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Comparative Study of Curcumin and Garlic Extracts as Antioxidants in Growing Rabbit Diets on Productive Performance and Antioxidant Status

AAVS_10_5_1039-1047

Research Article

Comparative Study of Curcumin and Garlic Extracts as Antioxidants in Growing Rabbit Diets on Productive Performance and Antioxidant Status

A. Samy1*, H.M.A. Hassan1, Fatma T.F. Abd-El Ghany2, Shama H. Morsy2

1Department of Animal Production, National Research Centre, 12622, Giza, Egypt; 2Animal Production Research Institute, Agricultural Research Center, Giza, Egypt.

Abstract | This study aimed to evaluate how adding curcumin and garlic extracts to the diet of growing rabbits affected productive performance, carcass characteristics and antioxidant status. Sixty growing rabbits (APRI) were divided into five groups of 12 rabbits each at the age of six weeks. Five diets containing the same proportions of all nutrients were made. The first control diet (without any additives); curcumin (CE) or garlic extract (GE) at concentrations of 200 or 400 ppm were added to the other diets. The results revealed that adding curcumin or garlic extract to growing rabbit diets boosted significantly meat crude protein (P<0.05) while, decreasing moisture and fat levels. Digestibility coefficients of CP, CF, and EE, as well as the nutritive values of TDN, DCP, and DE, were considerably improved (P<0.05), although DM, OM, and NFE digestibility was unaffected in all treatments. Considerably, Addition of curcumin or garlic extract boosted final weight, weight gain, and feed efficiency compared to the control group. Dietary treatments were significantly (P<0.05) raised carcass weight and carcass percent, while liver, heart, kidney, giblets, and spleen percentage were not affected. When curcumin or garlic extract were added at 200 or 400 ppm, Improved the antioxidants status by enhanced total antioxidant capacity also, significantly (P<0.05) enhanced hepatic antioxidants enzyme (superoxide dismutase, catalase, and glutathione peroxidase) compared with the control. Slightly (P>0.05) decreased in malondialdehyde of all treatments compared to the control. Also, there is no any negative effect on the thyroid hormones with any treatments compared to the control. These results suggested that rabbits fed diets enriched with curcumin or garlic extract could have better performance, carcass characteristics, and antioxidant status compared to the control.

 

Keywords | Curcumin extract, Garlic extract, Growing rabbits, Antioxidant status, Productive performance and Thyroid hormone


Received | February 22, 2022; Accepted | March 14, 2022; Published | April 15, 2022

*Correspondence | A. Samy, Department of Animal Production, National Research Centre, 12622, Giza, Egypt; Email: [email protected]

Citation | Samy A, Hassan HMA, Abd El-Ghany FTF, Morsy SH (2022). Comparative study of curcumin and garlic extracts as antioxidants in growing rabbit diets on productive performance and antioxidant status. Adv. Anim. Vet. Sci. 10(5): 1039-1047.

DOI | http://dx.doi.org/10.17582/journal.aavs/2022/10.5.1039.1047

ISSN (Online) | 2307-8316

 

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Copyright: 2022 by the authors. Licensee ResearchersLinks Ltd, England, UK.

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).


 

INTRODUCTION

Feed additives are an important component of poultry feeds that help them perform better and produce more (Abd-Elsamee et al., 2012; Mohamed et al., 2016; Hassan et al., 2016; Khan and Iqbal, 2016; Elsherif et al., 2021). In terms of weight increase, feed efficiency, and reduced mortality in chicken, natural feed additives (phytogenic) have shown promising results (Jahan et al., 2008). Phytogenic are supposed to boost poultry performance by encouraging the release of digestive enzymes, which leads to better digestion and absorption (Recoquillay, 2006; Elsherif et al., 2021). Phytochemicals or their extracts have a positive impact on bird performance, immunity, and blood parameters. Phytogenic and their extracts are effective feed additions in poultry nutrition because of their favorable effects and safety (Hassan et al., 2015; Elsherif et al., 2021). Many studies were conducted on natural feed additives such as garlic, ginger, fenugreek, curcumin, castor, propolis and other plant extracts as an alternative to antibiotic to enhance performance and gut function of broiler chicks (Schepetkin et al., 2019; Oluwafemi et al., 2021; Elsherif et al., 2021). Alliin, allicin, ajoenesn, vinyldithiins, and flavonoids are among the sulfur-containing phyto constituents found in garlic. Allicin is the principal active component in garlic (Allium sativum L.) extract (Gaber et al., 2020). Garlic extract could be beneficial in broiler feed as a natural feed additive. Garlic’s antibacterial properties are related to the presence of organosulfur compounds such allicin and diallyl sulphide. Organosulfur compounds may also be able to impact gut fermentation patterns by increasing propionate and butyrate and decreasing acetate levels (Mbiriri et al., 2016). Supplementing garlic to the rabbit diet increased live body weight and improved feed efficiency (Ahmed et al., 2002). Garlic in the diet of rabbits enhanced body weight and feed efficiency (Gebreyohannes and Gebreyohannes, 2013). Also, Broilers with garlic extract supplemented diet had superior growth performance (Khan et al., 2017). Garlic promotes nutrient digestion by reducing peptic and stomach ulcers, boosting the growth of helpful microbes digesting fibrous feed, and therefore increasing the number of nutrients accessible for assimilation (Chen et al., 2019). Garlic contains Polyphenols and flavonoids, which protect cell membranes and DNA from oxidative damage (Shahidi and Hossain, 2018; Rodrigues and Percival, 2019). In addition to, Garlic includes various antioxidant actions, such as organosulfur, flavonoids like quercetin, which may contribute to a healthier animal and improved nutrient utilization and performance (Schepetkin et al., 2019). Oluwafemi et al. (2021) found that adding 0.4% of ginger and garlic oil mixture to broiler feed significantly increased growth performance. Shiyou et al. (2011) reported that turmeric (Curcuma longa) is a rich source of phenolic chemicals, terpenoids, and curcuminoids. Curcumin is the primary bioactive component of turmeric, and it has antioxidant, antiviral, and antibacterial properties (Mehdipour Biregani and Gharachorloo, 2020). Curcumin’s improved the excretion of lipase, trypsin, chymotrypsin, and amylase, which may be responsible for curcumin’s beneficial effects on broiler growth performance (Olukosi and Dono, 2014). Al-Sultan (2003) concluded that using turmeric at 5.0 g/kg in broiler diets improved the growth performance. Al-Jaleel (2012) observed that introducing 0.50% turmeric in broiler diets increased body weight compared to the control and other dietary treatments (0.25, 1, 1.5 % turmeric). Curcumin significantly reduced total cholesterol, probably by inhibiting the hepatic enzyme 3-hydroxyl-3-methyglutaryl Co-A reductase, that is responsible for the synthesis of cholesterol in the liver (Al-Kassie et al., 2011). Therefore, the goal of this study was to investigate the influence of the addition curcumin or garlic extract in rabbit diets on productive performance, digestibility, carcass characteristics, thyroid hormones, and antioxidant enzyme activities.

MATERIALS AND METHODS

This study was conducted at Egypt’s Kafr Elsheikh Governorate’s Ministry of Agriculture’s Sakha Research Station. The laboratory work was carried out at department of Animal Production, National Research Centre, Egypt and department of by Products Research, Animal Production Research Institute, Agricultural Research Center. The goal of this study was to investigate the influence of curcumin and garlic extracts in growing rabbit diets on performance and antioxidants status.

Curcumin and garlic were extracted using dried turmeric rhizomes and fresh garlic which acquired from a local Egyptian market. All of the chemicals and solvents were acquired from Merck and were of analytical grade.

Curcumin extract (CE) is obtained by extracting curcumin from dried turmeric rhizomes. To obtain a curcuminoid-rich extract, use Soxhlet extraction by Percolation (boiler and reflux) with acetone as solvent (Zieliska et al., 2020; Yadav et al., 2017).

Garlic extract (GE) was extracted using a heat reflux extraction process including 70% ethanol and continuous stirring for three hours, following by separation of the extract using a rotary evaporator at 40°C (Loghmanifar et al., 2020; Elsherif et al., 2021).

Finally, calcium carbonate was used as a carrier material to load the extracts separately so that they could be easily used and mixed with feed ingredients.

Experimental diets

According to Agriculture Ministry Decree (1996) instructions, the control diet was formulated to meet the nutritional requirements of growing rabbits. Five diets containing the same proportions of all nutrients were made. The first control diet (without any additives); curcumin (CE) or garlic extract (GE) at concentrations of 200 or 400 ppm were added to the other diets. The experiment period lasted from 6 - 14 week of age. Components and chemical analysis of a control diet are presented in Table 1.

Animals and management

Sixty growing rabbits (APRI strain) were randomly distributed into five groups, 12 rabbits of each, the average start body weight was closely to 635 g. The rabbits were housed in battery cages measuring 60 x 50 x 40 inches with separate feeders. Water and feed were freely available. The rabbits were housed in the same sanitary and management conditions. Weekly feed intake and live body weights data were used to calculate feed conversion ratio (FCR) and body weight gain (BWG).

 

Table 1: Components and chemical analysis of a control diet.

Ingredient % % Chemical analysis  
Alfalfa hay 34.95 DM % 87.57
Barley grain 25.60 OM % 81.55
Soybean meal 44% 14.30 CP % 16.94
Wheat bran 20.60 CF % 12.98
Molasses 3.02 EE % 2.28
Soft Limestone 0.43

DE (kcal/kg)2

2505
Salt 0.30 AP % 0.545
Dicalcium phosphate 0.30 Ca% 0.795
Mineral-vitamin premix* 0.30 Methionine % 0.445
DL-Methionine 0.20 Lysine % 0.805
Total 100    

* Each 3 kg of mineral and vitamin premix contains the following: Vit. A (12000000 IU), Vit. D3 (200000 g), Vit. E (10 g), Vit. K3 (2.5 g), Vit. B1 (1.0 g), Vit. B2 (5.0 g), Vit. B6 (1.5 g), Vit. B12 (10 g), Pantothenic acid (10 g), Niacin (30 g), Choline chloride (500 g), Folic acid (1.0 g), Biotin (50 mg), Fe (30 mg), Mn (40 mg), Zn (45 mg), Cu (3 g), Co (100 mg), I (300 mg), Se (100 mg). 2DE was estimated using values from the N R C (1977).

 

Digestibility trail

Five rabbits from each group were used in a digestibility trial at the end of the study. According to AOAC (2000) feces were daily collected and dried at 50-60 oC for 24-48 hours for constant weight before being finely powdered and were kept till chemical analysis. The digestibility coefficients of nutrients and nutritive values of the dietary treatments were determined using data from quantities and chemical analyses of feed and feces, according to Cheeke et al. (1982).

Blood samples and carcass parameters

At the end of the experiment, 5 rabbits per feeding treatment were starved for 24 hours and slaughtered for carcass and internal organs measures. Live weight, carcass weight (g), carcass percentage, gastrointestinal tract weight percent (GIT percent), organs represented as percentages of live weights, giblet (heart, liver, and kidney) percentage, and abdominal fat percentage were calculated. The meat composition of breast muscle was determined using the AOAC (2000). The blood samples were taken with the rabbits slaughtering.

Analyses of antioxidants status

Blood serum samples were separated by centrifugation at 4000 rpm for 10 minutes, and then stored at -20 oC until chemical analysis. Total antioxidant capacity (TAC) and malondialdehyde (MDA) concentrations were assessed in blood serum.

Furthermore, the livers were collected for the analysis of catalase (CAT), superoxide dismutase (SOD) and glutathione peroxidase (GSH) antioxidant enzymes using commercial kits (biodiagnostic, Cairo, Egypt) in an automatic calibration spectrophotometer with high-performance readings (FlexorEL200 Biochemical Analyzer).

Thyroid hormone concentration

Commercial ELISA kits were used to measure total T3 and T4 concentrations in the blood (MyBioSource, Inc., San Diego, CA). The T4/T3 ratio was obtained by dividing the value of T4 by the value of T3.

Statistical analysis

SAS’s (2001) General Linear Models technique was used to examine the data. The statistical data of 95 percent reliability was analyzed using one-way analyses of variance. The differences among means were compared using Duncan’s multiple rang test (Duncan, 1955) at significance level (P<0.05).

RESULTS AND DISCUSSION

The effects of curcumin or garlic extract on live body weight (LBW), daily weight gain (DWG), daily feed intake (DFI), and feed conversion ratio (FCR) of growing rabbits are shown in Table 2. The results showed that adding 200 ppm (CE1, GE1) or 400 ppm (CE2, GE2) of curcumin or garlic extract had a significant (P<0.05) favorable effect on LBW during the experimental period. The greatest significant (P<0.05) LBW values were obtained when curcumin or garlic extract were used at 400 ppm. At 14 weeks of age, the inclusion of CE2 and GE2 resulted in the greatest LBW and DWG values (2230 and 2249g) and (28.35 and 28.82g), respectively compared to the control group that had the lowest LBW (1899g) and DWG (22.83g) values. At all ages, the daily feed consumption of rabbits fed diets containing various doses of curcumin or garlic extract remained were no significantly affected. Curcumin and garlic extract supplementation had a significant (P<0.05) effect on the FCR of growing rabbits during the experimental period. In comparison to 200 ppm levels and the control group, inclusion of curcumin or garlic extract at 400 ppm resulted in considerably (P<0.05) enhanced FCR values during the experimental period. The results of the performance index (PI) and growth rate (GR) showed significant (P<0.05) differences in PI and GR among the dietary treatments at overall ages of the rabbits, with the best values of PI and GR for rabbits fed diets containing CE2 (81.88 and 110.54) and GE2 (82.61 and 111.93), respectively and the worst values recorded for rabbits fed control diet (56.93 and 101.51), respectively.

The improvement in body weight and feed conversion ratio could be attributed to optimum antioxidant activity of curcumin and garlic extracts, which stimulate protein synthesis via the enzymatic system, based on the findings of this and prior investigations. Furthermore, curcumin and garlic extracts can inhibit or limit the growth and colonization of a wide range of pathogenic and non-pathogenic bacteria in the gut, resulting in a more balanced microbial ecosystem and improved nutrient digestion and absorption, as well as improved growth performance and physiological status.

These findings are consistent with those of numerous researches, including Kafi et al. (2017), who found that adding 0.75 percent turmeric (Curcuma longa) to broiler diets were significantly enhanced growth rate. Hussein (2012) also found that using curcumin in the broiler diet significantly (P<0.05) improved growth performance. Growing rabbits fed a diet supplemented with Curcuma longa showed a slight increase in body weight at all ages (Abd El-Latif et al., 2019). Al-Sultan (2003) found that adding 5 g/kg turmeric to the diet of broilers was boosted body weight. Similarly, Al-Jaleel (2012) investigated the effect of feeding broiler chicks dietary Curcuma longa at 0, 0.25, 0.50, 1, 1.5 percent on performance and found that including 0.50 percent curcumin enhanced body weight compared to the other groups. El-Rawi et al. (2020) found that adding 4 and 8 g/kg of turmeric powder (Curcuma longa) to rabbit diet had a significant impact on final weight, weight gain, feed intake, feed conversion ratio, and relative growth ratio when compared to the control group. Garlic supplementation to broiler chicks improved growth performance and feed conversion ratio by increasing villus height, digestive enzyme activity, and nutrient absorption in the intestine (Tollba and Hassan, 2003). Garlic supplementation significantly improved (P<0.05) rabbit weight gain, feed conversion ratio, and hematological parameters, according to Onu and Aja (2011). Garlic supplementation improved body weight gain and feed conversion ratio in broilers, according to (Makwana et al., 2018; Chimbaka and Walubita, 2020; Gaber et al., 2020). This could be due to the action of allicin, which has antibacterial, antiviral, antiprotozoal, antifungal, antioxidant, anticancer, and anti-inflammatory properties in garlic and its extract.

Coefficients of digestibility and nutritive values

Table 3 are showings the influence of curcumin and garlic extracts on digestibility coefficients and nutritive values. The addition of CE or GE had no significant effect on the digestibility coefficients of DM, OM, or NFE. While the digestibility coefficients of CP, CF, and EE were significantly (P<0.05) affected. The addition of CE or GE were substantially raised the digestibility coefficient of CP (P<0.05), with the inclusion of 200 ppm GE yielding the highest value (78.60%). The digestibility coefficients of CF and EE were significantly (P<0.05) different where, the best digestibility coefficient of CF value (38.13%) was achieved, with no significant differences with the addition of 200 ppm GE or CE. The addition of 400 ppm CE considerably (P<0.05) enhanced the digestibility coefficient of EE, with the addition of 400 ppm CE recording the highest value (76.33%). The addition of CE or GE were significantly (P<0.05) improved total digestible nutrients (TDN), digestible energy (DE), and digestible crude protein (DCP), where 400 ppm CE had the best DE (2876.06 Kcal/Kg) compared to control group. There were no significant differences in DE among 200 ppm CE, 200 ppm GE, and 400 ppm GE. The group supplemented with 400 ppm CE had the highest TDN value (64.92%) on record, while no significant differences in TDN percent with 200ppm CE, 200ppm GE, and 400ppm GE addition.

The beneficial effects of herbal plants and their extracts in animal nutrition include improving digestive enzyme secretion, stimulation of appetite, activation of the immune response, and antibacterial, antiviral, and antioxidant actions that may affect the digestive tract’s physiological and chemical function (Rahimi and Ardekani, 2013). Turmeric extract (curcumin) is an antioxidant that can help the gallbladder secrete bile and boost the secretion of pancreatic juice, which contains enzymes like amylase, lipase, and protease that help with carbohydrate, fat, and protein digestion (Utami et al., 2020). These findings are consistent with those of Astawa et al. (2016), who found that turmeric extract (curcumin) had the best CP and OM digestibility coefficients of body weight when compared to the control group. The bile synthesis and secretion into the small intestine may be linked to improve fat and protein digestion when CE was added by 0.04 ml/Kg to diets (Al-Sultan and Gameel, 2004).

Carcass characteristics

Table 4 is showing the effects of dietary treatments on carcass characteristics. The effects of dietary treatments on carcass weight, carcass percent, gastrointestinal tract percent (GIT), and abdominal fat percent were significant (P<0.05) compared to the control group. The highest carcass weight and carcass precentage values were recorded with the groups supplemented with 400 ppm CE (1312g, 65.63) and 400 ppm GE (1304 g, 64.53), respectively. Different additions had no effect on the liver, heart, kidney, giblets, and spleen percentage. All dietary treatments significantly (P<0.05) decreased GIT percent compared to the control which had the largest GIT percent (20.08%), while dietary supplementation with CE or GE at 400 ppm having a lowest value 16.47% and 17.88%, respectively.

 

Table 2: Effect of curcumin and garlic extracts on growth performance of rabbits.

Item Control CE1 200 ppm CE2 400 ppm GE1 200 ppm GE2 400 ppm Se of mean P value
LBW (g)              
Initial W (6 wk) 620 636 643 645 635 ±6.65 0.410
At 10 wk

1199b

1364a

1406a

1340a

1418a

±19.54 0.015
At 14 wk

1899c

2148b

2230a

2093b

2249a

±30.81 0.001
DWG) (g)              
6-10 wk

20.68 c

25.95 ab

27.28 ab

24.82 b

27.96 a

±0.70 0.005
6-14 wk

22.84 c

26.96 b

28.35 a

25.85 b

28.82 a

±0.52 0.001
DFI (g)              
6-10 wk 55.53 54.10 56.60 56.94 56.79 ±0.32 0.170
6-14 wk 76.30 76.79 77.23 77.21 78.53 ±0.48 0.320
FCR (g/g)              
6-10 wk

2.69 a

2.09 b

2.08 b

2.29 b

2.03 b

±0.07 0.002
6-14 wk

3.34 a

2.85 bc

2.72 c

2.99 b

2.73 c

±0.06 0.001
PI%

56.93d

75.42b

81.88a

70.15c

82.61a

±2.21 0.001
GR

101.51c

108.52ab

110.54ab

105.83bc

111.93a

±1.09 0.005

a,b,c Means in the same row with different superscript are significantly different (P< 0.05). LBW: live body weight, DWG: daily weight gain, FI: feed intake, FCR: feed conversion ratio. Performance index % (PI)= final live body weight (Kg)/feed conversion ratio x 100. Growth rate% (GR)= (W2-W1)/(1/2(W2+W1))x100. Whereas: W1= initial bodyweight, W2= Final body weight (g)

 

Table 3: Effect of curcumin and garlic extracts on nutrients digestibility of rabbits

Item Control CE1 200 ppm CE2 400 ppm GE1 200 ppm GE2 400 ppm Se of mean P value
Nutrients digestibility          
DM 64.30 66.30 67.17 67.07 66.60 ±0.41 0.123
OM 66.50 67.57 67.60 68.13 67.87 ±0.32 0.330
CP

75.07b

77.97a

78.47a

78.60a

77.67a

±0.41 0.011
CF

36.47b

37.03b

37.31ab

37.20ab

38.13a

±0.26 0.360
EE

74.53ab

75.30ab

76.33a

73.50b

72.83b

±0.17 0.022
NFE 73.83 74.27 75.70 75.20 74.93 ±0.33 0.402
Nutritive value%          
DCP

13.03b

13.53a

13.62 a

13.65 a

13.48 a

±0.07 0.011
TDN

63.47c

64.11b

64.92a

64.61ab

64.21b

±0.13 0.001
*DE

2811.52c

2840.19b

2876.06a

2862.34ab

2844.50b

±5.90 0.001

a,b Means in the same row with different superscript are significantly different (P< 0.05). *DE = TDN X 44.3 (Schneider and Flatt, 1975).

 

Table 4: Effect of curcumin and garlic extracts on carcass characteristics of rabbits.

Item Control CE1 200 ppm CE2 400 ppm GE1 200 ppm GE2 400 ppm Se of Mean P value
Live body weight (g)

1862 ab

1865ab

2000a

1795b

2022a

±30.40 0.046
Carcass weight (g)

1105b

1166b

1312a

1112b

1304a

±27.33 0.002
Carcass %

59.32c

62.50b

65.63a

61.97b

64.53a

±0.63 0.002
Liver % 3.17 3.38 3.56 3.27 3.44 ±0.06 0.317
Heart % 0.35 0.35 0.37 0.37 0.36 ±0.02 0.547
Kidney % 0.57 0.57 0.56 0.57 0.59 ±0.02 0.615
Giblets % 4.10 4.29 4.49 4.22 4.39 ±0.06 0.281
Spleen % 0.06 0.06 0.06 0.06 0.06 ±0.01 0.691
GIT %

20.08a

18.66bc

16.47d

19.71ab

17.88c

±0.38 0.007
Abdominal fat %

0.43bc

0.49ab

0.56a

0.41bc

0.38c

±0.02 0.016

a,b,c Means in the same row with different superscript are significantly different (P< 0.05).

These findings were in line with those of Sarica et al. (2005), who discovered that thyme and garlic extracts had no influence on the weight of broiler chickens’ hearts, livers, gizzards, or spleens. In addition, Alçiçek et al. (2003) discovered that using herb extract improved carcass weight but had no effect on belly fat percentage. According to Raghdad and Al-Kassie (2012), adding turmeric powder to broiler chicken feeds dramatically enhanced the dressing percentage as the quantity of inclusion increased. According to Okanlawon et al. (2020), rabbits fed a diet supplemented with 10 g and 15 g turmeric/kg feed had the highest dressing percentage.

Meat composition

Table 5 is showing the impact of curcumin and garlic extracts on rabbit meat composition. The addition of CE or GE to the diet of growing rabbits had a significant (P<0.05) impact on the meat moisture, protein, and ether extract content. While the addition of curcumin or garlic extract had no effect on the meat content of ash, there was no significant effect on the meat content of ash. Curcumin or garlic extract were significantly (P<0.05) boosted crude protein while decreasing moisture and fat levels in meat. With the addition of 200 ppm GE, the highest value of crude protein (25.77%) was observed. While, control had the greatest moisture and ether extract values (70.88% and 2.31%), respectively.

Meat moisture content reduced in response to CE or GE, implying that CE and GE may impact meat’s water retaining ability. These findings are consistent with Rajput et al. (2013), who found that adding turmeric powder curcumin (150-200 mg/kg of feed) to the diet significantly reduced belly fat relative to the control group. This reduction in abdominal fat could be attributed to better fat digestion and metabolism (Sugiharto et al., 2011). Dzinic et al. (2013), on the other hand, found that adding 2% garlic to the feed of broiler chicks had no influence on the protein level of the meat. Similarly, Kanani et al. (2017) found that adding 0.5 percent turmeric powder to broiler chicks had no influence on meat protein content.

Figures 1 and 2 are showing the effects of different treatments on antioxidant enzymes in rabbits. The addition of 200 or 400 ppm CE or GE significantly (P<0.05) enhanced TAC, SOD, CAT, and GSH compared to the control group. The inclusion of curcumin and garlic extract, resulted in a slight (P>0.05) reduction in MDA. Total antioxidant capacity is an important metric that takes into account all antioxidants in the blood (Ghiselli et al., 2000). Total antioxidant capacity, SOD, CAT, and GSH all increased in response to dietary CE or GE supplementation in this investigation, demonstrating that CE or GE treatment may improve the total antioxidant status of rabbits. Total antioxidant capacity changes in blood plasma after supplementation with antioxidant-rich feeds offer information on the absorption and bioavailability of ingested antioxidants (Ghiselli et al., 2000). The present findings tie with prior research on the antioxidant properties of CE or GE, which were also demonstrated in this study. Allicin, alliin, allyl disulfide, and allyl cysteine are antioxidant chemicals found in garlic (Elkelawy et al., 2017). These findings are in line with those of other research (Durak et al., 2002), which found that garlic extract lowered MDA levels in blood samples, indicating fewer oxidation reactions in the body.

Thyroid hormones

Table 6 is showing the effects of dietary treatments on thyroid hormones. The addition of 200 or 400 ppm CE or GE to the growing rabbit diets had no influence on T3, T4, or T4/T3 in any of the groups. Hassan et al. (2015) confirmed these findings and reported that phytogenic and their extracts are good feed additives and safe in poultry nutrition.

 

Table 5: Effect of curcumin and garlic extract on meat composition of rabbits

Item Control CE1 200 ppm CE2 400 ppm GE1 200 ppm GE2 400 ppm Se of Mean P value
Moisture

70.88a

70.04b

69.91b

69.77b

70.31ab

±0.13 0.016
Crude protein

24.57c

25.28b

25.58ab

25.77a

25.44ab

±0.12 0.001
Ether extract

2.31a

2.15b

2.16b

2.06b

2.05b

±2.24 0.013
Ash 2.24 2.53 2.43 2.40 2.21 ±0.06 0.381

a,b Means in the same row with different superscript are significantly different at (P< 0.05).

 

Table 6: Effect of curcumin and garlic extracts on thyroid hormones of rabbits

Item Control CE1 200 ppm CE2 400 ppm GE1 200 ppm GE2 400 ppm Se of mean P value
T3 3.71 4.94 4.57 4.22 4.63 ±0.19 0.311
T4 14.80 15.84 15.64 15.02 15.28 ±0.28 0.421
T4/T3 4.05 3.21 3.59 3.61 3.35 ±0.17 0.343

a,b Means in the same row with different superscript are significantly different at (P< 0.05). T3: Triiodothyronine, T4: Thyroxin.

 

CONCLUSIONS AND RECOMMENDATIONS

It could be stated that adding up to 400 ppm of curcumin and garlic extracts to growing rabbit diets can improve growth performance, carcass weight, and antioxidant status without any negative effect.

Novelty Statement

Using a simple method to extract both curcumin and garlic to obtain phenolic compounds and flavonoids, which considered as natural antioxidants that have been used as important alternatives to antibiotics in feeding rabbits, and the results led to an improvement in body weight gain, nutritional efficiency and the state of the antioxidants in the body without any harmful effect on the rabbits.

AUTHOR’S CONTRIBUTION

All authors contributed equally to the manuscript.

Conflict of interest

The authors have declared no conflict of interest.

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