Document Type : Research article
Authors
Department of Poultry Production, Faculty of Agriculture, Assiut University, Assiut, Egypt
Abstract
Keywords
Main Subjects
Assiut University web-site: www.aun.edu.eg
EFFECT OF USING FORMIC ACID ON GROWTH PERFORMANCE AND SOME BLOOD PARAMETER OF BROILER CHICKEN
H.A. MAHMOUD; O.S. AFIFFY AND M. MAHROUS
Department of Poultry Production, Faculty of Agriculture, Assiut University, Assiut, Egypt
Received: 21 November 2019; Accepted: 30 January 2020
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ABSTRACT
The aim of this study was conducted to evaluate the efficiency of formic acid supplementation as growth promoters in broiler chicken. The study was carried out utilizing 132 Cobb commercial broiler chicks which were randomly assigned into two groups one having three levels of formic acid and the other one as control. Each level contained 2 replicates of 11 chicks each. Birds in tow groups were fed basal diet (starter and grower) whereas birds in formic acid treatment were received water with 0.5, 0.75 and 1% formic acid. Results revealed that the birds supplemented with formic acids had significantly (p<0.0001) lower body weight (BW) and higher body weight gains (BWG) at the levels of 0.75 and 1.0% at 35 days of age. Cumulative feed consumption was decreased (p<0.0001) in the groups supplemented formic acids compared to control group which had high feed intake. Supplementation of formic acid improved (p<0.0001) the feed conversion ratio (FCR) as compared with control group. Increased total fat and bursa weight were observed in groups fed formic acid while, the breast yield and dressed carcass were decreased. Addition of formic acid at level of 1% to the diets of broiler chicken decreased (p<0.001) the caecal viable and coliform counts compared to the un-supplemented group. The pH was decrease in formic acid treated group.
Key words: Broiler chicken, growth, bacteria population, formic acid.
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INTRODUCTION
The key aim of poultry production for the food chain is to obtain proper growth rate and feed conversion efficiency, while maintaining optimal animal health. To achieve this, different feed additives have been produced and offered to poultry market. Recently, poultry industry has paid more attention towards addressing public concern for environmental and food safety. Thus, the non-prescription use of antibiotics in poultry feeds has been eliminated or
Corresponding author: Dr. H.A. MAHMOUD
E-mail address: hussein1905@yahoo.com
Present address: Department of Poultry Production, Faculty of Agriculture, Assiut University, Assiut, Egypt
severely limited. One of the potent feed additives in poultry nutrition is organic acids (OA). Recently, these compounds have been recently investigated by several authors (Gunal et al., 2006; Abdel-Fattah et al., 2008; Biggs and Parsons, 2008) and it has been shown that OA can improve poultry productivity.
Organic acids are used in feeds for their various beneficial effects on gut function and microflora, feed preservation from microbial invasion, inhibition of pathogenic bacteria, enhancing mineral absorption, accelerating recovery from cage fatigue and improvement of nutrient digestibility (Syed et al., 1994; Abdel-Azeem et al., 2000; Fushimi et al., 2001; Dibner and Buttin, 2002; Gornowicz and Dziadek, 2002; Abdo, 2004; Ricke, 2003; Jahanian and Golshadi, 2015). Organic acids and their salts are generally regarded as safe (GRAS) and have been approved by most member states of the EU to be used as feed additives in animal production. Organic acids have growth promoting properties and can be used as alternatives to antibiotics (Patten and Waldroup 1988). Following organic acid feeding, reduction in gastric pH occurs which may increase the pepsin activity (Kirchgessner and Roth 1982) and the peptides arising from pepsin proteolysis trigger the release of hormones, including gastrin and cholecystokinin, which regulate the digestion and absorption of protein (Hersey 1987). The present study was carried on with the objectives to determine the effect of formic acid supplementation on the growth performance and intestinal microflora of broiler chicken.
MATERIALS AND METHODS
A total number of 132 one-day old Cobb broiler chicks were used in this study. All chicks were wing banded, individually weighed and randomly distributed into 2 groups, (1 controls and formic acid treatment). Each group included three level of organic acids. Each level included 2 replicates of 11 chicks each. Each replicate was kept in a partition of 2 square meter provided with wheat straw litter of 5 cm depth. The chicks were maintained under a regimen of 24 hours continuous lighting (Incandescence lambs, 60 watts at 180 cm from the floor) with ad-libitum feed and water.
The feeding program consisted of a starter diet until 15 days and a grower diet until 35 days of age. The composition of basal diet is shown in Table 1. Birds in the control group were given diets without additives (T1). The other treatment was given the same diets as fed to the control groups, but supplemented with 0.5, 0.75 and 1% formic acid (T2). The chemical analysis of feed samples was done as per AOAC (1996). The dietary ingredients were analyzed for crude protein, crude fiber, ether extract and total ash. The body weight of birds per replicate was recorded on individual basis at weekly intervals. Cumulative feed consumption per replicate was also recorded on weekly basis. Feed conversion ratio per replicate was worked out at weekly intervals by taking into consideration weekly body weight gain and feed consumption of respective replicate.
At 35 days of age, six birds per group (one bird from each replicate) around the average weight of the group were taken and slaughtered as a representative sample. Birds were fasted for 8 hours, and then were slaughtered. After slaughtering, the internal organs (heart, liver, empty gizzard and gall- bladder) were removed from the body and then they were weighed. The head, feet and shanks, wings and skin were removed at the occipital bone, hock joints, shoulder joints, and neck close to the shoulder, respectively and then all were individually weighed. Breast (with and without the bones of sternum and ribs), femurs and drumsticks were also weighed as separate carcass parts. The back was separated from breast along the vertebral column. Carcass criteria (weights of carcass, feet and shanks, drumsticks, femurs, drumsticks and femurs, breast and back) were calculated as a percentage of pre-slaughter live body weight. While body organs (heart, liver, full gizzard and gall-bladder) were calculated as a percentage of carcass weight. The fat of abdomen, neck, gizzard, heart, proventriculus, vent and subcutaneous fat were removed and weighed. The fat contents were calculated as a percentage of carcass weight.
blood samples were collected during slaughter period. An aliquot of 3mL of blood was collected and transferred to sterile tubes without anticoagulant. The collected blood samples were submitted in insulated boxes to the Microbiology Lab at Faculty of Medicine. Upon arrival, samples were centrifuged at 720xg for 10 minutes. The obtained sera were transferred to micro tubes and stored under refrigeration (2º to 8º C) for 24 hours until serum biochemical analyses. Levels of total protein (biuret method), albumin (bromocresol green method), globulins (calculated as the difference between the total protein and albumin were determined in individual samples in an automatic analyzer and using commercial kits.
The caecum and ileum of each bird were carefully removed and intestinal contents were immediately collected from the slaughtered bird samples were taken and transferred to the sterile tubes and placed on ice and immediately sent to the Microbiology Lab at Faculty of Medicine to determine the counts of total bacterial and gram negative bacterial counts. Each sample was serially diluted from initial 10-1 to 10-9. Then, 100 µL of diluted samples were plated on the Eosin Methylene Blue (EMB) (for E. Coli) and De Man, Rogosa and Sharpe (MRS) (for Lactobacillus) agar media. Finally, EMB and MRS media were incubated at 37º C for 24 and 48 hours under anaerobic and aerobic conditions, respectively. The results are shown as colony forming unit (CFU) per gram of cecal digesta. (Weinack et al., 1979).
The data obtained were statistically expressed as means ± standard error and assessed by General Linear Model procedure of Data were SAS software (SAS institute, version 6. 2, 1996). Duncan's multiple range test (Duncan, 1955) was used to detect differences among means of different groups.
Table 1: Composition and calculated analysis of the experimental diets.
|
Ingredient % |
Starter diet |
Grower diet |
|
Yellow corn, ground |
53.35% |
58.85% |
|
Soybean meal (44% CP) |
35.10% |
29.60% |
|
Corn gluten meal (60% CP) |
5.50% |
5.50% |
|
Vit. & Min. Premix* |
0.30 |
0.30 |
|
Sunflower oil |
1.90% |
2.3% |
|
Dicalcium phosphate |
2.00% |
1.75% |
|
Limestone |
1.04% |
0.95% |
|
Salt |
0.3% |
0.3% |
|
L- lysine |
0.3% |
0.25% |
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DL- methionine |
0.21% |
0.20% |
|
Total |
100 |
100 |
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Calculated Analysis |
|
|
|
ME, Kcal ∕ Kg |
3000 |
3100 |
|
Crude Protein, (%) |
23 |
21 |
|
Crude Fiber, (%) |
2.88 |
2.95 |
|
Crude Fat, (%) |
5.87 |
6.4 |
|
Ca, (%) |
1.05 |
1.02 |
|
P (Available, %) |
0.39 |
0.4 |
|
Lysine, (%) |
0.75 |
0.71 |
|
Methionine, (%) |
0.37 |
0.32 |
*Vitamins and minerals premix provided per Kilogram of the diet: Vit A, 10.000 IU; Vit D3, 2000 IU; Vit E, 10 mg; Vit K3 , 1 mg; Vit B1, 10 mg; Vit B2, 5 mg; Vit B6, 15000 mg; Vit B12, 10 mg; Nicotinic acid, 30 mg; Pantothenic acid, 10 mg; Folic acid, 1 mg; Biotin, 50 mcg; Chlorine chloride 50%, 500 mg; Iron, 50 mg; Copper, 10 mg; Zinc, 50 mg; Manganese, 60 mg; Iodine, 10 mg; Selenium, 0.1 mg; ** Calculated according to the NRC (1994)
RESULTS
Table 2: The effects of different level of formic acid on growth performance at 35 days of age
|
Levels |
BW |
BWG |
FI |
FCR |
FE |
|
Control |
2000.25a ± 47.66 |
570.70b ±28.82 |
1058.00b ± 4.93 |
1.85b ± 0.12 |
0.54b ± 0.03 |
|
Formic acid (0.5%) |
1742.25b ±81.21 |
427.10c± 46.72 |
915.43a± 6.55 |
2.14b ± 0.28 |
0.47c ± 0.07 |
|
Formic acid (0.75%) |
1733.91b± 53.02 |
734.09a ± 26.34 |
947.24a± 5.31 |
1.29a ± 0.05 |
0.77a ± 0.05 |
|
Formic acid (1.0%) |
1743.64b± 47.25 |
772.14a ± 21.62 |
1055.90b± 2.18 |
1.37a± 0.04 |
0.73a ± 0.04 |
|
P value |
<0.0001** |
<0.0001** |
<0.0001** |
<0.0057* |
<0.0042* |
a, b and c Means (±SE) in the same column with different superscripts are significantly different ** is high significance * is significance
Body weight (BW): The birds were received formic acid at all level at all level had the lowest BW (p<0.0001) as compared with the control groups. The lowest BW (1733.9 g) was recorded for birds were received formic acid level of 0.75%.
Body weight gain (BWG): The data shown in table (2) cleared that the formic acid at level of 0.5 and 1.0% had improved BWG (p<0.0001)the result in contrast obtained at level of 0.5% compared with control group.
Feed Consumption (FC): The results obtained from table (2) explained thatthere is no significant differences (p<0.0001) between the FC of control group and formic acid at level of 1.0%. The differences of FC between birds were received formic at levels of 0.5 and 0.75% were significantly decreased (p<0.0001) as compared with the other groups.
Feed conversion ratio (FCR): Fed formic acid at levels of 0.75 and 1.0% had significantly improved (P <0.0057) the FCR as compared with control group. No significant differences detected of FCR between birds were received formic acid at level of 1.0% and control group.
Table 3: The effect of formic acid on Lipid profiles of the studied broiler chickens
|
Parameter |
Control |
Formic acid |
P value |
|
TCHOL (mg/dl) |
65.04±4.14 |
65.17±4.14 |
--------- |
|
HDL (mg/dl) |
50.87b±6.65 |
29.33a±6.65 |
<0.0001** |
|
LDL (mg/dl) |
14.17a±8.51 |
35.84b ± 8.51 |
<0.0001** |
|
TG (mg/dl) |
47.80±20.69 |
48.00±11.94 |
<0.561 |
a, b and c Means (±SE) in the same row with different superscripts are significantly
** is high significance
HDL cholesterol: The results obtain from table (3) cleared that there is significantly increased (P <0.0001) of HDL cholesterol, in formic acid treated group.
LDL cholesterol: The results obtain from table (3) indicated that the formic acid had increased (P <0.0001) LDL cholesterol compared with control group.
Triglycerides (TG): The results of triglycerides (TG)indicated thatno significance difference (P <0.0001) between formic acid compared with the control group.
Table 5: The antibacterial effect of formic acid
|
Treatments
Parameter |
Control |
Formic acid |
P value |
|
Bacteria population (0.5%) |
2.85X106 |
1.0X106 |
------- |
|
Bacteria population (0.75%) |
2.85X106 |
4.5X106 |
------- |
|
Bacteria population (1.0%) |
2.85X106b |
8X104a |
<0.001** |
a, b and c Means (±SE) in the same row with different superscripts are significantly
** is high significance
The antibacterial effect of formic acid was also observed in the present study (Table 5) in which significantly (p<0.001) reduction in total bacterial and gram negative bacterial counts in broiler chicken received formic acid at level of 1.0%.
Table 4: Carcass parts as affected by formic acid supplementation
|
Treatments
Parameter |
Control |
Formic acid |
P value |
|
Live body weight |
2095a±102.25 |
1964b ± 87.15 |
<0.001** |
|
Dressed carcass (g) (including giblets) |
1551.66a± 74.12 |
1432.50b± 52.41 |
<0.007** |
|
Chilled carcass (g) |
1588.33a± 74.92 |
1476.67b± 74.93 |
<0.001** |
|
Heart (g) |
9.73± 7.51 |
9.08± 5.31 |
<0.743 |
|
Liver (g) |
39.47 b ± 5.09 |
32.20a ± 3.60 |
<0.0226* |
|
Gizzard (g) |
42.84b ± 3.52 |
31.6a± 2.98a |
0.004* |
|
Kidney (g) |
2.83a± 0.39 |
1.97b± 0.27 |
<0.006* |
|
Spleen (g) |
37.47± 0.99 |
40.20± 0.70 |
<0.235 |
|
Bursa (g) |
1.47a± 0.64 |
4.15b± 0.45 |
<0.001** |
|
Fat pad (g) |
13.87b± 3.78 |
20.18a± 2.93 |
<0.004* |
|
Total fat (g) |
46.17b± 8.58 |
64.62a± 9.38 |
<0.0267* |
|
Breast (g) including sternum bone |
540.00± 31.61 |
510.00± 25.81 |
0.325 |
|
Breast yield (g) |
460.00a± 29.95 |
431.67b± 24.45 |
0.0417* |
|
Feet & Shank (g) |
86.67a± 4.97 |
71.67b± 3.52 |
<0.0692* |
|
Drumstick (g) |
220.00± 15.84 |
218.33± 12.93 |
<0.4295 |
|
Femurs (g) |
380.00± 16.86 |
368.33± 13.77 |
<0.195* |
|
Back (g) |
145.00b±16.88 |
146.67b± 13.78 |
<0.534 |
a, b and c Means (±SE) in the same row with different superscripts are significantly different ** is high significance * is significance
Dressed carcass (including giblets): The dressed carcass of formic acid treated groupt was significantly lower than the control group. The same trend was observed in the chilled carcass values.
Breast yield: The average of breast weight of formic acid treated group was significantly decreased (p
Liver weight: Formic acid had decreased (P<0.0226) the lever weight by 18% as compared with the control group.
Gizzard weight: Formic acid decreased (P<0.004) the gizzard weight by 26% as compared with the control group.
Fat pad: The average of fat pad of formic acid treatment was numerically significantly higher (p<0.004) as compared with control group.
Bursa weight: The average of bursa weight of formic acid treatment was numerically significantly higher (p<0.001)by 182% as compared with the control group.
Table 6: Comparison between chemical composition of carcass meat of the studied broiler chickens.
|
Treatments
Parameter |
Control |
Formic acid |
P value |
|
protein % |
24.08± 2.13 |
23.32± 1.05 |
<0.362 |
|
Fiber % |
0.57b± 0.94 |
0.47b±0.47 |
<0.0593* |
|
Fat % |
12.94± 4.78 |
13.32±2.765 |
<0.486 |
|
Moister |
68.23± 2.58 |
68.63±1.29 |
<0.327 |
|
Ash |
4.11± 0.97 |
5.01±0.56 |
<0.497 |
a, b and c Means (±SE) in the same row with different superscripts are significantly
* is significance
Table 7: Serum biochemical parameters of broilers fed different experimental diets
|
Treatments
Parameter |
Control |
Formic acid |
P value |
|
pH |
7.09±0.08 |
6.88±.09 |
<0.274 |
|
Glucose (mg/dl) |
207.00a± 25.72 |
156.67b± 14.85 |
<0.058* |
|
Total protein (g/L) |
26.04± 4.12 |
29.76±4.14 |
<0.0437* |
|
Globulin (g/L) |
14.75a±1.22 |
16.48b±1.14 |
<0.036* |
|
Albumin (g/L) |
11.29a±1.01 |
13.28b±1.17 |
<0.286* |
|
A/G ratio |
0.77a±0.11 |
0.82b±0.11 |
<0.028* |
a, b and c Means (±SE) in the same row with different superscripts are significantly
* is significance
DISCUSSION
Cumulative feed consumption was found decreased (p<0.0001) in formic acid group compared to control group (Table 2). Vogt et al. (1979)reported that the reduction in the feed intake might be due to the strong taste associated with the formic acids which would have decreased the palatability of feed, thereby reduced feed intake. Runho et al. (1997)observed that formic acid improved significantly feed: gain ratio in broiler chickens when it was included in the diet from 0·25 to 1%, because a reduction of consumption was noticed, but growth was significantly decreased (p<0.001). The performance-enhancing effects of organic acids in poultry do not appear to be as pronounced as in pigs (Langhout, 2000).
Similar results were found by Leeson et al. (2005) who reported reduction in the feed consumption in groups fed butyric acid supplemented diets compared with the group fed control diet. Chicks fed the diets supplemented with formic acids at level of 0.75 and 1% showed a significant (p<0.001) improved in the FCR as against the chicks fed control diet. The improvement in FCR could be possibly due to lesser feed intake resulting in increased body weight gain because of better utilization of nutrients in the birds fed formic acids supplemented diet. These results are in agreement with the reports of Vogt et al. (1981) who reported that organic acids improved the FCR in broiler chicken and Adil et al. (2010, 2011b) who found that the highest weight gains were achieved in the birds fed 3% fumaric acid as compared to the group fed diet supplemented with 3% lactic acid. Chicks fed the diet supplemented with organic acids showed a significant (P < .05) improvement in the FCR as against the chicks fed the control diet.
Results indicated that the birds fed formic acid at level of 0.75 and 1.0% in water had higher BWG (p<0.001) at 35 days of age compared to control group (Table 3). These results are in agreement with Owens et al. (2008) who reported that improved body weight gains in broiler chicken fed organic acid supplemented diet. Also there was decrease in dressed carcass and breast yield while, increased total fat and bursa weight.
The formic acid had worst effects (p<0.0001) on lipid profile through increasing LDL and TG levels while decreasing HDL level as showed in table (3). These results may be due to increase the total fat of carcass. The results related to carcass part (Table 4) rivaled supplemented formic acid in water had significantly decreased breast yield (p<0.0417) and dressed carcass weight (p<0.007).
The antibacterial effect of formic acids was also observed in the present study (Table 4).A significant (p<0.001) reduction in the caecal viable and coliform counts in birds fed formic acid at level of 1% was recorded. Similar effects were observed by Owens et al. (2008) and Pirgozliev et al. (2008) reporting significantly (p<0.05) reduced total viable coliform numbers in the ileum and caecum of broiler chicken due to organic acid supplementation. Gunal et al. (2006) also reported that the use of organic acid mixture significantly decreased the total bacterial and gram negative bacteria. (Moharrery and Mahzonieh 2005) recorded decrease in E. coli population in the intestines of broiler chicken with malic acid. Hamed and Hassan (2013) reported that a significant (P < .5) reduction in total bacterial count in ceca was observed in both the groups treated with acetic acid (3 mL/L) and organic acid mixture (3 mL/L; acetic acid, phosphoric acid, lactic acid, fumaric acid and tartaric acid), which were administered through drinking water to Japanese quails at 7 days post infection as compared to the non-treated group. These studies explained that the key basic principle of the mode of action of organic acids on bacteria is that non-dissociated organic acids can penetrate the bacteria cell wall and disrupt the normal physiology of certain types of bacteria that we call ‘pH sensitive’ meaning that they cannot tolerate a wide internal and external pH gradient. Furthermore, the organic acids in poultry might have a direct effect on the gastrointestinal tract (GIT) bacteria population, reducing the level of some pathogenic bacteria and mainly controlling the population of certain types of bacteria that compete with the birds for nutrients.
The effect of dietary supplementation of different levels of formic acid on carcass characteristics and none-carcass components are presented in (Table 4). Dressed carcass weight (g) was significantly decreased (P<0.007) in the group fed diet supplemented with formic acid compared to the group received control diet. In contrast Garcıá et al. (2007) reported that the carcass, right breast and right thigh yields of broilers at 49 days of age were unaffected by supplementation of formic acid (0.5% or 1.0%).
In the current study, Liver, gizzard and kidney weight, were significantly decreased (P<0.007)when the broilers fed different levels of formic acid compared to the control diet; however, the heart and spleen weight were not affected. the reducing effect of formic acid on liver and gizzard weight could be attributed in part to the partial hydrolysis and destruction of cell wall components of feed ingredients, whereby reduce the grinding action of gizzard and its relative weight (Leeson et al., 2005; Jahanian and Golshadi, 2015). On the other hand, the antibacterial effect of organic acid is believed to take mainly place in the upper part of the digestive tracts like crop and gizzard (Canibe et al., 2001). Therefore, decrease in gizzard weight could be explained in part by the decrease in microbial populations of upper parts by dietary organic acid supplementation (Dehghani-Tafti and Jahanian, 2016).
The pH value in the crop and caeca was decreased but the values were not significant (p<0.001) in caecum agreeing with the results of Waldroup et al. (1995) who reported that the addition of lactic acid at a concentration from 0.25 to 2% or formic acid from 0.5 to 2% to broiler diet had no effect on caecal pH. The pH values in the crop and caeca got reduced as the concentration of dietary organic acids increased, but the values were within the physiological pH range. Bolton and Dewar (1964) found that the effects of organic acids down the digestive tract gets diminished because of reduction in the concentration of acids as a result of absorption and metabolism, thus justifying the present findings of significantly decreased pH in the crop and not in the caeca. Caecal pH did not decrease much but there was significant (p<0.001) reduction in the number of caecal microflora which could be plausibly due to the reduced entry of pathogenic bacteria from the upper parts of GIT (crop) into the intestines of broiler chicken. The lowered pH is conducive for the growth of favourable bacteria simultaneously hampering the growth of pathogenic bacteria which grow at relatively higher The effect of dietary supplementation of different levels of formic acid on carcass characteristics and none-carcass components are presented in (Table 4). Dressed carcass weight (g) was significantly decreased (P<0.007) in the group fed diet supplemented with formic acid compared to the group received control diet. Ghazala et al. (2011) reported that dietary 0.5% of formic acid and 0.75% of acetic or 2% citric acid improved both ME and nutrient digestibility, crude protein (CP), ether extract (EE), crude fibre (CF) and nitrogen-free extract (NFE) of broiler diets. Moreover, Hernández et al. (2006) and Garciá et al. (2007) reported that supplementation of formic acid (0.5% or 1.0%) in broiler finisher diet was found to improve apparent ileal digestibility (AID) of dry matter (DM) (67.8% or 68.8%, respectively) and CP (72.5% or 73.5%, respectively) as compared with control (56.4% DM and 60.7% CP). Similarly, 2% citric acid in the broiler diet also increased the retention of DM, CP and neutral detergent fiber (Ao et al., 2009).
In the present study, liver, gizzard and kidney weight, were significantly decreased (P<0.007)when the broilers fed different levels of formic acid compared to the control diet; however, the heart and spleen weight were not affected. the reducing effect of formic acid on liver and gizzard weight could be attributed in part to the partial hydrolysis and destruction of cell wall components of feed ingredients, whereby reduce the grinding action of gizzard and its relative weight (Leeson et al., 2005; Jahanian and Golshadi, 2015). On the other hand, the antibacterial effect of organic acid is believed to take mainly place in the upper part of the digestive tracts like crop and gizzard (Canibe et al., 2001). Therefore, decrease in gizzard weight could be explained in part by the decrease in microbial populations of upper parts by dietary organic acid supplementation (Dehghani-Tafti and Jahanian, 2016).
Due to pH reducing properties and direct antimicrobial effect, formic acids might have resulted in inhibition of intestinal bacteria leading to the reduced bacterial competition with the host for available nutrients and diminution in the level of toxic bacterial metabolites as a result of lessened bacterial fermentation resulting in the improvement of protein and energy digestibility, thereby ameliorating the weight gain and performance of broiler chicken. In conclusion, formic acid supplementation had positive effect in improving the performance in terms of body weight gain and FCR. The reduction in the pH value of various GIT segments.
Serum proteins are mainly synthesized in the liver, and, among other functions, maintain blood volume through the colloidal osmotic effect, buffer blood pH, transport hormones and drugs, participate in cell coagulation, catalyze chemical reactions (enzymes), regulate the metabolism (hormones), and participate in the body defense against foreign agents (Melillo, 2013).
The higher total protein concentration determined in the serum of formic acid group compared with control groups is attributed to their higher albumin values, as globulin values were statistically similar (Table 7). According to Harr et al. (2002), serum total protein values of broilers tend to be lower than those of mammals, ranging from 25.00 to 45.00 g/L.
Albumin values were higher in formic acid group than in control birds (Table 7). The main functions of albumin are the transport of several molecules and the maintenance of blood oncotic pressure (Melillo, 2013).
The higher globulin values determined in formic acid group suggest increased globulin levels of in broilers submitted to formic acid against control group with values of 16.48 g/L and 14.75 g/L in the control group.
The A/G ratio values of formic acid group were higher than those of control group due to the higher albumin concentration in formic acid group. When this ratio is reduced, there may be hypoproteinemia, and may indicate acute or chronic inflammatory processes due to the elevation of globulins (Lumeij, 1997).
CONCLUSION
The results of the current study concluded that formic acid supplementation at level of 0.75 and1%, had a beneficial effect on the Performance of broiler chicken. Formic acid significantly and increased BWG and FCR at level of Organic acids improved nutrient at level of at level of 0.75 and1% by increasing the nutrients and endogenous nitrogen losses, by lowering the incidence of subclinical infections and secretion of immune mediators, and by reducing production of ammonia and other growth-depressing microbial metabolites. Formic had acid benefit is related to uncontrolled variables such as buffering capacity of dietary ingredients, presence of other antimicrobial compounds. Additional research can clarify the role and management of these factors.
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تأثير إستخدام بعض الأحماض العضوية على الأداء الإنتاجى لدجاج التسمين
حسين عبد الفتاح محمود ، أسامة سامى عفيفى ، محمد محروس محمد
E-mail: hussein1905@yahoo.com Assiut University web-site: www.aun.edu.eg
الهدف من هذه الدراسة هو تقييم إضافة حامض الفورميک کمحفز للنمو فى دجاج التسمين. هذه الدراسة تم تنفيذها بإستخدام 132 کتکوت من سلالة الکوب التجارية تم توزيعها عشوائيا إلى مجموعتين واحدة أٌستخدم فيها حامض الفورميک بثلاث مستويات والأخرى کانت مجموعة ضابطة. کل مستوى إحتوى عل مکررتين فى کل مکررة 11 کتکوت. الطيور فى المجموعتين غذيت عل العليقة الأساسية (بادئ ونامى) بينما مجموعة المعاملة بحامض الفورميک تم إمدادها بماء يحتوى على حامض فورميک عند مستويات 0.5, 0.75 و 1.0%. النتائج أظهرت أن الطيور التى تم إمدادها بحامض الفورميک عند کل المستويات کانت الأقل فى وزن الجسم(p<0.0001) وکانت الأعلى فى معدل الزيادة فى وزن الجسم عند مستوى 0.75 و1.0% عند 35 يوم من العمر. إنخفض (p<0.0001) أستهلاک الغذاء التراکمى للطيور التى تم إمدادها بحامض الفورميک.الإمداد بحامض الفورميک عند مستويات 0.75 و 1.0% أدى إلى تحسين معدل تحويل الغذاء مقارنة بالمجموعة الضابطة. إستخدام حامض الفورميک أدى إلى إنخفاض وزن محصول لحم الصدر والذبيحة المجهزة وزيادة وزن الدهن الکلى وغدة فابريشى. حامض الفورميک عند مستوى 1.0% أدى إلى تقليل تعداد بکتيريا القولون وخفض درجة ترکيز أيون الأيدروجبن.
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