5.1. Chestnut tannins

Hydrolyzable tannins from chestnut (Castanea sativa Mill.) have recently been assessed as feed additive for monogastric food producing animals. Although in vitro studies showed strong activities against parasites and pathogens residing in animal digestive tract (Chung et al., 1998, Athanasiadou et al., 2000, Butter et al., 2001), the in vivo assessments have yielded inconsistent results for animal performance. At the concentrations from 0.11% to 0.45% in swine diets, it was found that chestnut HT improved feed efficiency, tended to increase viable counts of Lactobacilli in the jejunum and reduced caecal concentrations of ammonia, iso-butyric, and iso-valeric acid, but had no effect on bacterial caecal counts, faecal excretion of Salmonella or colonization of the intestines (Biagia et al., 2010, Parys et al., 2010). However, increasing concentration from 0.71% to 1.5% reduced feed efficiency although feed intake, growth and carcass weight were not affected (Bee et al., 2016). Štukelj et al. (2010) reported that chestnut HT at the level of 0.15% in combination with 0.15% of a mixture of acids had no effects on health status or growth performance of pigs whereas Brus et al. (2013) found that 0.19% of it in combination with 0.16% of a mixture of acids increased growth performance, increased lactic acid bacteria and reduced E. coli populations in the intestines.

Schiavone et al. (2008) evaluated the effects of adding 0.15%, 0.20% and 0.25% of chestnut tannin product (77.8% HT) on growth performances of broiler chicks. The results showed that inclusion of up to 0.20% of chest nut tannin increased daily feed intake and average daily gain. However, increasing its concentration to 0.25% seemed to lead to negative effects as all the measured parameters were the lowest. Jamroz et al. (2009) assessed the effects of dietary addition of 0.025%, 0.05% and 0.1% of sweet chestnut tannins on the performance, intestinal microbial populations and histological characteristics of intestine wall in chickens. Their results showed that tannin supplementation had no effects on feed conversion and carcass quality, but tannin at 0.1% reduced final body weight and slowed down the proliferation rate in the mother-cell zone. E. coli and coliform bacteria in the small intestines of 28-d-old chickens were also reduced at the tannin levels of 0.05% to 0.1%. In another study, Rezar and Salobir (2014) found that addition of 0.07% and 0.2% of the same tannin product (0.05% and 0.1% HT) did not affect broiler growth performance or the organic matter, crude protein, crude ash, calcium and phosphorus balance and utilization, but increased dry matter content of excreta. In a challenged study, Tosi et al. (2013) reported that chestnut HT at the dietary concentrations of 0.71% and 1.5% reduced Clostridium perfringens (Eimeria tenella, Eimeria acervulina, Eimeria maxima) in the gut of broiler chicken orally challenged with these coccidia.

Supplementations of chestnut HT at levels of 0.45% and 0.5% also have been shown to increase live weight gain and feed intake of rabbits (Maertens and Štruklec, 2006, Zoccarato et al., 2008). However, Liu et al. (2009) found that inclusion of chestnut HT at the concentrations of 0.5% and 1.0% had no effect on growth performance of rabbits. All above information suggest that depending on the type of animals and the type of diets, dietary addition of chestnut HT at the levels lower than 0.5% for swine and rabbit and lower than 0.2% for chicken may have positive effects on their growth performance and improve intestinal health. Higher chestnut HT concentration in the diets than the above mentioned will mostly lead to decreased animal growth performance by decreasing nutrient digestion and absorption (Iji et al., 2004, Ebadi et al., 2005, Mansoori, 2009, Mansoori et al., 2015).

5.2. Grape tannins

Extracts of grape (Vitis vinifera) seed and grape pomace contain significant amount of polyphenolic compounds including CT (Prieur et al., 1994, Choy et al., 2014), which have been assessed for their uses as natural feed additives to monogastric food producing animals. Choy et al. (2014) reported that adding 1% of grape seed extract to pig diets increased abundances of Lachnospiraceae, Clostridales, Lactobacillus and Ruminococcaceae in fecal microbiome. They found that oligomers (dimer–pentamer) of grape tannin were only partially metabolized by the gut microbiota, producing phenolic metabolites that are known to be more readily absorbed. These phenolic compounds may have contributed to the altered bacterial populations thereby exerted the beneficial effects on the colon. Wang et al. (2008) found that CT in grape seed extract at the dietary concentrations from 5 to 80 mg/kg significantly decreased fecal shedding of E. tenella, improved antioxidant status, reduced mortality and increased growth performance of E. tenella infected broiler chicken and the most favorable results were observed with diets containing 10 to 20 mg CT/kg DM. Farahat et al. (2017) showed that grape seed extract possessed significant antioxidant and immunostimulant effects when fed to broiler chickens at the dietary concentrations of 0.125% to 2% with 0.125% to 0.25% being the optimum dosages. Further increasing the concentration negatively affected birds’ growth performance, protein and amino acid digestion (Chamorro et al., 2013).

Grape pomace, which includes skins, pulp and contain significant amount of CT and other simple phenolic compounds, is the by-product of grape processing. Several studies evaluating the effects of grape pomace on swine and poultry performance indicated that addition of such tannin-rich product up to 10% of the diet had no effect on growth performance of broiler chicken, but enhanced anti-oxidant status and increased intestinal populations of beneficial bacteria (Brenes et al., 2008, Viveros et al., 2011, Chamorro et al., 2015). Yan and Kim (2011) showed that supplementation of a Saccharomyces boulardii fermented grape pomace to pig diets at the level of 0.3% improved growth performance, nutrients digestibility and altered the fatty acid pattern in the subcutaneous fat as well as some attributes of pork meat. The grape pomace was also found to improve antioxidant activity of pork and reduced the gastrointestinal absorption of mycotoxins in swine. These effects of grape pomace, however, may not be exclusively attributed to the CT because other phenolic compounds also are present in the product.

5.3. Tannic acid

Tannic acid is a HT from varying plants including tara pods (Caesalpinia spinosa), gallnuts from Rhus semialata, Quercus infectoria or Sicilian Sumac leaves (Rhus coriaria). Lee et al. (2010) reported that addition of tannic acid at the dietary levels of 0.0125% to 0.1% negatively impacted growth performance, hematological indices and plasma iron status of pigs, and linearly reduced faecal coliform bacteria count. However, the same authors found that feeding 0.0125% of tannic acid had no effect on growth performance, but negatively affected blood hematology and plasma Fe status when pigs were fed Fe deficient diets. It was also observed that total anaerobic bacteria, Clostridium spp. and coliforms were decreased but Bifidobacterium spp. and Lactobacillus spp. were increased by 0.0125% tannin acid (Lee et al., 2009a, Lee et al., 2009b). Tannic acid at the concentration of 0.5% increased growth performance and fat content in breast and thigh meat, but reduced blood glucose concentration and cholesterol content in the liver of broiler chicken (Starčević et al., 2015). It is also reported that tannic acid at the dietary concentrations of 0.75% and 1.5% did not alter Salmonella cecal culture-positive chicks or the numbers of Salmonella typhimurium in the cecal contents of broiler chickens (Kubena et al., 2001). Increasing concentrations to 2.5% and 3.0% reduced weight gain and protein efficiency and impaired the immune function of growing chickens by decreasing weight of bursa of fabricius, thymus and spleen, reducing total immunoglobulin (Ig) M and IgG immunoglobulin levels and total white blood cells and absolute lymphocytes in a dose-dependent manner (Marzo et al., 1990). Ebrahim et al. (2015) found that 1% of tannic acid decreased body weight gain and feed intake but improved the fatty acid profile of breast muscle of broilers under heat stress by decreasing monounsaturated fatty acids. From above results, it seems that application rates of tannic acid in both swine and poultry are higher than those of other sources of tannins, but rarely result in positive effect on animal performance although increased antioxidant status were reported in several studies. High concentrations (e.g., ≥1%) appear to be toxic to animals in terms of decreasing production efficiency.

5.4. Other sources of tannins

There are a few studies that assessed several other sources of tannins for monogastric animals. Iji et al. (2004) reported that addition of mimosa (Mimosa pudica) tannin extract (CT) to broiler diets at the levels of 0.5%, 1.5%, 2.0%, 2.5% reduced feed intake and body weight gain but improved feed efficiency at the levels less than 1.5%. Birds fed tannin supplemented diets also reduced ileal digestibilities of energy, protein and amino acids. However, no negative effect was observed on pancreatic and jejunal enzymes activities. Cappai et al. (2014) found that supplementing acorn (Quercus pubescens Willd.) HT at the dietary level of 0.516 tannic acid equivalent/kg diets did not affect feed intake or gastric mucosa but improved feed efficiency. Red quebracho (Schinopsis lorentzii) CT was assessed for its effects on decreasing coccidiosis in E. tenella challenged broilers (Cejas et al., 2011). The study revealed that addition of 10% quebracho CT extract increased body weight gain of challenged birds, increased crypt:villi ratio of the intestine and decreased oocyst excretion. This study suggest that quebracho CT could be a potential prophylactic anti-coccidials agent. Zotte and Cossu, 2009 also found that 1% and 3% of red quebracho tannins improved significantly weight gain and feed conversion of rabbits in a 6-week feeding trial.