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Asian-Australasian Journal of Animal Sciences logoLink to Asian-Australasian Journal of Animal Sciences
. 2013 Jul;26(7):987–994. doi: 10.5713/ajas.2012.12545

Intestinal Development and Function of Broiler Chickens on Diets Supplemented with Clinoptilolite

Q J Wu 1,1, Y M Zhou 1, Y N Wu 1, T Wang 1,*
PMCID: PMC4093499  PMID: 25049877

Abstract

The purpose of this study was to evaluate the effect of natural clinoptilolite (NCLI) and modified clinoptilolite (MCLI) on broiler performance, gut morphology, intestinal length and weight, and gut digestive enzyme activity. A total of 240 d-old male chicks were randomly assigned to 3 treatments, each of which comprised 8 pens of 10 chicks per pen. Birds in the control group were fed the basal diet, while those in the experimental groups were fed diets supplemented with NCLI at 2% (NCLI group), or MCLI at 2% (MCLI group), respectively, for 42 d. Compared with the control, supplementation with NCLI or MCLI had no significant (p>0.05) effects on productive parameters from d 1 to 42. Supplementation with NCLI or MCLI had no influence on the relative length and weight of small intestine at d 1 to 21. But supplementation with NCLI or MCLI significantly reduced the relative weight of duodenum. Supplementation with MCLI and NCLI was associated with greater (p<0.05) villus height in the jejunal and ileal mucosa compared with those areas in the controls from d 1 to 42. However, supplementation with NCLI and MCLI had no significant (p>0.05) influence on the crypt depth in the jejunal and ileal mucosa compared with those in the controls. The addition of either NCLI or MCLI to the diet improved the activities of total protease, and amylase in the small intestinal contents. In conclusion, supplementation with NCLI or MCLI in diets improved intestinal morphology, increased the intestinal length and weigh and gut digestive enzyme activity.

Keywords: Broiler, Clinoptilolite, Histology, Gut, Digestive Enzyme

INTRODUCTION

Natural clinoptilolite (NCLI) is a natural zeolite, which is among the aluminosilicate materials. The aluminosilicate structure is negatively charged and attracts cations that come to reside inside the pores and channels (Mumpton and Fishman, 1977). Zeolites have large empty spaces, or cages, which can accommodate large cations, molecules and cationic groups. The basic structure of zeolites is biologically neutral, so this kind of zeolites have found diverse applications as adsorbents, ion exchangers and catalysts in industry, agriculture, veterinary medicine, sanitation and environmental protection. They are also used as a feed additive (Mumpton and Fishman, 1977; Mumpton, 1999; Martin-Kleiner et al., 2001).

Data support a favorable situation for potential applications in animal feeding. Numerous studies were shown that added CLI as a dietary supplement to the rations of cattle, pigs and poultry frequently were resulted in beneficial weight gains and less subject to disease, and show regular digestions, as well as an increase in appetite of animal. Because zeolites can slows the passage rate of digesta through the digestive tract and controls the release of nutrients in the gut (Evans, 1993; Olver, 1997; Papaioannou et al., 2002). On the other hand, zeolite’s primary values are as growth promoters and carriers of a number of macro- and microchemical elements which are necessary for the vital activity of living organisms (such as vitamins; minerals, antibiotics and other active compounds). As growth promotoers zeolites appear to act as a buffer in the animals digestive system, storing nitrogen in the form of ammonium and releasing it gradually by ion exchange with zeolite (Maeda and Nosé, 1999). And the microelements present in zeolite, like calcium, potassium, sodium, as well as the majority of microelements can enhanced mineral metabolism, increased the content of macro- (Ca, K, Na) and microelements in the tissues and the organs. Due to the presence of these elements, which are capable of getting involved in the exchange, the ion composition of the chyme changes, which normalizes the pH and optimizes the activity of digestive enzymes, favorable effect on feed components hydrolysis over a wider range of pH, improved energy and protein retention (Cabezas et al., 1991; Shadrin, 1998; Parisini et al., 1999; Teimuraz et al., 2009). It is also possible that CLI remove toxins and create changes in enzymology and immunological responses (Oguz, 2011).

Similar effects were observed with some synthetic zeolites. Zeolites NaX, NaY, NaA, and CaA were evaluated in vitro for their ability to protect animal against the effects caused by bacteria or toxins, and further improving animal growth performance by enhancing nutrient absorption in cows, lambs, pigs and laying hens (Pond, 1995; Olver, 1997; Miazzo et al., 2000; Heather et al., 2009). However, further studies are needed to investigate the effect of CLI specifically on gut morphology, gut development and gut digestive enzyme activity in broilers.

It is well known that NCLI and modified CLI (MCLI) can affect the nutrient absorption and animal growth performance. Enterocyte enzymatic activity, structure and development are the most important features of the intestinal mucosal physiology. However, no information is available regarding the effect of adding NCLI and MCLI to broiler diets on the intestinal morphology. Based on this concept, the aim of the study is to evaluate the impact of dietary supplementation with these compounds, to test whether they also have an overall beneficial effect on broiler growth performance gut morphology, gut development and gut digestive enzyme activity of broiler chickens.

MATERIALS AND METHODS

Birds, housing and diets

A total of 240 d-old Arbor Acres male broiler chicks were allocated to three dietary treatments in a randomized complete block design for 42 d, each of which was replicated three times with 10 broilers per replicate. The dietary treatments were: i) basal diet, ii) basal diet+2% NCLI, iii) basal diet+2% MCLI. All birds were housed in wire cages in a 3-level battery, and housed in pens of identical size (1.75×6 m) in a deep litter system.

All the procedures were approved by the Institutional Animal Care and Use Committee of the Nanjing Agricultural University. Birds were housed in an environmentally controlled room. The initial temperature of 32°C was gradually reduced according to the age of the birds, reaching 20°C at the end of the experiment. The lighting cycle was 24 h from 1 to 3 d of age, 18 h from 4 to 20 d of age, 21 h from 21 to 35 d of age, and 23 h from 35 to 42 d of age.

The basal diets were of the maize-soya bean type. Broilers were fed a starter diet from d 1 to 21 and a grower diet from d 22 to 42 (Table 1). The diets were formulated in accordance with the NRC (1994) guidelines to meet the nutrient requirements of broilers. Diet compositions are shown in Table 3. Fresh diets were prepared once a week and were stored in sealed bags at 4°C.

Table 1.

Formulation and calculated composition of broiler diets (on fed basis)

Item 1–21 d 22–42 d
Ingredients (%)
  Maize 59.1 64.3
  Soybean meal 30.6 24.3
  Corn gluten meal 3.8 4.5
  Lard 1.7 2.5
  Limestone 1.31 1.23
  Dicalcium phosphate 1.77 1.58
  Sodium chloride 0.42 0.33
  L-lysine 0.15 0.16
  DL-methionine 0.15 0.1
  Premix* 1 1
Calculation of nutrients
  Apparent metabolism energy (MJ/kg) 12.27 12.77
  Crude protein (%) 21.2 19.3
  Ca (%) 1.0 0.91
  Available P (%) 0.43 0.38
  Lysine (%) 1.08 0.95
  Methionine (%) 0.50 0.43
  Methionine+cystine (%) 0.82 0.73
*

Premix provided per kg of diet: limestone, 3.3 g; L-lysine HCl, 1.5 g; Dl-methionine, 1.3 g; VA 10,000 IU, VD3 3,000 IU, VE 30 IU, menadione, 1.3 mg, thiamine 2.2 mg, riboflavin, 8 mg, nicotinamide 40 mg, choline chloride 600 mg, calcium pantothenate 10 mg, pyridoxine HCl, 4 mg, biotin 0.04 mg, folic acid 1 mg; vitamin B12 (cobalamine) 0.013 mg, Fe (from ferrous sulphate) 80 mg, Cu (from copper sulphate) 8 mg, Mn (from manganese sulphate) 110 mg, Zn (Bacitracin Zn), 65 mg, iodine (from calcium iodate) 1.1 mg, Se (from sodium selenite), 0.3 mg.

Table 3.

Effects of NCLI (2%) and MCLI (2%) on the relative length (cm/kg) and relative weights (g/kg) of small intestine in broilers

Items1 Diet treatments
SEM p value
Control2 NCLI2 MCLI2
1 to 21 d
  Relative length
    Duodenum 34.47 31.55 31.05 0.84 0.206
    Jejunum 73.50 74.26 73.60 0.69 0.980
    Ileum 67.71 69.63 70.74 0.63 0.606
  Relative weights
    Duodenum 9.52 8.62 8.59 0.29 0.347
    Jejunum 14.67 15.35 15.87 0.37 0.433
    Ileum 10.34 10.73 11.10 0.22 0.384
22 to 42 d
  Relative length
    Duodenum 11.27 10.71 10.59 0.39 0.769
    Jejunum 25.04a 24.44a 29.54b 0.94 0.042
    Ileum 28.70 28.17 31.97 0.85 0.140
  Relative weights
    Duodenum 7.61a 3.95b 5.34c 0.43 0.002
    Jejunum 8.44a 8.37a 10.56b 0.41 0.036
    Ileum 8.05 7.93 9.03 0.22 0.079
1

Data represent means from 8 replicates per treatment, SEM = Standard error of mean.

2

Control = Basal diet; NCLI = Basal diet supplemented with 2% natural Clinoptilolite; MCLI = Basal diet supplemented with 2% formic acid modified clinoptilolite.

3

Means with different superscript letters in the same line differ significantly; Lowercases represent p<0.05.

The NCLI used in this study was collected from the Center of China Geological Survey (Nanjing). The grain-size distributions for the samples studied were 0.15 to 0.2 mm. For modification of natural CLI, the starting material was calcined in a muffle oven at 400°C for 4 h, and formic acid was gently stirred in to ensure good dispersion. The mixture was repeatedly washed with deionized water. After stirring, the sample was allowed to settle. The sediment was oven-dried at 65°C for 2 h, then ground in an agate mortar and sieved through a 100-mesh.

Performance and the length and weight of intestinal segments

During the overall experimental period, weights of chicks were measured weekly. Feed supplied and feed leftover were weighed on the same days as above, to calculate the feed intake (FI) and feed/gain ratio (F/G). Mortalities were recorded daily and were used to adjust the total number of birds by the end of 42 d, to determine the feed intake and F/G of the broilers. At the end of each experimental period (21 or 42 d), 8 broilers per group (one bird per replicate) from each treatment were randomly selected and weighed after feed deprivation for 12 h, were slaughtered. Then, the intestinal segments were excised. The small intestine was divided into 3 segments: duodenum (from gizzard outlet to the end of the pancreatic loop), jejunum (from the pancreatic loop to Meckel’s diverticulum), and ileum (from Meckel’s diverticulum to the cecum junction). The contents of the duodenum, jejunum, and ileum (aseptically) were emptied by gentle pressure, then the length and weight were recorded.

Morpholoical measurement of the jejunal and ileal mucosa

Three cross-sections for each intestinal segment (jejunum and ileum) were fixed with formalin solution and were prepared using standard paraffin embedding procedures by sectioning at 5 μm thickness, and staining with hematoxylin and eosin. A total of 15 intact, well-oriented crypt-villus units were measured in each type of tissue from each broiler. Villus height and crypt depth were determined using an image processing and analyzing system (version 6.0, Image-Pro Plus), and were expressed as micrometers (μm).

Digestive enzyme activities of intestinal contents

The samples of duodenum, jejunum, and ileum contents (0.2 g) were homogenized with 4 ml icecold saline (0.9% NaCl). The digesta sample were stored immediately at −70°C until it be used. The small intestinal digesta samples were diluted 10×, based on the sample weight, with ice-cold PBS (pH 7.0), homogenized for 60 s, and sonicated for 1 min with three cycles at 30 s intervals. The sample was then centrifuged at 6,000 g for 15 min at 4°C. The supernatants were divided into small portions and stored at −70°C for assay of enzyme assays. Protease, trypsin, chymotrypsin and amylase were measured according to the methods described by Lhoste et al. (1993).

Statistical analysis

Analyses of variance were performed using the General Linear Model procedure of statistical package for social sciences 18.0 (SPSS Inc., Chicago, IL, USA) as a completely randomized design. Results are presented as mean±standard error of the mean (SEM). The significant differences among different treatment means were investigated using Duncan’s new multiple range test. Effects were considered significant at p<0.05.

RESULTS AND DISCUSSION

Effects of NCLI (2%) and MCLI (2%) on the growth performance of broilers

The effects of the dietary treatments on broiler chicks’ feed intake, average body weight gain (BWG), and F/G data in the periods of starter, grower, and the whole trial are presented in Table 2. It can be seen that no significant differences were observed between treatments from 1 to 42 d.

Table 2.

Effects of NCLI (2%) and MCLI (2%) on the growth performance of broilers

Item1 Diet treatments
SEM p value
Control3 NCLI3 MCLI3
BWG2 (kg)
  1 to 21 d 0.542 0.551 0.564 0.011 0.976
  22 to 42 d 1.392 1.421 1.435 0.017 0.432
  1 to 42 d 1.934 1.972 1.999 0.015 0.831
FI2 (g/bird/d)
  1 to 21 d 41.12 40.97 40.83 0.786 0.765
  22 to 42 d 130.85 129.87 128.01 1.235 0.798
  1 to 42 d 171.97 170.84 168.84 2.034 0.874
F:G2
  1 to 21 d 1.593 1.560 1.519 0.034 0.792
  22 to 42 d 1.974 1.918 1.873 0.036 0.823
  1 to 42 d 1.867 1.819 1.774 0.021 0.715
1

Data represent means from 8 replicates per treatment, SEM = Standard error of mean.

2

BWG = Body weight gain; FI = Feed intake; F/G = Feed intake/BW gain.

3

Control = Basal diet; NCLI = Basal diet supplemented with 2% natural Clinoptilolite; MCLI = Basal diet supplemented with 2% formic acid modified clinoptilolite.

In the present study, the results presented in Table 2 show that adding NCLI and MCLI to the diets of broilers from 1 to 42 d of age produced no significant differences in terms of BWG, F/G. These findings are in agreement with those of Evans (1989), who concluded from several experiments that CLI had no consistent beneficial effects. Similarly, the lack of response exhibited by BWG with CLI supplementation concurs with previous reports by Olver (1989), Elliot and Edwards (1991) and Zhou (2008). But some researchers reported that the supplementation of CLI to the diet improves the health status and body weight gain as well as feed efficiency of the animals (Ly et al., 2007). The expected effects of zeolites (CLI) may exhibit variation due to such factors as nature, purity, concentration, particle distribution, the CLI content of the zeolite and formulation composition in the diet. Moreover, Shariatmadari (2008) consider as this phenomenadepending on the aims and objectives of the experimental programme.

No effects of diet on mortality were detected in the present study. These findings suggested that further research regarding CLI as a feed additive is required. Numerous reports indicated that CLI is harmless, by including CLI into mixed feed; it is well tolerated by the animals and improves the production characteristics of broilers (Elliot and Edwards, 1991; Trckova et al., 2004).

Effects of NCLI and MCLI on the relative length, weights of intestine and morphology (μm) of intestinal mucosa in broilers

The effects of dietary NCLI and MCLI on the relative length and weight of small intestine in broilers are shown in Table 3. Broilers were pretreated with NCLI or MCLI, there was no dietary effect on the relative length and weight of duodenum, jejunum and ileum (p>0.05) in the period of 1 to 21. Moreover, there was no significant influence on the relative length of duodenum and ileum (p>0.05), and the relative weights of ileum (p>0.05) in the period of 22 to 42. When broilers were treated with MCLI, the relative length and weight of jejunum were significant increased (p<0.05). However, the relative weight of duodenum in the NCLI group were significantly lower than the control group and the MCLI group (p<0.05), and those of the MCLI group were significantly lower than the control group (p<0.05).

Morphological measurements of jejunal and ileal mucosae are presented in Table 4. During the overall experimental period the villus height in the jejunal mucosa in the MCLI group were higher (p<0.05) than those of the control group and NCLI group. The villus heights in the jejunal mucosa in the NCLI group were greater (p<0.05) than those in the control group, but they were lower (p<0.05) than in the MCLI group. The villus height in the ileal mucosae of chicks receiving the NCLI and MCLI in the feed was significantly greater than in the control group (p<0.05), but there were no significant differences between the two groups (p>0.05) during the overall experimental period. Supplementation with NCLI and MCLI had no significant (p>0.05) influence on the crypt depth in the jejunal and ileal mucosa compared with the controls during the overall experimental period. During the overall experimental period, the MCLI-supplemented group differed significantly from the control group in terms of the villus height to crypt depth ratio in the jejunal and ileal mucosa (p<0.05).The villus height to crypt depth ratio in the NCLI group was not significantly different from either the control group or the MCLI group (p>0.05).

Table 4.

Effects of NCLI (2%) and MCLI (2%) on the morphology (μm) of the intestinal mucosa in broilers

Items Diet treatments
SEM p value
Control2 NCLI2 MCLI2
1 to 21 d
  Jejunum
    Villus height (μm) 818.78a 904.96b 969.35c 12.62 0.002
    Crypt depth (μm) 123.00 114.17 106.03 3.80 0.194
    Villus height:crypt depth 6.66a 7.93ab 9.16b 0.31 0.003
  Ileum
    Villus height (μm) 517.83a 549.32b 570.76b 6.21 0.001
    Crypt depth (μm) 131.49 118.74 105.06 5.68 0.166
    Villus height:crypt depth 3.95a 4.66ab 5.45b 0.23 0.012
22 to 42 d
  Jejunum
    Villus height (μm) 1,054.94a 1,193.63b 1,344.99c 14.69 0.001
    Crypt depth (μm) 146.44 134.53 121.22 4.75 0.091
    Villus height:crypt depth 7.21a 8.88ab 10.13b 0.38 0.001
  Ileum
    Villus height (μm) 789.49a 844.64b 902.55b 9.27 0.002
    Crypt depth (μm) 148.44 128.55 125.13 4.27 0.051
    Villus height:crypt depth 5.32a 6.57ab 7.21b 0.23 0.001
1

Data represent means from 8 replicates per treatment, SEM = Standard error of mean.

2

Control = Basal diet; NCLI = Basal diet supplemented with 2% natural Clinoptilolite; MCLI = Basal diet supplemented with 2% formic acid modified clinoptilolite.

3

Means with different superscript letters in the same line differ significantly; Lowercases represent p<0.05.

The present study showed change in the relative weight of the jejunum in birds fed with NCLI or MCLI supplemented diet (p<0.05). These may be associated with slower passage of ingest through the digestive tract, and the jejunum utilized the limited nutrients for its growth with higher priority over body weight increase. Greater villus heights in the jejunal and ileal mucosa indicate that the function of the intestinal villi was increased (Ruttanavut and Yamauchi, 2010). In the present study, increases were observed in villus height and villus height to crypt depth ratio in the small intestinal mucosa of the broiler chicks supplemented with NCLI and MCLI. These results are in agreement with the findings of Tatar et al. (2008), who suggest that zeolite can stimulate villi of the small intestine. Such improvement in the morphology of the intestinal mucosa may be explained by the lower numbers of E. coli and Salmonella. It is reported that NCLI, a mucus stabilizer, effectively acts by attaching to the mucus to reinforce the intestinal mucosal barrier, and helps in the regeneration of the epithelium, therefore reducing intestinal colonization and infectious processes. This ultimately decreases inflammatory processes at the intestinal mucosa, thus increasing villus height and secretory activity (Loddi et al., 2004). Furthermore, increased villus size was also associated with activated cell proliferation in the crypt (Lauronen et al., 1998). In conclusion, the present results and related literature suggested that these intestine morphological changes might be induced by improved jejumum and ileum lumen due to adsorptive function of the crystal structural cavities of CLI (Khambualai et al., 2009), because a crystal structure of CLI is thought to induce epithelial cell generation in broilers (Mumpton and Fishman, 1977).

Effects of NCLI (2%) and MCLI (2%) on the activities of digestive enzymes of the intestinal contents in broilers (U/g)

As shown in Table 5, NCLI and MCLI had an effect on digestive enzyme activities of duodenum content. Markedly increased activities of digestive enzyme including protease, chymotrypsin, trypsin and amylase in the small intestinal contents were observed in the NCLI and MCLI-treated groups during the overall experimental period (p<0.05).

Table 5.

Effects of NCLI (2%) and MCLI (2%) on the activities of digestive enzymes of the intestinal contents in broilers (U/g)

Items1 Diet treatments
SEM p value
Control2 NCLI2 MCLI2
1 to 21 d
  Duodenum
    Amylase 446.09a 632.27b 645.23b 20.03 0.002
    Trypsin 4.38a 5.47b 5.83b 0.14 0.001
    Chymotrypsin 5.23a 6.23b 6.50b 0.64 0.000
    Protease 6.84a 8.21b 8.62b 0.89 0.001
  Jejumum
    Amylase 468.35a 576.88b 620.75b 15.20 0.002
    Trypsin 5.11a 6.53b 6.88b 0.18 0.001
    Chymotrypsin 5.93a 6.85b 7.28b 0.15 0.003
    Protease 7.07a 8.59b 9.08b 0.21 0.001
  Ileum
    Amylase 462.78a 546.48b 552.61b 11.48 0.001
    Trypsin 4.89a 6.19b 6.31b 0.18 0.002
    Chymotrypsin 5.73a 6.91b 7.14b 0.15 0.001
    Protease 6.88a 8.37b 8.49b 0.22
22 to 42 d
  Duodenum
    Amylase 422.82a 465.15b 479.48b 7.37 0.001
    Trypsin 5.35a 6.12b 6.26b 0.11 0.001
    Chymotrypsin 5.47a 7.16b 6.83b 0.17 0.002
    Protease 7.02a 8.35b 8.94b 0.19 0.002
  Jejumum
    Amylase 439.59a 586.26b 601.60b 16.52 0.001
    Trypsin 5.31a 6.23b 6.28b 0.12 0.001
    Chymotrypsin 6.12a 7.18b 7.19b 0.13 0.012
    Protease 7.14a 8.29b 8.53b 0.23 0.002
  Ileum
    Amylase 436.74a 535.62b 554.78b 13.13 0.007
    Trypsin 5.30a 6.73b 6.96b 0.18 0.001
    Chymotrypsin 6.09a 7.01b 7.22b 0.14 0.002
    Protease 7.25a 8.86b 8.99b 0.21 0.006
1

Data represent means from 8 replicates per treatment, SEM = Standard error of mean.

2

Control = Basal diet; NCLI = Basal diet supplemented with 2% natural Clinoptilolite; MCLI = Basal diet supplemented with 2% formic acid modified clinoptilolite.

3

Means with different superscript letters in the same line differ significantly; Lowercases represent p<0.05.

In the present experiment, supplementation with NCLI and MCLI could significant improved the activities of the digestive enzymes in the small intestinal contents (p<0.05). Our results were consistent with the previous studies of the clay minerals. It has been reported that the addition of clay to the feedstuffs improved the nutrient digestibility and the enzymatic activity of gastrointestinal secretions (Cabezas et al., 1991; Ouhida et al., 2000; Alzueta et al., 2002; Hu et al., 2004). Because, the ion-exchange properties of the zeolite could alter the pH and increase the content of macro- (Ca, K, Na) and microelements in the gastrointestinal fluids (Teimuraz et al., 2009), thereby changing the enzymatic activity of gastrointestinal secretions (Martin-Kleiner et al., 2001). Moreover, some reports indicate that the villi and microvilli of intestinal mucosa can affect the secretion of digestive enzymes (Gao, 1998). In the present study, increases in villus height and villus height:crypt depth ratio were observed in the small intestinal mucosa of chicks supplemented with NCLI and MCLI. Such improved intestinal mucosal morphology may be explained by the higher enzymatic activity of gastrointestinal contents.

From this study, the following conclusion can be drawn. The supplementation of NCLI and MCLI into the diets of broiler chicks can exert beneficial effect in the gut morphology, gut development and gut digestive enzyme activity. But the mechanism(s) of CLI on the gastrointestinal tract has not yet been studied. Thus, NCLI and MCLI can be beneficial as a feed additive in the broilers diet, and there is a need for further research to understand and clarify the mechanism(s) involved.

Acknowledgments

This research was supported by a project funded by the priority academic program development of Jiangsu higher education institutions.

REFERENCES

  1. Alzueta C, Ortiz LT, Rebole A, Rodriguez ML, Centeno C, Trevino J. Effects of removal of mucilage and enzyme or sepiolite supplement on the nutrient digestibility and metabolyzable energy of a diet containing linseed in broiler chickens. Anim Feed Sci Technol. 2002;97:169–181. [Google Scholar]
  2. Cabezas MJ, Salvador D, Sinisterra JV. Stabilisation-activation of pancreatic enzymes adsorbed on to a sepiolite clay. J Chem Tech Biotechnol. 1991;52:265–274. [Google Scholar]
  3. Elliot MA, Edwards HM. Comparison on the effects of synthetic and natural zeolite on laying hen and broiler chicken performance. Poult Sci. 1991;70:2115–2130. doi: 10.3382/ps.0702115. [DOI] [PubMed] [Google Scholar]
  4. Evans M. 1993. Investigations into the practical applications of zeolites in diets for poultry. PhD Thesis University of New England. [Google Scholar]
  5. Evans M. Zeolites- Do they have a role in poultry production. In: Farrell DJ, editor. Recent Advances in Animal Nutrition in Australia. Armidale: University of New England; 1989. pp. 249–268. [Google Scholar]
  6. Gao LS. (In Chinese) in Digestive Physiology and Health Protection. Curatorial Science and Technology Press; Beijing: 1998. pp. 173–230. [Google Scholar]
  7. Heather AR, Olson K, Johnson P, Wright C. Clinoptilolite as a supplement to reduce the toxic: effects of High-Sulfate Water. 2009. 62nd Society for Range Management Annual Meeting Paper. No 2030-18.
  8. Hu CH, Xia MS, Xu ZR, Xiong L. Effects of copper-bearing montmorillonite on growth performance and digestive function of growing pigs. Asian-Aust. J Anim Sci. 2004;17:1575–1581. [Google Scholar]
  9. Khambualai O, Ruttanavut J, Kitabatake M, Goto H, Erikawa T, Yamauchi K. Effects of dietary natural zeolite including plant extract on growth performance and intestinal histology in Aigamo ducks. Br Poult Sci. 2009;50:123–130. doi: 10.1080/00071660802662788. [DOI] [PubMed] [Google Scholar]
  10. Lauronen J, Pakarinen MP, Kuusanmaki P, Savilahti E, Vento P, Paavonen T, Halttunen J. Intestinal adaptation after massive proximal small-bowel resection in the pig. Scand J Gastroenterol. 1998;33:152–158. doi: 10.1080/00365529850166879. [DOI] [PubMed] [Google Scholar]
  11. Lhoste EF, Fiszlewicz M, Gueugneau AM, Wicker-Planquart C, Puigserver A, Corring T. Effects of dietary proteins on some pancreatic mRNAs encoding digestive enzymes in the pig. J Nutr Biochem. 1993;4:143–152. [Google Scholar]
  12. Loddi MM, Maraes VMB, Nakaghi ISO, Tucci F, Hannas Mi, Ariki JA. Mannan oligosaccharide and organic acids on performance and intestinal morphometric characteristics of broiler chickens. In proceedings of the 20th annual symposium. 2004;1(Supplement):45. [Google Scholar]
  13. Ly J, Grageola F, Lemus C, Castrp M. Ileal and rectal digestibility of nutrients in diet based on leucaena for pigs, influence of the inclusion zeolite. J Anim Vet Adv. 2007;6:1371–1376. [Google Scholar]
  14. Maeda T, Nosé Y. A new antibacterial agent: Antibacterial Zeolite. Artificial Organs. 1999;23:129–130. doi: 10.1046/j.1525-1594.1999.00751.x. [DOI] [PubMed] [Google Scholar]
  15. Martin-Kleiner I, Flegar-Meštrić Z, Zadro R, Breljak D, Janda S, Stojković S, Marušić RM, Radačić M, Boranić M. The effect of the zeolite clinoptilolite on serum chemistry and hematopoiesis in mice. Food Chem Toxicol. 2001;39:717–727. doi: 10.1016/s0278-6915(01)00004-7. [DOI] [PubMed] [Google Scholar]
  16. Miazzo R, Rosa CAR, Cavalho ECDQ, Magnoli C, Chiacchiera SM, Palacio G, Saenz M, Kikot A, Basaldella E, Dalcero A. Efficacy of synthetic zeolite to reduce the toxicity of aflatoxin in broiler chicks. Poult Sci. 2000;79:1–6. doi: 10.1093/ps/79.1.1. [DOI] [PubMed] [Google Scholar]
  17. Mumpton FA. La roca magica: Uses of natural zeolites in agriculture and industry. Proceedings of the National Academy of Sciences of the USA. 1999;96:3463–3470. doi: 10.1073/pnas.96.7.3463. [DOI] [PMC free article] [PubMed] [Google Scholar]
  18. Mumpton FA, Fishman PH. The application of natural zeolites in animal science and aquaculture. J Anim Sci. 1977;45:1188–1203. [Google Scholar]
  19. Oguz H. A review from experimental trials on detoxification of aflatoxin in poultry feed. Eurasian J Vet Sci. 2011;27:1–12. [Google Scholar]
  20. Olver MD. Effect of feeding clinoptilolite (zeolite) on the performance of 3 strains of laying hens. Br Poult Sci. 1997;38:220–222. doi: 10.1080/00071669708417973. [DOI] [PubMed] [Google Scholar]
  21. Olver MD. Effect of feeding Clinoptilolite (zeolite) to three strains of laying hens. Br Poult Sci. 1989;30:115–121. doi: 10.1080/00071668908417130. [DOI] [PubMed] [Google Scholar]
  22. Ouhida I, Perez JF, Piedrafita J, Gasa J. The effects of sepiolite in broiler chicken diets of high, medium and low viscosity. Productive performance and nutritive value. Anim Feed Sci Technol. 2000;85:183–194. [Google Scholar]
  23. Papaioannou DS, Kyriakis SC, Papasteriadis A, Roumbies N, Yannakopoulos A, Alexopoulos C. Effect of in-feed inclusion of a natural zeolite(clinoptilolite) on certain vitamin, macro and trace element concentrations in the blood, liver and kidney tissues of sows. Res Vet Sci. 2002;72:61–68. doi: 10.1053/rvsc.2001.0524. [DOI] [PubMed] [Google Scholar]
  24. Parisini P, Martelli G, Sardi L, Escribano F. Protein and energy retention in pigs fed diets containing sepiolite. Anim Feed Sci Technol. 1999;79:155–162. [Google Scholar]
  25. Pond WG. Zeolites in animal nutrition and health: a review. In: Ming DW, Mumpton FA, editors. Natural Zeolites ’93. 1st edition. International Community of Natural Zeolites; Brockport, New York: 1995. p. 449. [Google Scholar]
  26. Ruttanavut J, Yamauchi K. Growth performance and histological alterations of intestinal villi in broilers fed dietary mixed minerals. Asian J Anim Sci. 2010;4:96–106. [Google Scholar]
  27. Shadrin AM. Prirodnye tseolity Sibiri v zhivotnovodstve, veterinarii i okhrane okruzhayushchei sredy. Novosibirsk. 1998:116. (in Russian) [Google Scholar]
  28. Shariatmadari F. The application of zeolite in poultry Production. World Poult Sci J. 2008;64:76–84. [Google Scholar]
  29. Tatar A, Boldaji F, Dastar B, Yaghobfar A. Comparison of different levels of zeolite on serum characteristics, gut pH, apparent digestibility of crude protein and performance of broiler chickens. International Zeolite Conference; Tehran, Iran. 2008. p. 235. [Google Scholar]
  30. Teimuraz A, Karaman P, Tengiz K, Eprikashvili L. Possibility of application of natural zeolites for medicinal purposes. Bull Georg Natl Acad Sci. 2009;3:158–167. [Google Scholar]
  31. Trckova M, Matlova L, Dvorska L, Pavlik I. Kaolin, bentonite and zeolites as feed supplements for animals: Health advantages and risks. Vet Med. 2004;49:389–399. [Google Scholar]
  32. Yang Y, Iji PA, Kocher A, Mikkelsen LL, Choct M. Effects of mannanoligosaccharide on growth performance, the development of gut microflora, and gut function of broiler chickens raised new litter. J Appl Poult Res. 2007;16:280–288. [Google Scholar]
  33. Zhou YM. 2008. Mechanism of nutritional effect and harmful agent reduction of natural zeolite in broilers. PhD thesis, Nanjing Agricultural University, China. [Google Scholar]

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