Cooperative Interaction of Phenolic Acids and Flavonoids Contained in Activated Charcoal with Herb Extracts, Involving Cholesterol, Bile Acid, and FXR/PXR Activation in Broilers Fed with Mycotoxin-Containing Diets

The charcoal–herb extract complex (CHC) is a product of activated charcoal sorption of herb extracts that contain phenolic acids and flavonoids. The effective dose of CHC to promote animal growth is about one tenth of effective dosage of activated charcoal. The purpose of this study was to evaluate potential cooperative interactions between activated charcoal and herb extracts. Two feeding experiments were conducted. In Experiment 1, a responsive dose of CHC to broiler growth was determined to be 250 mg/kg of the diet. In Experiment 2, CHC increased growth performance and improved meat quality, but decreased indices of oxidative stress and inflammation as compared with similar doses of activated charcoal or herb extracts. CHC also increased concentrations of serum cholesterol, bile acid in the gallbladder, and bile acid in feces. The herb extracts present in CHC were largely represented by phenolic acids (PAs, caffeic acid, and vanillin) and flavonoids (FVs, daidzein, and quercetin-D-glucoside) in the detoxification activity of CHC in a mouse rescue test when the mice were gavaged with T-2 mycotoxin. PAs and FVs significantly increased the expression of CYP7A1, PXR, CYP3A37, Slco1B3, and Bsep in chicken primary hepatocytes. In conclusion, CHC integrated the cooperative interactions of activated charcoal and herb extracts via the FXR/RXR-PXR pathway to detoxify mycotoxins.


Introduction
The contamination of animal feed by mycotoxins is extensively present in the world, especially in developing countries. About 25% of the world's feed supply is contaminated with mycotoxins [1]. Supplementation with absorbents such as activated charcoal in broiler feed is an approach to sequester mycotoxins and ameliorate oxidative stress caused by mycotoxins. Commercial broilers endure several conditions that can cause oxidative stress. Fast growth and the associated high metabolic rates cause local hypoxia within the muscle, which leads to the release of reactive oxygen species (ROS) by the mitochondrial electron transport chain. This release of ROS causes oxidative stress. Mycotoxins, metabolites of mycotoxins, and pathogens commonly present in feed can cause the excessive production of free radicals and inflammation in broilers [2][3][4]. Common approaches to mycotoxin mitigation focus on the absorption and degradation of mycotoxins in feed [5]. An alternative columns (AflaTest ® , Vicam, Waters, Milford, MA, USA). The second, used for the analysis of other mycotoxins, was cleaned up with the use of C18 sorbent (50 mg) and magnesium sulphate (150 mg). Extracts were evaporated, mixed with a labelled internal standard solution (used for quantitation), and determined using a UPLC-MS/MS technique. The LC-MS/MS analysis of all the targets was carried out by using the Waters ACQUITY UPLC system (Waters, Milford, MA, USA) coupled to a 5500 Quadrupole TRAP ® hybrid triple quadrupole/linear ion trap MS (AB SCIEX, Foster City, CA, USA) via a Turbo V Ion Spray interface with an electrospray ionization (ESI) source. Analyst ® 1.6.2 software (AB SCIEX) was used to control the UPLC-QTrap-MS/MS system and for data acquisition and processing. Nitrogen was used as the nebulizer (GS1), heater (GS2), and curtain (CUR) gas as well as the collision activation dissociation gas. Each mycotoxin standard was directly infused into the mass spectrometer to obtain the MS/MS parameters for each analyte. The MS/MS was performed with electrospray ionization (ESI) in positive mode under the multiple reaction monitoring (MRM) condition. Ion source temperature was set at 550 • C, and the spray voltage was +5500 V. Ion sources GS1 and GS2 together with CUR gas were set at 55, 55, and 35 psi, respectively. The MRM mode was used for quantitation. The UPLC separation of all analytes was carried out on a SHISEIDO Capcell Core C18 column (2.1 × 50 mm, 2.7 µm) at a flow rate of 0.3 mL/min. The mobile phase was composed of 0.1% formic acid aqueous solution (A) and ACN with 0.1% formic acid (B) using the following gradient elution program: 0-2.0 min, linear change from 25 to 55% B; 2.0-5.5 min, from 55 to 90% B; 5.5-5.51 min, switch from 90 to 25% B, and hold at 25% B for an additional 2 min to re-equilibrate the column. The column was kept at 30 • C, and the injection volume was 2 µL. All trials were performed in triplicate. Absorption and desorption values were calculated for each toxin and expressed as percentages.

Antioxidant Activities of CHC In Vitro
The radical scavenging activity of CHC against 2,2-diphenyl-1-picrylhydrazyl (DPPH) was measured according to Shimada et al. [41]. Various concentrations (25,50,100, and 150 µg/mL) of CHC were subjected to the assay. Vitamin C was used for comparison. DPPH radical scavenging activity was determined by measuring the absorbance at 517 nm (OD 517 ). Each sample was repeated three times. A blank control that included all reagents without CHC (OD 517-blank ) was used to correct readings for the samples. The scavenging activity of the DPPH radical was calculated as follows: [(1 − OD 517 )/OD 517-blank ] × 100%. Total antioxidant activities of CHC were determined using the ABTS (2,2 -azino-bis(3ethylbenzthiazoline-6-sulfonic acid radical cation) assay [42]. Trolox was used for comparison. Total antioxidant activity was determined by measuring the absorbance at 734 nm (OD 734 ). A blank control that included all reagents without CHC (OD 734-blank ) was used to correct readings for the samples. Each sample was repeated three times. The total antioxidant activity was calculated as follows: [(1 − OD 734 )/OD 734-blank ] × 100%. Superoxide radical scavenging activity was determined according to procedures reported by Jing and Zhao [43]. Absorbance was measured at 420 nm (OD 420 ). Vitamin C was used for comparison (OD 420-VC ). A blank was the absorbance of Tris-HCl buffer instead of the pyrogallol solution (OD 420-blank ). Each sample was repeated three times. The superoxide radical scavenging activity was calculated as follows: [1 − (OD 420 − OD 420-blank )/OD 420-VC ] × 100%.

Cell Culture and Treatments
To reveal the anti-inflammatory effect of CHC-Herb in vitro, the RAW 264.7 cell line was cultured in Dulbecco's modified Eagle's medium (DMEM) supplemented with 10% heat-inactivated fetal bovine serum, 100 units/mL penicillin, and 0.1 mg/mL streptomycin and then incubated at 37 • C, in an atmosphere of 85 % humidified air with 5% CO 2 . The reagents were all from Gibco, Thermo Fisher Scientific, Grand Island, NY, USA. The cells were plated into 24-well plates at a concentration of 10 6 cells/mL and with a final volume of 1 mL. Cell viability was measured after 24 h of incubation with CHC-Herb, using the Vybrant 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) cell proliferation assay kit (Thermo Fisher Scientific, Grand Island, NY, USA). Cells were pretreated with various concentrations of CHC-Herb for 2 h and then treated with lipopolysaccharide (LPS, 1 µg/mL, Sigma-Aldrich, St. Louis, MO, USA) for an additional 24 h. The supernatants were collected and analyzed to obtain the levels of nitric oxide (NO, Promega Corp., Madison, WI, USA) and IL-6 (Bio-Rad Laboratories Inc., Irvine, CA, USA) using commercial kits, according to the manufacturers' instructions. The control was the DMEM medium without LPS or CHC-Herb. L-N-methylarginine (NMMA, 100 µm) was used as comparison.
To reveal the effects of the PF-Cocktail on gene expression, hepatocytes from adult broiler livers (180-250 g) were isolated by collagenase perfusion in situ [44] and purified by centrifugation by applying Percoll for better separation [45]. Isolated hepatocytes were cultured with M199 in 35 mm dishes. The dishes were coated with collagen prepared from rat tail tendons (1 g/300 mL), which had been dissolved in 0.1% acetic acid for 24 h. The M199 culture medium additionally contained 4% new-born calf serum, 15 mM Hepes, 10 mM glucose, 0.2% BSA, and 10−7 M insulin. Every dish was filled with 10 6 cells/mL and 2 mL of the culture medium. The medium was changed after 4 h and 24 h. The hepatocytes were cultured for 48 h in a gas atmosphere containing 5% CO 2 at 37 • C. The cells were incubated with phenolic acids (PAs, composed of caffeic acid and vanillin at a ratio of 1:1, w/w; 150 µg/mL), flavonoids (FVs, composed of daidzein and quercetin-D-glucoside at a ratio of 1:1, w/w, 50 µg/mL), PF-Cocktail (PAs+FVs, 200 µg/mL), and CHC-Herb (200 µg/mL) for 48 h before being harvested for mRNA quantification. All the reagents above in the cell culture were purchased from Cayman (Cayman Chemical, Ann Arbor, MI, USA).

Animals, Diets, and Experimental Design
Broiler feeding studies were conducted via two experiments. Experiment 1 (Exp. 1) was a dose-dependent trial that aimed to find a responsive dose for the following experiment. A total of 540 male Arbor Acres chicks (42.8 ± 0.7 g body weight, BW) were randomly assigned to 5 dietary treatments (6 pens/treatment; 18 birds/pen): a corn-soybean meal basal diet (CON) and CON supplemented with 250, 500, 750, 1000 mg/kg of CHC (CHC250, CHC500, CHC750, CHC1000, respectively). Experiment 2 (Exp. 2) was carried out to compare the CHC effects with its constituents, herb extracts, and activated charcoal. A total of 432 chickens (45.1 g ± 1.0 g BW) were randomly assigned to 4 dietary treatments: CON, CON supplemented with 25 mg/kg of CHC-Herb (Herb), CON supplemented with 225 mg/kg of activated charcoal (AC), and CON supplemented with 250 mg/kg of CHC (CHC). The 250 mg/kg dose of CHC was responsive to the CHC treatment from Experiment 1. For preparation of CHC, herb extracts were mixed with activated charcoal at a ratio of 1:9 (w/w), which meant herb extracts took up of 10% of CHC weight, and activated charcoal took up 90% of CHC weight. Thus, in broiler diets, the supplemental doses of herb extracts and activated charcoal were 25 mg/kg and 225 mg/kg, respectively. All chicks were given ad libitum access to feed and water for 42 days. The diets were offered in two phases (starter phase: d 1-21; grower phase: d 22-42. Table 1). Room temperature was maintained at 34~35 • C during the first 7 d and was then gradually reduced to 25~26 • C, with a drop of 2 • C per week. The broilers were vaccinated against Newcastle on d 7 and against infectious bursal disease on d 14. The corn-soybean meal basal diet met the nutrient requirements of broilers, as stated by NRC [46]. All diets were prepared in one batch. Herb extracts, activated charcoal, or CHC was first mixed with premixed vitamins and minerals, subsequently mixed with other ingredients, and then stored in covered containers. All diets were made in one batch and stored in a cool and dry environment. A fresh feed sample (from same source and batch) without moistening or the addition of additives was kept at −20 • C until the samples were shipped for mycotoxin concentration analyses. All the feed samples were analyzed in order to determine the dietary mycotoxin concentration before being administered to experimental broilers. This experiment was carried out at the National Feed Engineering Technology Research Center of the Ministry of Agriculture Feed Industry Center Animal Testing Base (Hebei, China). All procedures used in this study were conducted in accordance with Chinese Guidelines for Animal Welfare and approved by the China Agricultural University Institutional Animal Care and Use Committee (AW52501102-1, AW54906203).

Growth Performance and Sample Collection
The body weight of birds was recorded on days 1, 21, and 42 of the experiment after a 12 h withdrawal of feed, but not water. Average daily body weight gain (ADG) was calculated for the starter phase (d 1-21), grower phase (d , and whole phase (d 1-42). Average daily feed intake (ADFI) was recorded. On days 21 and 42, one broiler closest to the average BW of each pen was selected for blood sampling from the jugular vein. On d 42, the birds were euthanized after blood collection. Intestine tissues were sampled for histological analysis. In Experiment 2, mucosa from intestines was scraped using glass slides, and the liver and kidneys were sampled, chilled, and stored at −80 • C for further analysis. Sampled breast and thigh muscles were stored at 4 • C for meat quality assessment and at −80 • C for further analysis.

Meat Quality Assessment
Immediately following fabrication, boneless and skinless breast and thigh samples from the right side were assessed for pH and meat color. Muscle pH at 45 min and 24 h after slaughter (pH 45min and pH 24h ) were determined in triplicate by a portable pH meter (Testo 205, Melrose, MA, USA) [47]. Lightness (L*), redness (a*), and yellowness (b*) values were determined at 24 h postmortem with a spectrometer (CM-3500d; Konica Minolta, Tokyo, Japan), according to the methods of Li et al. [48]. Shear force was measured using a TA.XT plus texture analyzer (Stable Micro Systems Ltd., Surrey, UK), with a 5 kg load cell and a Meullenet-Owens Razor Shear Blade. The water holding capacity (WHC) of meat was assayed according to the methods of Wardlaw et al. [49]. Every measurement was performed in triplicate. The amount of protein in the breast and thigh meat was calculated using the method 981.10 described by the Association of Analytical Chemists [50].

Analyses of Indices of Antioxidant Enzymes, Inflammatory and Immune Factors of Broilers
The activity of serum and tissue malondialdehyde (MDA), total superoxide dismutase (T-SOD), and indices of interleukin-1β (IL-1β), interferon-γ (IFN-γ), and insulin-like growth factor 1 (IGF-I) were measured using commercial assay kits (Nanjing Jiancheng Bioengineering Institute, Nanjing, China), according to manufacturers' instructions. Intestinal secretory immunoglobulin (SIgA) concentrations were assayed using an Sn-69513-type immune counter (Shanghai Nuclear Annular Photoelectric Instrument Co., Ltd., Shanghai, China). The analysis of serum triglyceride, total cholesterol, low-density lipoprotein cholesterol, and high-density lipoprotein cholesterol were performed using an automatic biochemical analyzer (Hitachi 7600, Tokyo, Japan).

Quantitative Analyses of Bile Acids
Bile acids were quantified using our established methods [51], with modifications. Briefly, tissues were weighed, and internal standards were added before extraction with 0.2 M NaOH (0.5-6 mL) at -80 • C for 20 min. After cooling, 1.5-6 mL of water was added, and the samples were purified using liquid-liquid extraction with 1.5-6 mL of hexane. The extraction step was repeated three times, and the water phases were combined and the samples were further purified with Oasis HLB 3 cc 60 mg (Waters, Milford, MA, USA). There were 6 internal standards (D4-glycocholic acid (GCA), D4-glycodeoxychlic acid (GDCA), D4-cholic acid (CA), D4-Ursodeoxycholic acid (UDCA), D4-lithocholic acid (LCA), and D4glycochenodeoxycholic acid (GCDCA); 50 nM for each). All mixtures were kept at -20 • C for 10 min and were then centrifuged at 13,000× g and 4 • C for 15 min. A 240 µL aliquot of the supernatant was transferred and vacuum dried. A total of 40 µL acetonitrile-methanol (9:1, v/v) containing 0.01% formic acid was added. The supernatant from the extraction was used for UPLC-MS analysis. A Waters ACQUITY ultra performance LC system equipped with a binary solvent delivery manager and a sample manager (Waters, Milford, MA, USA) was used for BA analysis. The mass spectrometer was a Waters XEVO TQ instrument with an ESI source (Waters Corp., Milford, MA, USA). The entire LC−MS system was controlled using the MassLynx software (Version 4.1). All chromatographic separations were performed with an ACQUITY BEH C18 column (1.7 µm, 100 mm × 2.1 mm internal dimensions) (Waters Corp., Milford, MA, USA). The mobile phase consisted of water with 0.01% formic acid (mobile phase A) and acetonitrile/methanol (9/1, v/v) with 0.01% formic acid (mobile phase B).

Preparation of Total RNA and Quantitative Reverse Transcriptase PCR (qPCR)
Total RNA was isolated using the RNAgents Total RNA Isolation System (Promega, Madison, WI, USA). RNA samples were reverse transcribed in a Programmable Thermal Controller (PTC)-100 (MJ Research, Watertown, MA, USA). RNA was converted into cDNA using the commercial kits (all from Promega). The primers of the qPCR analysis were synthesized in Sangon Biotech (Shanghai, China). The quantitative real-time PCR reaction was performed with the PowerUp SYBR Green PCR Master Mix (Applied Biosystems, Thermo Fisher Scientific, San Jose, CA, USA), and the reaction was accomplished using the QuantStudio 7 Flex Real-Time System (Applied Biosystems Instruments, Thermo Fisher Scientific, San Jose, CA, USA). The gene expression values were normalized in terms of the glyceraldehyde-3-phophate dehydrogenase (GAPDH) levels and were expressed as fold changes relative to the control group by using the 2 −∆∆CT method. The primers of CYP450 isozymes, metabolism enzymes, nuclear receptors, and reference gene GAPDH were designed using Primer Premier 5.0 and are listed in Table 2. Table 2. PCR primer sequences.

Gene Accession No. Forward Primers Reverse Primers
Bsep

Assessment of Efficacy of PF-Cocktail for Acute T-2 Mycotoxin Challenge
Male ICR mice (21-24 g) (Weitonglihua Limited Co., Beijing, China) were maintained at a controlled temperature (~22 • C) and had ad libitum access to feed and water. The T-2 mycotoxin challenge was performed according to a reported method [52]. The T-2 toxin stock solution (Cayman Chemical, Ann Arbor, MI, USA) was diluted with a solution of propylene glycol and ethanol (mixed ratio was 9:1, v/v), and 100 µL of diluted T-2 toxin was administered to mice by subcutaneous injection (2 mg/kg). After 1 h, the mice were assigned to 4 different treatments: saline (CON), activated charcoal (AC, 7 g/kg BW), PF-Cocktail and AC (PF-Cocktail+AC, 0.78 g/kg BW of PF-Cocktail and 7 g/g BW of activated charcoal), and CHC (7 g/kg BW). Mice were gavaged with saline, activated charcoal, PF-Cocktail, respectively. All experiments were performed on 16 h fasted mice. The mice were free to feed 2 h after treatment. The number of surviving mice for each treatment (n = 10) was determined at different times after exposure to T-2 mycotoxin. Data were analyzed for statistical significance using the Graphpad Prism 7 software. All procedures used in this study were conducted in accordance with the Chinese Guidelines for Animal Welfare and approved by the China Agricultural University Institutional Animal Care and Use Committee (MC3965881).

Statistical Analysis
Differences among the treatments were determined using the Student t-test or a oneway analysis of variance (ANOVA) with the JMP software program (JMP ® , version 14; SAS Institute Inc., Cary, NC, USA). Mean comparisons were conducted using Duncan's New Multiple Range Test. The errors were presented as Standard Errors of Mean (SEM). Regression analysis was used to test the linear and quadratic effects of increasing levels of CHC supplementation. Differences were regarded as statistically significant at p < 0.05; an indicative trend was defined as 0.05 ≤ p < 0.10. Survival analyses were conducted using the Log-rank (Mantel-Cox) test in GraphPad Prism 7.

Characterization of CHC-Herb
CHC-Herb contained various phytochemical compounds. The level of total phenolic compounds was 110.4 ± 2.2 mg of equivalent gallic acid per gram of extract. The flavonoid concentration was 40.9 ± 0.8 mg of equivalent catechin per gram of extract. CHC-Herb was analyzed with UPLC ( Figure 1), and the active components are presented in Table 3 according to their abundance, as reflected by the peak areas. The active components of CHC-Herb include phenolic acids (salsolinol, shogaol, caffeic acid, vanillin), flavonoids (daidzein, formononetin, puerarin, quercetin-3-β-glucodide, calycosin, kaempferol-7-β-D-glucopyranoside, astragalin, isorhamnetin-3-glucoside, genistein), and organic acids (citric acid, azelaic acid, succinic acid, isocitric acid). To dissect the function of the bioactive components of CHC-Herb, we designed a mixture of phenolic acids and flavonoids called PF-Cocktail in order to mimic CHC-Herb based on the quantification assay, for further studies. The PF-Cocktail contained 110.4 mg of phenolic acids (PAs, composed of caffeic acid and vanillin at a ratio of 1:1, w/w) and 40.9 mg of flavonoids (FVs, composed of daidzein and quercetin-D-glucoside at a ratio of 1:1, w/w) per gram of PF-Cocktail solution (1 g/mL). In simple words, caffeic acid and vanillin (representing PAs) along with daidzein and quercetin-D-glucoside (representing FVs) were used to represent the herb components of CHC-Herb. Regression analysis was used to test the linear and quadratic effects of increasing levels of CHC supplementation. Differences were regarded as statistically significant at p < 0.05; an indicative trend was defined as 0.05 ≤ p < 0.10. Survival analyses were conducted using the Log-rank (Mantel-Cox) test in GraphPad Prism 7.

Characterization of CHC-Herb
CHC-Herb contained various phytochemical compounds. The level of total phenolic compounds was 110.4 ± 2.2 mg of equivalent gallic acid per gram of extract. The flavonoid concentration was 40.9 ± 0.8 mg of equivalent catechin per gram of extract. CHC-Herb was analyzed with UPLC ( Figure 1), and the active components are presented in Table 3 according to their abundance, as reflected by the peak areas. The active components of CHC-Herb include phenolic acids (salsolinol, shogaol, caffeic acid, vanillin), flavonoids (daidzein, formononetin, puerarin, quercetin-3-β-glucodide, calycosin, kaempferol-7-β-D-glucopyranoside, astragalin, isorhamnetin-3-glucoside, genistein), and organic acids (citric acid, azelaic acid, succinic acid, isocitric acid). To dissect the function of the bioactive components of CHC-Herb, we designed a mixture of phenolic acids and flavonoids called PF-Cocktail in order to mimic CHC-Herb based on the quantification assay, for further studies. The PF-Cocktail contained 110.4 mg of phenolic acids (PAs, composed of caffeic acid and vanillin at a ratio of 1:1, w/w) and 40.9 mg of flavonoids (FVs, composed of daidzein and quercetin-D-glucoside at a ratio of 1:1, w/w) per gram of PF-Cocktail solution (1 g/mL). In simple words, caffeic acid and vanillin (representing PAs) along with daidzein and quercetin-D-glucoside (representing FVs) were used to represent the herb components of CHC-Herb.

In Vitro Assay of CHC and CHC-Herb Activities
As the concentrations of mycotoxin increased in the solutions (DON, AFB1, OTA, and ZEN), the absorption of mycotoxin content was progressively increased (Figure 2A). When the DON concentrations were within 1 µg/mL, CHC absorption rates were 100%; when the DON concentrations were higher than 10 µg/mL, the absorption rates dropped to 91.92 ± 0.81%, with the absorption content at 8.432 µg/mg. When the AFB1 concentrations ranged from 10 to 200 ng/mL, CHC absorption rates were within 99.48 ± 0.89 and 100 ± 0.92%. When the ZEN concentrations were 5 µg/mL or lower, the absorption rate was maintained at 100 ± 0.86%. When the OTA concentrations were 500 ng/mL or lower, the absorption rates ranged from 99.63 ± 0.90 to 99.74 ± 0.85%, with the absorbed content at 469.44 ng/mg. In the PBS solutions(pH 2.0 and pH 6.0), andin gastric solutions (data not shown), CHC maintained its high absorption rates for AFB1, ZEN, and OTA, which ranged from 95.78 ± 0.86 % to 100 ± 0.01%, while CHC's absorption rate for DON in simulated gastric solutions (69.34 ± 0.78%) was lower than it was for AFB1 (100 ± 0.01%), ZEN (99.23 ± 0.04%), and OTA (95.78 ± 0.86%). The desorption rate of CHC for mycotoxins were as low as 0.00 ± 0.01% to 0.52 ± 0.07%. As the concentrations of CHC-Herb increased, the DPPH scavenging effects increased ( Figure 2B). The SC50 of the DPPH radical scavenging activity of CHC-Herb was 89.5 μg/mL. It showed 70% DPPH radical scavenging ability at 150 mg/mL, which was lower than the effect of vitamin C. CHC-Herb (150 μg/mL) showed a total antioxidant activity of 38%, while it was 89% in comparison to Trolox. The SC50 of the ABTS radical cation scavenging activity of CHC-Herb was 65.1 μg/mL. In the present conditions, CHC-Herb showed lower free radical scavenging activities as compared to Trolox when As the concentrations of CHC-Herb increased, the DPPH scavenging effects increased ( Figure 2B). The SC 50 of the DPPH radical scavenging activity of CHC-Herb was 89.5 µg/mL. It showed 70% DPPH radical scavenging ability at 150 mg/mL, which was lower than the effect of vitamin C. CHC-Herb (150 µg/mL) showed a total antioxidant activity of 38%, while it was 89% in comparison to Trolox. The SC 50 of the ABTS radical cation scavenging activity of CHC-Herb was 65.1 µg/mL. In the present conditions, CHC-Herb showed lower free radical scavenging activities as compared to Trolox when scavenging ABTS radical cation. At a concentration of 150 µg/mL, the scavenging activity of CHC for superoxide was 40.9% as compared to 93.2% for vitamin C. The SC 50 of the superoxide radical scavenging activity of CHC-Herb was 88.1 µg/mL.
To determine the cytotoxic potential of CHC-Herb, RAW 264.7 cells were treated with different concentrations of CHC-Herb, and cell viability was measured after 24 h of incubation ( Figure 2C). The results showed no significant cytotoxicity in the RAW 264.7 cells at their effective concentrations (≤75 µg/mL). Therefore, the maximum concentration of CHC-Herb was limited to 75 µg/mL. The production of IL-6 by the cells was considerably reduced by the treatment with CHC-Herb (25, 50, and 75 µg/mL) as compared with the control. CHC-Herb at these concentrations inhibited LPS-induced NO production in the RAW 264.7 cells. The results demonstrated the anti-inflammatory and anti-oxidative effects of CHC-Herb in vitro.

CHC Effects on Growth Performance of Broilers
In Experiment 1, during d 1-21, ADG was increased in the broilers treated with 250 or 500 mg/kg as compared to the unsupplemented birds fed with CON (p < 0.05, Figure 3A). As the supplementation level of CHC increased, ADG tended to responded quadratically (p = 0.042) on d 21. During d 1-42, CHC supplementation at 500 mg/kg increased ADG (p = 0.035) ( Figure 3B). Accordingly, serum IGF-1 showed a well-matched trend to ADG values at d 21 and d 42. CHC showed its active effect on ADG at the supplemental dose of 250 mg/kg; thus, CHC at 250 mg/kg was selected for the comparison with its two constituents, Herb and AC, for the following study on broiler growth. In Experiment 2, Herb (25 mg/kg) and AC (225 mg/kg) supplementation did not show any improvement of ADG during d 1-21 and d 1-42 as compared to CON ( Figure 3C). These results indicate a synergy of Herb and AC combined with CHC in the promotion of broiler growth performance.

CHC Effects on Antioxidative and Inflammatory Indices of Serum and Tissues
In CHC-treated broilers, MDA levels were decreased and T-SOD activities were increased in the serum, liver, and ileum ( Figure 4A,B,D. p < 0.01), except for the kidney ( Figure 4C), as compared to CON. Levels of MDA or T-SOD as compared to that of the CON group were not significantly altered by the sole supplementation of Herb or AC in the diets. CHC supplementation decreased the IL-1β and IFN-γ levels in the serum and the IL-1β level in the ileum as compared to CON ( Figure 3E,F. p < 0.01). Similar to the indices of antioxidants, only CHC (not Herb or AC) altered IL-1β and IFN-γ levels in the serum and ileum. with its two constituents, Herb and AC, for the following study on broiler growth. In Experiment 2, Herb (25 mg/kg) and AC (225 mg/kg) supplementation did not show any improvement of ADG during d 1-21 and d 1-42 as compared to CON ( Figure 3C). These results indicate a synergy of Herb and AC combined with CHC in the promotion of broiler growth performance. , different doses of CHC (0, 250, 500, 750, and 1000 mg/kg) were supplemented in cornsoybean-based diets, which were fed to broilers for 42 days. In Experiment 2 (C), broilers were fed CON, Herb (25 mg/kg), AC (225 mg/kg), or CHC (250 mg/kg)-supplemented diets for 42 days. CON was corn-soybean basal die. Herb, herb extracts. AC, activated charcoal. ADG, average daily gain; ADFI, average daily feed intake; IGF-1: insulin-like growth factor 1. t-test was performed to compare differences between CON and the treatment group. Significant differences were labelled as ** (p < 0.01) or * (p < 0.05).  1 (A,B), different doses of CHC (0, 250, 500, 750, and 1000 mg/kg) were supplemented in cornsoybean-based diets, which were fed to broilers for 42 days. In Experiment 2 (C), broilers were fed CON, Herb (25 mg/kg), AC (225 mg/kg), or CHC (250 mg/kg)-supplemented diets for 42 days. CON was corn-soybean basal die. Herb, herb extracts. AC, activated charcoal. ADG, average daily gain; ADFI, average daily feed intake; IGF-1: insulin-like growth factor 1. t-test was performed to compare differences between CON and the treatment group. Significant differences were labelled as ** (p < 0.01) or * (p < 0.05).
( Figure 4C), as compared to CON. Levels of MDA or T-SOD as compared to that of the CON group were not significantly altered by the sole supplementation of Herb or AC in the diets. CHC supplementation decreased the IL-1β and IFN-γ levels in the serum and the IL-1β level in the ileum as compared to CON ( Figure 3E,F. p < 0.01). Similar to the indices of antioxidants, only CHC (not Herb or AC) altered IL-1β and IFN-γ levels in the serum and ileum. Broilers were fed with CON, Herb (25 mg/kg), AC (225 mg/kg), or CHC (250 mg/kg)-supplemented diets for 42 days. CON was corn-soybean basal die. Herb, herb extracts. AC, activated charcoal. One-way ANOVA was performed for statistical analysis. Bars with different letters indicate significant differences (p < 0.01).

CHC Effects on Meat Quality of Broilers
Dietary treatments had no effects on the pH45min or pH24h of the breast and thigh muscles of broilers ( Table 4). The water-holding capacity at 24 h was not affected by dietary treatments. Regarding meat color, CHC decreased the lightness of the breast muscle (p < 0.05), while it increased the redness of the thigh muscle (a*, p < 0.05). CHC Broilers were fed with CON, Herb (25 mg/kg), AC (225 mg/kg), or CHC (250 mg/kg)-supplemented diets for 42 days. CON was corn-soybean basal die. Herb, herb extracts. AC, activated charcoal. Oneway ANOVA was performed for statistical analysis. Bars with different letters indicate significant differences (p < 0.01).

CHC Effects on Meat Quality of Broilers
Dietary treatments had no effects on the pH 45min or pH 24h of the breast and thigh muscles of broilers ( Table 4). The water-holding capacity at 24 h was not affected by dietary treatments. Regarding meat color, CHC decreased the lightness of the breast muscle (p < 0.05), while it increased the redness of the thigh muscle (a*, p < 0.05). CHC tended to decrease the shear force of the breast (p = 0.094) and thigh (p = 0.063). Herb and AC showed no significant effects on meat color or shear force.

Effects on Bile Acid Synthesis and Metabolism
Supplementation with CHC at doses of 250, 500, 750, and 1000 mg/kg increased the serum levels of cholesterol as compared to the unsupplemented CON ( Figure 5A, p < 0.01). However, as the dose of CHC increased, the cholesterol levels did not increase accordingly ( Figure 5B, p > 0.05), which indicated a path for cholesterol excretion. Both CHC and AC which had similar dosed AC as CHC contained, increased serum cholesterol as compared to CON (p < 0.01). CHC and AC supplementation numerically increased the serum levels of triglyceride without any statistical difference (p > 0.05). Analysis of bile acids in the gallbladder revealed that supplemented CHC and AC significantly increased free bile acids (cholic acid (CA), chenodeoxycholic acid (CDCA), ursodeoxycholic acid (UDCA), deoxycholic acid (DCA), and lithocholic acid (LCA)) and conjugated bile acids (taurocholic acid (TCA), taurochenodeoxycholic acid (TCDCA), taurolithocholic acid (TLCA), and glycolithocholic acid (GLCA)) as compared to CON ( Figure 5C, p < 0.01). Both CHC and AC resulted in a greater level of free and conjugated bile acids in feces in comparison to CON, which indicated that CHC and AC promoted the excretion of bile acids from broilers via feces. Comparatively, CHC had much greater effects than AC in the stimulation of bile acid synthesis and excretion (p < 0.01). Broilers were fed with treatment diets. CON was corn-soybean basal die. Herb, herb extracts. AC, activated charcoal. Specific bile acids in the gallbladder and feces (C), including free and conjugated bile acids. Survival rate of four groups of mice gavaged with AC, PF-Cocktail, and CHC upon challenge with oral T-2 mycotoxin (D). Male ICR mice were challenged with mycotoxin T-2 by subcutaneous injection (2 mg/kg). After 1 h, these mice were treated with gavage of saline (CON), activated charcoal (AC, 7 g/kg BW), PF-Cocktail and AC (PF-Cocktail+AC, 0.78 g/kg BW of PF-Cocktail and 7 g/g BW of activated charcoal), and CHC (7 g/kg BW), respectively. The number of surviving mice for each treatment (n = 10) was determined at different times after exposure to T-2 mycotoxin. Survival analyses were conducted using the log-rank (Mantel-Cox) test in GraphPad Prism 7. Treatments with phenolic acids (PAs), flavonoids (FVs) or PF-Cocktail altered the expression of xenobiotic detoxification enzymes in broiler primary hepatocytes (E). The mRNA levels of metabolic enzymes and nuclear receptors involved in bile synthesis, metabolism, and Figure 5. CHC effects on bile acid synthesis, metabolism, and alleviation of liver damage. Effects of CHC supplementation at different doses (0, 250, 500, 750, and 1000 mg/kg), of Herb (25 mg/kg), and of AC (225 mg/kg) on the levels of serum cholesterol (* indicates p < 0.05) (A) and triglyceride (B). Broilers were fed with treatment diets. CON was corn-soybean basal die. Herb, herb extracts. AC, activated charcoal. Specific bile acids in the gallbladder and feces (C), including free and conjugated bile acids. Survival rate of four groups of mice gavaged with AC, PF-Cocktail, and CHC upon challenge with oral T-2 mycotoxin (D). Male ICR mice were challenged with mycotoxin T-2 by subcutaneous injection (2 mg/kg). After 1 h, these mice were treated with gavage of saline (CON), activated charcoal (AC, 7 g/kg BW), PF-Cocktail and AC (PF-Cocktail+AC, 0.78 g/kg BW of PF-Cocktail and 7 g/g BW of activated charcoal), and CHC (7 g/kg BW), respectively. The number of surviving mice for each treatment (n = 10) was determined at different times after exposure to T-2 mycotoxin. Survival analyses were conducted using the log-rank (Mantel-Cox) test in GraphPad Prism 7. Treatments with phenolic acids (PAs), flavonoids (FVs) or PF-Cocktail altered the expression of xenobiotic detoxification enzymes in broiler primary hepatocytes (E). The mRNA levels of metabolic enzymes and nuclear receptors involved in bile synthesis, metabolism, and xenobiotic detoxification (CYP7A1, FXR, RXR, PXR, CYP3A37, Slco1B3, and Bsep) in cultured primary chicken hepatocytes were quantified by qRT-PCR, with GAPDH mRNA as an internal control. PAs (phenolic acids, composed of caffeic acid and vanillin at a ratio of 1:1, w/w, 150 µg/mL); FVs (flavonoids, composed of daidzein and quercetin-D-glucoside at a ratio of 1:1, w/w, 50 µg/mL); PF-Cocktail (PAs+FVs, 200 µg/mL). One-way ANOVA was performed for statistical analysis. Bars with different letters indicate significant differences within a quantified gene (p < 0.01).

Effects of PAs and FVs Representing CHC-Herb on Detoxification of T-2 Mycotoxin in Mice
The survival rate of mice in the control (saline) treatment declined steadily throughout the observation period, reaching a value of 10% after 60 h ( Figure 5D). All mice treated with AC, AC+PF-Cocktail, or CHC were protected against the lethal effects of T-2 mycotoxin in different degrees (p < 0.01). The 50% survival of mice in the control group was significantly lower than the value of 90% for the treated group. The detoxification effect of AC alone was different from the CHC effect (p = 0.03), while the effect of AC with the PF-Cocktail showed no difference from that of CHC (p = 0.35). These results confirm that CHC had the most significant effects on the detoxification of T-2 toxin. PAs and FVs (PF-Cocktail) represented a majority effect of detoxification of T-2 toxin of the herb portion of CHC.

Effects of PF-Cocktail on Gene Expressions in Primary Chicken Hepatocytes
The genes related to bile acid synthesis, transportation, and metabolism as well as their nuclear receptors that were regulated by PAs, FVs, and the PF-Cocktail were quantified ( Figure 5E). The results showed significantly increased mRNA levels of bile acid synthesis (CYP7A1), bile salt export pump (Bsep), and the genes related to xenobiotic metabolism (CYP3A37 and Slco1B3) due to the PF-Cocktail. Compared to CON, both PAs and FVs alone moderately increased the expression of the above genes, but the increase was much lower than that resulting from their combination (PF-Cocktail). FXR were the target nuclear receptors of bile acids, and bile acids were ligands that activated FXR by conformation alteration. Thus, the expression level of FXR was not significantly altered by the dietary treatments. The PXR expression level was increased by FVs and the PF-Cocktail since it could be regulated by FVs at both the transcriptional level and via conformation alteration. These results proved the synergy of PAs and FVs in the activation of gene expression related to bile acid synthesis and the genes of xenobiotic metabolism.

Discussion
Mycotoxin contamination has been estimated to affect 25% of global feed production [53]. Concentrations of individual mycotoxins in feed are regulated in many developed countries [54] and in China [55]; however, the regulation of individual mycotoxins ignores the deleterious effects of synergistic interactions among mycotoxins [56]. The severity of mycotoxicosis can be complicated by vitamin deficiency, caloric deprivation, and infectious diseases [57]. Mycotoxins in feed can cause the overproduction of free radicals, which leads to oxidative stress in animals. Oxidative stress and inflammatory reactions are often associated with enteritis in broilers and piglets [58,59].
Dietary supplementation with charcoal or activated charcoal is an effective detoxification strategy due to charcoal's high absorptive capacity, particularly in relation to a variety of toxins such as mycotoxins, toxic metabolites, and pathogens. Effective doses of activated charcoal in broilers range from 0.3% to 10%, as reported in the literature [11]. In the current study, CHC improved the growth performance of broilers at a very low dose of 250 mg/kg, which is about one-tenth of the reported effective dose for charcoal or activated charcoal alone. In addition, the dietary supplementation of activated charcoal alone at 225 mg/kg, a level similar to that of activated charcoal at 250 mg/kg CHC, did not affect the growth performance of the broilers.
Herb extracts contain various glycosides, phenolics, and flavones, including flavonoids that have intense antioxidant and anti-inflammatory activities [16]. Beneficial effects of plant extracts on poultry performance can be achieved with doses ranging from 0.5% to 3% for mixed extracts [60]. In the current study, we used herb extracts from Pulsatilla chinensis, Portulaca oleracea L., Artemisia argyi Folium, and Pteris multifida Poir at a dose as low as 25 mg/kg to supplement diets for broilers. This dosage of herb extracts was similar to the compositional content of herb extracts contained in CHC (10% herb extracts, w/w). As expected, herb extracts alone at such a low dose had no effect on broiler performance. However, feeding herb extracts at this low dose combined with activated charcoal in CHC improved growth performance and positively affected the anti-inflammatory and antioxidant indices. These findings indicate the cooperative interactions of the charcoal portion and the herb portion of CHC. Consequently, the intrinsic mechanism for the interactions between activated charcoal and herb extracts was investigated.
Firstly, multiple active components in the herb extracts, including total phenolics and flavonoids, were quantified; individual active components were also identified and quantified. In addition to these identified bioactive phenolic acids, flavonoids, and organic acids, there are numerous bioactive compounds that have been reported in the scientific literature (Table S1, refs. [19,20,[61][62][63][64][65][66][67][68][69][70][71][72]). Some of these active compounds are ligands of transcription factors for the activation of xenobiotic detoxification genes. For example, flavonoids such as isoflavone, genistein, and daidzein are agonists of the pregnane X receptor (PXR) [73]. Phenolic acids such as gallic acid [74], protocatechuic acid [75], chlorogenic acid [76], and caffeic acid [76] are PXR ligands that induce CYP3A4 expression (CYP3A37 in chicken). PXR, a generalized xenobiotic sensor rather than a receptor for endogenous ligands [77], is a master transcription factor of the xenobiotic-and drug-inducible expression of key genes that encode metabolic enzymes and drug transporters [78]. Based on the total phenols, total flavonoids, and the abundance of key phenolic acids and flavonoids in the herb extracts, we designed a cocktail of PAs and FVs representing the active portion of phenols and flavonoids present in CHC's herb portion to investigate the intrinsic mechanisms in cell culture and in a mouse gavage study.
The herb extracts also contained multiple unsaturated fatty acids. Some unsaturated fatty acids can be ligands in vitro for the activation of the retinoid X receptor (RXR). The RXR can bridge different signaling pathways by binding with other nuclear receptors as heterodimers [79] such as FXR and PXR. Unlike steroid receptors that translocate from the cytoplasm to the nucleus once activated by ligands, FXR and PXR are already located in the DNA where they create heterodimers with the RXR. When FXR and PXR's ligands binding, their structural conformation can change, thus they can interact with co-activator proteins [80]. This may be the reason why gene expression was not significantly changed by the ligands of FXR and PXR in the current study. We measured very low concentrations of fatty acids (4.5 µg per mg of CHC, Table S2, refs. [81][82][83]) in CHC. With such low concentrations of fatty acids, we could not perform the treatment of primary cells. Thus, it is likely that the poly unsaturated fatty acids in CHC did not activate the RXR. However, PAs showed a slight enhancement of the RXR gene expression, which indicates a possible regulation of caffeic acid and vanillin in RXR activity.
Secondly, activated charcoal contained in CHC elevated serum cholesterol, which was the precursor of bile acid under the catalysis of CYP7A1. In previous studies, activated charcoal increased cholesterol synthesis in humans [84], increased serum cholesterol in chickens [10] and in piglets [18], but the mechanisms responsible for the elevation of blood cholesterol are not known. Flavonoids such as quercetin, quercetin-glucoside, and kaempferol can elevate hepatic CYP7A1 expression in mice [85][86][87]. Some phenolic acids increased CYP7A1 gene expression and increased the concentration of bile acids in feces [88,89]. In the present study, we found the increased expression of CYP7A1 in primary hepatocytes treated with PAs, FVs, or cocktails of PAs and FVs.
We also found that activated charcoal or activated charcoal contained in CHC had elevated bile acids in the gallbladder and caused a higher excretion of bile acids in feces. CHC elicited a much greater effect than activated charcoal. This indicates a pathway that starts from bile acid synthesis to the clearance of bile acids via feces. This pathway, is elevated by both activated charcoal and the herb extracts. In this process, activated charcoal is responsible for the elevation of cholesterol, while PAs and FVs are responsible for bile acid synthesis and the activation of the transcription factors that could trigger the expression of xenobiotic detoxification genes. Increased bile acids, mainly consisting of lithocholic acid (LCA), chenodeoxycholic acid (CDCA), and cholic acid (CA) in chickens, are active ligands of the farnesoid X receptor (FXR). FXR is one of the most extensively studied nuclear receptors of bile acids. Upon activation by ligands, FXR interacts with its heterodimer partner, retinoid X receptor (RXR), and binds to a specific FXR response element on the promoter to activate gene expression. A proposed working model that integrates the cooperative interactions of activated charcoal and the herb extracts of CHC is illustrated in Figure 6. In the current study, we used four types of Chinese herbs: Pulsatilla chinensis, Portulaca oleracea L., Artemisia argyi Folium, and Pteris multifida Poir. According to the literature and based on their functional components, herb extracts contain phenolic acids and flavonoids that can activate PXR at certain concentrations.
Thirdly, we proved that CHC had much higher efficiency in the detoxification of mycotoxin in the mouse gavage study. Mice gavaged with toxic doses of the T-2 mycotoxin were saved by CHC, but activated charcoal or PAs and FVs, separately, were ineffective.
Fourthly, the genes expressed in broiler primary hepatocytes treated with PAs, FVs, or the cocktail (PAs and FVs) were quantified. The genes differentially expressed were related to bile acid synthesis, transportation and metabolism, and the nuclear receptors (transcription factors) that could be activated by PAs or FVs. The pathway of bile acid synthesis, export, and hydrolysis to activate the expression of PXR, FXR, and RXR was revealed. The cocktail of PAs and FVs was especially efficient in enhancing the expression of CYP7A1 and PXR as compared to PAs or FVs alone. This finding indicates t PAs, FVs, or intracellular bile acids are ligands to activate their receptors and transcription factors.
PXR has a broad spectrum of ligands [90,91]. PXR's unique features allow it to be activated and mobilized by multiple ligands at much lower concentrations than those required for individual ligands to produce a similar response [92]. In this study, intracellular bile acids that were produced by liver CYP7A1 may join PAs and FVs as the ligands of PXR. Multiple ligands could significantly reduce the required concentration of ligands to activate PXR. This was likely the reason why PXR was induced by a cocktail of PAs and FVs rather than individual PAs and FVs.
Bile acids can activate FXR at physiological concentrations, which bind to RXRs forming heterodimers to activate their target gene PXR. Therefore, PXR could be activated in two pathways. One is via the heterodimer FXR/RXR on the transcriptional level, and the other is via PXR's ligand binding with flavonoids. FXR is expressed strongly in the liver and intestine, and it is the master transcriptional regulator of several entero-hepatic metabolic pathways implicated in bile acid, lipid, and glucose homeostasis [93]. Bile acids activate FXR, which blocks synthesis and promotes the breakdown of bile acids through PXR transcriptional activation, thus making PXR the target gene of FXR [94]. A key function of the liver is the elimination of xenobiotics and endogenous catabolites from systemic circulation. This elimination generally involves three phases: hydroxylation (phase I), conjugation (phase II), and transport (phase III). As a xenobiotic receptor, PXR regulates many genes involved in detoxification pathways in the liver such as cytochrome P450 (CYP3A), CYP2B, and CYP2C [95]; Phase II conjugation enzymes such as sulfotransferases (SULTs) and Ces 1 [96]; Phase III drug transporters such as OATP2 (in human), Slco1B3 (in chicken), and Bsep [97]. We found that CHC largely increased the expression of these genes of xenobiotic detoxification as compared to a much more moderate effect from activated charcoal and herb extracts. This observation partially proves the cooperative interactions between activated charcoal and bioactive components contained in herb extracts on detoxification pathways. In other words, increased cholesterol levels trigger the initiation of detoxification by increased bile acid levels. Moreover, this effect is amplified by ligand-activated RXR and PXR. In this way, the toxins in feed are efficiently detoxified by hydroxylation, conjugation, and secretion/excretion. heterodimer partner, retinoid X receptor (RXR), and binds to a specific FXR response element on the promoter to activate gene expression. A proposed working model that integrates the cooperative interactions of activated charcoal and the herb extracts of CHC is illustrated in Figure 6. In the current study, we used four types of Chinese herbs: Pulsatilla chinensis, Portulaca oleracea L., Artemisia argyi Folium, and Pteris multifida Poir. According to the literature and based on their functional components, herb extracts contain phenolic acids and flavonoids that can activate PXR at certain concentrations. Figure 6. A working model of CHC promotes bile acid metabolism and xenobiotic detoxification in livers of broilers fed with mycotoxin-containing diets. CHC contains two portions: activated charcoal and herb extracts. The portion of activated charcoal can increase cholesterol level, which is the precursor of bile acid synthesis. Phenolic acids and flavonoids increase the synthesis of bile acids such as CDCD, LCA, and CA by enhancing CYP7A1 expression. These bile acids are the ligands that Figure 6. A working model of CHC promotes bile acid metabolism and xenobiotic detoxification in livers of broilers fed with mycotoxin-containing diets. CHC contains two portions: activated charcoal and herb extracts. The portion of activated charcoal can increase cholesterol level, which is the precursor of bile acid synthesis. Phenolic acids and flavonoids increase the synthesis of bile acids such as CDCD, LCA, and CA by enhancing CYP7A1 expression. These bile acids are the ligands that activate the farnesoid X receptor (FXR) transcription factor. The portion of herb extracts contains multiple types of flavonoids and phenols, including daidzein, quercetin, and genistein, which are the ligands that activate the pregnane X receptor (PXR), a crucial transcription factor in drug metabolism. Herb extracts also contain numerous types of phenolic acids such as caffeic acid and vanillin, which are potentially active ligands of the retinoid X receptor (RXR). FXR and RXR can form a heterogenous dimer to promote the expression of PXR. Subsequently, PXR activates the expression of genes for xenobiotic detoxification. Therefore, there are two pathways for the activation of PXR: 1 Activation of the FXR-RXR heterodimer by bile acids and phenolic acids that act on the PXR gene promoter, and 2 Activation of PXR by ligand (flavonoids, phenolic acids, or bile acids) binding. Separately, activated charcoal or herb extract, at a dose similar to that of CHC, is not sufficient to activate PXR to trigger the expression of the genes for xenobiotic detoxification. CHC integrates the cooperative interactions between the activated charcoal and the herb extract (CHC) in this detoxification process. Besides the components that could activate nuclear receptors upstream of the P450 series enzymes, herb extracts contain other components such as glycosides, polysaccharides, terpenes, and triterpene saponins that have anti-inflammatory activities [20,65,70,72].
In the present study, stimulated macrophages (RAW 264.7 cells) in vitro confirmed the anti-inflammatory activity of the herb extracts of CHC. In vivo, at a low dose of supplementation, the herb extracts showed no significant effect on the stimulation of the anti-inflammatory factors IL-1β and IFN-γ in serum and ileum. However, when the herb extracts were used in combination with activated charcoal, the herb extracts demonstrated very significant anti-inflammatory effects. This effect was an integrated effect because charcoal itself has mild anti-inflammatory effects [15]. Charcoal sorption might protect herb extracts from degradation and conjugation in the intestines [98]. However, this significant anti-inflammatory effect was most likely due to the activation of PXR, either by the activated heterodimer FXR/RXR or the flavonoid ligand, which involves anti-inflammatory processes [99,100].
Mycotoxins and their metabolites can be enzymatically degraded [101]. During this process, free radicals are generated, and oxidative stress arises. When invading pathogens encounter phagocytes, phagocytosis occurs, which induces ROS production in cells [102]. Oxidative stress damages macromolecules such as proteins, DNA, and polyunsaturated fatty acids in membrane lipids. In broilers, oxidative stress can decrease the absorption of nutrients, deteriorate immune capacity, and compromise meat quality. In the current study, CHC alleviated oxidative stress in broilers. One possible mechanism of CHC function might be the absorption of feed-borne toxins. The in vitro assay proved that CHC had a high absorption rate for AFB1, ZEN, and OTA, ranging from 95.78% to 100% at pH values of 2.0 and 6.0 in artificial stomach solutions. Once absorbed, the complex of CHC and mycotoxins was not easily dissociated. In broiler feed, we detected trace contents of DON, ZEN, AFB1, and OTA. In vivo, the antioxidative activity of CHC in broilers was significantly higher than activated charcoal at the same dose. This indicated that CHC's antioxidative effect was mainly due to the clearance of mycotoxins in accordance with the above pathway.
Oxidative stress is capable of damaging muscle structures and can diminish meat quality of broilers [103]. Markers of meat quality include meat color (lightness, redness, and yellowness), water-holding capacity (drip loss), and tenderness (shear force) [104]. In this study, we found that dietary CHC supplementation increased the antioxidant activity of meat by increasing radical scavenging activities, which in turn decreased lightness in the breast muscle and increased meat redness in the thigh muscle. This result was consistent with broilers fed wood charcoal and vinegar [105]. Poultry meat contains high concentrations of polyunsaturated fatty acids [106], which makes it sensitive to free radical attack and oxidative deterioration [107]. The color of meat is related to the concentration of myoglobin, the chemical state of myoglobin, and light scattering. Myoglobin changes color based on different compounds bound at the iron atom in its protoporphyrin ring structure [108]. When oxygen is bound to the reduced form of molecules, the oxymyoglobin shows its pigment. When no ligand is attached, metmyoglobin forms, which has a purple color. The three chemical states of myoglobin, where iron is oxidized to Fe 3+ [109], are combined to develop meat color that is acceptable to consumers. Light scatter from denatured proteins or reduced myofilament lattice spacing can also change the lightness of meat [110]. Any factors that help to maintain the integrity of myocytes and myofibrils impact light scattering on the meat surface. CHC's influence on meat lightness confirms its antioxidant activity. CHC tended to decrease the shear force of the breast and thigh meat in this study.
Taken together, CHC had beneficial effects on broiler growth and meat quality. It alleviated oxidative stress that may have been introduced through feed mycotoxins. The activated charcoal portion increased the cholesterol level, and phenolic acids and flavonoids present in the herb extract portion of CHC enhanced bile acid synthesis by increasing CYP7A1 expression. The cooperative binding of phenolic acids, flavonoids, and bile acids in hepatocytes activated the PXR and FXR transcription factors and triggered the expression of xenobiotic detoxification genes through RXR. This efficiency of detoxification was proved by CHC's high rescued rate for mice gavaged with T-2 mycotoxin. CHC synergized the effects of activated charcoal and herb extracts via the FXR/RXR-PXR pathway to detoxify xenobiotic from the body.

Conclusions
In conclusion, CHC demonstrated in vitro absorptive activity on mycotoxin, but also antioxidant properties. The in vivo study revealed that CHC integrates the synergy of activated charcoal and herb extracts (CHC) in the detoxification of mycotoxin contained in feed via the promotion of bile acid production and their excretion via feces. At doses similar to those of CHC, activated charcoal or herb extracts fed separately could not act as efficiently as CHC. Activated charcoal, with similar doses of flavonoids (represented by daidzein and quercetin-D-glucoside) and phenolic acids (represented by caffeic acid and vanillin) to those of CHC, functioned no differently from CHC in the detoxification of T-2 mycotoxin in the mouse survival test. Phenolic acids and flavonoids activated the genes for xenobiotic detoxification via the FXR/RXR-PXR pathway in primary broiler hepatocytes. CHC integrated the functions of flavonoids and phenolic acids contained in the herb extracts and activated charcoal to detoxify mycotoxins from the broiler body.
Supplementary Materials: The following supporting information can be downloaded at: https://www. mdpi.com/article/10.3390/antiox11112200/s1, Table S1: Bioactive components of four Chinese herbs reported in the literature; Table S2: Composition of fatty acids in herb extracts of CHC (CHC-Herb).