Influence of Phytase with Or without Organic Acid (Sodium Di-Formate) Supplementation on Growth Performance, Carcass Response, Protein and Mineral Digestibility in Starter Phase of Broilers

Anwar, U; Ahmad, S; Abdelgayed, SS; Hussain, M; Rehman, A; Riaz, M; Yousaf, M; Bilal, MQ; Bhatti, SA; Rahman, MA

doi:10.1590/1806-9061-2021-1502

ABSTRACT

This experiment was planned to evaluate the effects of phytase supplementation with or without organic acid (OA) on performance, protein, calcium (Ca), phosphorus (P) and sodium (Na) digestibility and carcass parameters in broiler chickens fed low Ca and low P diets in comparison to a high Ca and high P diet with standard specifications. For this purpose, two iso-nitrogenous and iso-caloric diets were prepared in such a way that one diet had high Ca (9.80) and high P (4.50) and second diet had low Ca (8.50) and low P (2.40), respectively. Low Ca and low P diet was further supplemented with enzyme phytase @ 500 FTU/kg, and phytase @ 500 FTU/kg + organic acid (1 kg/ton). Rations were offered to seven replicates of ten birds each, from day 1 to 21. Results revealed that the experimental treatments had no effect on feed intake and growth performance of birds (p>0.05). Carcass parameter results showed highest thigh meat yield % and liver weight % in the birds fed diet with low Ca & P and supplemented with enzymes phytase (p<0.05). Fecal P and Na digestiblities were high (p<0.05) in experimental broilers fed low Ca low P with enzyme phytase supplementation as compared to the diet without phytase supplementation. It is concluded that phytase and OA supplementation in the starter diet with low Ca and low P level did not influence intake, growth and feed conversion of the broilers. However, thigh meat yield percent and mineral digestiblities (P and Na) increased in the broilers that received the diet with low Ca and low P level and supplemented with enzyme phytase.

Keywords:
Phytase; organic acid; growth; digestibility

INTRODUCTION

In poultry nutrition, plant base ingredients form the major part of ration and more than 60% of the total phosphorus (P) present in plant base ingredients are in the form of phytate (Gautier et al., 2017Gautier A, Walk C, Dilger R. Effects of a high level of phytase on broiler performance, bone ash, phosphorus utilization, and phytate dephosphorylation to inositol. Poultry Science 2017;97(1):211-218.). Poultry birds do not have the ability to use this phytate P (Waldroup et al., 2000Waldroup P, Kersey J, Saleh E, Fritts C, Yan F, Stilborn H, et al., Nonphytate phosphorus requirement and phosphorus excretion of broiler chicks fed diets composed of normal or high available phosphate corn with and without microbial phytase. Poultry Science 2000;79(10):1451-1459.). This P in the form of phytate is present in aleurone layers and outer bran of grains (Steiner et al., 2007Steiner T, Mosenthin R, Zimmermann B, Greiner R, Roth S. Distribution of phytase activity, total phosphorus and phytate phosphorus in legume seeds, cereals and cereal by-products as influenced by harvest year and cultivar. Animal Feed Science and Technology 2007;133(3):320-334.). It has been reported that phytate is the storage form of P and inositol. It forms complexes with proteins, lipids and with many other micro-minerals in the gastro intestinal tract, thus reduces the solubility and absorption of nutrients (Cowieson et al., 2011Cowieson A, Wilcock P, Bedford M. Super-dosing effects of phytase in poultry and other monogastrics. World's Poultry Science Journal 2011;67(2):225-236.; Alshamiri et al., 2021Alshamiri MMA, Ali SAM, Abdalla HO, Ahmed HB. The effect of supplementing different levels of phytase enzyme on performance, some carcass properties and economics of broiler chickens. Agrobiological Records 2021;4:14-22.). It has also been reported that phytate also forms complexes with other minerals and nutrient like sodium (Na), calcium (Ca), iron and protein resulting in their deprived availability to the poultry birds. It also inhibits the efficiency of protein digesting enzymes like pepsin and trypsin and hence reduces digestibility of major nutrient proteins (Adeola & Cowieson, 2011Adeola O, Cowieson A. Board-invited review: opportunities and challenges in using exogenous enzymes to improve nonruminant animal production. Journal of Animal Science 2011;89(10):3189-3218.), that are considered crucial for the growth of broilers.

The supplementation of exogenous enzymes phytase @ 500 FTU/kg has been beneficial to reduce the negative impact for birds due to low P availability, results in the release of phytate P, increase in nutrient digestibility, increase in ash content in bones and finally have good effect on the growth performance of birds (Onyango et al., 2005Onyango E, Bedford M, Adeola O. Phytase activity along the digestive tract of the broiler chick: a comparative study of an Escherichia coli-derived and Peniophora lycii phytase. Canadian Journal of Animal Science 2005;85(1):61-68.). Phytase reduces the endogenous secretions which lead to high energy consumption (Pirgozliev et al., 2008Pirgozliev V, Oduguwa O, Acamovic T, Bedford M. Effects of dietary phytase on performance and nutrient metabolism in chickens. British Poultry Science 2008;49(2):144-154.). Dibner & Buttin (2002Dibner J, Buttin P. Use of organic acids as a model to study the impact of gut microflora on nutrition and metabolism. Journal of Applied Poultry Research 2002;11(4):453-463.) reported that different organic acids (OA) such as acetic acid, formic acid, propionic acid, butyric acids and other carboxylic acids such as lactic, tartaric, citric, malic and fumaric are being used in the poultry diet, and known for their antimicrobial activity and improved bird performance (Adil et al., 2010; Ashraf et al., 2020Ashraf S, Bhatti SA, Nawaz H, Khan MS. Assessment of dietary selenium sources in commercial male broiler breeders: effects on semen quality, antioxidant status and immune responses. Pakistan Veterinary Journal 2020;40(1):13-18.; Shawky et al., 2020Shawky SM, Orabi SH, Dawod A. Effect of marjoram supplementation on growth performance and some immunological indices in broilers. International Journal of Veterinary Science 2020;9:297-300.). Organic acids lower the pH of digesta (Dibner & Buttin 2002; Masood et al., 2020Masood A, Qureshi AS, Shahid RU, Jamil H. Effects of oral administration of essential oil (Mix Oil(r)) on growth performance and intestinal morphometry of Japanese quails (Coturnix coturnix japonica). Pakistan Veterinary Journal 2020;40(3):385-389.) especially in GIT and increase the activity of pepsinogens and zymogens (Jongbloed et al., 2000Jongbloed A, Mroz Z, Van der Weij-Jongbloed R, Kemme P. The effects of microbial phytase, organic acids and their interaction in diets for growing pigs. Livestock Production Science 2000;67(1):113-122.; Tammam et al., 2020Tammam AM, Ibrahim SA, Hemid AA, Abdel-Azeem F, Salem W. Effect of nanoparticles supplementation in broiler diets on performance, microbial population and digestive tract measurements. International Journal of Veterinary Science 2020;9:373-378.). A previous study also demonstrated that the pH of the crop in birds also affects the activity of phytase enzymes (Murai et al., 2001Murai A, Kita K, Tsuruta S, Okumura J-i. Interaction of dietary phytase and glutamic acid on bone ash response in chicken thigh. The Journal of Poultry Science 2001;38(2):146-151.). As described earlier, organic acids lower the pH of the gut in broilers and thus supplementation of organic acids in the diet may improve efficiency of supplemental phytase. It has also been reported that supplementation of chicken diet with organic acid reduces the production of toxins produced by bacteria or by the pathogens residing in the GIT thus lower the damage of the epithelial wall of the GIT (Langhout, 2000Langhout P. New additives for broiler chickens. World Poultry 2000;16(3):22-27.; Khan et al., 2019Khan M, Anjum AA, Nawaz M, Awan AR, Ali MA. Effect of newly characterized probiotic lactobacilli on weight gain, immunomodulation and gut microbiota of Campylobacter jejuni challenged broiler chicken. Pakistan Veterinary Journal 2019;39(4):473-478.; Khan et al., 2020). OAs increase the digestibility of protein, Ca, magnesium, P and zinc by lowering the pH of the GIT and thus making the phytase more effective at lowering the intestinal pH and increase the growth performance of the birds (Kirchgessner & Roth, 2012Kirchgessner M, Roth F. Ergotrope Effekte durch organische Säuren in der Ferkelaufzucht und Schweinemast. Übersichten zur Tierernährung 2012;16:93-108.).

Thus, the purpose of the study reported was to evaluate the effect of phytase and OA supplementation on feed intake, growth performance, carcass characteristics, protein and mineral digestibility in broiler chickens fed low Ca and low P diets in comparison to a high Ca and high P diet with standard specifications in starter phase of broiler chicken.

MATERIALS AND METHODS

The experimental procedure of the current study was approved by the Director Graduate Studies, University of Agriculture, Faisalabad, Pakistan. Institute of Animal and the Dairy Sciences, University of Agriculture Faisalabad also approved the current study. Experimental feeds were formulated to be isocaloric and isonitrogenous for starter phase (d zero to 21) (Table 1). The experimental feeds were offered to experimental birds from 1 to 21 days. The specifications of the ingredients used in the experimental diet preparation were taken from Brazilian Tables for Poultry and Swine (Rostagno et al., 2011Rostagno H, Albino LT, Donzele JL, Gomes P, Oliveira R, Lopes D, et al., Brazilian tables for poultry and swine: composition of feedstuffs and nutritional requirements. Viçosa: UFV; 2011). The experimental diets fed to the birds were in the form of pellets from day 1 to 21 of the experimental trial. For this experiment, two iso-nitrogenous and iso-caloric diets were prepared in such a way that one diet had high Ca (9.80) and high P (4.50) and second diet had low Ca (8.50) and low P (2.40). Low Ca and low P diet were further supplemented with phytase enzyme@ 500 FTU/kg, phytase enzyme@500 FTU/kg + OA (1 kg/ton).

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Table 1
Ingredients composition and nutrient profile of experimental diets.

Animal Husbandry and Experimental Procedure

The experiment was carried out at the Research Center of Animal Nutrition, Faculty of Animal Husbandry, University of Agriculture, Faisalabad. Two hundred and eighty Cobb 500 (day old) male broiler chicks were purchased from a local hatchery. The number of birds and samples were ruled by the available resources and ethical considerations. Procured broiler chicks (Cobb 500) were randomly distributed into 28 replicates in that manner that each replicate had10 birds. Each replicate was housed in a pen having dimension of 1.2 x 0.9 x 0.8 m. Litter was spread in each pen. Gas brooder was used during the brooding period. Sugar solution (1kg sugar/5L water) was used for flushing on the very first day of experiment. For the comfort of the experimental birds, house temperature was set at 95 °F before the arrival of the chicks, and this temperature was maintained for the first week of the experiment to serve the purpose of brooding. After that brooding temperature was reduced by 5° F every week until it reached 75 °F. In the current experiment, the chicks had free access to feed and water round the clock. Shed temperature and ventilation was maintained with the help of electric water cooler, and ceiling fans. Standard management conditions were ensured in the shed throughout the experimental trial. The birds were free from fear of thrust and hunger, and welfare conditions were ensured as described in recent studies of animal’s research (Aziz ur Rahman et al., 2017Aziz ur Rahman M, Chuanqi X, Huawei S, Binghai C. Effects of hay grass level and its physical form (full length vs. chopped) on standing time, drinking time, and social behavior of calves. Journal of Veterinary Behavior: Clinical Applications and Research 2017;21(Supplement C):7-12.; Aziz ur Rahman et al., 2019).

Data Collection

Feed intake was calculated by subtracting the feed refused from the total feed offered during the week. The weight gain (WG) data was obtained on a weekly basis. The weekly average WG was determined by simply subtracting the average body weight (BW) of the previous week from the average BW at the end of the next week. The data collected for intake and WG were adjusted for mortality and feed conversion ratio (FCR) was calculated by dividing intake on total WG.

Digestibility Assay

Protein, P, Ca and Na digestibility was determined on the 21st day by using an external marker that was acid insoluble ash (AIA). For this objective, acid insoluble ash source, Celite® was included in the experimental feeds @ 1% of feed (Sales & Janssens, 2003) three days before digestibility trial. Feed samples were analyzed for dry matter, ether extract, crude protein (CP), ash and crude fiber and ash. On the 21stday fecal digesta from 3 birds per replicate was collected. These samples were oven dried at 65°C and then they were grinded for further analysis.

Chemical Analysis

Dry matter, crude protein, crude fiber, ether extract and crude were determined according to the guideline of AOAC, 1990. Sodium concentration of excreta samples were quantified by using flame absorption spectrophotometry. Phosphorus was determined by using molybdo-vanadate method (method 965.17, AOAC, 2000). Calcium concentration was determined by titration method (AOAC, 2000). All chemical analysis were done carefully, considering the protocol of previous studies (Muhammad et al., 2016Muhammad AU, Xia CQ, Cao BH. Dietary forage concentration and particle size affect sorting, feeding behaviour, intake and growth of Chinese holstein male calves. Journal of Animal Physiology and Animal Nutrition (Berl) 2016;100(2):217-223.; Wang et al., 2016Wang C, Muhammad A, Liu Z, Huang B, Cao B. Effects of ensiling time on banana pseudo-stem silage chemical composition, fermentation and in sacco rumen degradation. The Journal of Animal & Plant Sciences 2016;26(2):339-346.; Niu et al., 2017Niu W, He Y, Xia C, Rahman MAU, Qiu Q, Shao T, et al., Effects of replacing Leymus chinensis with whole-crop wheat hay on Holstein bull apparent digestibility, plasma parameters, rumen fermentation, and microbiota. Scientific Reports 2017;7; He et al., 2018He Y, Niu W, Qiu Q, Xia C, Shao T, Wang H, et al., Effect of calcium salt of long-chain fatty acids and alfalfa supplementation on performance of Holstein bulls. Oncotarget 2018;9(3):3029.; Hussain et al., 2018Hussain M, Mahmud A, Hussain J, Qaisrani S, Mehmood S, Rehman A. Subsequent effect of dietary lysine regimens fed in the starter phase on the growth performance, carcass traits and meat chemical composition of aseel chicken in the grower phase. Brazilian Journal of Poultry Science 2018;20:455-462.; Sharif et al., 2018Sharif M, Shoaib M, Rahman MAU, Ahmad F, Rehman SU. Effect of distillery yeast sludge on growth performance, nutrient digestibility and slaughter parameters in Japanese quails. Scientific Reports 2018;8(1):8418.; Xia et al., 2018Xia CQ, Muhammad AUR, Niu W, Shao T, Qiu Q, Huawei S, et al., Effects of dietary forage to concentrate ratio and wildrye length on nutrient intake, digestibility, plasma metabolites, ruminal fermentation and fecal microflora of male chinese Holstein calves. Journal of Integrative Agriculture 2018;17(2):415-427.; Xia et al., 2018; Xia et al., 2018; Hussain et al., 2020).

Calculation and Statistical Analysis

The apparent digestibility coefficient of the nutrient was calculated by the method described by Ravindran et al. (1999).

N u t r i e n t D i g e s t i b i l i t y (%) = \frac{(\frac{N}{A I A}) d i e t \times (\frac{N}{A I A}) d i g e s t}{(\frac{N}{A I A}) d i e t}

N: Nutrient

AIA: Acid insoluble ash

General Linear Model of Minitab Statistical Software 17 (Minitab Inc. 2010) under CRD was used to analyze collected data. Tukey’s test was used to compare the means.

RESULTS

Growth Performance

Data of growth performance parameter is present in Table 2. Result revealed that the experimental treatments had no effect on feed intake during starter phase (p>0.05). Similarly, there was no difference in the WG of the birds by giving different dietary treatments during starter phase. Feed conversion ratio was also not changed by the experimental treatments in starter phase (p>0.05). However, numerically better FCR was observed in the broilers offered the experimental diet low in Ca & P and supplemented with phytase (p>0.05) for1-21 days lifespan.

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Table 2
Influence of phytase with or without organic acid (sodium di-formate) supplementation on growth performance of broiler chicken in starter phase.

Carcass Characteristics

Results of carcass characteristics are presented in Table 3. Findings of carcass characteristics explored that live weight %, and dressing percentage were similar for all groups (p>0.05). However, dietary treatments influenced the thigh meat yield %, chest meat yield %, heart weight, liver weight %, gizzard weight % and spleen weight % (p<0.05). In the current experiment, the highest breast meat yield % was observed in the birds fed high Ca & P diet (p<0.05). While, the highest thigh meat yield % and liver weight % were observed in the birds fed the diet that had low Ca & P and was supplemented with phytase (p<0.05). However, the highest heart weight %, gizzard weight % and spleen weight % was observed in the birds on high Ca & P supplemented diet with phytase and OA (p<0.05).

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Table 3
Influence of phytase with or without organic acid (sodium di-formate) supplementation on carcass characteristics of broiler chicken in starter phase.

Serum Phosphorus Level

Results of blood serum P level are presented in Figure 1. On day 21, better serum P level was noted in the birds fed High Ca, high P (HCHP) and Low Ca, low P+ Phytase+ OA (LCLPPHOA) diet (p<0.05). Poor serum P was observed in the birds fed Low Ca, low P (LCLP) and Low Ca, low P+ Phytase (LCLPPH) (p<0.05).

Crude Protein and Mineral Digestibility

Results of CP and mineral digestibility are exhibited in Table 4. Better CP digestibility on day 21 was noted in the birds fed HCHP diet (p<0.05) as compared to other experimental treatments. While, the lowest CP digestibility on day 21 was noted in the birds offered the LCLP experimental diet (p<0.05). On day 21, the results of Ca digestibility revealed better Ca digestibility in the birds offered HCHP experimental diet (p<0.05). Poor Ca digestibility on day 21 was noted in the birds offered the LCLP experimental feed (p<0.05). Calcium digestibility in treatment LCLPPH was better than in treatment LCLP and poorer than in HCHP (p<0.05). Phosphorus digestibility was changed due to dietary treatments on day 21 (p>0.05). Phosphorus digestibility results on day 21 presented that the birds fed HCHP diet had better P digestibility (p<0.05). Poor P digestibility on day 21 was observed in the birds fed LCLP diet (p<0.05). Sodium digestibility on day 21 showed that the birds fed HCHP diet had better Na digestibility (p<0.05).

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Table 4
Influence of phytase with or without organic acid (sodium di-formate) supplementation on crude protein, calcium, phosphorus and sodium digestibility of broiler chicken in starter phase.

Figure 1
Influence of phytase with or without organic acid (sodium di-formate) supplementation on serum phosphorus level of broiler chicken in starter phase.

DISCUSSION

In the present experiment, feed intake was not changed by phytase in diets with LCLP compared to HCHP diet which agrees with the results reported by previous researchers (Namkung & Leeson, 1999Namkung H, Leeson S. Effect of phytase enzyme on dietary nitrogen-corrected apparent metabolizable energy and the ileal digestibility of nitrogen and amino acids in broiler chicks. Poultry Science 1999;78(9):1317-1319.; Lan et al., 2002Lan G, Abdullah N, Jalaludin S, Ho Y. Efficacy of supplementation of a phytase-producing bacterial culture on the performance and nutrient use of broiler chickens fed corn-soybean meal diets. Poultry Science 2002;81(10):1522-1532.; Tizziani et al., 2016Tizziani T, Donzele RFMdO, Donzele JL, Balbino EM, Silva AD, Figueiredo ÉM de, et al., Available phosphorus levels in diets supplemented with phytase for male broilers aged 22 to 42 days kept in a high-temperature environment. Revista Brasileira de Zootecnia 2016;45(2):48-55.). Namkung & Leeson (1999), reported that feed intake (629.38) from day 1-14 of broiler chicks offered feed that contained exogenous enzyme phytase with the low Ca (0.79%) and available P (0.35%) were similar to the feed intake (639.54g) of the control group chicks fed the diet that contained normal levels of available Ca (0.90%) and available P (0.45%). In contrary to the current findings, Lan et al. (2002) reported that the supplementation of different levels of phytase-producing bacterial culture (equivalent to 250, 500, 750, and 1,000 U of phytase/ kg of feed) to the low available P diet (0.24%) increased the feed intake of broiler chickens to a level similar to broiler chicks offered feed with high Ca and P level (0.45%). The difference in results with Lan et al.´s (2002) study could be explained by the age difference of broilers. In the current study, we just observed the intake in starter phase while in Lan et al. (2002) study reported the result of the overall study period of broiler growth. Similarly, OA and phytase supplementation in LCLP and HCHP starter diet of broiler didn’t affect the intake. Interesting results of WG was observed in the current study. In the current study WG was similar among all treatments, which is contradictory to the previous research of Gehring et al., (2013Gehring C, Bedford M, Dozier III W. Extra-phosphoric effects of phytase with and without xylanase in corn-soybean meal-based diets fed to broilers. Poultry Science 2013;92(4):979-991.). Gehring et al., (2013) examined the impact of the supplementation of phytase enzymes with variable levels of available P in sorghum soybean meal corn gluten diets from day one to day 21 of broiler. They reported that WG was increased in diets supplemented with phytase when compared to the LCLP diets. They conducted another experiment with different levels of available P and with and without phytase supplementation, WG was increased at the level of P which was high and available to the bird for its proper functioning of the body. The level of P, which was high without supplementation of phytase, has lower WG when compared to the phytase supplementation. The current study´s findings, which based the diets in corn-soya diets, disagree with Gehring et al. (2013) study, which based their diets in sorghum soybean meal corn gluten. Moreover, no difference of the experimental diets on FCR in starter phase of broiler was observed in the current study, which indicates that all dietary treatments have the same dietary nutrient absorption efficiency in starter phase. Our results agree with the study of Rutherfurd et al. (2012Rutherfurd S, Chung T, Thomas D, Zou M, Moughan P. Effect of a novel phytase on growth performance, apparent metabolizable energy, and the availability of minerals and amino acids in a low-phosphorus corn-soybean meal diet for broilers. Poultry Science 2012;91(5):1118-1127.), who stated that the FCR was the same for the birds fed phytase enzymes supplemented feed as compared with the diets with low level of P and with high Ca and P diet. Interestingly, HCHP, LCLP diets, with the supplementation of OA, behave the same in terms of growth and FCR compared to other treatments in the current experiment.

Although, a lot of work has been done on phytase supplementation and its impact on carcass parameters of pigs the impact of phytase on carcass characteristics in broilers is also important, but information regarding characteristics of carcass is limited. Research of phytase supplementation on P deficient diets had been studied in pigs to evaluate its effect on carcass characteristics and it has been documented that results on carcass characteristics were variable with phytase supplementation (Liu et al., 1998; Lysenko et al., 2021Lysenko Y, Koshchayev A, Luneva A, Omarov R, Shlykov S. Organic meat production of broiler chickens Hubbard Redbro cross. International Journal of Veterinary Science 2021;10:25-30.). For example, Walz & Pallauf (2003) conducted a trial on barrows and stated that phytase enhanced digestibility of minerals but had no effect on carcass and meat characteristics. Similarly, research on drakes reported by Attia (2003Attia Y. Performance, carcass characteristics, meat quality and plasma constituents of meat type drakes fed diets containing different levels of lysine with or without a microbial phytase. Archives of Animal Nutrition 2003;57(1):39-48.) demonstrated that supplementation of phytase had no effect on carcass yield and meat quality. However, Shelton et al. (2004Shelton J, Southern L, LeMieux F, Bidner T, Page T. Effects of microbial phytase, low calcium and phosphorus, and removing the dietary trace mineral premix on carcass traits, pork quality, plasma metabolites, and tissue mineral content in growing-finishing pigs. Journal of Animal Science 2004;82(9):2630-2639.) reported phytase inclusion in the mineral deficient diet reversed the negative effects of mineral deficient diets on carcass characteristics. In the current study, thigh meat yield was higher in diets with low level of P supplemented with phytase compared to diets with low level of P without phytase supplementation. So, it could be hypothesized that the inclusion of the phytase in broiler diets with deficient P, not only prevented negative effects on thigh meat yield in birds, but also enhance its yield. Our finding is in agreement with Scheideler & Ferket (2000Scheideler S, Ferket P. Phytase in broiler rations-effects on carcass yields and incidence of Tribal Dyschondroplasia. Journal of Applied Poultry Research 2000;9(4):468-475.) who also reported that thigh yield was higher in broilers fed LCLP diets with phytase supplementation. Our result is in line with Pillai et al., (2006Pillai P, O'Connor-Dennie T, Owens C, Emmert J. Efficacy of an Escherichia coli phytase in broilers fed adequate or reduced phosphorus diets and its effect on carcass characteristics. Poultry Science 2006;85(10):1737-1745.) who stated that the addition of phytase in P deficient feed of broiler not only reduce the negative effect on thigh yield but also on breast yield. Preston et al. (2000Preston C, McCracken K, McAllister A. Effect of diet form and enzyme supplementation on growth, efficiency and energy utilisation of wheat-based diets for broilers. British Poultry Science 2000;41(3):324-331.) found interesting results of phytase enzymes addition in P deficient feed in broiler and claimed that the addition of enzyme phytase in P deficient feed of broiler can increased the yield of important parts of carcass; however, Angel et al. (2006Angel R, Saylor W, Mitchell A, Powers W, Applegate T. Effect of dietary phosphorus, phytase, and 25-hydroxycholecalciferol on broiler chicken bone mineralization, litter phosphorus, and processing yields. Poultry Science 2006;85(7):1200-1211.) opposed these findings. Similarly, in the current study, breast yield results revealed that phytase supplementation failed to reduce the negative effect of low P diet on breast meat yield. Similarly, OA and phytase supplementation with LCLP diet failed to overcome the negative effect of breast meat yield in broiler fed low P diet.

The observed increase in internal organ´s weights, e.g. heart and liver in the broilers fed in low available P without phytase supplementation diets, is perhaps due to lower supply of P. Temprano et al. (2004Temprano J, Bretón I, Zugasti A, Cuerda C, Camblor M, Pérez-Díaz M, et al., Hipofosfatemia grave tras el inicio de nutrición parenteral en una paciente con fístula intestinal. Nutrición Hospitalaria 2004;19(4):243-247.) reported that insufficient supply of P resulted in heart hypertrophy due to hypophosphatemia. Hypertrophy along with hypophosphatemia resulted in reduced contraction of the heart due to reduced myosin ATPase activity and lower cyclic adenosine monophosphate. This may cause heart failure, increasing diameter of myocardial fiber and decrease in the systolic pressure as reported by Martinez et al., (2004). The increase in liver weight could be attributed to low ATP creation which stimulates the formation of liver enzymes. The findings of the current study are supported with the findings of de Oliveira et al. (2009) who reported decreased weight of internal organs including heart and liver when broilers were fed low available P. However, the increase in internal organs including heart and liver weight in diets with low available P plus phytase could be attributed to higher mineral digestibility and higher growth with this treatment.

Previous researcher reported that CP digestibility is not changed by the supplementation of phytase enzyme in low P feed compared to diets with normal P level (Woyengo et al., 2010Woyengo T, Adeola O, Udenigwe C, Nyachoti C. Gastro-intestinal digesta pH, pepsin activity and soluble mineral concentration responses to supplemental phytic acid and phytase in piglets. Livestock Science 2010;134(1):91-93.; Rutherfurd et al., 2012Rutherfurd S, Chung T, Thomas D, Zou M, Moughan P. Effect of a novel phytase on growth performance, apparent metabolizable energy, and the availability of minerals and amino acids in a low-phosphorus corn-soybean meal diet for broilers. Poultry Science 2012;91(5):1118-1127.; Lalpanmawia et al., 2014Lalpanmawia H, Elangovan A, Sridhar M, Shet D, Ajith S, Pal D. Efficacy of phytase on growth performance, nutrient utilization and bone mineralization in broiler chicken. Animal Feed Science and Technology 2014;192:81-89.). However, in the current study, on day 21 fecal CP digestibility was improved with the supplementation of phytase in LCLP diet which is in line with the results of the previous studies (Chung et al., 2013Chung T, Rutherfurd S, Thomas D, Moughan P. Effect of two microbial phytases on mineral availability and retention and bone mineral density in low-phosphorus diets for broilers. British Poultry Science 2013;54(3):362-373.; Cowieson et al., 2006Cowieson A, Acamovic T, Bedford M. Supplementation of corn-soy-based diets with an Eschericia coli-derived phytase: effects on broiler chick performance and the digestibility of amino acids and metabolizability of minerals and energy. Poultry Science 2006;85(8):1389-1397.; Selle et al., 2006Selle PH, Ravindran V, Bryden WL, Scott T. Influence of dietary phytate and exogenous phytase on amino acid digestibility in poultry: a review. The Journal of Poultry Science 2006;43(2):89-103.). Ravindran et al. (2006Ravindran V, Morel P, Partridge G, Hruby M, Sands J. Influence of an Escherichia coli-derived phytase on nutrient utilization in broiler starters fed diets containing varying concentrations of phytic acid. Poultry Science 2006;85(1):82-89.) examined the impact of phytase enzyme supplementation feed having low P on broiler digestibility and reported that digestibility of CP was increased with phytase enzyme supplementation compared to feed having LCLP. Similarly, Cowieson et al., (2006) also stated that phytase enzymes supplementation in the feed of broiler fed low P diet enhance apparent CP protein digestibility compared to control feed. Pirgozliev et al., (2010Pirgozliev V, Karadas F, Pappas A, Acamovic T, Bedford M. The effect on performance, energy metabolism and hepatic carotenoid content when phytase supplemented diets were fed to broiler chickens. Research in Veterinary Science 2010;89(2):203-205.) stated that superdose of phytase (12 500 FTU) in the diet of broiler deficient in P further enhance total tract amino acid digestibility. These findings are further confirmed by Rutherfurd et al. (2012a) and Chung et al. (2013) who stated that the apparent amino acids digestibility increased with the supplementation of phytase in low P feed of broilers. Furthermore, other researchers also have similar findings (Mansoori & Acamovic, 1998Mansoori B, Acamovic T. The excretion of minerals from broilers fed tannic acid, polyethylene glycol and protein. Toxic Plants and other Natural Toxicants 1998:101-105.; Cowieson et al., 2004). Furthermore, in the current experiment, phytase supplementation in diets with low available P improved Ca and P fecal digestibility on day 21. It has been reported in many studies that P and Ca digestibility were improved by phytase supplementation (Ravindran et al., 2006; Lalpanmawia et al., 2014). Several scientists reported similar findings and it is well documented that P digestibility increased with the supplementation of phytase in low P diets (Wu et al., 2004Wu Y, Ravindran V, Thomas D, Birtles M, Hendriks W. Influence of phytase and xylanase, individually or in combination, on performance, apparent metabolisable energy, digestive tract measurements and gut morphology in broilers fed wheat-based diets containing adequate level of phosphorus. British Poultry Science 2004;45(1):76-84.; Olukosi et al., 2007Olukosi O, Cowieson A, Adeola O. Age-related influence of a cocktail of xylanase, amylase, and protease or phytase individually or in combination in broilers1. Poultry Science 2007;86(1):77.; Ravindran et al., 2008; Rutherfurd et al., 2012; Walk et al., 2013Walk C, Bedford M, Santos T, Paiva D, Bradley J, Wladecki H, et al., Extra-phosphoric effects of superdoses of a novel microbial phytase. Poultry Science 2013;92(3):719-725.). The increase in P digestibility could be explained by the mechanism of action of phytase enzyme on phytate which probably release or remove minerals from the phytate bond as well as stoppage of bounding mineral with phytate. The release of P from phytate is well recognized, however, impact of phytase on release and bioavailability of other minerals is not clear as documented by Chung et al. (2013). However, current study findings reported that phytase have the ability to increase the digestibility of Ca and Na. Formic acid addition is known to improve apparent digestibility of nutrients in broilers (Hernandez et al., 2006Hernandez F, Garcia V, Madrid J, Orengo J, Catala P, Megias M. Effect of formic acid on performance, digestibility, intestinal histomorphology and plasma metabolite levels of broiler chickens. British Poultry Science 2006;47(1):50-56.; Garcia et al., 2007Garcia V, Catala-Gregori P, Hernandez F, Megias M, Madrid J. Effect of formic acid and plant extracts on growth, nutrient digestibility, intestine mucosa morphology, and meat yield of broilers. Journal of Applied Poultry Research 2007;16(4):555-562.). Emami et al. (2013Emami NK, Naeini SZ, Ruiz-Feria C. Growth performance, digestibility, immune response and intestinal morphology of male broilers fed phosphorus deficient diets supplemented with microbial phytase and organic acids. Livestock Science 2013;157(2-3):506-513.) noted that supplementing diets with LCLPPHOA improve the digestibility of P compared to LCLP. Our results of P digestibility of low available P diet with phytase and OA agree with the study of Emami et al., 2013. Furthermore, current study findings explored that Ca and Na digestibility of LCLP diet with phytase and OA is increased compare to LCLP diet without phytase supplementation.

In case of serum P level, some studies indicated that phytase supplementation can increase significantly serum P (Scheideler & Ferket 2000Scheideler S, Ferket P. Phytase in broiler rations-effects on carcass yields and incidence of Tribal Dyschondroplasia. Journal of Applied Poultry Research 2000;9(4):468-475.; Ghasemi et al., 2006Ghasemi H, Tahmasbi AM, Moghaddam G, Mehri M, Alijani S, Kashefi E, et al., The effect of phytase and Saccharomyces cervisiae (Sc47) supplementation on performance, serum parameters, phosphorus and calcium retention of broiler chickens. International Journal of Poultry Science 2006;5(2):162-168.). Shirley & Edwards Jr (2003Shirley R, Edwards Jr H. Graded levels of phytase past industry standards improves broiler performance. Poultry Science 2003;82(4):671-680.) observed that phytase supplementation in LCLP diet enhance blood P level because phytase in low Ca and P diet enhance more P removal/released from phytate. However, our findings showed that phytase in LCLP diet did not alter the blood P level in starter phase. Findings are consistent with other studies that reported that phytase supplementation into feeds for broiler chickens did not increase the P concentration in blood serum of birds (Bozkurt et al., 2006Bozkurt M, Çabuk M, Alçiçek A. The effect of microbial phytase in broiler grower diets containing low phosphorus, energy and protein. The Journal of Poultry Science 2006;43(1):29-34.; Plumstead et al., 2008Plumstead P, Leytem A, Maguire R, Spears J, Kwanyuen P, Brake J. Interaction of calcium and phytate in broiler diets. 1. Effects on apparent prececal digestibility and retention of phosphorus. Poultry Science 2008;87(3):449-458.; Kliment & Angelovičová 2012Kliment M, Angelovicová M. Microbial phytase and phosphorus utilization by broiler chickens. Scientific Papers Animal Science and Biotechnologies 2012;45(1):41-45.; Amerah et al., 2014Amerah A, Plumstead P, Barnard L, Kumar A. Effect of calcium level and phytase addition on ileal phytate degradation and amino acid digestibility of broilers fed corn-based diets. Poultry Science 2014;93(4):906-915.).

CONCLUSION

Based on the results, it is concluded that phytase and organic acid supplementation in the starter diet with low Ca and low P level did not influence intake, growth and feed conversion of the broilers. However, thigh meat yield percentage and mineral digestibility (P and Na) increased in the broilers that received the diet with low Ca and low P level and supplemented with phytase in the starter phase of broiler.

ACKNOWLEDGMENT

This study was funded by Asia Feed Pvt. Ltd. Lahore, Pakistan. The authors also acknowledged the contribution of master students, Awais Ali, Saad Jameel, and Hafiz Nawaz Ali for their efforts to conduct this experiment.

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Amerah A, Plumstead P, Barnard L, Kumar A. Effect of calcium level and phytase addition on ileal phytate degradation and amino acid digestibility of broilers fed corn-based diets. Poultry Science 2014;93(4):906-915.
Angel R, Saylor W, Mitchell A, Powers W, Applegate T. Effect of dietary phosphorus, phytase, and 25-hydroxycholecalciferol on broiler chicken bone mineralization, litter phosphorus, and processing yields. Poultry Science 2006;85(7):1200-1211.
Ashraf S, Bhatti SA, Nawaz H, Khan MS. Assessment of dietary selenium sources in commercial male broiler breeders: effects on semen quality, antioxidant status and immune responses. Pakistan Veterinary Journal 2020;40(1):13-18.
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Aziz ur Rahman M, Xia C, Ji L, Cao B, Su H. Nutrient intake, feeding patterns, and abnormal behavior of growing bulls fed different concentrate levels and a single fiber source (corn stover silage). Journal of Veterinary Behavior 2019;33:46-53.
Bozkurt M, Çabuk M, Alçiçek A. The effect of microbial phytase in broiler grower diets containing low phosphorus, energy and protein. The Journal of Poultry Science 2006;43(1):29-34.
Chung T, Rutherfurd S, Thomas D, Moughan P. Effect of two microbial phytases on mineral availability and retention and bone mineral density in low-phosphorus diets for broilers. British Poultry Science 2013;54(3):362-373.
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Cowieson A, Acamovic T, Bedford M. Supplementation of corn-soy-based diets with an Eschericia coli-derived phytase: effects on broiler chick performance and the digestibility of amino acids and metabolizability of minerals and energy. Poultry Science 2006;85(8):1389-1397.
Cowieson A, Wilcock P, Bedford M. Super-dosing effects of phytase in poultry and other monogastrics. World's Poultry Science Journal 2011;67(2):225-236.
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Emami NK, Naeini SZ, Ruiz-Feria C. Growth performance, digestibility, immune response and intestinal morphology of male broilers fed phosphorus deficient diets supplemented with microbial phytase and organic acids. Livestock Science 2013;157(2-3):506-513.
Garcia V, Catala-Gregori P, Hernandez F, Megias M, Madrid J. Effect of formic acid and plant extracts on growth, nutrient digestibility, intestine mucosa morphology, and meat yield of broilers. Journal of Applied Poultry Research 2007;16(4):555-562.
Gautier A, Walk C, Dilger R. Effects of a high level of phytase on broiler performance, bone ash, phosphorus utilization, and phytate dephosphorylation to inositol. Poultry Science 2017;97(1):211-218.
Gehring C, Bedford M, Dozier III W. Extra-phosphoric effects of phytase with and without xylanase in corn-soybean meal-based diets fed to broilers. Poultry Science 2013;92(4):979-991.
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Hussain M, Mahmud A, Hussain J, Qaisrani S, Mehmood S, Rehman A. Subsequent effect of dietary lysine regimens fed in the starter phase on the growth performance, carcass traits and meat chemical composition of aseel chicken in the grower phase. Brazilian Journal of Poultry Science 2018;20:455-462.
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Khan M, Anjum AA, Nawaz M, Awan AR, Ali MA, Rehman FU. Effect of Lactobacillus gallinarum PL 53 supplementation on xylose absorption and intestinal morphology in broilers challenged with Campylobacter jejuni. Pakistan Veterinary Journal 2020;40(2):163-168.
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Publication Dates

Publication in this collection
18 Mar 2022
Date of issue
2022

History

Received
18 Aug 2021
Accepted
13 Oct 2021

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

[1] Adeola O, Cowieson A. Board-invited review: opportunities and challenges in using exogenous enzymes to improve nonruminant animal production. Journal of Animal Science 2011;89(10):3189-3218.

[2] Alshamiri MMA, Ali SAM, Abdalla HO, Ahmed HB. The effect of supplementing different levels of phytase enzyme on performance, some carcass properties and economics of broiler chickens. Agrobiological Records 2021;4:14-22.

[3] Amerah A, Plumstead P, Barnard L, Kumar A. Effect of calcium level and phytase addition on ileal phytate degradation and amino acid digestibility of broilers fed corn-based diets. Poultry Science 2014;93(4):906-915.

[4] Angel R, Saylor W, Mitchell A, Powers W, Applegate T. Effect of dietary phosphorus, phytase, and 25-hydroxycholecalciferol on broiler chicken bone mineralization, litter phosphorus, and processing yields. Poultry Science 2006;85(7):1200-1211.

[5] Ashraf S, Bhatti SA, Nawaz H, Khan MS. Assessment of dietary selenium sources in commercial male broiler breeders: effects on semen quality, antioxidant status and immune responses. Pakistan Veterinary Journal 2020;40(1):13-18.

[6] Attia Y. Performance, carcass characteristics, meat quality and plasma constituents of meat type drakes fed diets containing different levels of lysine with or without a microbial phytase. Archives of Animal Nutrition 2003;57(1):39-48.

[7] Aziz ur Rahman M, Chuanqi X, Huawei S, Binghai C. Effects of hay grass level and its physical form (full length vs. chopped) on standing time, drinking time, and social behavior of calves. Journal of Veterinary Behavior: Clinical Applications and Research 2017;21(Supplement C):7-12.

[8] Aziz ur Rahman M, Xia C, Ji L, Cao B, Su H. Nutrient intake, feeding patterns, and abnormal behavior of growing bulls fed different concentrate levels and a single fiber source (corn stover silage). Journal of Veterinary Behavior 2019;33:46-53.

[9] Bozkurt M, Çabuk M, Alçiçek A. The effect of microbial phytase in broiler grower diets containing low phosphorus, energy and protein. The Journal of Poultry Science 2006;43(1):29-34.

[10] Chung T, Rutherfurd S, Thomas D, Moughan P. Effect of two microbial phytases on mineral availability and retention and bone mineral density in low-phosphorus diets for broilers. British Poultry Science 2013;54(3):362-373.

[11] Cowieson A, Acamovic T, Bedford M. The effects of phytase and phytic acid on the loss of endogenous amino acids and minerals from broiler chickens. British Poultry Science 2004;45(1):101-108.

[12] Cowieson A, Acamovic T, Bedford M. Supplementation of corn-soy-based diets with an Eschericia coli-derived phytase: effects on broiler chick performance and the digestibility of amino acids and metabolizability of minerals and energy. Poultry Science 2006;85(8):1389-1397.

[13] Cowieson A, Wilcock P, Bedford M. Super-dosing effects of phytase in poultry and other monogastrics. World's Poultry Science Journal 2011;67(2):225-236.

[14] Dibner J, Buttin P. Use of organic acids as a model to study the impact of gut microflora on nutrition and metabolism. Journal of Applied Poultry Research 2002;11(4):453-463.

[15] Emami NK, Naeini SZ, Ruiz-Feria C. Growth performance, digestibility, immune response and intestinal morphology of male broilers fed phosphorus deficient diets supplemented with microbial phytase and organic acids. Livestock Science 2013;157(2-3):506-513.

[16] Garcia V, Catala-Gregori P, Hernandez F, Megias M, Madrid J. Effect of formic acid and plant extracts on growth, nutrient digestibility, intestine mucosa morphology, and meat yield of broilers. Journal of Applied Poultry Research 2007;16(4):555-562.

[17] Gautier A, Walk C, Dilger R. Effects of a high level of phytase on broiler performance, bone ash, phosphorus utilization, and phytate dephosphorylation to inositol. Poultry Science 2017;97(1):211-218.

[18] Gehring C, Bedford M, Dozier III W. Extra-phosphoric effects of phytase with and without xylanase in corn-soybean meal-based diets fed to broilers. Poultry Science 2013;92(4):979-991.

[19] Ghasemi H, Tahmasbi AM, Moghaddam G, Mehri M, Alijani S, Kashefi E, et al., The effect of phytase and Saccharomyces cervisiae (Sc47) supplementation on performance, serum parameters, phosphorus and calcium retention of broiler chickens. International Journal of Poultry Science 2006;5(2):162-168.

[20] He Y, Niu W, Qiu Q, Xia C, Shao T, Wang H, et al., Effect of calcium salt of long-chain fatty acids and alfalfa supplementation on performance of Holstein bulls. Oncotarget 2018;9(3):3029.

[21] Hernandez F, Garcia V, Madrid J, Orengo J, Catala P, Megias M. Effect of formic acid on performance, digestibility, intestinal histomorphology and plasma metabolite levels of broiler chickens. British Poultry Science 2006;47(1):50-56.

[22] Hussain M, Mahmud A, Hussain J, Qaisrani S, Mehmood S, Rehman A. Subsequent effect of dietary lysine regimens fed in the starter phase on the growth performance, carcass traits and meat chemical composition of aseel chicken in the grower phase. Brazilian Journal of Poultry Science 2018;20:455-462.

[23] Hussain M, Mahmud A, Hussain J, Qaisrani SN, Mehmood S, Ahmad S, et al., Effect of dietary amino acid regimens on growth performance and body conformation and immune responses in Aseel chicken. Indian Journal of Animal Research 2020;(54):53-58.

[24] Jongbloed A, Mroz Z, Van der Weij-Jongbloed R, Kemme P. The effects of microbial phytase, organic acids and their interaction in diets for growing pigs. Livestock Production Science 2000;67(1):113-122.

[25] Khan M, Anjum AA, Nawaz M, Awan AR, Ali MA. Effect of newly characterized probiotic lactobacilli on weight gain, immunomodulation and gut microbiota of Campylobacter jejuni challenged broiler chicken. Pakistan Veterinary Journal 2019;39(4):473-478.

[26] Khan M, Anjum AA, Nawaz M, Awan AR, Ali MA, Rehman FU. Effect of Lactobacillus gallinarum PL 53 supplementation on xylose absorption and intestinal morphology in broilers challenged with Campylobacter jejuni. Pakistan Veterinary Journal 2020;40(2):163-168.

[27] Kirchgessner M, Roth F. Ergotrope Effekte durch organische Säuren in der Ferkelaufzucht und Schweinemast. Übersichten zur Tierernährung 2012;16:93-108.

[28] Kliment M, Angelovicová M. Microbial phytase and phosphorus utilization by broiler chickens. Scientific Papers Animal Science and Biotechnologies 2012;45(1):41-45.

[29] Lalpanmawia H, Elangovan A, Sridhar M, Shet D, Ajith S, Pal D. Efficacy of phytase on growth performance, nutrient utilization and bone mineralization in broiler chicken. Animal Feed Science and Technology 2014;192:81-89.

[30] Lan G, Abdullah N, Jalaludin S, Ho Y. Efficacy of supplementation of a phytase-producing bacterial culture on the performance and nutrient use of broiler chickens fed corn-soybean meal diets. Poultry Science 2002;81(10):1522-1532.

[31] Langhout P. New additives for broiler chickens. World Poultry 2000;16(3):22-27.

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Ingredients	Experimental diets
	Starter Ration
	(High Ca and P)	(Low Ca and P)
Corn	590.69	570.32
Rice polishing	50.00	90.00
Soybean meal	300.32	290.55
Vegetable oil	0.680	-
Limestone	10.45	10.48
Mono-calcium phosphate	10.62	8.760
Sodium chloride	2.60	2.20
Sodium-bicarbonate	2.90	2.40
Lysine sulphate	4.10	4.20
DL-Methionine	3.00	3.00
L-Threonine	1.00	1.00
Premix3	5.00	5.00
Total	1000	1000
Calculated nutrients composition g/kg
Crude protein	20	20
Metabolizeable energy (MJ/kg)	12.13	12.13
Calcium	9.80	8.50
Available P	4.50	3.00
Sodium	2.00	1.70
Potassium	8.10	8.50
Chloride	2.30	2.00
DEB4	2310	2340
Dig. Lys	11.5	11.5
Met+Cys	8.50	8.50
Dig. Thr	7.70	7.70
Dig. Tryp	2.20	2.18

Parameters	Dietary treatments
Parameters	1HCHP	2LCLP	3LCLPPH	4LCLPPHOA	p-Values
Feed intake (g)	645±34	632±53	656±23	664±33	0.41
Weight gain (g)	768±63	792±53	809±36	788±45	0.537
Feed conversion ratio	1.55±0.07	1.50±0.18	1.49±0.16	1.54±0.17	0.551

Carcass characteristics	Dietary Treatments
Carcass characteristics	1HCHP	2LCLP	3LCLPPH	4LCLPPHOA	p-Values
Dressing%	56±0.16	54±0.42	57±1.01	59±0.01	0.408
Breast meat yield%	24a±0.24	23ab±0.38	22b±0.36	22b±0.25	0.009
Thigh meat yield%	10b±0.09	10ab±0.09	11a±0.17	11ab±0.16	0.004
Liver weight%	2.1b±0.02	2.2ab±0.05	2.4a±0.05	2.3ab±0.05	0.040
Heart weight%	0.43c±0.01	0.50bc±0.00	0.54ab±0.01	0.56a±0.01	0.003
Gizzard weight%	1.21ab±0.02	1.14b±0.01	1.20ab±0.01	1.28a±0.02	0.011
Spleen weight%	0.08b±0.00	0.11ab±0.00	0.12ab±0.00	0.13a±0.00	0.039

Digestibility	Dietary Treatments
Digestibility	1HCHP	2LCLP	3LCLPPH	4LCLPPHOA	p-Values
Crude protein	70a±3	51b± 4	57ab±4	65ab±3	0.024
Ca	80a±2	53c±2	67b±2	74ab ±2	0.000
p	82a±1	52c±3	75ab ±1	71b ±1	0.000
Na	76a±1	63b±3	70ab±2	64b±3	0.018