during midday and kept indoors at night. Chicks were exposed to 16:8 h light/dark cycle and light intensity for all groups ranged between 24 and 50 Lux. All chicks were kept under similar managerial and hygienic conditions during the experimental period. Food was provided ad libitum to all groups during the experimental period. Fresh water was made available at all times.

DATA COLLECTION AND MEASUREMENTS

All chicks were individually weighed using an electronic balance accurate to 5 g and body weight was recorded at 2, 6 and 10 weeks of age. Daily body weight gain was calculated as the difference between the two successive weights and divided by the number of days. Feed consumption was weekly recorded for each group, and calculated as gram diet per bird by dividing feed consumption of the group by the number of birds in this group. Feed conversion ratio (g feed /g gain) was calculated. Protein efficiency ratio was calculated by dividing daily weight gain by protein intake. Linear dimensions of the body (body height, neck length, neck diameter, thoracic girth, phalanges length, tarsometatarsus length, tarsometatarsus girth, tibiotarsus length and tibiotarsus girth) were taken twice during the experimental period (at 6 and 10 weeks of age) to the nearest 0.5 cm with dressmaker’s flexible tape-measure and are described as follows; bird height was taken from claws to dorsal of the thorax. Thoracic girth was measured behind the shoulders at the notch in the junction between the cervical and thoracic vertebrae. Length of tibiotarsus was measured on the lateral side of the leg from the front of the patella to the back of the hock joint as described by DeemingDEEMING D, SIBLY R and MAGOLE I. 1996. Estimation of the weight and body condition of ostriches (Struthio camelus) from body measurements. Vet Rec 139: 210-213. et al. (1996). Tibiotarsus girth was taken from the mid. The length of the tarsometatarsus was measured on the caudal side of the leg from the back of the hock joint to the phalangeal joint. Tarsometatarsus girth was taken from the its mid.

STATISTICAL ANALYSIS

Data of the present study were statistically analyzed by ANOVA of 3×2 factorial design experiment. Differences between means were tested by DuncanDUNCAN DB. 1955. Multiple range and multiple F tests. Biometrics 11: 1-42.’s multiple range test at level of α = 0.05 (Duncan 1955). The statistical model used was:

Y_{i j k} = μ + C P_{i} + S D_{j} + C P S D_{i j} + e_{i j k}

Where: Y_ijk = an observation, μ = the overall mean, CP_i = fixed impact of crude protein levels, SD_j = fixed impact of stocking density, CPSD_ij = fixed impact of interaction between CP and SD levels and e_ijk = random error associated to each observation.

RESULTS

Results of live body weight and daily body weight gain as affected by dietary crude protein levels and stocking density are presented in Table II. It is obvious from the results that live body weight and daily body weight gain during the experimental periods were insignificantly affected by dietary crude protein levels, stocking density and their interactions. Results affirmed the occurrence of insignificant differences in body weight at 2 weeks of age among the different groups, a finding that gives an idea about the accuracy in distributing chicks among the treated feeding groups without any bias.

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TABLE II
Live body weight and daily body weight gain of growing ostrich as affected by dietary crude protein levels, stocking density and their interactions.

Results in Table III revealed that dietary crude protein level, stocking density and their interactions did not significantly alter feed consumption, feed conversion ratio and protein efficiency ratio. However, the highest value of protein efficiency ratio (1.19), during 2-10 weeks of age, was observed in ostrich chicks fed diet containing 240 g/kg, followed by those fed 210 g/kg CP then those fed 180 g/kg CP (1.01). Also, birds fed diet containing 240 g/kg CP and kept at stocking density of 3 m² per bird had insignificantly the highest protein efficiency ratio in comparison to the other groups (Table III).

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TABLE III
Feed consumption, feed conversion ratio and protein efficiency of growing ostrich as affected by dietary crude protein levels, stocking density and their interactions.

Table IV presents the effects of dietary protein levels, stocking density and their interactions on body measurements including body height, tibiotarsus length and tibiotarsus girth. It could be seen that each of shank girth and tibiotarsus length were decreased (P < 0.01) with increasing dietary protein level. Where, the highest values of shank girth and tibiotarsus length (9.1 and 18.4 cm, respectively) were observed in chicks fed 180 g/kg dietary protein level. The other body measurements were not significantly affected due to dietary protein level. Stocking density did not change values of body measurements, except tibiotarsus length at 6 weeks of age, which was increased (P < 0.05) in birds kept at 3 m²/ bird. Body height at 10 weeks of age was the exceptional measurement. It was significantly (P < 0.05) affected by the interactions among dietary protein levels and stocking density. Birds kept at a lower density and fed higher levels of crude protein had the higher values of body height.

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TABLE IV
Body dimensions (cm) of growing ostrich as affected by dietary crude protein levels, stocking density and their interactions.density

DISCUSSION

Growth performance traits of ostrich chicks are important for their rearing under different farming conditions and assessing the performance of rearing practices. Results of the present work demonstrated that extra protein consumed by birds could not be productively utilized by ostrich chicks and were probably eliminated via fecal nitrogen as reported in previous publications (Ahmed et al. 2011, Mahrose et al. 2015). However, BoveraBOVERA F, MARONO S, DI MEO C, IANNACCONE F, ATTIA Y and NIZZA A. 2011. Comparison of caecal and faeces fermentation characteristics of ostrich by in vitro gas production technique. Acta Agric Scand Section A-Anim Sci 61: 72-79. et al. (2011) claimed that feed containing 17% CP was optimum for ostrich chicks at 20 weeks of age and feeding growing ostriches on higher protein levels not only wasteful but also pollute the environment through the excretion of more unutilized nitrogen (AbdABD EL-HACK ME, EL-HINDAWY MM, ATTIA AI and MAHROSE KM. 2017. Does the use of distiller’s dried grains with solubles (DDGS) in layer diets affect the nutrients digestibility and manure pollution by nitrogen and phosphorous?. Environ Sci Poll Res 24(15): 13335-13343. El-Hack et al. 2017, 2018ABD EL-HACK ME, NORELDIN AE, MAHGOUB SA and ARIF M. 2018. Ways to Minimize Nitrogen Emissions in Agricultural Farms. In: Negm A and Abu-Hashim M (Eds), Sustainability of Agricultural Environment in Egypt: Part II: Soil-Water-Plant Nexus (The Handbook of Environmental Chemistry), vol. 77, Springer, Cham, p. 357-368.). Due to these explanations, growth rate of the ostriches appeared to be influenced by other environmental factors (DeemingDEEMING D and AYRES L. 1993. Factors affecting the rate of growth of ostrich (Struthio camelus) chicks in captivity. Vet Rec 135: 617-622. and Ayres 1993), such as stocking density. In addition, BunterBUNTER K. 2002. The genetic analysis of reproduction and production traits recorded for farmed ostriches (Struthio camelus). PhD thesis, University of New England, Armidale. (Unpublished). (2002) demonstrated that variability in growth rates in ostrich chicks is attributed to general factors such as season, diet, aspects of social behavior and health. Ahmed et al. (2011) reported that ostrich chicks aged between 10 to 14 weeks of age and fed diets containing 22.5 and 17.5% CP insignificantly consumed more feed, grew better and were more efficient in converting feed to body weight than birds fed diet containing 12.5% CP. Carstens et al. (2014) found insignificant differences between the high (23.48% CP) and low (16.8% CP) diets on body weight gain during the first 7 weeks of age, insignificant differences between the high and medium (20.28% CP) diets on body weight gain during the first eleven weeks of age and insignificant differences between the medium and low diets on body weight gain during the first fourteen weeks of age. Our results are similar to those obtained by BrandBRAND T, NELL C and VAN SCHALKWYK S. 2000. The effect of dietary energy and protein level on the production of growing ostriches. South African J Anim Sci 30: 15-16. et al. (2000) who concluded that dietary protein levels (13, 15 and 17%) had no effect on the growth performance of ostrich chicks during 16 to 44 weeks of age. GandiniGANDINI H and BURROUGHS G. 1986. Preliminary investigation into the nutrition of ostrich chicks (Struthio camelus) under intensive conditions. J South African Vet Assoc 57: 39-42. and Burroughs (1986) showed comparable results, where ostrich chicks, aged up to 8 weeks of age, fed diets of different protein levels (14, 16, 18 and 20%), no differences were found in growth performance among diets with 16, 18 or 20% protein, while birds on these diets performed better compared to those on a 14% protein diet and those received 20% CP showed the superior feed conversion. Vahabi-Asil et al. (2017) assured that dietary protein level had a significant effect on body weight gain and feed conversion ratio of turkeys during the finisher phase.

In the present work, the best ratio of feed conversion (3.8 g feed / g gain) was seen in the group of chicks that fed on 180 g/kg CP diet during the whole period (2-10 weeks of age). The average of the feed conversion ratio from hatch to 9 months of ostrich age ranges from 3.6 to 3.9 (Bunter 2002), so our results are in that range. Ahmed et al. (2011) indicated that ostrich chicks during 10-14 weeks of age fed diets containing 22.5 or 17.5% CP consumed more feed and were more efficient in converting feed than birds fed diets containing 12.5% CP. However, the later author added that the differences between the two diets contained 22.5 and 17.5% CP were inconsistent and not significant on feed consumption and feed conversion ratio. The inability of the digestive tract of the ostrich chicks to secrete trypsin immediately after hatching constitutes a major difference between this species and broiler chickens (Iji 2005). This suggests that utilization of dietary protein during early life will be less efficient in the ostrich than in poultry. Commercial diets for ostriches are still based on poultry formulations, but it is unlikely that the high levels of dietary protein used in broiler chicken diets will be efficiently utilized by the neonatal ostrich. The activity of amylase is low and remains relatively unchanged from hatch until 72 days of age (Mahrose et al. 2015).

AmadoAMADO MF, XAVIER DB, BOERE V, TORRES-PEREIRA C, MCMANUS C and BERNAL FEM. 2011. Behaviour of captive Ostrich chicks from 10 days to 5 months of age. Rev Brasil Zootec 40: 1613-1618. et al. (2011) indicated that ostrich chicks walked and ran more than when they were older. In turn, it means that ostrich chicks may need more space to show their behavior and grow better. Space requirements for ostriches vary slightly according to type of accommodation. However, from a welfare point of view, 0.5 m² of floor space per bird during the first three weeks is generally recommended, increasing to 0.7 m² up to five weeks. From about five weeks of age (depending on weather conditions), the chicks should be allowed out for about one hour daily (ShanawanySHANAWANY MM and DINGLE JH. 1999. Ostrich production systems. Food and Agriculture Organization, 144, 256 p. and Dingle 1999). In this regard, in the study carried out by DegenDEGEN A, KAM M, ROSENSTRAUCH A and PLAVNIK I. 1991. Growth rate, total body water volume, dry-matter intake and water consumption of domesticated ostriches (Struthio camelus). Anim Sci 52: 225-232. et al. (1991), ostrich chicks were kept at stocking density of 1 bird/m². Overcrowding during the brooding and rearing stages can lead to slow growth rates. In an experiment conducted by Cornetto et al. (2003) on ostrich chicks aged between 21 to 98 days, they found that there were significant differences in body weight gain only during 28 to 56 days of age, where ostrich chicks kept in the lower stocking density (33.5 m²/bird) had the higher body weight gain. However, they did not find significant changes in feed conversion ratio due to stocking density, but they concluded that the stocking density of 16 m² per bird was found to maximize chicks’ performance. In our study, feed conversion ratios were higher than what was reported by the latter author. In line, Bouyeh et al. (2017) found no significant impact for stocking density on productive and reproductive performance of ostriches.

Measuring body dimensions could be a useful tool to estimate body weight and the area of the skin (BezuidenhoutBEZUIDENHOUT AG and SCHALKWYK SJV. 1996. Improving our understanding of ratites in a farming environment. In: Deeming DC (Ed), Ratite Conference, 5 p. and Schalkwyk 1996, Deeming et al. 1996, AliALI SYA. 2004. Genetical and physiological studies of some productive traits in ostrich (Struthio camelus). M.Sc. Thesis, Faculty of Agriculture. Minufiya University, Shibin El-Kom, Egypt. (Unpublished). 2004) that is a way to predict profit at marketing and to solve one of the main problems in ostrich trading, which is the cheating in age or weight of chicks in some areas. Body condition of ostriches is very important to avoid obesity and loss of weight is an important indicator of malnutrition (Deeming et al. 1996). The same author added that the body measurements are important in aiding the calculation of dosage of medications. The later authors added that tibiotarsus length in growing ostriches up to sub-adults (less than two years of age) ranged from 10 to 64 cm. MushiMUSHI EZ, ISA JF, CHABO RG and SEGAISE TT. 1998. Growth rate of ostrich (Struthio camelus) chicks under intensive management in Botswana. Tropic Anim Health Prod 30: 197-203. et al. (1998) pointed out that the average of body height rapidly increased reaching 134 cm in the 16^th week, and this is very close to what is reported in the present study with taking age into consideration. Body measurements in the present study are higher than those reported by Ali (2004) at 75 days of age.

The results of the present study indicated that ostrich chicks (during 2-10 weeks of age) could grow on diets containing low levels of CP (180-210 g/kg). The present study suggested the needs for further research on the protein requirements for ostrich. Also, our results imply that space availability for ostrich chicks during 2-10 weeks of age can influence their performance. Results of the present work provide a comprehensive set of morphometric data for ostrich chicks during 2-10 weeks of age as affected by dietary protein level, stocking density and their interactions, which could be useful for the breeders.

ACKNOWLEGMENTS

The authors would like to thank Zagazig University for the logistic support they received.

REFERENCES

ABD EL-HACK ME, EL-HINDAWY MM, ATTIA AI and MAHROSE KM. 2017. Does the use of distiller’s dried grains with solubles (DDGS) in layer diets affect the nutrients digestibility and manure pollution by nitrogen and phosphorous?. Environ Sci Poll Res 24(15): 13335-13343.
ABD EL-HACK ME, NORELDIN AE, MAHGOUB SA and ARIF M. 2018. Ways to Minimize Nitrogen Emissions in Agricultural Farms. In: Negm A and Abu-Hashim M (Eds), Sustainability of Agricultural Environment in Egypt: Part II: Soil-Water-Plant Nexus (The Handbook of Environmental Chemistry), vol. 77, Springer, Cham, p. 357-368.
AHMED E, AZAHAN E and NORAZIAH M. 2011. Evaluation of dietary protein intake by growing ostriches. Asian J Poult Sci 5: 102-106.
ALAGAWANY M, ABD EL-HACK ME, ARIF M and ASHOUR EA. 2016a. Individual and combined effects of crude protein, methionine, and probiotic levels on laying hen productive performance and nitrogen pollution in the manure. Environ Sci Pollu Res 23(22): 22906-22913.
ALAGAWANY M, ABD EL-HACK ME, FARAG MR, TIWARI R, SACHAN S, KARTHIK K and DHAMA K. 2016b. Positive and negative impacts of dietary protein levels in laying hens. Asian J Anim Sci 10: 165-174.
ALAGAWANY M, ABD EL-HACK ME, LAUDADIO V and TUFARELLI V. 2014. Effect of low-protein diets with crystalline amino acid supplementation on egg production, blood parameters and nitrogen balance in laying Japanese quails. Avian Biol Res 7(4): 235-243.
ALI SYA. 2004. Genetical and physiological studies of some productive traits in ostrich (Struthio camelus). M.Sc. Thesis, Faculty of Agriculture. Minufiya University, Shibin El-Kom, Egypt. (Unpublished).
AMADO MF, XAVIER DB, BOERE V, TORRES-PEREIRA C, MCMANUS C and BERNAL FEM. 2011. Behaviour of captive Ostrich chicks from 10 days to 5 months of age. Rev Brasil Zootec 40: 1613-1618.
BEZUIDENHOUT AG and SCHALKWYK SJV. 1996. Improving our understanding of ratites in a farming environment. In: Deeming DC (Ed), Ratite Conference, 5 p.
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BOVERA F, MARONO S, DI MEO C, IANNACCONE F, ATTIA Y and NIZZA A. 2011. Comparison of caecal and faeces fermentation characteristics of ostrich by in vitro gas production technique. Acta Agric Scand Section A-Anim Sci 61: 72-79.
BRAND T, NELL C and VAN SCHALKWYK S. 2000. The effect of dietary energy and protein level on the production of growing ostriches. South African J Anim Sci 30: 15-16.
BUNTER K. 2002. The genetic analysis of reproduction and production traits recorded for farmed ostriches (Struthio camelus). PhD thesis, University of New England, Armidale. (Unpublished).
CARSTENS P, SHARIFI A, BRAND T and HOFFMAN L. 2014. The growth response of ostrich (Struthio camelus var. domesticus) chicks fed on diets with three different dietary protein and amino acid concentrations. Br Poult Sci 55: 510-517.
CILLIERS S. 1998. Feedstuff evaluation, metabolisable energy and amino acid requirements for maintenance and growth in ostriches. 2. International Scientific Ratite Congress. Ratites in a competitive world, Oudtshoorn (South Africa), 21-25 Sep 1998. Dept. of Agriculture Western Cape. (Unpublished).
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DEEMING D and AYRES L. 1993. Factors affecting the rate of growth of ostrich (Struthio camelus) chicks in captivity. Vet Rec 135: 617-622.
DEEMING D, SIBLY R and MAGOLE I. 1996. Estimation of the weight and body condition of ostriches (Struthio camelus) from body measurements. Vet Rec 139: 210-213.
DEGEN A, KAM M, ROSENSTRAUCH A and PLAVNIK I. 1991. Growth rate, total body water volume, dry-matter intake and water consumption of domesticated ostriches (Struthio camelus). Anim Sci 52: 225-232.
DU PREEZ J. 1991. Ostrich nutrition and management. In: Farrel DJ (Ed), Recent Advances in Animal Nutrition in Australia. University of New England, Armidale, Australia, p. 278-291.
DUNCAN DB. 1955. Multiple range and multiple F tests. Biometrics 11: 1-42.
EL-SAFTY S and MAHROSE KM. 2009. Evaluation of some phenotypic, physiological and egg quality traits of african black neck ostrich under arid desert conditions of Libya. Inter J Poult Sci 8: 553-558.
GANDINI H and BURROUGHS G. 1986. Preliminary investigation into the nutrition of ostrich chicks (Struthio camelus) under intensive conditions. J South African Vet Assoc 57: 39-42.
IJI P. 2005. Anatomy and digestive physiology of the neonatal ostrich (Struthio camelus) in relation to nutritional requirements. Recent Adv Anim Nutr 15: 165-170.
LAUDADIO V and TUFARELLI V. 2011. Influence of substituting dietary soybean meal for dehulled-micronized lupin (Lupinus albus cv. Multitalia) on early phase laying hens production and egg quality. Livest Sci 140: 184-188.
MAHROSE K, ELSAYED M, BASUONY H and GOUDA N. 2016. Effects of exposing ostrich eggs to doses of gamma radiation on hatchability, growth performance, and some blood biochemicals of hatched chicks. Environ Sci Poll Res 23: 23017-23022.
MAHROSE KM, ATTIA A, ISMAIL I, ABOU-KASSEM D and ABD EL-HACK ME. 2015. Growth performance and certain body measurements of ostrich chicks as affected by dietary protein levels during 2-9 weeks of age. Open Vet J 5: 98-102.
MINKA N. 2004. Evaluation of the performance of farmed ostrich chicks to juvenile age in Northern Nigeria. Nigerian J Anim Sci 6: 1.
MUSHI EZ, ISA JF, CHABO RG and SEGAISE TT. 1998. Growth rate of ostrich (Struthio camelus) chicks under intensive management in Botswana. Tropic Anim Health Prod 30: 197-203.
REDA FM, ASHOUR EA, ALAGAWANY M and ABD EL-HACK ME. 2015. Effects of dietary protein, energy and lysine intake on growth performance and carcass characteristics of growing Japanese quails. Asian J Poult Sci 9(3): 155-164.
REHMAN ZU, KAMRAN J, ABD EL-HACK ME, ALAGAWANY M, BHATTI SA, AHMAD G, SALEEM A, ULLAH Z, YAMEEN RMK and DING C. 2018. Influence of low-protein and low-amino acid diets with different sources of protease on performance, carcasses and nitrogen retention of broiler chickens. Anim Prod Sc 58(9): 1625-1631.
SHANAWANY MM and DINGLE JH. 1999. Ostrich production systems. Food and Agriculture Organization, 144, 256 p.
SIGOLO S, ZOHRABI Z, GALLO A, SEIDAVI A and PRANDINI A. 2017. Effect of a low crude protein diet supplemented with different levels of threonine on growth performance, carcass traits, blood parameters, and immune responses of growing broilers. Poult Sci 96(8): 2751-2760.
VAHABI-ASIL O, BOUYEH M, QOTBI A, KADIM IT, SEIDAVI A, CENTODUCATI G, LAUDADIO V and TUFARELLI V. 2017. Effects of a prebiotic on growth performance, blood parameters and immunity response of turkeys fed low protein diets. European Poult Sci 81: 1-12.
VERWOERD DJ. 1999. Rearing environments around the world. The ostrich: Biology, production and health, p. 191-216.

Publication Dates

Publication in this collection
08 Apr 2019
Date of issue
2019

History

Received
16 May 2018
Accepted
9 July 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[25] DUNCAN DB. 1955. Multiple range and multiple F tests. Biometrics 11: 1-42.

[26] EL-SAFTY S and MAHROSE KM. 2009. Evaluation of some phenotypic, physiological and egg quality traits of african black neck ostrich under arid desert conditions of Libya. Inter J Poult Sci 8: 553-558.

[27] GANDINI H and BURROUGHS G. 1986. Preliminary investigation into the nutrition of ostrich chicks (Struthio camelus) under intensive conditions. J South African Vet Assoc 57: 39-42.

[28] IJI P. 2005. Anatomy and digestive physiology of the neonatal ostrich (Struthio camelus) in relation to nutritional requirements. Recent Adv Anim Nutr 15: 165-170.

[29] LAUDADIO V and TUFARELLI V. 2011. Influence of substituting dietary soybean meal for dehulled-micronized lupin (Lupinus albus cv. Multitalia) on early phase laying hens production and egg quality. Livest Sci 140: 184-188.

[30] MAHROSE K, ELSAYED M, BASUONY H and GOUDA N. 2016. Effects of exposing ostrich eggs to doses of gamma radiation on hatchability, growth performance, and some blood biochemicals of hatched chicks. Environ Sci Poll Res 23: 23017-23022.

[31] MAHROSE KM, ATTIA A, ISMAIL I, ABOU-KASSEM D and ABD EL-HACK ME. 2015. Growth performance and certain body measurements of ostrich chicks as affected by dietary protein levels during 2-9 weeks of age. Open Vet J 5: 98-102.

[32] MINKA N. 2004. Evaluation of the performance of farmed ostrich chicks to juvenile age in Northern Nigeria. Nigerian J Anim Sci 6: 1.

[33] MUSHI EZ, ISA JF, CHABO RG and SEGAISE TT. 1998. Growth rate of ostrich (Struthio camelus) chicks under intensive management in Botswana. Tropic Anim Health Prod 30: 197-203.

[34] REDA FM, ASHOUR EA, ALAGAWANY M and ABD EL-HACK ME. 2015. Effects of dietary protein, energy and lysine intake on growth performance and carcass characteristics of growing Japanese quails. Asian J Poult Sci 9(3): 155-164.

[35] REHMAN ZU, KAMRAN J, ABD EL-HACK ME, ALAGAWANY M, BHATTI SA, AHMAD G, SALEEM A, ULLAH Z, YAMEEN RMK and DING C. 2018. Influence of low-protein and low-amino acid diets with different sources of protease on performance, carcasses and nitrogen retention of broiler chickens. Anim Prod Sc 58(9): 1625-1631.

[36] SHANAWANY MM and DINGLE JH. 1999. Ostrich production systems. Food and Agriculture Organization, 144, 256 p.

[37] SIGOLO S, ZOHRABI Z, GALLO A, SEIDAVI A and PRANDINI A. 2017. Effect of a low crude protein diet supplemented with different levels of threonine on growth performance, carcass traits, blood parameters, and immune responses of growing broilers. Poult Sci 96(8): 2751-2760.

[38] VAHABI-ASIL O, BOUYEH M, QOTBI A, KADIM IT, SEIDAVI A, CENTODUCATI G, LAUDADIO V and TUFARELLI V. 2017. Effects of a prebiotic on growth performance, blood parameters and immunity response of turkeys fed low protein diets. European Poult Sci 81: 1-12.

[39] VERWOERD DJ. 1999. Rearing environments around the world. The ostrich: Biology, production and health, p. 191-216.

Ingredients (g/kg as fed basis)180		Crude protein (g/kg diet)
Ingredients (g/kg as fed basis)180		210	240
Yellow Corn		377	438	462
Soybean meal 44 (%)		360	313	190
Gluten meal 62 (%)		26	0.0	20
Hay		72.5	94.0	200.0
Wheat bran		100.0	89.0	70.0
Molasses		8.5	12.5	9.5
Vit-min Premix#		12.5	10.0	8.0
DL Methionine		2.0	2.0	1.5
L-Lysine		4.0	4.0	1.5
Di Calcium phosphate		20.0	20.0	10.0
Limestone		15.0	15.0	25.0
NaCl		2.5	2.5	2.5
Calculated analysis (g/kg as fed basis)
CP (g/kg)	180		210	240
MJ/kg	10.3		10.4	10.3

Items		Live body weight (g)			Daily body weight gain (g/d)
Items		2 wks	6 wks	10 wks	2-6 wks	6-10 wks	2-10 wks
CP level
180		2961	6170^c	11263	114.6^c	181.9	148.3
210		2662	6453^b	11240	135.4^b	171.0	153.2
240		2797	7737^a	12921	176.5^a	185.1	180.8
Stocking density (m²/bird)
4.5		2800	6888	12049	146.0	184.4	165.2
3		2814	6686	11566	138.3	174.3	156.3
Interaction effect
CP level	Stocking density
180	4.5	2960	6517	11968	127.0	194.7	160.9
180	3	2962	5824	10557	102.2	169.0	135.6
210	4.5	2744	6181	11737	122.8	198.4	160.6
210	3	2580	6724	10743	148.0	143.5	145.8
240	4.5	2693	7964	12443	188.2	160.0	174.1
240	3	2900	7510	13399	164.7	210.3	187.5
SEM		105.94	12.84	14.27	2.72	2.87	2.17
Probabilities:
CP level		0.527	0.021	0.100	0.036	0.850	0.148
Stocking density		0.084	0.634	0.482	0.662	0.643	0.523
CP× Stocking density		0.203	0.455	0.334	0.426	0.153	0.502

Items		Feed consumption (g)			Feed conversion ratio(g feed/g gain)
Items		2-6wks	6-10wks	2-10wks	2-6wks	6-10 wks	2-10wks	2-6wks	6-10wks	2-10wks
CP level
180		584.8	826.6	705.7	5.4	4.7	5.1	1.23	1.17	1.16
210		538.5	702.6	620.6	4.5	4.4	4.4	1.14	1.18	1.18
240		522.8	785.3	654.0	3.0	4.6	3.8	1.01	1.16	1.19
Stocking density (m²/bird)
4.5		539.2	834.8	687.0	4.2	4.8	4.5	1.08	1.16	1.18
3		558.2	708.2	633.2	4.5	4.2	4.4	1.17	1.17	1.17
Interaction effect
CP level	Stocking density
180	4.5	592.8	894.5	743.6	4.7	4.7	4.7	1.23	1.21	1.21
	3	576.8	758.8	667.8	6.2	4.6	5.4	1.24	1.13	1.11
210	4.5	487.0	760.3	623.6	4.8	4.2	4.5	1.23	1.23	1.24
	3	590.1	644.9	617.5	4.1	4.5	4.3	1.06	1.12	1.13
240	4.5	537.8	849.8	693.8	2.9	5.5	4.2	0.79	1.05	1.10
	3	507.7	720.8	614.3	3.1	3.6	3.4	1.22	1.27	1.28
SEM		15.73	21.92	13.23	0.41	0.49	0.35	0.31	0.26	0.26
Probabilities:
CP level		.1643	10.736	9.920	0.060	0.919	0.089	0.403	0.990	0.968
Stocking density		0.428	32.419	11.722	0.670	0.291	0.754	0.525	0.891	0.948
CP × Stocking density		2.116	0.072	2.305	0.484	0.251	0.339	0.219	0.332	0.422

		Body height		Neck length		Neck diameter		Thoracic girth		Phalanges length		Shank length		Shank girth		Tibiotarsus length		Tibiotarsus girth
		6 wks	10 wks	6 wks	10 wks	6 wks	10 wks	6 wks	10 wks	6 wks	10 wks	6 wks	10 wks	6 wks	10 wks	6 wks	10 wks	6 wks	10 wks
CP level
180		89.8	141.4	33.5	51.5	10.5	15.4	52.85	79.3	12.4	18.7	22.9	32.8	9.1^a	11.6	18.4^a	37.8	52.8	27.4
210		77.7	146.0	29.5	52.0	9.8	14.5	51.4	86.3	10.9	16.8	21.0	34.0	7.5^c	12.3	10.6^c	37.8	51.4	27.5
240		86.7	154.0	32.6	59.2	9.8	14.7	56.8	74.2	12.1	14.8	22.1	31.0	8.3^b	13.3	12.8^b	40.2	56.8	29.7
Stocking density (m²/bird)
4.5		87.2	149.7	33.2	55.7	10.27	15.1	56. 4	78.2	12.3	17.3	23.0	323	8.3	12.9	15.2	39.8	56.6	28.8
3		82.2	144.68	30.5	52.8	9.9	14.6	50.7	81.6	11.3	16.2	20.9	32.8	8.3	11.9	12.6	37.3	50.7	27.5
Interaction effect
CP level	Stocking density
180	4.5	94.5	132.5	35.5	51.0	10.5	15.5	54.5	73.0	13.5	19.0	24.3	32.0	9.3	12.0	20.0	36.0	54.0	28.0
	3	85.0	150.3	31.5	52.0	10.5	15.3	51.0	85.5	11.3	18.3	21.5	33.5	9.0	11.3	16.8	39.5	51.0	26.8
210	4.5	77.0	156.5	30.0	54.0	10.0	15.5	53.8	91.0	10.8	16.5	21.1	35.0	7.1	12.5	11.5	41.0	53.8	26.5
	3	78.3	135.5	29.0	50.0	9.7	13.5	49.0	81.5	11.0	17.0	20.8	33.0	7.8	12.0	9.7	34.5	49.0	28.5
240	4.5	90.0	160.0	34.2	62.0	10.0	14.3	61.7	70.7	12.5	16.3	23.7	30.0	8.5	14.3	14.2	42.3	61.7	32.0
	3	83.3	148.0	31.0	56.3	9.5	15.0	52.0	77.7	11.7	13.3	20.5	32.0	8.2	12.3	11.5	38.0	52.0	27.3
SEM		2.62	3.50	0.99	1.52	0.20	0.32	1.70	2.83	0.44	1.03	0.90	0.95	0.20	0.38	0.99	1.17	1.70	1.00
Probabilities
CP level		0.178	0.253	0.252	0.078	0.336	0.517	0.404	0.226	0.384	0.116	0.737	0.514	0.000	0.179	0.000	0.624	0.404	0.624
Stocking density		0.354	0.408	0.187	0.319	0.534	0.427	0.097	0.548	0.316	0.441	0.313	0.814	0.862	0.151	0.046	0.309	0.097	0.550
CP× Stocking density		0.679	0.050	0.812	0.607	0.893	0.266	0.730	0.262	0.542	0.582	0.815	0.700	0.176	0.659	0.884	0.216	0.730	0.463