Phytogenic Feed Additives in Poultry: Achievements, Prospective and Challenges
Abstract
:Simple Summary
Abstract
1. Introduction
2. Gastrointestinal Health and Functionality
3. Phytogenics as an Alternative to Antimicrobials in Poultry Feeding
4. Effects of Phytogenic Feed Additives on Chickens
4.1. Effects of Dietary PFA Supplementation on Growth Performance
4.1.1. Chickens Maintained under Non-Challenging Conditions
4.1.2. Chickens Maintained under Challenging Conditions
Feed Additive | Major Components | Dose, (mg/kg Diet) | Diet | Age | Treatment Effects (%, Compared to Control) | References | ||
---|---|---|---|---|---|---|---|---|
BW | ADFI/FI | FCR | ||||||
Olea europaea extract | Triterpenes (10%) polyphenols (2%) | 750 | Wheat-soybean meal based diet | 21–42 d | NM | NS | −7.9 | [62] |
Achyranthes japonica extract | Flavonoid (1.15 mg/g), polyphenol (4.26 mg/g) and saponin (0.47 mg/g) | 1000 | Corn-soybean meal based diet | 0–35 d | 3.5 | −2.4 | −6.2 | [60] |
EOs | Carvacrol (20%) and thymol (25%) | 200 | Corn-soybean meal based diet | 29–42 d | NS | −9.6 | −11.8 | [43] |
EOs | Carvacrol (5%), cinnamaldehyde (3%), and capsicum oleoresin (2%) | 100 | Corn-soybean or wheat -soybean meal based diet | 16.4 | 6.1 | −9.4 | [86] | |
Aerva lanata, Cynodon dactylon, Piper nigrum and Piper betle | Phenolic acid contents (10,176.8 μg/g), flavonoids (53.0 μg/g), other (220.2 μg/g) | 10,000 | Corn-soybean meal based diet | 0–42 d | 14.1 | NS | −14.0 | [58] |
Pulicaria gnaphalodes powder | Phenolic compounds, alkaloids, terpenoids, and triterpene saponins | 3000 | Corn-soybean meal based diet | 0–42 d | 4.3 | NS | −3.0 | [59] |
Standardized lipophilic turmeric extract | 3.1% of curcuminoids content and terpenes (turmerones) | 10,000 | NM | 0–42 d | 9.0 | 1.6 | −7.7 | [57] |
EOs | Carvacrol (63.5%), thymol (3.4%) and paracymene (13.1%) | 400 μL | Corn-wheat-soybean meal based diet | 28–43 d | 4.2 | NS | −3.9 | [40] |
Thyme powder | Major EO (thymol (50.48%), γ-terpinene (11.03%), P-cymene (9.77%), and carvacrol (4.30%)), phenolic acids (salicylic acid (2450.03 ppm), ellagic acid (1240.42 ppm)) and flavonoid compounds | 5000 | Corn-soybean meal-based diet | 0–42 d | 4.6 | 3.3 | NS | [87] |
EOs (oregano, anise, and citrus peel; CBP) | Carvacrol: 102 g of the chemical component/kg of CBP | 150 | Corn-soybean meal-based diet | 0–42 d | NS | -5.3 | NS | [88] |
Combination of herbs, spices, EOs and extracts | Mainly EOs from mint, star anise and cloves | 100 | Corn-soybean meal-based diet | 0–42 d | 7.0 | NS | NS | [39] |
EO (powdered and matrix-encapsulated form) | -Powdered: menthol and anethole -Encapsulaed: carvacrol, thymol, and limonene | 150 100 | Corn-wheat-soybean meal based diet | 0–42 d | NS 2.4 | NS NS | NS NS | [44] |
EOs | Oregano containing carvacrol (26.4 mg/kg) or thymol (13 mg/kg) | 300 600 | Corn-soybean meal-based diet | 0–42 d | 7.8 9.6 | 4 8 | NS NS | [41] |
Spices: Nigella sativa seeds | Thymoquinone, dithymo- quinone, thymohydroquinone, nigellone, melanthin, nigilline, nigelamine, damascenone, p-cymene and pinene | 10,000 20,000 | Corn-soybean meal-based diet | 0–35 d | 3 | NS | 5.6 | [52] |
Feed Additive | Major Components | Dose (mg/kg Diet) | Diet | Line and Age | Main Findings | References |
---|---|---|---|---|---|---|
Non-Challenging Conditions | ||||||
Mentha arvensis (MA) and Geranium thunbergii (GT) extracts | MA: menthol, isomenthol, neomenthol, p-cymene, d-menthone, eugenol, and cineol GT: citronellol, isomenthone, and geraniin | 100, 500 and 1000 | Corn-wheat- soybean meal based diet | Hy-Line Brown layers (28–44 weeks) | ↑ FI, egg production and egg weight | [89] |
Fermented pine (Pinus densiflora) needle extract | α-pinene, caryophyllene, beta-pinene and bisbenzene, camphene, borneol, phellandrene, quercetin, kaempferol, and terpene | 2.5 and 5 | Corn-soybean meal-based diet | Hy-Line Brown laying hens (40–46 weeks) | ↑ FI, egg production and egg mass | [90] |
Fermented Schisandra chinensis pomace (SC), fermented Pinus densiflora (PD) needle extract, and Allium tuberosum (AT) powder | SC: lignin PD: phenolics, flavonoids, and tannins AT: organosulfur compounds, polyphenols, and saponins | 1000 and 3000 | Corn-soybean meal-based diet | Hy-line brown laying hens (48–54 weeks) | -=Egg production, daily egg mass and FCR. -↑ FI | [91] |
Dry leaf extract of peppermint (Mentha piperita L.) | Menthol | 0, 74, 148, 222, and 296 | Corn-soybean meal-based diet | Bovans Brown laying hens (32–44 weeks) | ↑ FI, egg production, egg weight and egg mass | [48] |
Citrullus lanatus EOs | Phenolics (1.57 mg/100 g) Sterols (600.56 mg/100 g) Flavonoids (163.5 mg RE/kg) | 1000 and 2000 | Corn-soybean meal-based diet | White Leghorn laying hens (18–26 weeks) | ↑ Weight gain, ADFI, ADG and egg mass; ↓ FCR | [46] |
Tea tree (Melaleuca alternifolia) EO | Terpinen-4-ol (40.0%), γ-Terpinene (23.0%) and α-Terpinene (10.4%) | 40 and 80 | NM | Lohmann Brown hens (55–58 weeks) | ↑ Daily egg production and ↓ FCR | [47] |
Thyme (Thymbra spicata) and Rosemary (Rosemarinus officinalis) | -Thyme: Carvacrol (87.81%), thymol (9.58%), L-Linalool (0.86%), borneol (0.74%) -Rosemary: 1.8 cineole (34.08%), camphor (27.95%), alpha-Pinene (14.50%), borneol l(8.65%), alpha-Terpineol (7.39%), alpha-Thujone (1.09%), camphene (0.55%) | 1000 for each source | Corn-soybean meal-based diet | Bovans-White (48–56 weeks) | -No effects on FCR -↓ Egg production and egg weight | [92] |
Cumin (Cuminum cyminum L.) seed oil | Cuminol, cuminique alcohol, cuminaldehyde, cymine, phellandrene, carvone, cymol, terpenes, α-pinene… | 500 | Corn-soybean meal-based diet | Boven hens (24–30 weeks) | =Egg production rate, egg mass and FI ↓ FCR and ↑ egg weight | [93] |
Eucalyptus leaves | Polyphenols | 500, 800 and 1200 | Corn-soybean meal-based diet | Yueqinhuang laying hens (35–44 weeks) | ↑ Egg production and egg mass | [94] |
Fennel seeds (F), black cumin (BC) seeds and hot red pepper (RP) | F: trans-anethole BC: thymoquinone, anethole, carvacrol and 4-terpinol RP: Capsaicin | 5000 for each | Corn-soybean meal-based diet | Lohmann Brown Lite laying hens (32–40 weeks) | ↑ Egg weight, egg production, egg mass and ↓ FCR by F and RP | [53] |
Green tea | Polyphenols | 200 | Corn-soybean meal-based diet | Hy-line Brown (65–74 weeks) | ↑ Egg production and ↓ FCR | [95] |
EOs | Thymol (13.5%) and cinnamaldehyde (4.5%) | 50, 100 and 150 | Corn-wheat-soybean meal based diet | Lohmann White (54–65 weeks) | =Egg production, egg weight, egg quality, FI and FCR | [65] |
Echinacea purpurea powder | Caffeic acid and alkamids, phenolic acids, polyacetylenes | 2500, 5000, 7500 and 10,000 | Corn-soybean meal-based diet | Leghorn laying hens (43–53 weeks) | ↑ Egg production and egg mass | [96] |
Peppermint EO Thyme EO | -Menthol and menthone -Thymol, γ-Terpinen and ρ-Cymene | 1000 | Corn-soybean meal-based diet | Lohmann LSL-lite (40–48 weeks) | ↑ Egg production and egg mass ↓ FCR | [97] |
Dried grape pomace | Polyphenols | 40,000 and 60,000 | Corn-soybean meal-based diet | Bovans laying hens (80–92 weeks) | =Live weight, feed intake, egg production and feed efficiency | [98] |
Fennel (F) and thyme (T) extracts | F: anethole, limonene T:-Thymol, γ-Terpinen and ρ-Cymene | 40 | Corn-soybean meal-based diet | Hy-Line White (26–38 weeks) | ↑ Egg weight and egg mass | [99] |
Cold stress + Escherichia coli | ||||||
Curcuma longa | Curcumin | 200 | Corn-soybean meal-based diet | Hy-Line Brown laying hens (84–90) | =Egg production, egg mass, feed intake and FCR | [100] |
Cold stress | ||||||
Oregano EO | Carvacrol and thymol | 50, 100, 150 and 200 | Corn-soybean meal-based diet | Semi-heavy laying hens (59–71 weeks) | =FCR, egg production and egg mass | [73] |
Heat stress | ||||||
Grape pomace flour | Polyphenols | 10,000, 20,000 and 30,000 | Corn-soybean meal-based diet | Hy-Line lineage (74–79 weeks) | ↑ FI | [101] |
Feed Additive | Major Components | Dose (mg/kg Diet) | Diet | Line and Age | Main Findings | References |
---|---|---|---|---|---|---|
Grape seed extract | Polyphenols | 100 and 200 | Corn-soybean meal-based diet | Duckling (Pekin- female; 0–6 weeks) | ↑ ADG, and final body weight with ↓ FCR | [102] |
Oregano EO | Carvacrol and thymol (85%) | 100 | Corn-soybean meal-based diet | Duckling (Cherry valley; 0–5 weeks) | =ADG, FCR | [103] |
Eucalyptus (Eucalyptus camaldulensis) | p-cymene, 1, 8-cineole, b-phellandrene, spathulenol, cryptone aldehydes, cuminal, phellandral, and a-phellandrene | 100 and 200 | NM | Laying Japanese quails | =Productive traits | [104] |
Oregano EO | Thymol (5%) and carvacrol (65%) | 150 and 300 | Corn-soybean meal-based diet | Duckling (Cherry valley; 11–42 days) | =Final body weight, ADG, FI, and FCR | [105] |
NM | Thymol | 2000, 4000 and 6250 | NM | Quail (Coturnix japonica; 85–128 days) | =BWG, FI, egg production, and egg weight | [106] |
Leaves of Astragalus membranaceus | Polyphenols (saponins, flavonoids) | 10,000, 30,000 and 50,000 | Corn-soybean meal-based diet | Japanese quail (0–35 days) | ↑ FI, and weight gain | [107] |
Mentha piperita (peppermint) | Phenolic compounds | 10,000, 20,000, 30,000 and 40,000 | Corn-soybean meal-based diet | Quail | =FI and ADG | [108] |
Feed Additive | Major Components | Dose, (mg/kg Diet) | Diet | Age | Treatment Effects (%, Compared to Control) | References | ||
---|---|---|---|---|---|---|---|---|
BW | ADFI/FI | FCR | ||||||
Clostridium perfringens | ||||||||
Herb: Macleaya cordata plant | Four specific alkaloids mainly sanguinarine and protopine | 120 | Corn-soybean meal-based diet | 15–35 d | 12.7 | NS | −14.8 | [109] |
Plant: Macleaya cordata Plant extracts EOs | Benzo [c]phenanthridine alkaloids Carvacrol (4.95 g/100 g), cinnamaldehyde (2.97 g/100 g), and capsaicin (1.98 g/100 g) Thyme and anise, oregano, carvacol, yucca extract and cinnamaldehyde | NM NM NM | Corn-soybean meal-based diet | 15–21 d | NS NS NS | NS NS NS | −8.9 −10.0 −11.6 | [74] |
EO | Thymol (25%) and carvacrol (25%) as active components | 60, 120 and 240 | Wheat-soybean meal-based diet | 14–28 d | NS | NS | NS | [76] |
Eimeria | ||||||||
Herb: Curcuma longa | Curcumin | 100 and 200 | Corn-soybean meal-based diet | 12–20 d | NS | NS | NS | [81] |
EOs: cashew nut shell liquid and castor oil | Cardanol, cardol, and anacardic acid Ricinoleic acid | 1500 | Corn-soybean meal-based diet | 0–42 d | 2.3 | NS | NS | [77] |
Escherichia coli | ||||||||
Resveratrol | Polyphenols | 600 | Corn-soybean meal-based diet | 0–42 d | 6.1 | 2.2 | −3.9 | [84] |
Salmonella typhimurium | ||||||||
Plant: Macleaya cordata | Benzo [c]phenanthridine alkaloids | 5000 | Corn-soybean meal-based diet | 8–15 d | NS | NS | −11.0 | [85] |
Heat-Stress | ||||||||
Plant: Turmeric | Curcumin | 100 | Corn-soybean meal-based diet | 21–42 d | NS | NS | −2.8 | [71] |
Herb: Zingiber officinale | Gingerdiol, gingerol, gingerdione, and shogaols | 2000 | Corn-based diet | 0–42 d | 3.3 | NS | 3.0 | [70] |
Herb: Artemisia annua | Phenolics (44.24 mg GAE/g) and flavonoids (27.8 mg RE/g) | 1000 | NM | 21–42 d | 8.2 | 4.1 | NS | [69] |
Turmeric rhizome powder | Phenolic compounds: curcuminoids | 2000 | Corn-soybean meal-based diet | 0–42 d | 10.6 | NS | 6.9 | [68] |
4.2. Effects of Dietary PFA Supplementation on Digestibility
4.3. Effects of Dietary PFA Supplementation on Intestinal Microbiota
Feed Additive | Major Components | Dose | Duration of Supplementation | Site and Age of Sampling | Main Effects on Microbiota | References |
---|---|---|---|---|---|---|
Green tea leaves (Camellia sinensis) and pomegranate rinds (Punica granatum) | Green tea: catechins Pomegranate: tannins and flavonoids | 2 mL/L in drinking water | From 0 to 4 days, 10, 11, 20, and 21. | Cecum Day 50 | Family: ↑ Lactobacillaceae and Peptococcaceae Genus: ↑ Roseburia and ↓ Shuttleworthia | [123] |
Aerva lanata, Cynodon dactylon, and Piper nigrum (2 kg from each) and Piper betle (2 L.) | Phenolic acid contents (10,176.8 μg/g), Flavonoids (53.0 μg/g), others (220.2 μg/g) | 1 and 2% in the feed | 42 days | Cecum 42 days | ↑ Bifidobacterium | [58] |
EOs | Carvacrol (102 g/kg PFA) | 115 g/kg in the feed | 42 days | Ileum and cecum 42 days | ↑ Cecal Bacteroides, Clostridium cluster IV, and Clostridium cluster XIVa | [124] |
EOs | Carvacrol (20%) and thymol (25%) | 200 (LPE) and 400 (HPE) g/mg in the feed | 42 days | Duodenum, ileum, and cecum 14 and 28 days | -Day 14: ↑ Firmicutes, Bacteroidetes and Thermi in the ileal microbiota of the HPE group ↓ Proteobacteria and Tenericutes, and 10 genera (e.g., Ruminococcus, Faecalibacterium) -Day 28: ↑ Bacteroidetes and Cyanobacteria and three genera (e.g., Alistipes) in the cecal microbiota of the HPE group ↓ Actinobacteria and two genera (Lactobacillus and unclassified Coriobacteriaceae). | [43] |
-Oregano essential oil (OEO) -Commercial blend of phytogenic (CBP) | 5% essential oil of Origanum vulgare subsp. Hirtum plants -Carvacrol (102 g/kg CBP) | 300 and 500 ppm 150 ppm in the feed | 42 days | Ileum 21 days | ↓ Escherichia coli for both OEO and CBP groups compared to the NC. =Lactobacillus | [137] |
EOs | Thymol, eugenol and piperine (29%) | 0.03% in the feed | 35 days | Ileum 35 days | ↑ Lactobacillus counts ↓ Escherichia coli counts | [121] |
Tea polyphenols (TP) | Caffeine (69.8 mg), (–)-EGCG (495 mg), (–)-epicatechin gallate (112 mg), (–)-epicatechin (100 mg), (–)-epigallocatechin (78 mg) and (–)-gallocatechin gallate (96 mg/1000 mg TP) | 0.03, 0.06 and 0.09 kg−1 BW in the feed | 56 days | Ileum mixed with cecum 56 days | ↑ Species of Lactobacillus reuteri, uncultured Bacteroides sp. and L. crispatus | [135] |
EOs | Thymol (25%) and carvacrol (25%) | 120 mg/kg in the feed | 21 days | Ileum 21 days | ↑ Lactobacillus crispatus and Lactobacillus agilis abundance ↓ Lactobacillus salivarius and Lactobacillus johnsonii abundance | [131] |
EOs | Equal mixture of thymol plus carvacrol | 100 and 200 mg/kg in the feed | 42 days | Duodenum, jejunum, and ileum; 24 days | ↑ Lactobacilli counts ↓ Escherichia coli and Clostridium perfringens counts with 200 mg/kg | [120] |
EOs | Thymol (25%) and carvacrol (25%) | 60, 120, and 240 mg/kg in the feed | 28 days | Ileum and cecum; 21 and 28 days | Ileum: ↓ Escherichia populations Cecum: ↓ numbers of total bacteria and Escherichia on day 28 | [130] |
4.4. Effects of Dietary PFA Supplementation on Immunity
4.5. Effects of Dietary PFA Supplementation on Blood Biochemical Parameters and Oxidant Status
4.6. Effects of Dietary PFA Supplementation on Meat, Internal and External Egg Quality
5. Challenges and Prospective of Using PFAs in Animal Nutrition
5.1. Challenges of Using PFAs in Animal Nutrition
5.2. Prospective of PFAs in Animal Nutrition: Combination of EOs with OAs
6. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Feed Additive | Major Components | Dose, (mg/kg Diet) | Experimental Conditions | Immune Response | References |
---|---|---|---|---|---|
Curcumin EOs (PHY) | Curcumin (72%; CU) carvacrol (21.55 mg/g), thymol (18.76 mg/g) and cinnamaldehyde (27.62 mg/g) of PHY | 50 100 | Corn-soybean meal-based diet | ↓ Total leukocyte and heterophils number in the CU and PHY + CU groups, ↓ lymphocytes in the CU group | [144] |
EOs | Oregano oil (50 g), carvacrol (10 g), thyme oil (33.33 g), eucalyptus oil (50 g), thymol (5 g), eucalyptol(10 g), and acacia (Arabic gum) surfactant (27 g) in water up to 1 L | 500 | Challenge with virulent Newcastle disease virus+ vaccin against Newcastle disease (ND), the avian influenza (AI), infectious bronchitis (IB), and infectious bursal disease (IBD) | ↓ Hemagglutination inhibition and viral shedding titres 1 wk after challenge ↑ ELISA antibody titre for IBD virus at the 28th d of age | [145] |
Resveratrol | Polyphenols | 300 and 600 | Corn-soybean meal-based diet and chickens challenged with Escherichia coli | ↑ Total Ig and IgG at d22 and total Ig and IgM at d 35 | [84] |
Cashew nut shell liquid and castor oil | Cardanol, cardol, and anacardic acid Ricinoleic acid | 1500 | Broilers challenged with Eimeria spp. | ↑ Gene expression of TNF-α, IL-6 and IFN-γ and ↓ expression of IL-1 and COX-2 | [146] |
Yucca schidigera | Saponins | 250 | Corn-soybean meal-based diet Mixed Eimeria challenge | =Lymphocyte percentages to that of unchallenged birds on d7 p.i | [80] |
EOs | Carvacrol (5%), cinnamaldehyde (3%), and capsicum oleoresin (2%) | 100 | Two control diets based on either wheat or maize | ↓ CD40LG, IFN-γ and IL-6. | [86] |
EOs | Cinnamon bark oil (CNO) Clove bud oil (CLO) Ajwain seed oil (AJO) | 300 600 400 | Corn-soybean meal-based diet. Broilers vaccinated against NDV at 5 and 18 d of age, and IBDV at 14 d of age. | ↑ Antibody titres against NDV vaccine with CNO and CLO at 35 d of age | [147] |
EOs | Carvacrol, thymol and cinnamic aldehyde | 5000 and 10,000 | Corn-soybean meal-based diet. | ↑ Total erythrocyte counts, hemoglobin content and ↓ leucocyte count | [42] |
Thyme powder | Major EOs (thymol (50.48%), γ-terpinene (11.03%), P-cymene (9.77%), and carvacrol (4.30%)), phenolic acids (salicylic acid (2450.03 ppm), ellagic acid (1240.42 ppm)) and flavonoid compounds | 2000, 5000 and 8000 | Corn-soybean meal-based diet. | ↑ Lymphocytes, white blood cells, and IgG. ↓ TNF-α, IFN-γ, NF-κBP50 by all the doses. ↓ IL-6 by the dose of 8000 | [87] |
Allium hookeri (AH) roots Fermented root | Phenols | 10,000 and 50,000 for both | Corn-soybean meal-based diet. LPS-induced young broiler chicken | ↓ IL-1b with 1% AH root and 5% fermented root, TNFSF15 expression with fermented root (1% and 5%), and IL-8 with 1% fermented root supplementation | [148] |
EOs | Oregano: (5%) | 300 | Corn-soybean meal-based diet. | ↑ Secondary antibody titer and IgG titer, ↓ H/L ratio | [88] |
Artemisia annua | Phenolics (44.24 mg GAE/g) and flavonoids (27.8 mg RE/g) | 1000 | Heat-stressed broilers | ↑ Intestinal SIgA and IgG | [69] |
Turmeric rhizome | Phenolic compounds (16.2 mg/g) | 2000 | Corn-soybean meal-based diet and broilers kept under chronic heat stress | ↑ Total secondary antibody titer, and ↓ H/L ratio | [68] |
EOs | Carvacrol (60.2%) and thymol (4%) | 50 and 100 in water | Corn-soybean meal-based diet and broilers vaccinated with inactivated avian influenza and Newcastle disease (NDV) | ↑ Antibody titer against NDV and avian influenza virus | [149] |
Mixture of OA+EO | Study Design | Main Findings | Reference |
---|---|---|---|
Citric (25%) and sorbic (16.7%) acids, thymol (1.7%), and vanillin (1.0%) | Type: male breeder chickens Dose: 500 g/metric ton diet Form: microencapsulated Duration: 15 days Conditions: without challenge | -Increased Lactobacilliaceae, Clostridiaceae and Ruminococcaceae abundance -Decreased Staphylococcaceae, | [185] |
Thyme (4%), carvacrol (4%), hexanoic acid (0.5%), benzoic acid (3.5%) and butyric acid (0.5%) | Type: male Arbor Acres broiler chickens Dose: 500 mg/kg diet Form: Encapsulated Duration: 42 days Conditions: Eimeria spp. and Clostridium perfringens | -Improved FCR -Higher villus height and villus height/crypt depth ratio. -Reduced intestinal C. perfringens counts, liver C. perfringens carriage, and gut lesion scores. -Reduced serum fluorescein isothiocyanate dextran (FITC-D) concentrations. -Upregulated claudin-1, IGF-2 and A20 mRNA expression. -Downregulated TRAF-6, TNFSF15 and TOLLIP mRNA levels | [181] |
Citric (25%, as fed) and sorbic acids (16.7%, as fed), thymol (1.7%, as fed) and vanillin (1%, as fed) | Type: Male Ross 308 broiler chickens Dose: 5 g/kg diet Form: Encapsulated Duration: 47 days Conditions: without challenge | -Improved growth performances -Improved gut morphology -Microbial control against Clostridium perfringens, Enterobacteriaceae, Enterococci and Mesophilic bacteria | [186] |
Fumaric, sorbic, malic, and citric acids, thymol, vanillin, and eugenol | Type: Cobb 500 male broilers Dose: 300 g/t diet Form: Protected Duration: 42 days Conditions: Eimeria spp. and Clostridium perfringens | -Greater body weight gain -Higher apparent ileal nutrient and energy digestibility -Improved intestinal integrity with lower blood fluorescein isothiocyanate-dextran concentration -Improved intestinal macroscopic and histologic alterations -Greater expression of MUC2, CLDN1, and OCLN genes | [182] |
Citric andsorbic acids, thymol, and vanillin | Type: By-product breeder chicks Dose: 500 g/metric ton diet Form: Microencapsulated Duration: 4 days Conditions: Without challenge | -Enhanced in vitro functional activity of peripheral blood leukocytes (degranulation, oxidative burst, and nitric oxide production) | [187] |
Sorbic acid (200 g/kg), fumaric acid (200 g/kg), and thymol (100 g/kg) | Type: Roman laying hens Dose: 150 and 300 mg/kg diet Form: Encapsulated Duration: 21–30 weeks Conditions: Without challenge | -Increased laying rate with 150 mg/kg. -A linear increase in ileal villus height. -Increased mRNA relative expression of aminopeptidase, sodium-glucose cotransporter 1, and Na+-independent neutral amino acid transporter in duodenum and glucose transporter 2 in jejunum with 300 mg/kg. -Higher mRNA relative expression ofmucin-2 in ileum with 300 mg/kg. -Linear decrease of the secretory immunoglobulin in ileum A. | [188] |
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Abdelli, N.; Solà-Oriol, D.; Pérez, J.F. Phytogenic Feed Additives in Poultry: Achievements, Prospective and Challenges. Animals 2021, 11, 3471. https://doi.org/10.3390/ani11123471
Abdelli N, Solà-Oriol D, Pérez JF. Phytogenic Feed Additives in Poultry: Achievements, Prospective and Challenges. Animals. 2021; 11(12):3471. https://doi.org/10.3390/ani11123471
Chicago/Turabian StyleAbdelli, Nedra, David Solà-Oriol, and José Francisco Pérez. 2021. "Phytogenic Feed Additives in Poultry: Achievements, Prospective and Challenges" Animals 11, no. 12: 3471. https://doi.org/10.3390/ani11123471
APA StyleAbdelli, N., Solà-Oriol, D., & Pérez, J. F. (2021). Phytogenic Feed Additives in Poultry: Achievements, Prospective and Challenges. Animals, 11(12), 3471. https://doi.org/10.3390/ani11123471