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Review: Modulating ruminal lipid metabolism to improve the fatty acid composition of meat and milk. Challenges and opportunities

Published online by Cambridge University Press:  24 August 2018

P. G. Toral*
Affiliation:
Instituto de Ganadería de Montaña, CSIC-Universidad de León, Finca Marzanas s/n, 24346 Grulleros, León, Spain
F. J. Monahan
Affiliation:
UCD School of Agriculture and Food Science, University College Dublin, Belfield, Dublin 4, Ireland
G. Hervás
Affiliation:
Instituto de Ganadería de Montaña, CSIC-Universidad de León, Finca Marzanas s/n, 24346 Grulleros, León, Spain
P. Frutos
Affiliation:
Instituto de Ganadería de Montaña, CSIC-Universidad de León, Finca Marzanas s/n, 24346 Grulleros, León, Spain
A. P. Moloney
Affiliation:
Animal and Grassland Research and Innovation Centre, Teagasc, Grange, Dunsany Co., Meath, C15 PW93, Ireland
*

Abstract

Growth in demand for foods with potentially beneficial effects on consumer health has motivated increased interest in developing strategies for improving the nutritional quality of ruminant-derived products. Manipulation of the rumen environment offers the opportunity to modify the lipid composition of milk and meat by changing the availability of fatty acids (FA) for mammary and intramuscular lipid uptake. Dietary supplementation with marine lipids, plant secondary compounds and direct-fed microbials has shown promising results. In this review, we have compiled information about their effects on the concentration of putative desirable FA (e.g. c9t11-CLA and vaccenic, oleic, linoleic and linolenic acids) in ruminal digesta, milk and intramuscular fat. Marine lipids rich in very long-chain n-3 polyunsaturated fatty acids (PUFA) efficiently inhibit the last step of C18 FA biohydrogenation (BH) in the bovine, ovine and caprine, increasing the outflow of t11-18:1 from the rumen and improving the concentration of c9t11-CLA in the final products, but increments in t10-18:1 are also often found due to shifts toward alternative BH pathways. Direct-fed microbials appear to favourably modify rumen lipid metabolism but information is still very limited, whereas a wide variety of plant secondary compounds, including tannins, polyphenol oxidase, essential oils, oxygenated FA and saponins, has been examined with varying success. For example, the effectiveness of tannins and essential oils is as yet controversial, with some studies showing no effects and others a positive impact on inhibiting the first step of BH of PUFA or, less commonly, the final step. Further investigation is required to unravel the causes of inconsistent results, which may be due to the diversity in active components, ruminant species, dosage, basal diet composition and time on treatments. Likewise, research must continue to address ways to mitigate negative side-effects of some supplements on animal performance (particularly, milk fat depression) and product quality (e.g. altered oxidative stability and shelf-life).

Type
Review Article
Copyright
© The Animal Consortium 2018 

Implications

Much research effort in ruminant nutrition is focussed on meeting current consumer demand for healthier foods. This review summarises the literature on nutritional strategies to manipulate ruminal lipid metabolism with the goal of enhancing the concentration of potentially beneficial fatty acids (FA) in milk and meat (e.g. use of marine lipid supplements or plant secondary compounds). Additional studies are, however, required to unravel the causes of some inconsistent results in the literature. Associated side effects on animal performance and product quality represent challenges that need to be addressed before practical application of some promising treatments in animal production.

Introduction

Although improvements in living standards and availability of food are taken for granted in developed and newly industrialised countries, changes in lifestyle and eating habits have been accompanied by a higher incidence of chronic cardiovascular, metabolic and degenerative diseases (Salter, Reference Salter2013; Parodi, Reference Parodi2016). Consumers are now increasingly aware of the multiple links between diet and well-being, giving rise to a growing market for foods with demonstrated or perceived beneficial effects on health. The concentration of a number of health-promoting FAs in milk and meat can be effectively increased through livestock feeding strategies (Dewhurst and Moloney, Reference Dewhurst and Moloney2013; Shingfield et al., Reference Shingfield, Bonnet and Scollan2013). In recent years, multiple studies have shown that ruminal lipid metabolism is a key point in determining the content of many desirable FA in ruminant products, such as c9t11-CLA, t11-18:1 (vaccenic acid), c9-18:1 (oleic acid), 18:2n-6 (linoleic acid) and 18:3n-3 (α-linolenic acid) (Chilliard et al., Reference Chilliard, Glasser, Ferlay, Bernard, Rouel and Doreau2007; Scollan et al., Reference Scollan, Dannenberger, Nuernberg, Richardson, MacKintosh, Hocquette and Moloney2014). This review summarises the available literature on the manipulation of the rumen environment to modulate milk and meat FA profile. Reference is also made to recent research on the associated positive and negative effects on animal performance and product quality. No information is provided on the use of ionophores (for which evidence of modulatory effects on biohydrogenation (BH) exists; Chilliard et al., Reference Chilliard, Glasser, Ferlay, Bernard, Rouel and Doreau2007) because their use for non-medicinal purposes is banned in some places (e.g. European Union).

Metabolic origin of lipids in ruminants:the importance of ruminal metabolism

Ruminant-derived products are characterised by the presence of a broad variety of FA that are not found in the diet of livestock but derive largely from ruminal metabolism of its fat. Under conventional feeding conditions, the major lipid sources for ruminants are forages, cereal grains and oilseeds, which contain high proportions of unsaturated FA (mainly 18:2n-6 and 18:3n-3; Jenkins et al., Reference Jenkins, Wallace, Moate and Mosley2008; Buccioni et al., Reference Buccioni, Decandia, Minieri, Molle and Cabiddu2012). On entering the rumen, dietary lipids are extensively metabolised (Jenkins et al., Reference Jenkins, Wallace, Moate and Mosley2008), starting with the release of free FA by the action of lipases. Recent data highlight the role of endogenous plant factors in this process, which may enable its manipulation (Lee et al., Reference Lee, Evans, Nute, Richardson and Scollan2009; Buccioni et al., Reference Buccioni, Decandia, Minieri, Molle and Cabiddu2012). Lipolysis is followed by BH, a process consisting of sequential FA isomerisation and saturation performed by some bacteria to reduce the toxicity of unsaturated lipids for microbial growth (Jenkins et al., Reference Jenkins, Wallace, Moate and Mosley2008). Molecular biology techniques have revealed that earlier explanations of rumen microbial BH based mainly on in vitro cultures of Butyrivibrio strains were rather weak. Instead, it is now accepted that a number of uncultured bacterial species play a key role in the in vivo process (e.g. Huws et al., Reference Huws, Kim, Lee, Scott, Tweed, Pinloche, Wallace and Scollan2011; Toral et al., Reference Toral, Bernard, Belenguer, Rouel, Hervás, Chilliard and Frutos2016). The contribution of fungi to BH in the rumen seems to be marginal and that of protozoa would derive from associated bacteria (Jenkins et al., Reference Jenkins, Wallace, Moate and Mosley2008).

Since BH of dietary FA is usually incomplete, numerous intermediate metabolites reach the duodenum and, after absorption, are available for incorporation into tissues and milk fat (Shingfield et al., Reference Shingfield, Bonnet and Scollan2013). Therefore, the manipulation of microbial lipid metabolism to enhance the outflow of beneficial FA from the rumen represents a major challenge, and also an opportunity, for ruminant nutritionists (Chilliard et al., Reference Chilliard, Glasser, Ferlay, Bernard, Rouel and Doreau2007; Scollan et al., Reference Scollan, Dannenberger, Nuernberg, Richardson, MacKintosh, Hocquette and Moloney2014).

Rumen microbial fermentation has a further impact on the lipid composition of milk and meat by providing precursors (volatile FA) for de novo FA synthesis in the mammary gland and intramuscular lipid (Bernard et al., Reference Bernard, Leroux and Chilliard2008; Shingfield et al., Reference Shingfield, Bonnet and Scollan2013). This metabolic pathway usually yields saturated fatty acid (SFA) of up to 16-carbon atoms, which can subsequently serve as substrates for desaturases and, in some tissues, elongases (Bernard et al., Reference Bernard, Leroux and Chilliard2008; Shingfield et al., Reference Shingfield, Bonnet and Scollan2013).

Improving the fatty acid composition of meat and milk through modulators of ruminal lipid metabolism

Replacing SFA with monounsaturated FA and polyunsaturated fatty acid (PUFA), respectively, in ruminant derived-products has been a major aim for animal nutritionists, although this may result simplistic due to specific biological effects of individual FA within each group (Shingfield et al., Reference Shingfield, Bonnet and Scollan2013; Parodi, Reference Parodi2016). A wide variety of feeding strategies has been tested with varying success, due in part to the complexity of rumen microbial responses (Jenkins et al., Reference Jenkins, Wallace, Moate and Mosley2008; Huws et al., Reference Huws, Kim, Lee, Scott, Tweed, Pinloche, Wallace and Scollan2011; Toral et al., Reference Toral, Bernard, Belenguer, Rouel, Hervás, Chilliard and Frutos2016). Much attention has been paid to the effects of supplementation with vegetable lipids (Shingfield et al., Reference Shingfield, Bonnet and Scollan2013; Scollan et al., Reference Scollan, Dannenberger, Nuernberg, Richardson, MacKintosh, Hocquette and Moloney2014).

On the contrary, less complete information is available on the modification of the FA profile of meat and milk FA by using specific modulators of the ruminal environment, such as marine lipids rich in very long-chain n-3 PUFA, plant secondary compounds (e.g. tannin extracts or essential oils (EO)) and direct-fed microbials (Vasta and Luciano, Reference Vasta and Luciano2011; Shingfield et al., Reference Shingfield, Bonnet and Scollan2013; Apás et al., Reference Apás, Arena, Colombo and González2015). In the present review, we have compiled information on the effects of these materials on the concentration of the putative desirable c9t11-CLA, t11-18:1, c9-18:1, 18:2n-6 and 18:3n-3 in digesta, milk and meat in bovine, ovine and caprine (Tables 1 and 2 and Supplementary Tables S1 to S7). Variations in ruminal disappearance of dietary unsaturated FA complement this information and provide a good proxy for the extent of the first BH step by avoiding confounding effects due to differences in dietary FA supply. The accumulation of 18:0 is reported as an indication of the overall extent of BH or inhibition of its terminal step, while increases in the proportion of t10-18:1 may reflect a shift towards alternative pathways.

Table 1 Main changes in digesta, milk and meat concentrations of selected fatty acids (compared with the control diet) in response to diet supplementation with marine lipids rich in n-3 polyunsaturated fatty acids (PUFA)

Data derived from individual studies reported in Supplementary Tables S1 to S3, corresponding to 123 dietary treatments in bovine, 55 in ovine and 22 in caprine.

1 For each marine lipid, predominant responses (i.e. those observed in more than 25% of cases) in digesta, milk or meat are codified as positive (+), negative (−) or not significantly different (=) compared with the control; ‘na’ denotes non-available data. This 25% cut-off value was arbitrarily established to counteract the high between-study variability and facilitate the identification of major trends. For positive and negative responses, the mean percentage of variation is reported as: + (<15% increase), ++ (15% to 50% increase), +++ (50% to 100% increase), ++++ (>100% increase), − (<15% decrease), − − (15% to 50% decrease), − − − (>50% decrease). For example, ‘++/=’ would indicate that in more than 25% of cases the response to the marine lipid was a significant increase of 15% to 50% in the fatty acid, while in other >25% there was no statistical difference. Other responses were either not observed or observed in <25% of cases. Parentheses are used for variables with a single datum.

Table 2 Main changes in digesta, milk and meat concentrations of selected fatty acids (FA) and rumen disappearance of c9-18:1, 18:2n-6 and 18:3n-3 (compared with the control diet) in response to diet supplementation with plant secondary compoundsFootnote 1

EO=essential oil.

Data derived from individual studies reported in Supplementary Tables S4 to S6, corresponding to 176 dietary treatments in bovine, 119 in ovine and 62 in caprine.

1 Detailed information about their source of origin and dose, if available, and results from other unclassified products and mixes of different types of plant secondary compounds are individually reported in Supplementary Tables S4 to S6.

2 For each plant secondary compound, predominant responses (i.e. those observed in more than 25% of cases) in digesta, milk or meat are codified as positive (+), negative (−) or not significantly different (=) compared with the control; ‘na’ denotes non-available data. This 25% cut-off value was arbitrarily established to counteract the high between-study variability and facilitate the identification of major trends. For positive and negative responses, the mean percentage of variation is reported as: + (<15% increase), ++ (15% to 50% increase), +++ (50% to 100% increase), ++++ (>100% increase), − (<15% decrease), − − (15% to 50% decrease), − − − (>50% decrease). For example, ‘++/=’ would indicate that in more than 25% of cases the response to the compound was a significant increase of 15% to 50% in the FA, while in other >25% there was no statistical difference. Other responses were either not observed or observed in <25% of cases. Parenthesis are used for variables with a single datum.

3 Subcategories include treatments with compounds identified as the main active components in garlic oil (diallyl sulphide and propyl propane thiosulfinate), cinnamon oil (cinnamaldehyde) and clove and eucalyptus oil (eugenol). Responses to EO in meat have been summarised in the ‘other EO’ category due to the few available data for growing ruminants.

Marine lipids rich in very long-chain n-3 polyunsaturated fatty acids

The efficacy of marine lipids for modulating BH of C18 FA and increasing VA and subsequently CLA in ruminant derived products has received considerable interest in recent years (Chilliard et al., Reference Chilliard, Glasser, Ferlay, Bernard, Rouel and Doreau2007; Noci et al., Reference Noci, Monahan, Scollan and Moloney2007). Two n-3 PUFA, specifically 20:5n-3 (EPA) and 22:6n-3 (DHA), appear to be the main FA responsible for the well-known inhibitory effect of these lipids on the conversion of t11-18:1 to 18:0 (Shingfield et al., Reference Shingfield, Kairenius, Arola, Paillard, Muetzel, Ahvenjarvi, Vanhatalo, Huhtanen, Toivonen, Griinari and Wallace2012; Toral et al., Reference Toral, Hervás, Carreño, Leskinen, Belenguer, Shingfield and Frutos2017). Consistent responses in the FA profile of digesta, milk and meat lipids have been reported for dietary use of EPA- and DHA-rich sources (Table 1 and Supplementary Tables S1 to S3), including fish oil (e.g. tuna, sardine, herring, mackerel and salmon oils), microalgae biomass and oil (from Schizochytrium sp. and Isochrysis sp.), and protected marine supplements and fish meal (e.g. Kitessa et al., Reference Kitessa, Gulati, Simos, Ashes, Scott, Fleck and Wynn2004; Shingfield et al., Reference Shingfield, Bonnet and Scollan2013; Scollan et al., Reference Scollan, Dannenberger, Nuernberg, Richardson, MacKintosh, Hocquette and Moloney2014).

As shown in Supplementary Table S1, ruminal responses to marine lipids followed similar trends in the bovine, ovine and caprine (Huws et al., Reference Huws, Kim, Lee, Scott, Tweed, Pinloche, Wallace and Scollan2011; Shingfield et al., Reference Shingfield, Kairenius, Arola, Paillard, Muetzel, Ahvenjarvi, Vanhatalo, Huhtanen, Toivonen, Griinari and Wallace2012; Toral et al., Reference Toral, Bernard, Belenguer, Rouel, Hervás, Chilliard and Frutos2016), and were broadly reflected in their milk FA composition (Boeckaert et al., Reference Boeckaert, Vlaeminck, Dijkstra, Issa-Zacharia, Van Nespen, Van Straalen and Fievez2008; Bernard et al., Reference Bernard, Leroux, Rouel, Delavaud, Shingfield and Chilliard2015; Frutos et al., Reference Frutos, Toral and Hervás2017). Direct interspecies comparisons support these findings (Toral et al., Reference Toral, Chilliard, Rouel, Leskinen, Shingfield and Bernard2015, Reference Toral, Bernard, Belenguer, Rouel, Hervás, Chilliard and Frutos2016 and Reference Toral, Hervás, Carreño, Leskinen, Belenguer, Shingfield and Frutos2017). Besides hampering ruminal t11-18:1 saturation, marine lipids may also partly inhibit cis-18:1 and trans 18:2 hydrogenation, as suggested by increases in the accumulation of c9-18:1 and c9t11-CLA in digesta (Table 1 and Supplementary Table S1; Huws et al., Reference Huws, Kim, Lee, Scott, Tweed, Pinloche, Wallace and Scollan2011; Toral et al., Reference Toral, Hervás, Carreño, Leskinen, Belenguer, Shingfield and Frutos2017). Decreases in ruminal 18:2n-6 and 18:3n-3 would indicate more extensive metabolism of C18 PUFA with marine lipid supplements, presumably by bacterial groups with low or no sensitivity to their toxic effect. The commonly observed higher content of t10-18:1, derived from alternative BH pathways, may be promoted more by DHA than EPA (Toral et al., Reference Toral, Hervás, Carreño, Leskinen, Belenguer, Shingfield and Frutos2017), which seems consistent with the frequently observed greater concentration of t10-18:1 in digesta and milk due to supplementation with DHA-rich algae compared with EPA-rich fish oils (Boeckaert et al., Reference Boeckaert, Vlaeminck, Dijkstra, Issa-Zacharia, Van Nespen, Van Straalen and Fievez2008; Shingfield et al., Reference Shingfield, Kairenius, Arola, Paillard, Muetzel, Ahvenjarvi, Vanhatalo, Huhtanen, Toivonen, Griinari and Wallace2012; Vahmani et al., Reference Vahmani, Fredeen and Glover2013; Supplementary Table S1).

Inhibition of the terminal BH step induces a shortage of ruminal 18:0, the major substrate for mammary stearoyl-CoA desaturase (SCD), which explains the lower milk concentration of c9-18:1, in cows, sheep and goats fed marine lipids (Table 1; Chilliard et al., Reference Chilliard, Glasser, Ferlay, Bernard, Rouel and Doreau2007; Frutos et al., Reference Frutos, Toral and Hervás2017). Down-regulation of the SCD gene by FA in marine lipids or BH intermediates might also contribute to this response (Ahnadi et al., Reference Ahnadi, Beswick, Delbecchi, Kennelly and Lacasse2002; Carreño et al., Reference Carreño, Hervás, Toral, Castro-Carrera and Frutos2016), although data on in vivo SCD activity are inconclusive (Faulconnier et al., Reference Faulconnier, Bernard, Boby, Domagalski, Chilliard and Leroux2018). Conversely, because most c9t11-CLA in the bovine, ovine and caprine derives from endogenous synthesis via SCD, its concentration in milk and meat increases with the higher ruminal outflow of t11-18:1 (Bernard et al., Reference Bernard, Leroux and Chilliard2008; Scollan et al., Reference Scollan, Dannenberger, Nuernberg, Richardson, MacKintosh, Hocquette and Moloney2014).

There is also evidence that marine lipids decrease the milk concentration of some undesirable SFA (12:0, 14:0 and 16:0), but with lower effectiveness than plant lipids (Shingfield et al., Reference Shingfield, Bonnet and Scollan2013; Vahmani et al., Reference Vahmani, Fredeen and Glover2013; Bernard et al., Reference Bernard, Leroux, Rouel, Delavaud, Shingfield and Chilliard2015).

Compared with lactating ruminants, there are fewer studies with growing ruminants and often the intramuscular FA profile reported is not as comprehensive (Supplementary Table S6). While supplementation with fish oil can cause sizeable changes in the n-6:n-3 PUFA ratio (whose implications for human health are under some debate; Salter, Reference Salter2013), it generally does not increase the PUFA : SFA ratio in intramuscular lipid above the 0.1 to 0.15 normally observed. Noci et al. (Reference Noci, Monahan, Scollan and Moloney2007) reported that increasing the level of fish oil fed to cattle led to a linear increase in the concentration of t9- and t11-18:1, c9t11-CLA, EPA and DHA, and a decrease in the n-6 : n-3 ratio in intramuscular lipid. Parvar et al. (Reference Parvar, Ghoorchi and Shams Shargh2017) reported increases in EPA and DHA proportions in intramuscular lipid for lambs fed 3% fish oil but CLA or trans-18:1 isomers were not reported. With respect to algae, inclusion of DHA-rich Schizochytrium biomass in a lamb ration increased the concentration of EPA and DHA and decreased the n-6 : n-3 PUFA ratio in intramuscular lipid (Hopkins et al., Reference Hopkins, Clayton, Lamb, van de Ven, Refahauge, Kerr, Bailes, Lewandowski and Ponnampalam2014). Increasing the level of inclusion of a similar algal product in a beef ration led to a linear increase in the concentration of t11-18:1, c9t11-CLA (quadratic), EPA and DHA and a linear decrease in the n-6 : n-3 ratio in intramuscular lipid (Phelps et al., Reference Phelps, Drouillard, O’Quinn, Burnett, Blackmon, Axman, Van Bibber-Krueger and Gonzalez2016).

A common feature of the effect of marine lipids is the increment in milk t10-18:1, which seems less pronounced in goats than in cows and ewes (Shingfield et al., Reference Shingfield, Bonnet and Scollan2013; Toral et al., Reference Toral, Chilliard, Rouel, Leskinen, Shingfield and Bernard2015; Supplementary Table S2). There is no information available for meat. The implication of the higher t10-18:1 concentration for consumers is still unclear because of the uncertain involvement of ruminant trans FA in cardiovascular disease (Salter, Reference Salter2013). In addition, although the association between t10-18:1 and milk fat depression (MFD) is also equivocal, it has been considered as a biomarker of altered BH pathways associated with this syndrome (Shingfield et al., Reference Shingfield, Bonnet and Scollan2013). Furthermore, there is a dearth of knowledge about the impact on human health and animal performance of other rumen-derived FA that increase after marine lipid supplementation, such as oxo-FA and several 16-, 20- and 22-carbon intermediate metabolites (Kairenius et al., Reference Kairenius, Ärölä, Leskinen, Toivonen, Ahvenjärvi, Vanhatalo, Huhtanen, Hurme, Griinari and Shingfield2015; Toral et al., Reference Toral, Chilliard, Rouel, Leskinen, Shingfield and Bernard2015), which highlights the need for further investigation in this field.

Another aspect that warrants additional research is the interaction with basal diet composition, which influences the BH responses to marine lipids through changes in the rumen microbiota (Jenkins et al., Reference Jenkins, Wallace, Moate and Mosley2008; Buccioni et al., Reference Buccioni, Decandia, Minieri, Molle and Cabiddu2012). For example, in cows fed fish oil, the higher the proportion of concentrate the higher the milk content of t10-18:1 at the expense of t11-18:1, with more adverse effects on t11-18:1 in diets based on corn silage than on grass silage (Shingfield et al., Reference Shingfield, Reynolds, Lupoli, Toivonen, Yurawecz, Delmonte, Griinari, Grandison and Beever2005). The method of silage making is also relevant, as incremental levels of fish oil induced quadratic responses in the concentration of 18:0, c9-18:1 and 18:3n-3 in intramuscular lipid from steers fed unwilted grass silage, but a linear decrease was found in those offered wilted silage and no interaction was detected for t11-18:1 (Noci et al., Reference Noci, Monahan, Scollan and Moloney2007). In goats, fish oil probably induced a more pronounced inhibition of the last BH step in diets rich in starch from extruded wheat than from barley (the former being more rapidly degradable), increasing c9t11-CLA in milk, but without affecting the low t10-18:1 level (Bernard et al., Reference Bernard, Toral, Rouel and Chilliard2016).

Finally, it is worth mentioning the limited transfer of dietary EPA and DHA into final products and the variable success of protection technologies (Ahnadi et al., Reference Ahnadi, Beswick, Delbecchi, Kennelly and Lacasse2002; Kitessa et al., Reference Kitessa, Gulati, Simos, Ashes, Scott, Fleck and Wynn2004). Apparent transfer efficiency to milk seems lower in cows and goats (≈4% to 5%) than in ewes (≈9%; Chilliard et al., Reference Chilliard, Glasser, Ferlay, Bernard, Rouel and Doreau2007; Bichi et al., Reference Bichi, Hervás, Toral, Loor and Frutos2013). Whether this is due to differences in diet composition, lipid dosage or actual interspecies variation in ruminal or post-ruminal metabolism (e.g. duodenal absorption, blood transport or mammary FA uptake and secretion) is unclear given the lack of direct comparative studies between species. Dietary inclusion of fish oil in growing ruminants can lead to an increase in the concentration of EPA and DHA in intramuscular lipid (maximum achieved is ~15 mg EPA+DHA/100 g muscle), but muscle from cattle fed fish oil does not generally reach the concentrations defined by the European Food Safety Authority (2009) to permit labelling as a ‘source’ of n-3 PUFA (40 mg/100 mg muscle).

Plant secondary compounds

Research on the role of plant secondary compounds in ruminant nutrition was initially driven by their negative effects on diet utilisation, but some studies revealed favourable modulation of rumen BH (Lourenço et al., Reference Lourenço, Cardozo, Calsamiglia and Fievez2008; Vasta et al., Reference Vasta, Mele, Serra, Scerra, Luciano, Lanza and Priolo2009). A wide variety of compounds has been examined, including tannins, EO, saponins, polyphenol oxidase (PPO) and oxygenated FA (Benchaar and Chouinard, Reference Benchaar and Chouinard2009; Buccioni et al., Reference Buccioni, Decandia, Minieri, Molle and Cabiddu2012; Ramos-Morales et al., Reference Ramos-Morales, McKain, Gawad, Hugo and Wallace2016). However, results are often inconsistent (Table 2 and Supplementary Tables S4 to S6), due to the diversity in active components, dosage, experimental approaches (in vivo v. in vitro) and ruminant species.

Replacing grass by forage legumes, in particular red clover, usually decreases the overall extent of BH, which has been attributed to the inhibition of lipolysis by the higher PPO activity in legumes (Vanhatalo et al., Reference Vanhatalo, Kuoppala, Toivonen and Shingfield2007; Buccioni et al., Reference Buccioni, Decandia, Minieri, Molle and Cabiddu2012). Ruminal responses to most other compounds (e.g. oxygenated FA, terpenes and tannins) may be largely mediated by their impact on the microbiota (Carreño et al., Reference Carreño, Hervás, Toral, Belenguer and Frutos2015; Ramos-Morales et al., Reference Ramos-Morales, McKain, Gawad, Hugo and Wallace2016). Both types of effect could be additive or synergistic, as shown with the combined use of PPO- and tannin-rich forages (Campidonico et al., Reference Campidonico, Toral, Priolo, Luciano, Valenti, Hervás, Frutos, Copani, Ginane and Niderkorn2016).

Tannins have been the focus of several studies, mainly in small ruminants, but their ability to modulate BH is still controversial (Khiaosa-ard et al., Reference Khiaosa-ard, Bryner, Scheeder, Wettstein, Leiber, Kreuzer and Soliva2009; Vasta and Luciano, Reference Vasta and Luciano2011; Carreño et al., Reference Carreño, Hervás, Toral, Belenguer and Frutos2015). Different publications, using either condensed or hydrolysable tannin extracts or tannin-rich forages, report a slowdown of initial PUFA metabolism in the rumen (Campidonico et al., Reference Campidonico, Toral, Priolo, Luciano, Valenti, Hervás, Frutos, Copani, Ginane and Niderkorn2016; Alves et al., Reference Alves, Francisco, Costa, Santos-Silva and Bessa2017), rather than the specific inhibition of t11-18:1 saturation that was initially suggested (Khiaosa-ard et al., Reference Khiaosa-ard, Bryner, Scheeder, Wettstein, Leiber, Kreuzer and Soliva2009; Vasta et al., Reference Vasta, Mele, Serra, Scerra, Luciano, Lanza and Priolo2009). A review on the use of EO supports a similar mechanism, with promising effects of cinnamon and garlic oils and their purified active components on decreasing the first step of BH of PUFA and, less commonly, the terminal step (Lourenço et al., Reference Lourenço, Cardozo, Calsamiglia and Fievez2008; Doreau et al., Reference Doreau, Arturo-Schaan and Laverroux2017). Deviation from major BH pathways has been reported in some cases (e.g. for garlic oil and the tanniferous bush Cistus ladanifer; Lourenço et al., Reference Lourenço, Cardozo, Calsamiglia and Fievez2008; Alves et al., Reference Alves, Francisco, Costa, Santos-Silva and Bessa2017; Doreau et al., Reference Doreau, Arturo-Schaan and Laverroux2017), but a lower t10-18:1 concentration in digesta is often found (Khiaosa-ard et al., Reference Khiaosa-ard, Bryner, Scheeder, Wettstein, Leiber, Kreuzer and Soliva2009; Carreño et al., Reference Carreño, Hervás, Toral, Belenguer and Frutos2015), which would be potentially advantageous. On the contrary, for other products such as plant saponins, quercetin or eugenol-rich EO, very little or no influence on the ruminal FA profile has been observed to date (Lourenço et al., Reference Lourenço, Cardozo, Calsamiglia and Fievez2008; Khiaosa-ard et al., Reference Khiaosa-ard, Bryner, Scheeder, Wettstein, Leiber, Kreuzer and Soliva2009).

The inconsistent effects of similar types of tannins or EO (Supplementary Table S4) may be partly due to different experimental approaches (in vivo v. in vitro) and, more importantly, to the variation in their structural features and reactivity (depending on extraction methods, plant varieties and parts, etc.; Mueller-Harvey, Reference Mueller-Harvey2006; Vasta and Luciano, Reference Vasta and Luciano2011; Kholif et al., Reference Kholif, Morsy, Abdo, Matloup and Abu El-Ella2012). Dosage could also be important: for example, Carreño et al. (Reference Carreño, Hervás, Toral, Belenguer and Frutos2015) reported that low and moderate levels of grape tannin extract (2% to 4% diet dry matter (DM)) favoured the accumulation of dietary PUFA (18:2n-6 and 18:3n-3) in digesta (in an in vitro system), whereas a higher dose (8%) enhanced t11-18:1 concentration. Using high levels of tannins, EO or other plant extracts is interesting from a research perspective (Khiaosa-ard et al., Reference Khiaosa-ard, Bryner, Scheeder, Wettstein, Leiber, Kreuzer and Soliva2009; Vasta et al., Reference Vasta, Mele, Serra, Scerra, Luciano, Lanza and Priolo2009), but would be impractical under farm conditions because of their cost and risk of toxicity. No study seems to have investigated variations among ruminant species in the modulatory effects on BH, but differences might be speculated due to their known different tolerances to some secondary metabolites, such as tannins (Mueller-Harvey, Reference Mueller-Harvey2006).

There is even less information on the influence of dietary secondary compounds on milk FA than on rumen BH (Supplementary Table S5) and interspecies comparisons are therefore more challenging because post-ruminal lipid metabolism may also vary among species. The positive impact of forages rich in PPO and oxygenated FA on rumen FA (e.g. increasing PUFA concentrations) has been confirmed in cow and ewe milk, respectively (Addis et al., Reference Addis, Cabiddu, Pinna, Decandia, Piredda, Pirisi and Molle2005; Vanhatalo et al., Reference Vanhatalo, Kuoppala, Toivonen and Shingfield2007), but promising in vitro effects of tannin extracts and EO are not always confirmed in lactating animals, probably due to the lower levels of inclusion used in vivo (Benchaar and Chouinard, Reference Benchaar and Chouinard2009; Toral et al., Reference Toral, Hervás, Belenguer, Bichi and Frutos2013). In any event, some EO (e.g. from garlic) and tannins (e.g. in sulla) appear to improve milk FA profile under practical conditions (Buccioni et al., Reference Buccioni, Decandia, Minieri, Molle and Cabiddu2012; Kholif et al., Reference Kholif, Morsy, Abdo, Matloup and Abu El-Ella2012). With regard to t10-18:1, although little or no changes are generally observed, caution should be taken because very few studies report intermediates from alternative BH pathways.

In meat animals, care should be taken to ensure that interpretation of the effect of rumen modifiers is not confounded by changes in intramuscular fat concentration since this can result in changes in the FA profile per se. Intramuscular lipid from cattle or lambs grazing a red clover-rich pasture had a higher 18:3n-3 concentration than that from similar animals grazing perennial ryegrass (but similar to that from the white clover-rich pasture) (Scollan et al., Reference Scollan, Dannenberger, Nuernberg, Richardson, MacKintosh, Hocquette and Moloney2014). Replacing grass silage with a mixture of grass and red clover silage increased the deposition of n-3 PUFA in intramuscular lipid of finishing cattle (Lee et al., Reference Lee, Evans, Nute, Richardson and Scollan2009). There is a general tendency for cattle grazing botanically diverse pastures that supply a range of plant secondary compounds, to have higher n-3 and total PUFA in intramuscular fat compared with cattle grazing predominantly ryegrass pastures (Moloney et al., Reference Moloney, Fievez, Martin, Nute and Richardson2008), despite both pastures having a similar FA profile.

More specifically, including quebracho tannins in lamb rations increased 18:3n-3 and total PUFA concentrations in muscle, supporting their ruminally active properties, but only improved t11-18:1 and c9t11-CLA levels when included in a concentrate diet (Vasta et al., Reference Vasta, Mele, Serra, Scerra, Luciano, Lanza and Priolo2009). Although additional information on the interaction between basal ration and plant secondary compounds is limited, dietary inclusion of a source of condensed tannins (C. ladanifer) had a minor effect in lambs when the basal diets had no oil but increased t11-18:1 and c9t11-CLA in muscle neutral lipids when it contained a blend of plant oils (Jeronimo et al., Reference Jeronimo, Alves, Dentinho, Martins, Prates, Vasta, Santos-Silva and Bessa2010). These results suggest that a cautious approach should be adopted before implementing a specific treatment in practical farming, and that it should be tested in advance in the particular conditions of each production system.

Dietary inclusion of EO improved the FA profile of intramuscular lipid from goats (increasing t11-18:1, c9t11-CLA and 18:2n-6 concentrations; Mandal et al., Reference Mandal, Roy and Patra2014) but not from bulls (Prado et al., Reference Prado, Cruz, Valero, Zawadzki, Eiras, Rivaroli, Prado and Visentainer2016). As well as the species variations, the different results for the two studies may reflect the different sources of EO (clove and castor/cashew oils, respectively) and basal diet composition (sunflower oil was included in the former study).

Direct-fed microbials

Data on the effects of direct-fed microbials, also known as probiotics, on ruminal BH and the FA profile of milk and meat are reported in Supplementary Table S7. Information is still very limited, but encouraging results (i.e. increased milk t11-18:1 and c9t11-CLA concentration) have been shown in goats fed strains of Butyrivibrio fibrisolvens (Shivani et al., Reference Shivani, Srivastava, Shandilya, Kale and Tyagi2016), Lactobacillus plantarum (Maragkoudakis et al., Reference Maragkoudakis, Mountzouris, Rosu, Zoumpopoulou, Papadimitriou, Dalaka, Hadjipetrou, Theofanous, Strozzi, Carlini, Zervas and Tsakalidou2010) and a mixture of Lactobacillus reuteri, Lactobacillus alimentarius, Enterococcus faecium and Bifidobacterium bifidum (Apás et al., Reference Apás, Arena, Colombo and González2015). Greater milk 18:2n-6 and 18:3n-3 proportions were also found in the two latter studies. Conversely, a multi-strain product containing Lactobacillus acidophilus, Lactobacillus casei, Bifidobacterium thermophilum and E. faecium slightly decreased t11-18:1, c9t11-CLA and 18:2n-6 in ovine milk (Payandeh et al., Reference Payandeh, Kafilzadeh, Juárez, de la Fuente, Ghadimi and Martínez Marín2017), and available data in lactating cows and beef (using mostly Propionibacterium spp. and Saccharomyces cerevisiae) do not seem very positive (Supplementary Table S7). Nevertheless, given that cows fed Propionibacterium spp. showed greater milk c9t11-CLA in a high-starch diet and no changes in a low-starch ration (Philippeau et al., Reference Philippeau, Lettat, Martin, Silberberg, Morgavi, Ferlay, Berger and Nozière2017), interactions with basal diet composition should be explored. Microbiology studies to identify and cultivate active biohydrogenating bacteria to be used as probiotics are also required.

Persistency of changes

Responses of rumen microbiota to BH modulators may vary over time, with some inconsistent effects being probably due to interspecies differences. For instance, in cows fed a ration based on corn silage, fish oil-induced decreases in milk 18:0 and c9-18:1 concentrations were transient, and the large enhancements in milk t11-18:1 and c9t11-CLA found during the first days on treatment subsequently declined (Shingfield et al., Reference Shingfield, Reynolds, Hervás, Griinari, Grandison and Beever2006). However, the effects of marine lipids in grazing cows (AbuGhazaleh, Reference AbuGhazaleh2008) were similar to those in ewes (Bichi et al., Reference Bichi, Hervás, Toral, Loor and Frutos2013), with quick and persistent enrichments in milk t11-18:1 and c9t11-CLA that suggest major changes in the rumen microbiota at the beginning of treatment and relative stability afterwards. Nevertheless, slower responses in milk t10-18:1 suggest that changes in microorganisms involved in alternative BH pathways may take longer (Shingfield et al., Reference Shingfield, Reynolds, Hervás, Griinari, Grandison and Beever2006; Boeckaert et al., Reference Boeckaert, Vlaeminck, Dijkstra, Issa-Zacharia, Van Nespen, Van Straalen and Fievez2008; Carreño et al., Reference Carreño, Hervás, Toral, Castro-Carrera and Frutos2016).

Variation with time also seems to occur with probiotics, where some changes in milk FA composition seem clearer after the 1st month on treatment (Maragkoudakis et al., Reference Maragkoudakis, Mountzouris, Rosu, Zoumpopoulou, Papadimitriou, Dalaka, Hadjipetrou, Theofanous, Strozzi, Carlini, Zervas and Tsakalidou2010; Apás et al., Reference Apás, Arena, Colombo and González2015), and some others may be reversed in the long term (3 months; Shivani et al., Reference Shivani, Srivastava, Shandilya, Kale and Tyagi2016). The impact of many plant secondary compounds on BH may also be compromised by time because of the adaptation of the microbiota. For example, in ewes, the positive effect of quebracho tannins on milk t11-18:1 and c9t11-CLA was only transient, and was subsequently displaced by a gradual increase in t10-18:1 (Toral et al., Reference Toral, Hervás, Belenguer, Bichi and Frutos2013).

There are no studies on the persistency of changes in the FA profile of intramuscular lipid due to dietary inclusion of marine oil or other ruminally active compounds. However, when bulls that had grazed a ryegrass pasture were housed and offered a concentrate ration for 168 days before slaughter, the proportion of 18:3n-3 in muscle was still higher than in bulls that had never been to pasture and were slaughtered at the same carcass weight (Mezgebo et al., Reference Mezgebo, Monahan, Mark McGee, O’Riordan, Richardson, Brunton and Moloney2017), demonstrating that a perturbation due to diet can persist. While the difference in FA is not relevant to human nutrition, it could be relevant to meat flavour (Mezgebo et al., Reference Mezgebo, Monahan, Mark McGee, O’Riordan, Richardson, Brunton and Moloney2017). Long-term supplementation might not be necessary to have a detectable effect on meat FA, which would be particularly advantageous if the supplement is expensive.

Associated positive and negative side effects in ruminant animals

Besides the impact on the FA profile of intramuscular lipid and milk, BH modulators can have a broad range of other effects (e.g. on fertility, as anti-parasitic treatments or to reduce the environmental footprint of livestock), depending on the type of product. Nevertheless, this section will only focus on potential side effects on animal performance and product quality.

Effects on animal performance

There is a widespread perception that marine lipids detrimentally affect ruminal fermentation and feed intake, with consequent reductions in milk production (e.g., Ahnadi et al., Reference Ahnadi, Beswick, Delbecchi, Kennelly and Lacasse2002; Boeckaert et al., Reference Boeckaert, Vlaeminck, Dijkstra, Issa-Zacharia, Van Nespen, Van Straalen and Fievez2008). However, small doses of marine lipids (⩽1.5% DM) can efficiently modify BH while maintaining rumen function and milk yield, but unfortunately MFD is a common feature of this feeding strategy (Bichi et al., Reference Bichi, Hervás, Toral, Loor and Frutos2013; Shingfield et al., Reference Shingfield, Bonnet and Scollan2013). This syndrome represents the main effect of marine lipids on animal performance and a major concern due to potential economic losses, especially in the small ruminant sector, as their milk is mostly processed into cheese.

Although ewes and goats appear to be less prone than cows to marine lipid-induced MFD, this condition has been described in the three species (Ahnadi et al., Reference Ahnadi, Beswick, Delbecchi, Kennelly and Lacasse2002; Shingfield et al., Reference Shingfield, Bonnet and Scollan2013; Toral et al., Reference Toral, Chilliard, Rouel, Leskinen, Shingfield and Bernard2015). Algae and both free and protected fish oils cause this syndrome (Kitessa et al., Reference Kitessa, Gulati, Simos, Ashes, Scott, Fleck and Wynn2004; Chilliard et al., Reference Chilliard, Glasser, Ferlay, Bernard, Rouel and Doreau2007; Boeckaert et al., Reference Boeckaert, Vlaeminck, Dijkstra, Issa-Zacharia, Van Nespen, Van Straalen and Fievez2008), which seems to be associated with the action of EPA and DHA on rumen microbiota, favouring alternative BH pathways that produce antilipogenic metabolites (Shingfield and Griinari, Reference Shingfield and Griinari2007). The shift towards the formation of t10-18:1 at the expense of t11-18:1 has received a great deal of attention as a marker of altered rumen function, but specific BH intermediates that could explain marine-lipid-induced MFD have not been well characterised yet (Shingfield and Griinari, Reference Shingfield and Griinari2007; Kairenius et al., Reference Kairenius, Ärölä, Leskinen, Toivonen, Ahvenjärvi, Vanhatalo, Huhtanen, Hurme, Griinari and Shingfield2015). Recent studies suggest a contribution of little known candidate inhibitors, such as metabolites of 18:3n-3 and very long-chain PUFA, and oxylipids of ruminal origin (e.g. t10c15-18:2, t10-containing C20 and C22 FA and 10-oxo-18:0; Kairenius et al., Reference Kairenius, Ärölä, Leskinen, Toivonen, Ahvenjärvi, Vanhatalo, Huhtanen, Hurme, Griinari and Shingfield2015; Toral et al., Reference Toral, Chilliard, Rouel, Leskinen, Shingfield and Bernard2015; Carreño et al., Reference Carreño, Hervás, Toral, Castro-Carrera and Frutos2016). Mammary mechanisms mediating this type of MFD have also been examined (Shingfield et al., Reference Shingfield, Bonnet and Scollan2013; Frutos et al., Reference Frutos, Toral and Hervás2017; Faulconnier et al., Reference Faulconnier, Bernard, Boby, Domagalski, Chilliard and Leroux2018). Molecular biology studies have shown that reductions in the mammary expression of enzymes involved in de novo FA synthesis (e.g. ACACA, ACSS2 and FASN) and related transcription factors (e.g. SREBF1 and INSIG1) are common features in responses to marine lipids, whereas downregulation of genes responsible for FA uptake and triacylglycerol synthesis (e.g. LPL and GPAT4) are less frequent (Shingfield et al., Reference Shingfield, Bonnet and Scollan2013; Carreño et al., Reference Carreño, Hervás, Toral, Castro-Carrera and Frutos2016; Frutos et al., Reference Frutos, Toral and Hervás2017). Nutrigenomic studies applying high-throughput technologies will likely provide new insight in this regard.

Regarding growing ruminants, since dietary inclusion of lipid must be restricted (to ≈60 g/kg DM consumed) to avoid impairment of rumen function, the capacity to manipulate the FA composition by use of ruminally available oil sources is limited. In support of this, Scollan et al. (Reference Scollan, Choi, Kurt, Fisher, Enser and Wood2001) found no adverse effect of dietary inclusion of fish oil at 30 g lipid/kg DM in a total diet that contained 60 g/kg DM. Wistuba et al. (Reference Wistuba, Kegley and Apple2006) added 30 g fish oil/kg, which increased the lipid content in the diet to 67 g/kg DM and intake was decreased. A similar negative impact of fish oil inclusion (30 g/kg) on intake and growth of lambs was reported by Parvar et al. (Reference Parvar, Ghoorchi and Shams Shargh2017). Scollan et al. (Reference Scollan, Choi, Kurt, Fisher, Enser and Wood2001) suggested that the negative effects of fish oil inclusion seen in some studies are likely mediated by specific BH intermediates of fish oil rather than a negative effect of fish oil on rumen function, analogous to MFD. Hopkins et al. (Reference Hopkins, Clayton, Lamb, van de Ven, Refahauge, Kerr, Bailes, Lewandowski and Ponnampalam2014) observed no negative effect of dietary inclusion of DHA-rich algae in the diet of lambs but referred to a related non-peer reviewed study where a reduction in intake in lambs offered the same product was observed.

Concerning plant secondary compounds, some reductions in milk fat concentration have also been observed in cows and ewes fed PPO- and tannin-rich legumes and in goats supplemented with EO, but their magnitude is small and likely due to a dilution effect by higher milk production (e.g. Addis et al., Reference Addis, Cabiddu, Pinna, Decandia, Piredda, Pirisi and Molle2005; Kholif et al., Reference Kholif, Morsy, Abdo, Matloup and Abu El-Ella2012). The positive response to legumes seems to be explained, at least in part, by higher feed intake, but improved nutrient utilisation could also contribute, as reported for EO (Kholif et al., Reference Kholif, Morsy, Abdo, Matloup and Abu El-Ella2012). However, inclusion of saponins and direct-fed microbials seems to have few effects on dairy performance (e.g. Benchaar and Chouinard, Reference Benchaar and Chouinard2009; Philippeau et al., Reference Philippeau, Lettat, Martin, Silberberg, Morgavi, Ferlay, Berger and Nozière2017). In lambs, the addition of quebracho to the ration decreased feed intake when included in an herbage- but not in a concentrate-diet (Vasta et al., Reference Vasta, Mele, Serra, Scerra, Luciano, Lanza and Priolo2009), which seems to be a consistent dose-dependent finding. In contrast, condensed tannins from either grape extract or C. ladanifer did not affect feed intake or growth of lambs (Jeronimo et al., Reference Jeronimo, Alves, Dentinho, Martins, Prates, Vasta, Santos-Silva and Bessa2010) and EO or saponins did not affect these variables in goats (Mandal et al., Reference Mandal, Roy and Patra2014).

Effects on product quality

The sensory quality of food can be defined by its texture, flavour, including the odour (smell attributes) and aroma (sensations perceived by the retro-nasal airway) and taste. The sensory quality of dairy products can be influenced by the FA composition of milk, for example, the production of oxidised flavour at 8 days post-sampling was positively correlated with levels of 18:2n-6, 18:3n-3 and total PUFA in milk fat (Timmons et al., Reference Timmons, Weiss, Palmquist and Harper2001). The FA composition of milk can also influence processing characteristics whereby milk with a high PUFA concentration is more susceptible to oxidation and therefore has a shorter shelf-life. However, milk from dairy cows supplemented with fish oil had no oxidised flavours (Nelson and Martini, Reference Nelson and Martini2009). Similarly, Kitessa et al. (Reference Kitessa, Gulati, Simos, Ashes, Scott, Fleck and Wynn2004) reported that milk from cows fed ruminally protected fish oil had similar organoleptic properties to that of a non-lipid supplemented control ration. High PUFA milk generally results in softer butter and cheese (Dewhurst and Moloney, Reference Dewhurst and Moloney2013) but Jones et al. (Reference Jones, Shingfield, Kohen, Jones, Lupoli, Grandison, Beever, Williams, Calder and Yaqoob2005) found no differences in flavour of butter or cheese manufactured from milk with a threefold increase in EPA+DHA, due to fish oil supplementation, compared with control milk. In contrast, while Glover et al. (Reference Glover, Budge, Rose, Rupasinghe, MacLaren, Green-Johnson and Fredeen2012) observed no effect of dietary algal supplementation on the oxidative stability of milk, that of butter was decreased. Plant secondary compounds that alter milk FA composition are likely to have a smaller effect on milk shelf-life than sources of marine oil since many of these compounds also have anti-oxidant properties that are detectable in milk. They may also be aromatic and so confer additional flavours to milk and meat but further studies are required on this topic.

Characteristics important to consumer perception of the quality or eating experience of meat may also be influenced by the FA composition of intramuscular lipid. When EPA and DHA increased in intramuscular lipid due to inclusion of protected fish oil in the diet of steers, lipid oxidation increased, resulting in a loss of shelf-life (Dunne et al., Reference Dunne, Rogalski, Childs, Monahan, Kenny and Moloney2011). A similar effect was seen due to the inclusion of microalgae in the diet of steers (Phelps et al., Reference Phelps, Drouillard, O’Quinn, Burnett, Blackmon, Axman, Van Bibber-Krueger and Gonzalez2016). The appropriate ratio of antioxidants to n-3 PUFA in meat to ensure lipid and colour stability during retail display remains to be determined. In this regard, combinations of plant-derived compounds that have antioxidant properties and marine lipids seem the most promising. There were few effects on product quality of unprotected fish oil or EO in the studies of Vatansever et al. (Reference Vatansever, Kurt, Enser, Nute, Scollan, Wood and Richardson2000) and Prado et al. (Reference Prado, Cruz, Valero, Zawadzki, Eiras, Rivaroli, Prado and Visentainer2016), respectively. Wistuba et al. (Reference Wistuba, Kegley and Apple2006) concluded that the differences found by a trained sensory panel due to fish oil inclusion in the diet of cattle were ‘relatively small and would probably not be discernible to the average consumer’. Ponnampalam et al. (Reference Ponnampalam, Sinclair, Egan, Ferrier and Leury2002) similarly reported that sensory characteristics of lamb were not affected by dietary inclusion of fish meal or fish oil. This likely reflects the relatively small change in muscle PUFA in these studies. The greater concentration of EPA and DHA in intramuscular lipid with the use of ruminally protected fish oil increased the sensory score for ‘abnormal’ but overall liking was not affected (Richardson et al., Reference Richardson, Hallett, Ball, Robinson, Nute, Enser, Wood and Scollan2004). Similarly, lamb from the combined unprotected fish oil/marine algae diet had higher sensory scores for ‘abnormal’ and ‘rancid’ compared with the unprotected fish oil treatment but overall liking was not affected (Nute et al., Reference Nute, Richardson, Wood, Hughes, Wilkinson, Cooper and Sinclair2007). In general, secondary plant compounds have few significant effects on meat eating quality.

Future perspectives

Manipulation of ruminal BH has proven effective in improving milk and meat FA profile, but further studies are required to unravel the causes of some inconsistent results. In addition, to be applied under practical farm conditions, feeding strategies have to be sustainable and cost-effective so research must continue to address ways to mitigate negative side effects on animal performance (e.g. MFD). A further challenge to be addressed is increasing our understanding of in vivo microbiology of ruminal BH, with an urgent need to determine which populations are truly involved in the process. This, in turn, may be useful for selection of new direct-fed microbials. Equally relevant is the acquisition of more in-depth knowledge of the effects of individual FA, including BH intermediates, on human health. Providing answers to this question seems key to assessing whether modified ruminant products would actually exert measurable effects on consumer health. Finally, evaluation of alternative feed resources with potential to modulate more efficiently the FA profile of milk and meat, including by-products rich in active compounds or EPA- and DHA-containing transgenic plants, as well as advances in microalgae production, are some of the topics with significant prospects for future growth in this field.

Acknowledgements

This work was conducted within the framework of the research projects AGL2014-54587 and AGL2017-87812 (Spanish Ministry of Economy and Competitiveness, MINECO). P.G.T. benefited from a Ramón y Cajal research contract (RYC-2015-17230, MINECO).

Declaration of interest

None.

Ethics statement

None.

Software and data repository resources

Data are available in the Supplementary Tables S1 to S7.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S1751731118001994

References

AbuGhazaleh, AA 2008. Effect of fish oil and sunflower oil supplementation on milk conjugated linoleic acid content for grazing dairy cows. Animal Feed Science and Technology 141, 220232.Google Scholar
Addis, M, Cabiddu, A, Pinna, G, Decandia, M, Piredda, G, Pirisi, A and Molle, G 2005. Milk and cheese fatty acid composition in sheep fed Mediterranean forages with reference to conjugated linoleic acid cis-9, trans-11. Journal of Dairy Science 88, 34433454.Google Scholar
Ahnadi, CE, Beswick, N, Delbecchi, L, Kennelly, JJ and Lacasse, P 2002. Addition of fish oil to diets for dairy cows. II. Effects on milk fat and gene expression of mammary lipogenic enzymes. Journal of Dairy Research 69, 521531.Google Scholar
Alves, SP, Francisco, A, Costa, M, Santos-Silva, J and Bessa, RJB 2017. Biohydrogenation patterns in digestive contents and plasma of lambs fed increasing levels of a tanniferous bush (Cistus ladanifer L.) and vegetable oils. Animal Feed Science and Technology 225, 157172.Google Scholar
Apás, AL, Arena, ME, Colombo, S and González, SN 2015. Probiotic administration modifies the milk fatty acid profile, intestinal morphology, and intestinal fatty acid profile of goats. Journal of Dairy Science 98, 4754.Google Scholar
Benchaar, C and Chouinard, PY 2009. Assessment of the potential of cinnamaldehyde, condensed tannins, and saponins to modify milk fatty acid composition of dairy cows. Journal of Dairy Sciece 92, 33923396.Google Scholar
Bernard, L, Leroux, C and Chilliard, Y 2008. Expression and nutritional regulation of lipogenic genes in the ruminant lactating mammary gland. Advances in Experimental Medicine and Biology 606, 67108.Google Scholar
Bernard, L, Leroux, C, Rouel, J, Delavaud, C, Shingfield, KJ and Chilliard, Y 2015. Effect of extruded linseeds alone or in combination with fish oil on intake, milk production, plasma metabolite concentrations and milk fatty acid composition in lactating goats. Animal 9, 810821.Google Scholar
Bernard, L, Toral, P, Rouel, J and Chilliard, Y 2016. Effects of extruded linseed and level and type of starchy concentrate in a diet containing fish oil on dairy goat performance and milk fatty acid composition. Animal Feed Science and Technology 222, 3142.Google Scholar
Bichi, E, Hervás, G, Toral, PG, Loor, JJ and Frutos, P 2013. Milk fat depression induced by dietary marine algae in dairy ewes: persistency of milk fatty acid composition and animal performance responses. Journal of Dairy Science 96, 524532.Google Scholar
Boeckaert, C, Vlaeminck, B, Dijkstra, J, Issa-Zacharia, A, Van Nespen, T, Van Straalen, W and Fievez, V 2008. Effect of dietary starch or micro algae supplementation on rumen fermentation and milk fatty acid composition of dairy cows. Journal of Dairy Science 91, 47144727.Google Scholar
Buccioni, A, Decandia, M, Minieri, S, Molle, G and Cabiddu, A 2012. Lipid metabolism in the rumen: new insights on lipolysis and biohydrogenation with an emphasis on the role of endogenous plant factors. Animal Feed Science and Technology 174, 125.Google Scholar
Campidonico, L, Toral, PG, Priolo, A, Luciano, G, Valenti, B, Hervás, G, Frutos, P, Copani, G, Ginane, C and Niderkorn, V 2016. Fatty acid composition of ruminal digesta and longissimus muscle from lambs fed silage mixtures including red clover, sainfoin, and timothy. Journal of Animal Science 94, 15501560.Google Scholar
Carreño, D, Hervás, G, Toral, PG, Belenguer, A and Frutos, P 2015. Ability of different types and doses of tannin extracts to modulate in vitro ruminal biohydrogenation in sheep. Animal Feed Science and Technology 202, 4551.Google Scholar
Carreño, D, Hervás, G, Toral, PG, Castro-Carrera, T and Frutos, P 2016. Fish oil-induced milk fat depression and associated downregulation of mammary lipogenic genes in dairy ewes. Journal of Dairy Science 99, 79717981.Google Scholar
Chilliard, Y, Glasser, F, Ferlay, A, Bernard, L, Rouel, J and Doreau, M 2007. Diet, rumen biohydrogenation and nutritional quality of cow and goat milk fat. European Journal of Lipid Science and Technology 109, 828855.Google Scholar
Dewhurst, RJ and Moloney, AP 2013. Modification of animal diets for the enrichment of dairy and meat products with omega-3 fatty acids. In Food enrichment with omega-3 fatty acids (ed. C Jacobsen, NS Nielsen and AF Horn), pp. 257287. Woodhead Publishing, Cambridge, UK.Google Scholar
Doreau, M, Arturo-Schaan, M and Laverroux, S 2017. Garlic oil reduces ruminal fatty acid biohydrogenation in vitro . European Journal of Lipid Science and Technology 119, 1500388.Google Scholar
Dunne, P, Rogalski, J, Childs, S, Monahan, FJ, Kenny, DA and Moloney, AP 2011. Long chain n-3 polyunsaturated fatty acid concentration and colour and lipid stability of muscle from heifers offered a ruminally protected fish oil supplement. Journal of Agricultural and Food Chemistry 59, 50155025.Google Scholar
European Food Safety Authority 2009. Scientific opinion: labeling reference intake values for n-3 and n-6 polyunsaturated fatty acids. The EFSA Journal 1176, 111.Google Scholar
Faulconnier, Y, Bernard, L, Boby, C, Domagalski, J, Chilliard, Y and Leroux, C 2018. Extruded linseed alone or in combination with fish oil modifies mammary gene expression profiles in lactating goats. Animal 12, 15641575.Google Scholar
Frutos, P, Toral, PG and Hervás, G 2017. Individual variation of the extent of milk fat depression in dairy ewes fed fish oil: milk fatty acid profile and mRNA abundance of candidate genes involved in mammary lipogenesis. Journal of Dairy Science 100, 96119622.Google Scholar
Glover, KE, Budge, S, Rose, M, Rupasinghe, HPV, MacLaren, L, Green-Johnson, J and Fredeen, AH 2012. Effect of feeding fresh forage and marine algae on the fatty acid composition and oxidation of milk and butter. Journal of Dairy Science 95, 27972809.Google Scholar
Hopkins, DL, Clayton, EH, Lamb, TA, van de Ven, RJ, Refahauge, G, Kerr, MJ, Bailes, K, Lewandowski, P and Ponnampalam, EN 2014. The impact of supplementing lambs with algae on growth, meat traits and oxidative status. Meat Science 98, 135141.Google Scholar
Huws, SA, Kim, EJ, Lee, MRF, Scott, MB, Tweed, JKS, Pinloche, E, Wallace, RJ and Scollan, ND 2011. As yet uncultured bacteria phylogenetically classified as Prevotella, Lachnospiraceae incertae sedis and unclassified Bacteroidales, Clostridiales and Ruminococcaceae may play a predominant role in ruminal biohydrogenation. Environmental Microbiology 13, 15001512.Google Scholar
Jenkins, TC, Wallace, RJ, Moate, PJ and Mosley, EE 2008. Board-invited review: recent advances in biohydrogenation of unsaturated fatty acids within the rumen microbial ecosystem. Journal of Animal Science 86, 397412.Google Scholar
Jeronimo, E, Alves, SP, Dentinho, MTP, Martins, SV, Prates, JAM, Vasta, V, Santos-Silva, J and Bessa, RJB 2010. Effect of grape seed extract, Cistus ladanifer L., and vegetable oil supplementation on fatty acid composition of abomasal digesta and intramuscular fat of lambs. Journal of Agricultural and Food Chemistry 58, 1071010721.Google Scholar
Jones, EL, Shingfield, KJ, Kohen, C, Jones, AK, Lupoli, B, Grandison, AS, Beever, DE, Williams, CM, Calder, PC and Yaqoob, P 2005. Chemical, physical, and sensory properties of dairy products enriched with conjugated linoleic acid. Journal of Dairy Science 88, 29232937.Google Scholar
Kairenius, P, Ärölä, A, Leskinen, H, Toivonen, V, Ahvenjärvi, S, Vanhatalo, A, Huhtanen, P, Hurme, T, Griinari, JM and Shingfield, KJ 2015. Dietary fish oil supplements depress milk fat yield and alter milk fatty acid composition in lactating cows fed grass silage based diets. Journal of Dairy Science 98, 56535672.Google Scholar
Khiaosa-ard, R, Bryner, SF, Scheeder, MRL, Wettstein, HR, Leiber, F, Kreuzer, M and Soliva, CR 2009. Evidence for the inhibition of the terminal step of ruminal alpha-linolenic acid biohydrogenation by condensed tannins. Journal of Dairy Science 92, 177188.Google Scholar
Kholif, SM, Morsy, TA, Abdo, MM, Matloup, OH and Abu El-Ella, AA 2012. Effect of supplementing lactating goats rations with garlic, cinnamon or ginger oils on milk yield, milk composition and milk fatty acids profile. Journal of Life Sciences 4, 2734.Google Scholar
Kitessa, SM, Gulati, SK, Simos, GC, Ashes, JR, Scott, TW, Fleck, E and Wynn, PC 2004. Supplementation of grazing dairy cows with rumen-protected tuna oil enriches milk fat with n-3 fatty acids without affecting milk production or sensory characteristics. British Journal of Nutrition 91, 271277.Google Scholar
Lee, MRF, Evans, PR, Nute, GR, Richardson, RI and Scollan, ND 2009. A comparison between red clover and grass silage feeding on fatty acid composition, meat stability and sensory quality of the M. longissimus muscle of dairy cull cows. Meat Science 81, 738744.Google Scholar
Lourenço, M, Cardozo, PW, Calsamiglia, S and Fievez, V 2008. Effects of saponins, quercetin, eugenol, and cinnamaldehyde on fatty acid biohydrogenation of forage polyunsaturated fatty acids in dual-flow continuous culture fermenters. Journal of Animal Science 86, 30453053.Google Scholar
Mandal, GP, Roy, A and Patra, AK 2014. Effects of feeding plant additives rich in saponins and essential oils on the performance, carcass traits and conjugated linoleic acid concentrations in muscle and adipose tissue of Black Bengal goats. Animal Feed Science and Technology 197, 7684.Google Scholar
Maragkoudakis, PA, Mountzouris, KC, Rosu, C, Zoumpopoulou, G, Papadimitriou, K, Dalaka, E, Hadjipetrou, A, Theofanous, G, Strozzi, GP, Carlini, N, Zervas, G and Tsakalidou, E 2010. Feed supplementation of Lactobacillus plantarum PCA 236 modulates gut microbiota and milk fatty acid composition in dairy goats - a preliminary study. International Journal of Food Microbiology 141, S109S116.Google Scholar
Mezgebo, GB, Monahan, FJ, Mark McGee, M, O’Riordan, EG, Richardson, IR, Brunton, NP and Moloney, AP 2017. Fatty acid, volatile and sensory characteristics of beef as affected by grass silage or pasture in the bovine diet. Food Chemistry 235, 8697.Google Scholar
Moloney, AP, Fievez, V, Martin, B, Nute, GR and Richardson, RI 2008. Botanically diverse forage-based rations for cattle: implications for product composition and quality and consumer health. Grassland Science in Europe 13, 361374.Google Scholar
Mueller-Harvey, I 2006. Review. Unravelling the conundrum of tannins in animal nutrition and health. Journal of the Science of Food and Agriculture 86, 20102037.Google Scholar
Nelson, KAS and Martini, S 2009. Increasing omega fatty acid content in cow’s milk through diet manipulation: effect on milk flavour. Journal of Dairy Science 92, 13781386.Google Scholar
Noci, F, Monahan, FJ, Scollan, ND and Moloney, AP 2007. The fatty acid composition of muscle adipose tissue of steers offered unwilted or wilted grass silage supplemented with sunflower oil and fish oil. British Journal of Nutrition 97, 502513.Google Scholar
Nute, GR, Richardson, RI, Wood, JD, Hughes, SI, Wilkinson, RG, Cooper, SL and Sinclair, LA 2007. Effect of dietary oil source on the flavour and the colour and lipid stability of lamb meat. Meat Science 77, 547555.Google Scholar
Parodi, PW 2016. Dietary guidelines for saturated fatty acids are not supported by the evidence. International Dairy Journal 52, 115123.Google Scholar
Parvar, R, Ghoorchi, T and Shams Shargh, M 2017. Influence of dietary oils on performance, blood metabolites, prune derivatives, cellulase activity and muscle fatty acid composition in fattening lambs. Small Ruminant Research 150, 2229.Google Scholar
Payandeh, S, Kafilzadeh, F, Juárez, M, de la Fuente, MA, Ghadimi, D and Martínez Marín, AL 2017. Probiotic supplementation effects on milk fatty acid profile in ewes. Journal of Dairy Research 84, 128131.Google Scholar
Phelps, KJ, Drouillard, JS, O’Quinn, TG, Burnett, DD, Blackmon, TL, Axman, JE, Van Bibber-Krueger, CL and Gonzalez, JM 2016. Feeding microalgae meal (All-G Rich™; Schizochytrium limacinum CCAP 4087/2) to beef heifers. 1. Effects on longissimus lumborum steak colour and palatability. Journal of Animal Science 94, 40164029.Google Scholar
Philippeau, C, Lettat, A, Martin, C, Silberberg, M, Morgavi, DP, Ferlay, A, Berger, C and Nozière, P 2017. Effects of bacterial direct-fed microbials on ruminal characteristics, methane emission, and milk fatty acid composition in cows fed high- or low-starch diets. Journal of Dairy Science 100, 26372650.Google Scholar
Ponnampalam, EN, Sinclair, AJ, Egan, AR, Ferrier, GR and Leury, BJ 2002. Dietary manipulation of muscle long chain omega-3 and omega-6 fatty acids and sensory properties of lamb meat. Meat Science 60, 125132.Google Scholar
Prado, IN, Cruz, OTB, Valero, MV, Zawadzki, F, Eiras, CE, Rivaroli, DC, Prado, RM and Visentainer, JV 2016. Effects of glycerin and essential oils (Anacardium occidentale and Ricinus communis) on the meat quality of crossbred bulls finished in a feedlot. Animal Production Science 56, 21052114.Google Scholar
Ramos-Morales, E, McKain, N, Gawad, RMA, Hugo, A and Wallace, RJ 2016. Vernonia galamensis and vernolic acid inhibit fatty acid biohydrogenation in vitro . Animal Feed Science and Technology 222, 5463.Google Scholar
Richardson, RI, Hallett, KG, Ball, R, Robinson, AM, Nute, GR, Enser, M, Wood, JD and Scollan, ND 2004. Effect of free and ruminally-protected fish oils on fatty acid composition, sensory and oxidative characteristics of beef loin muscle. In Proceedings of the 50th International Congress on Meat Science and Technology, 8–13 August, Helsinki, Finland.Google Scholar
Salter, AM 2013. Dietary fatty acids and cardiovascular disease. Animal 7, 163171.Google Scholar
Scollan, N, Dannenberger, D, Nuernberg, K, Richardson, I, MacKintosh, S, Hocquette, JF and Moloney, A 2014. Enhancing the nutritional and health value of beef lipids and their relationship with meat quality. Meat Science 97, 384394.Google Scholar
Scollan, ND, Choi, NJ, Kurt, E, Fisher, AV, Enser, M and Wood, JD 2001. Manipulating the fatty acid composition of muscle and adipose tissue in beef cattle. British Journal of Nutrition 85, 115124.Google Scholar
Shingfield, KJ, Bonnet, M and Scollan, ND 2013. Recent developments in altering the fatty acid composition of ruminant-derived foods. Animal 7 (suppl. 1), 132162.Google Scholar
Shingfield, KJ and Griinari, JM 2007. Role of biohydrogenation intermediates in milk fat depression. European Journal of Lipid Science and Technology 109, 799816.Google Scholar
Shingfield, KJ, Kairenius, P, Arola, A, Paillard, D, Muetzel, S, Ahvenjarvi, S, Vanhatalo, A, Huhtanen, P, Toivonen, V, Griinari, JM and Wallace, RJ 2012. Dietary fish oil supplements modify ruminal biohydrogenation, alter the flow of fatty acids at the omasum, and induce changes in the ruminal Butyrivibrio population in lactating cows. Journal of Nutrition 142, 14371448.Google Scholar
Shingfield, KJ, Reynolds, CK, Hervás, G, Griinari, JM, Grandison, AS and Beever, DE 2006. Examination of the persistency of milk fatty acid composition responses to fish oil and sunflower oil in the diet of dairy cows. Journal of Dairy Science 89, 714732.Google Scholar
Shingfield, KJ, Reynolds, CK, Lupoli, B, Toivonen, V, Yurawecz, MP, Delmonte, P, Griinari, JM, Grandison, AS and Beever, DE 2005. Effect of forage type and proportion of concentrate in the diet on milk fatty acid composition in cows given sunflower oil and fish oil. Animal Science 80, 225238.Google Scholar
Shivani, S, Srivastava, A, Shandilya, UK, Kale, V and Tyagi, AK 2016. Dietary supplementation of Butyrivibrio fibrisolvens alters fatty acids of milk and rumen fluid in lactating goats. Journal of the Science of Food and Agriculture 96, 17161722.Google Scholar
Timmons, JS, Weiss, WP, Palmquist, DL and Harper, WJ 2001. Relationship among roasted soybeans, milk components, and spontaneous oxidized flavour of milk. Journal of Dairy Science 84, 24402449.Google Scholar
Toral, PG, Bernard, L, Belenguer, A, Rouel, J, Hervás, G, Chilliard, Y and Frutos, P 2016. Comparison of ruminal lipid metabolism in dairy cows and goats fed diets supplemented with starch, plant oil, or fish oil. Journal of Dairy Science 99, 301316.Google Scholar
Toral, PG, Chilliard, Y, Rouel, J, Leskinen, H, Shingfield, KJ and Bernard, L 2015. Comparison of the nutritional regulation of milk fat secretion and composition in cows and goats. Journal of Dairy Science 98, 72777297.Google Scholar
Toral, PG, Hervás, G, Belenguer, A, Bichi, E and Frutos, P 2013. Effect of the inclusion of quebracho tannins in a diet rich in linoleic acid on milk fatty acid composition in dairy ewes. Journal of Dairy Science 96, 431439.Google Scholar
Toral, PG, Hervás, G, Carreño, D, Leskinen, H, Belenguer, A, Shingfield, KJ and Frutos, P 2017. In vitro response to EPA, DPA, and DHA: comparison of effects on ruminal fermentation and biohydrogenation of 18-carbon fatty acids in cows and ewes. Journal of Dairy Science 100, 61876198.Google Scholar
Vahmani, P, Fredeen, AH and Glover, KE 2013. Effect of supplementation with fish oil or microalgae on fatty acid composition of milk from cows managed in confinement or pasture systems. Journal of Dairy Science 96, 66606670.Google Scholar
Vanhatalo, A, Kuoppala, K, Toivonen, V and Shingfield, KJ 2007. Effects of forage species and stage of maturity on bovine milk fatty acid composition. European Journal of Lipid Science and Technology 109, 856867.Google Scholar
Vasta, V and Luciano, G 2011. The effects of dietary consumption of plants secondary compounds on small ruminants’ products quality. Small Ruminant Research 101, 150159.Google Scholar
Vasta, V, Mele, M, Serra, A, Scerra, M, Luciano, G, Lanza, M and Priolo, A 2009. Metabolic fate of fatty acids involved in ruminal biohydrogenation in sheep fed concentrate or herbage with or without tannins. Journal of Animal Science 87, 26742684.Google Scholar
Vatansever, L, Kurt, E, Enser, M, Nute, GR, Scollan, ND, Wood, JD and Richardson, RI 2000. Shelf life and eating quality of beef from cattle of different breeds given diets differing in n-3 polyunsaturated fatty acid composition. Animal Science 71, 471482.Google Scholar
Wistuba, TJ, Kegley, EB and Apple, JK 2006. Influence of fish oil in finishing diets on growth performance, carcass characteristics and sensory evaluation of cattle. Journal of Animal Science 84, 902909.Google Scholar
Figure 0

Table 1 Main changes in digesta, milk and meat concentrations of selected fatty acids (compared with the control diet) in response to diet supplementation with marine lipids rich in n-3 polyunsaturated fatty acids (PUFA)

Figure 1

Table 2 Main changes in digesta, milk and meat concentrations of selected fatty acids (FA) and rumen disappearance of c9-18:1, 18:2n-6 and 18:3n-3 (compared with the control diet) in response to diet supplementation with plant secondary compounds1

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