ABSTRACT

The effect of crude protein (CP), amino acid (AA), and dietary electrolyte balance (DEB) were evaluated on blood parameters, carcass traits, and broiler performance under heat stress (29-34°C). A total of 540 male chickens (Ross 308) were allocated to 12 diets with factorial arrangement 2 × 2 × 3, using a completely randomized design with three replicates of 15 chickens in grower (13 to 26 days) and finisher (27 to 42 days) periods. and 120, 220, and 320 mEq kg^-1 DEB. The level of 21% CP increased body weight gain (BWG) and decreased feed conversion ratio (FCR) at grower period (p < 0.05). In contrast, 20% CP level decreased BWG and increased FCR at finisher period (p < 0.05). Further, 20% CP level reduced blood sodium and blood electrolyte balance (p < 0.05). The highest blood electrolyte balance was achieved by DEB 320 mEq kg^-1 diet (p < 0.05). Broiler response to DEB in heat stress depended on the age of bird, length of exposure to high temperature and CP level of the diet. Under heat stress (29-34°C), the 21% CP level at grower period and 17% CP level at finisher period improved broiler BWG and FCR.

Keywords:
standard and additional of digestible amino acid; heat stress; carcass traits

RESUMO

O efeito de proteína bruta (PB), amino ácido (AA) e balanço alimentar eletrolítico (DAE) foi avaliado por parâmetros sanguíneos, características da carcaça e desempenho de aves de corte sob estresse calórico (29-34°C). Quinhentos e quarenta machos (Ross 308) foram alocados em 12 regimes alimentares num arranjo fatorial 2 × 2 × 3 totalmente aleatório com 3 repetições de 15 aves em períodos de crescimento (13 a 26 dias) e terminação (27 a 42 dias) e 120, 220 e 320 mEq kg^-1 DAE. Além disso, 21% de PB aumentou o ganho de peso corporal (GPC) e diminuiu a conversão alimentar (CAR) no período de crescimento (p < 0.05). Por outro lado, 20% de PB diminuiu GPC e aumentou CAR no período terminal (p < 0.05). O nível de 20% PB reduziu o sódio sanguíneo e o balanço eletrolítico sanguíneo (p < 0.05). O maior balanço eletrolítico sanguíneo ocorreu com DAE 320 mEq kg^-1 dieta (p < 0.05). A resposta das aves de corte a DAE no estresse calórico dependia da idade da ave, à exposição a altas temperaturas e ao nível de PB na dieta. Sob estresse calórico (29-34°C), 21% PB no período de crescimento e 17% de PB no período de terminação melhoraram o GPC e CAR das aves de corte.

Palavras-chave:
amino ácido padrão e adicional; estresse calórico; características da carcaça

Introduction

Nutrition and metabolism play an important role in the acid-base balance of broiler chickens (Borges, Silva, Maiorka, Hooge, & Cummings, 2004Borges, S. A., Silva, A. V. F., Maiorka, A., Hooge, D. M., & Cummings, K. R. (2004). Effects of diet and cyclic daily heat stress on electrolyte, nitrogen and water intake, excretion and retention by colostomized male broiler chicken. International Journal of Poultry Science 3(5), 313-321.; Olanrewaju, Wongpichet, Thaxton, Dozier, & Branton, 2006Olanrewaju, H. A., Wongpichet, S., Thaxton, J. P., Dozier, W. A., & Branton, S. L. (2006). Stress and acid-base balance in chickens. Poultry Science Journal 85(7), 1266-1274.) and eventually performance. Heat stress is one of the most problems in tropical regions to broiler production. Monovalent electrolytes, i.e., sodium (Na⁺⁾, potassium (K⁺⁾, and chloride (Cl⁻⁾ are the key minerals, which consider as dietary electrolyte balance (DEB, Na⁺ + K⁺ - Cl^-) (Mongin, 1981Mongin, P. (1981). Recent advances in dietary cation-anion balance: Applications in poultry. Proceeding of Nutrition Society 40(3), 285-294.; Borges, Silva, Ariki, Hooge, & Cummings, 2003aBorges, S. A., Silva, A. V. F., Ariki, J., Hooge, D. M., & Cummings, K. R. (2003a). Dietary electrolyte balance for broiler chickens under moderately high ambient temperatures and relative humidities. Poultry Science Journal 82(2), 301-308.), have the greatest impact on acid-base balance or pH of blood and tissues under heat stress (Borges et al., 2004Borges, S. A., Silva, A. V. F., Maiorka, A., Hooge, D. M., & Cummings, K. R. (2004). Effects of diet and cyclic daily heat stress on electrolyte, nitrogen and water intake, excretion and retention by colostomized male broiler chicken. International Journal of Poultry Science 3(5), 313-321.). High temperature accomplish with negative balance of minerals led to broiler respiratory alkalosis, decreased feed intake and growth performance (Belay & Teeter, 1993Belay, T., & Teeter, R. G. (1993). Broiler water balance and thermohalance during Thermoneutral and high ambient temperature exposure. Poultry Science Journal 72(1), 116-124.). The birds under heat stress fed diets with DEB of around 250 mEq kg^-1 showed better performance, well maintained blood physiological parameters [pH, HCO₃, pCO₂, hemoglobin (Hb), hematocrit (H), lymphocytes (L), and H to L ratio] and blood nutrients (glucose, Na, K and Cl) and also retained more strong ions (Na, K and Cl) (Ahmad & Sarwar, 2006Ahmad, T., & Sarwar, M. (2006). Dietary electrolyte balance: implications in heat stressed broilers. World's Poultry Science Journal 62(4), 638-653. ). On the other hand, the growth responses of broilers that consuming diets containing low CP at optimal requirement levels of limited AA (Lys, Met, and Thr) had similar to broiler performance fed diets based on National Research Council (NRC, 1994National Research Council. (1994). Nutrient requirements of poultry (9th ed.). Washington, DC: National Academy Press. ) recommendations (Safamehr, Narimani, & Nobakht, 2012Safamehr, A., Narimani, M., & Nobakht, A. (2012). Effects of electrolyte balance and dietary protein levels on production performance and carcass parameters in broiler chickens exposed to heat stress. Journal of Veterinary Research 67(3), 297-306.). Alternatively, DEB can affect nutrient metabolism, especially AA, in broiler (Murakami, Rondon, Martins, Pereira, & Scapinello, 2001Murakami, A. E., Rondon, E. O. O., Martins, E. N., Pereira, M. S., & Scapinello, C. (2001). Sodium and chloride requirements of growing broiler chickens (twenty-one to forty-two days of age) fed corn soybean diets. Poultry Science Journal 80(3), 289-294.). Reduction of nitrogen in poultry wastes and reduce environment pollution is primary consideration of these diets. So, CP levels in diets is depends on limited AA which supplemented in the diets. Therefore, it is necessary to be existent a balance among DEB, AA, and CP levels under heat stress to insure that optimal growth and well-being of broiler were attained. Keeping in view the role of strong ions to alleviate heat stress in broiler chicken and their different AA and CP requirements in this situation, a few publications investigated their interaction on broiler performance. Thus, an experiment was carried out to study the effects of crude protein, supplemental amino acids, and dietary electrolyte balance levels on some blood parameters, carcass traits and broiler performance under heat stress condition.

Material and methods

The experimental methods regarding Animal Care were approved by the Animal Ethics Committee of the Bu-Ali Sina University in Iran.

Husbandry, diets, and experimental design

The male broiler chickens (Ross 308) were fed with similar starter diet from 1 to 12 days of age (metabolisable energy, 2,950 kcal kg^-1 and CP, 21.45%). Experimental basal diet was formulated according to Ross 308 International (2013 -referenced) recommendation (Table 1). A total of 540 birds were allocated to 12 experimental diets consisted of three factor of CP (2 levels), AA (2 levels), and DEB (3 levels) with arranged a factorial using a completely randomized design (CRD). Each treatment was replicated 3 times with 15 chickens. Two periods: 1- grower (13-26 days of age) and finisher (27-42 days of age) were defined under heat stress condition (29-34°C) in all phases.

For grower period, 19% CP with digestible AA standard including [Methionine (Met): 0.245, Threonine (Thr): 0.500, and Lysine (Lys): 0.190%] and digestible AA additional levels including (Met: 0.280, Thr: 0.800, and Lys: 0.250%) as well as 21% CP with AA standard (Met: 0.200, Thr: 0.000, and Lys: 0.030%) and additional levels (Met: 0.240, Thr: 0.020, and Lys: 0.100%), and dietary electrolyte balance (DEB) 120, 220, 320 mEq kg^-1 was used (Table 1). Moreover, The 17% CP with digestible AA standard (Met: 0.180, Thr: 0.030, and Lys: 0.150%) and additional levels (Met: 0.210, Thr: 0.060, and Lys: 0.210%) and 20% CP with AA standard (Met: 0.110, Thr: 0.000, and Lys: 0.000%) and digestible additional levels (Met: 0.150, Thr: 0.000, and Lys: 0.000%), and DEB 120, 220, 320 mEq kg^-1 were used in finisher period (Table 2).

Feed and water were offered ad libitum. Light was provided for 24 hour day^-1 and gradually was reduced to 23 hour day^-1, and temperature was gradually reduced 3°C from the initial 32°C in each week. Feed intake (FI) and body weight gain (BWG) were measured weekly. Thus feed conversion ratio (FCR) was calculated.

Carcass traits

On 42 days of age, two birds from each replicate were randomLy selected, tagged, and weighted, then fasted for 8 hours (no limitation of water access) and were slaughtered. Carcass weight was measured after removal of feather, head, legs and abdominal contents. The abdominal fat dissected and recorded. The breast and thigh weights were calculated as the percentage of live body weights.

Blood parameters

On 42 days of age, two chickens selected randomLy from each replicate (n = 3) and blood taken from their wing vein and then immediately transferred on ice to laboratory. Serum samples were taken (centrifuged 3,500 × rpm for 15 min) and blood elements (Na, K, and Cl) were measured by ion selective electrode method of electrolyte analysis system (Kartium, Model E921-XI).

In addition, one extra chicken was selected from each replicate and 2 (for blood gases assay) and 1 mL (for blood cell count) blood were taken from their wing vein and transferred into heparin tubes. Blood cell counts, hemoglobin and hematocrit (Hk) was measured using cell counter (Model, ERMA-Japan). In addition, Gimsa stain was used to heterophile (H), and lymphocytes (L) measurement. Moreover, blood gas (CO₂, O₂, and HCO₃) concentrations were determined using 9950IVL system (Switzerland).

Statistical analysis

All data were analyzed with CP levels, AA levels, and DEB as factorial 2 × 2 × 3 using a completely randomized design by the GLM procedure of Statistical Analysis System (SAS, 2004Statistical Analysis System. (2004). SAS(r) user's guide: statistics. Cary, NC: SAS Institute Inc.). Significant differences were compared by Duncan's multiple range test (p ≤ 0.05).

Results

The effects of experimental diets on broiler performance at grower (13- 26 days of age) and finisher (27- 42 days of age) periods are presented in Tables 3 and 4, respectively. The 21% CP level increased BWG and improved FCR at grower period (p < 0.05). In contrast, BWG decreased and FCR increased by 20% CP at finisher period (p < 0.05). Other parameters did not affected by AA and DEB levels (p < 0.05) (Table 4). The effects of treatments on carcass traits of broiler chickens at 42 days are presented in Table 5. The results indicated that the level of 20% CP increased carcass percentage (p < 0.05) but other parameters or traits were not affected by AA and DEB levels. The results of diets on blood parameters of broiler chickens at 42 days of age are presented in Table 6. The results demonstrated that 20% CP level was significantly increased Hb concentration than 17% CP level (p < 0.05). Hematological profile of blood is good indicator of stress in birds. The results of blood gas concentration of broiler chickens in response to diets at 42 days of age are given in Table 7. The results indicated that CP, AA, and DEB levels had no significantly effects on blood pH, P_O2, P_CO2, and HCO₃ concentrations. Increased respiration rates induced by severe heat stress seemed necessary for evaporative cooling in broilers. The results of blood ingredient concentration of broiler chickens at 42 days of age are presented in Table 8. The results have shown that 20% CP level significantly reduced Na concentration and electrolyte balance than 17% CP level (p < 0.05). The highest electrolyte balance was achieved by the level of DEB 320 mEq kg^-1 other than treatments (p < 0.05).

Discussion

By using modern broiler chickens, the suitable DEB for starter and grower period reported 246-315 and 249-257 mEq kg^-1, respectively (Murakami et al., 2001Murakami, A. E., Rondon, E. O. O., Martins, E. N., Pereira, M. S., & Scapinello, C. (2001). Sodium and chloride requirements of growing broiler chickens (twenty-one to forty-two days of age) fed corn soybean diets. Poultry Science Journal 80(3), 289-294.) which are in contrast with results of current study. The results are in agreement with the findings of Temim et al. (1999Temim, S., Chagneau, A. M., Guillaumin, S., Michael, J., Peresson, R., Geraert, P. A., & Tesseraud, S. (1999). Effects of chronic heat exposure and protein intake on growth performance, nitrogen retention and muscle development in broiler chickens. Representative Nutrition Development 39(1), 145-156.), who reported that broilers feeding with high protein diets (25 vs. 20%) had higher BWG during grower period under heat stress condition (32°C). Because of the different levels of protein and strain of broiler, changes in nutrition requirements and metabolism, similar results did not observe in finisher period. Balnave and Oliva (1991Balnave, D., & Oliva, A. G. (1991). The influence of sodium bicarbonate and sulfur amino acids on the performance of broilers at moderate and high temperatures. Australian Journal of Agricultural Research 42(8), 1385-1397.) reported that maximum BWG and FI observed at 30°C with DEB 380 mEq kg^-1. Under moderate environmental condition, However, the effects of different DEB (87, 180, 280 and 380 mEq kg^-1) treatments were non-significant. Borges, Silva, Maiorka, Hooge, and Cummings (2004Borges, S. A., Silva, A. V. F., Maiorka, A., Hooge, D. M., & Cummings, K. R. (2004). Effects of diet and cyclic daily heat stress on electrolyte, nitrogen and water intake, excretion and retention by colostomized male broiler chicken. International Journal of Poultry Science 3(5), 313-321.) reported that DEB of 240 was most favorable for broilers in either temperature environment (22.5±3.5°C; and cyclic stress 22.5±3.5°C for 14 hours and 33±2.0°C for 10 hours). Borges, Silva, Ariki, Hooge, & Cummings (2003a) Borges, S. A., Silva, A. V. F., Ariki, J., Hooge, D. M., & Cummings, K. R. (2003a). Dietary electrolyte balance for broiler chickens under moderately high ambient temperatures and relative humidities. Poultry Science Journal 82(2), 301-308.reported that FI linearly increase with increasing of DEB (40-340 mEq kg^-1). Conflicting findings emphasized that the effects of DEB on broiler performance is diverse and seems depends on differences in basal diet, broiler strain, temperature of rearing and supplemented electrolyte salts. Moreover, increasing of CP levels with essential AA in 32°C temperature increased FI in male broiler chickens (Alleman & Leclercq, 1997Alleman, F., & Leclercq, B. (1997). Effects of dietary protein and environmental temperature on growth performance and water consumption of male broiler chickens. Journal of British Poultry Science38(5), 607-610.) that is in contrast with present study. This inconsistency could be related to differences in amount of CP levels and severity of heat stress condition. On the other hand, Flemming et al. (2001Flemming, J. S., Arruda, J. S., Souza, G. A., Fedalta, L. M., France, S. G., Fleming, R., ... Peron, I. (2001). Influence of dietary electrolyte balance on the performance traits of broiler. Archive Veterinary Science 6(3), 89-96. ) compared three different levels of high, modulate, and low DEB in broiler chickens during the summer, and indicated that DEB had no effect on BWG. In addition, Borges et al. (2003a) Borges, S. A., Silva, A. V. F., Ariki, J., Hooge, D. M., & Cummings, K. R. (2003a). Dietary electrolyte balance for broiler chickens under moderately high ambient temperatures and relative humidities. Poultry Science Journal 82(2), 301-308.pointed out that diets with DEB 240 mEq kg^-1 was showed the best BWG than diets with DEB 0, 120, and 360 mEq kg^-1 in broiler chicken at 23-30ºC. In this study, using 21% CP level in grower period and 17% CP level in finisher period had significant improvement on FCR than 19 and 20% CP levels in grower and finisher periods, respectively (p < 0.05). The results of present study are match with findings of Flemmnig et al. (2001)Flemming, J. S., Arruda, J. S., Souza, G. A., Fedalta, L. M., France, S. G., Fleming, R., ... Peron, I. (2001). Influence of dietary electrolyte balance on the performance traits of broiler. Archive Veterinary Science 6(3), 89-96. that FCR did not affect by various DEB levels. However, Borges et al. (2003a)Borges, S. A., Silva, A. V. F., Ariki, J., Hooge, D. M., & Cummings, K. R. (2003a). Dietary electrolyte balance for broiler chickens under moderately high ambient temperatures and relative humidities. Poultry Science Journal 82(2), 301-308. showed that 240 mEq kg^-1 DEB had best FCR comes before DEB than 120 and 360 mEq kg^-1 in broiler chickens under 30-32°C. The results showed that different CP, AA, DEB levels, and their interaction had not significantly effect on mortality. Results are in agreement of other researchers

(Flemming et al., 2001Flemming, J. S., Arruda, J. S., Souza, G. A., Fedalta, L. M., France, S. G., Fleming, R., ... Peron, I. (2001). Influence of dietary electrolyte balance on the performance traits of broiler. Archive Veterinary Science 6(3), 89-96. ; Borges et al., 2003aBorges, S. A., Silva, A. V. F., Ariki, J., Hooge, D. M., & Cummings, K. R. (2003a). Dietary electrolyte balance for broiler chickens under moderately high ambient temperatures and relative humidities. Poultry Science Journal 82(2), 301-308.), which no significant mortality was found by different DEB in broiler chickens under various temperature condition.

Kamran and Mirza (2004Kamran, Z., & Mirza, M. (2004). Effect of decreasing dietary protein levels with optimal aminoacids profile on the performance of broilers. Pakistan Veterinary Journal 24(4), 165-168.) observed that broiler carcass percentage significantly increased by fed diet with 20% CP in compared to 21, 22, and 23% CP levels. These results are in contrast with present study. No significant differences were obtained in other traits. Ahmad and Sarwar (2005Ahmad, T., & Sarwar, M. (2005). Influence of varying sources of dietary electrolytes on the performance of broilers reared in a high temperature environment. Animal Feed Science and Technology 120(3-4), 277-298.) showed that different sources of DEB supplemented with sodium bicarbonate increased significantly carcass weights, which supported the finding of current study. It is reported that DEB 40-340 mEq kg^-1 had no effects on abdominal fat and carcass percentage (Borges et al., 2003aBorges, S. A., Silva, A. V. F., Ariki, J., Hooge, D. M., & Cummings, K. R. (2003a). Dietary electrolyte balance for broiler chickens under moderately high ambient temperatures and relative humidities. Poultry Science Journal 82(2), 301-308.) which are inconsistence with the results of present study. Different experimental period (grower period) and severity of heat stress could explain to some extent of this inconsistency. Moreover, the similar breast and thighs percentage were reported in broiler chickens fed diets supplemented with Lys at 15-49 days of age (Holsheimer & Ruesink, 1993Holsheimer, J. P., & Ruesink, E. W. (1993). Effect of performance, carcass composition, yield and financial return of dietary energy and lysine levels in starter and finisher diet fed to broiler. Poultry Science Journal 72(5), 806-815.).

The differential leukocyte count and the monitoring of its changes in relation to effects of heat stress are an important part of the hematological profile of broilers (Ahmad & Sarwar, 2005Ahmad, T., & Sarwar, M. (2005). Influence of varying sources of dietary electrolytes on the performance of broilers reared in a high temperature environment. Animal Feed Science and Technology 120(3-4), 277-298.). In contrast with the results of present study, the finding of Safamehr, Narimani, and Nobakht (2012Safamehr, A., Narimani, M., & Nobakht, A. (2012). Effects of electrolyte balance and dietary protein levels on production performance and carcass parameters in broiler chickens exposed to heat stress. Journal of Veterinary Research 67(3), 297-306.) indicated that different levels of CP had no significant effect on broiler blood Hb concentration. Furthermore, 320 mEq kg^-1 level DEB increased Hk percentage than 220 mEq kg^-1 level but decreased H to L ratio (p < 0.05). No significant differences were observed on other parameters. Water loss by evaporation through respiration in heat stress induced an increase in plasma volume (hemodilution), that caused blood Hk and Hb values to be lowered down. Any therapy that increases blood Hk and Hb values in heat stress will be beneficial (Ahmad & Sarwar 2005Ahmad, T., & Sarwar, M. (2005). Influence of varying sources of dietary electrolytes on the performance of broilers reared in a high temperature environment. Animal Feed Science and Technology 120(3-4), 277-298.). Therefore, increasing DEB up to 320 mEq kg^-1 level could help to bearing of heat stress to broilers. The H and H to L ratio have been indicated to be reliable indicator to measure of stress (Zulkifli & Siegel, 1995Zulkifli, I., & Siegel, P. B. (1995). Is there a positive side to stress? World's Poultry Science Journal 51(1), 63-67.). Under heat stress the H increase and L decrease. Maxwell and Robertson (1998Maxwell, M. H., & Robertson, G. W. (1998). The avian heterophil leukocyte: a review. Poultry Science Journal 54(2), 155-178.) pointed out that moderate exposures to most stressors caused an increase in the number of H, and the H to L ratio in chickens. In contrast, Borges, Silva, Ariki, Hooge, and Cummings (2003bBorges, S. A., Silva, A. V. F., Ariki, J., Hooge, D. M., & Cummings, K. R. (2003b). Dietary electrolyte balance for broiler chickens exposed to thermoneutral or heat-stress environments. Poultry Science Journal 82(3), 428-435.) reported significantly low H to L ratio for DEB 240 than those of 40, 140 and 340 DEB in both thermoneutral and heat stressed rooms. The results of current study are in contrast with the finding of Safamehr et al. (2012)Safamehr, A., Narimani, M., & Nobakht, A. (2012). Effects of electrolyte balance and dietary protein levels on production performance and carcass parameters in broiler chickens exposed to heat stress. Journal of Veterinary Research 67(3), 297-306.. These could be due to differences in DEB levels, intensity of heat stress, or bird. Increasing blood Hk was

matched with results of other researchers (Zhou, Fujita, & Yamamoto, 1999Zhou, W. T., Fujita, M., & Yamamoto, S. (1999). Thermoregulatory responses and blood viscosity in dehydrated heat exposed broilers (Gallus Domesticus(. Journal of Thermal Biology 24(3), 185-192.; Vecerek, Strakova, Suchy, & Voslarova, 2002Vecerek, V., Strakova, E., Suchy, P., & Voslarova, E. (2002). Influence high environmental temperature on production and haematological and biochemical indexes in broiler chickens. Czech Journal of Animal Science47(5), 176-182.; Bedanova, Voslarova, Vecerek, Strakova, & Suchy, 2003Bedanova, I., Voslarova, E., Vecerek, V., Strakova, E., & Suchy, P. (2003). The haematological profile of broilers under acute and chronic heat stress at 30±1°C level. Folia Veterinaria 47(4), 188-192.). This increase in Hk concentration is due to DEB increases.

During severe panting, decreased blood partial pressure of CO₂ and, blood HCO₃ concentration but increased pH resulted in respiratory alkalosis and blood acid - base perturbations (Teeter, Smith, & Owens, 1985Teeter, R. G., Smith, M. O., & Owens, F. N. (1985). Chronic heat stress and respiratory alkalosis: occurrence and treatment in broiler chicks. Poultry Science Journal 64(6), 1060-1064.; Raup & Bottje, 1990Raup, T. J., & Bottje, W. G. (1990). Effect of carbonated water on arterial pH, pCO2 and plasma lactate in heat-stressed broilers. Brittish Poultry Science31(2), 377-384). Present results indicated that during panting phase, blood pH was not as much as worse by treatments and it remained relatively constant in the range of 7.38 to 7.44. In contrast to the present findings, Teeter, Smith, and Owens (1985) Teeter, R. G., Smith, M. O., & Owens, F. N. (1985). Chronic heat stress and respiratory alkalosis: occurrence and treatment in broiler chicks. Poultry Science Journal 64(6), 1060-1064.reported that blood pH was elevated by chronic heat stress (32°C), and broilers had intermittent respiratory alkalosis during panting.

It is reported that broiler chickens fed diets with DEB 360 mEq kg^-1 increased blood pH, and HCO₃ rather DEB 0, 120, 240 mEq kg^-1 without any significant effects on blood P_CO2 and P_O2 under relatively heat stress and relative moisture condition at 42 days of age (Borges et al,. 2003aBorges, S. A., Silva, A. V. F., Ariki, J., Hooge, D. M., & Cummings, K. R. (2003a). Dietary electrolyte balance for broiler chickens under moderately high ambient temperatures and relative humidities. Poultry Science Journal 82(2), 301-308.). The results of blood CO₂ is in agreement but the results of blood pH, P_O2, and HCO₃^- are in contrast with the findings Borges et al. (2003a)Borges, S. A., Silva, A. V. F., Ariki, J., Hooge, D. M., & Cummings, K. R. (2003a). Dietary electrolyte balance for broiler chickens under moderately high ambient temperatures and relative humidities. Poultry Science Journal 82(2), 301-308.. Moreover, DEB 360 mEq kg^-1 increased pH and blood HCO₃ rather 0, 120 and 240 mEq kg^-1 without any affection on blood P_CO2 and this inconsistency could be due to variation in the type of broiler chickens and severity of heat stress. Consequently, at high temperature, birds increase their respiration rate in an attempt to increase the rate of evaporative cooling. Such hyperventilation increases CO₂ losses and as a result respiratory alkalosis develops (Belay & Teeter, 1993Belay, T., & Teeter, R. G. (1993). Broiler water balance and thermohalance during Thermoneutral and high ambient temperature exposure. Poultry Science Journal 72(1), 116-124.) increase pH blood, and thereby increase blood CO₂ as well as decrease blood HCO₃ (Borges et al., 2003a).

Khone and Jones (1975Khone, H. J., & Jones, J. G. (1975). Changes in plasma electrolytes acid-base balance and other physiological parameters of adult female turkeys under conditions of acute hyperthermia. Poultry Science Journal 54(6), 2034-2038.) reported that an increase in blood K level in response to heat stress. This K response seems to be related to the time which birds are under stress. It is reported DEB affected Cl^- levels under heat stress as serum Cl^- increased with increasing DEB levels (Ahmad and Sarwar, 2005Ahmad, T., & Sarwar, M. (2005). Influence of varying sources of dietary electrolytes on the performance of broilers reared in a high temperature environment. Animal Feed Science and Technology 120(3-4), 277-298.). These observations are opposite of the results of present study which could be because of different DEB and age of broiler chickens. No significant difference were observed regarding Cl, Na, and K levels of blood serum with increasing DEB from 40 to 340 mEq kg^-1 (Borges et al., 2003aBorges, S. A., Silva, A. V. F., Ariki, J., Hooge, D. M., & Cummings, K. R. (2003a). Dietary electrolyte balance for broiler chickens under moderately high ambient temperatures and relative humidities. Poultry Science Journal 82(2), 301-308.). These results confirmed by the results of present study at finisher period. Moreover, in opposite of current study the different CP levels significantly changed Na on blood elements (Safamehr et al., 2009Safamehr, A., Narimani, M., & Nobakht, A. (2012). Effects of electrolyte balance and dietary protein levels on production performance and carcass parameters in broiler chickens exposed to heat stress. Journal of Veterinary Research 67(3), 297-306.). In addition, DEB at levels 147 to 247 mEq kg^-1 and calcium carbonate supplementation increased in blood electrolyte balance concentration (Olanrewaju et al., 2006Olanrewaju, H. A., Wongpichet, S., Thaxton, J. P., Dozier, W. A., & Branton, S. L. (2006). Stress and acid-base balance in chickens. Poultry Science Journal 85(7), 1266-1274.) that is in according to results of present study.

Conclusion

Under heat stress challenges, broiler chickens used compensatory mechanisms when attempting to maintain acid-base homeostasis and concentrations of blood nutrients and physiological variables. These reactions make difficult to explain more precisely interaction of CP, AA, and DEB in the heat stress condition. However, an identical DEB 320 mEq kg^-1 with 21% CP at grower and 17% CP at finisher period gave better carcasses traits and performance parameters with more reduction of sever of heat stress (H to L ratio). The present study indicates that AA levels had no obvious interaction with DEB and CP levels.

Acknowledgements

The authors are thankful to Bu-Ali Sina University, for providing facilities and financial support for this study.

References

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