Hostname: page-component-cd9895bd7-q99xh Total loading time: 0 Render date: 2024-12-26T15:16:43.207Z Has data issue: false hasContentIssue false

Review: Alternative and novel feeds for ruminants: nutritive value, product quality and environmental aspects

Published online by Cambridge University Press:  15 October 2018

A. Halmemies-Beauchet-Filleau*
Affiliation:
Department of Agricultural Sciences, University of Helsinki, FI-00014 Helsinki, Finland
M. Rinne
Affiliation:
Production Systems, Natural Resources Institute Finland (Luke), FI-31600 Jokioinen, Finland
M. Lamminen
Affiliation:
Department of Agricultural Sciences, University of Helsinki, FI-00014 Helsinki, Finland Helsinki Institute of Sustainability Science, University of Helsinki, FI-00014 Helsinki, Finland
C. Mapato
Affiliation:
Department of Animal Science, Tropical Feed Resources Research and Development Center, Faculty of Agriculture, Khon Kaen University, Khon Kaen 40002, Thailand
T. Ampapon
Affiliation:
Department of Animal Science, Tropical Feed Resources Research and Development Center, Faculty of Agriculture, Khon Kaen University, Khon Kaen 40002, Thailand
M. Wanapat
Affiliation:
Department of Animal Science, Tropical Feed Resources Research and Development Center, Faculty of Agriculture, Khon Kaen University, Khon Kaen 40002, Thailand
A. Vanhatalo
Affiliation:
Department of Agricultural Sciences, University of Helsinki, FI-00014 Helsinki, Finland Helsinki Institute of Sustainability Science, University of Helsinki, FI-00014 Helsinki, Finland

Abstract

Ruminant-based food production faces currently multiple challenges such as environmental emissions, climate change and accelerating food–feed–fuel competition for arable land. Therefore, more sustainable feed production is needed together with the exploitation of novel resources. In addition to numerous food industry (milling, sugar, starch, alcohol or plant oil) side streams already in use, new ones such as vegetable and fruit residues are explored, but their conservation is challenging and production often seasonal. In the temperate zones, lipid-rich camelina (Camelina sativa) expeller as an example of oilseed by-products has potential to enrich ruminant milk and meat fat with bioactive trans-11 18:1 and cis-9,trans-11 18:2 fatty acids and mitigate methane emissions. Regardless of the lower methionine content of alternative grain legume protein relative to soya bean meal (Glycine max), the lactation performance or the growth of ruminants fed faba beans (Vicia faba), peas (Pisum sativum) and lupins (Lupinus sp.) are comparable. Wood is the most abundant carbohydrate worldwide, but agroforestry approaches in ruminant nutrition are not common in the temperate areas. Untreated wood is poorly utilised by ruminants because of linkages between cellulose and lignin, but the utilisability can be improved by various processing methods. In the tropics, the leaves of fodder trees and shrubs (e.g. cassava (Manihot esculenta), Leucaena sp., Flemingia sp.) are good protein supplements for ruminants. A food–feed production system integrates the leaves and the by-products of on-farm food production to grass production in ruminant feeding. It can improve animal performance sustainably at smallholder farms. For larger-scale animal production, detoxified jatropha (Jatropha sp.) meal is a noteworthy alternative protein source. Globally, the advantages of single-cell protein (bacteria, yeast, fungi, microalgae) and aquatic biomass (seaweed, duckweed) over land crops are the independence of production from arable land and weather. The chemical composition of these feeds varies widely depending on the species and growth conditions. Microalgae have shown good potential both as lipid (e.g. Schizochytrium sp.) and protein supplements (e.g. Spirulina platensis) for ruminants. To conclude, various novel or underexploited feeds have potential to replace or supplement the traditional crops in ruminant rations. In the short-term, N-fixing grain legumes, oilseeds such as camelina and increased use of food and/or fuel industry by-products have the greatest potential to replace or supplement the traditional crops especially in the temperate zones. In the long-term, microalgae and duckweed of high-yield potential as well as wood industry by-products may become economically competitive feed options worldwide.

Type
Review Article
Copyright
© The Animal Consortium 2018 

Implications

Within ruminant-based food production, there are potential means to improve global food supply and to decrease its environmental footprint without compromising animal products. Alternative and novel feeds provide opportunities to (a) spare arable land, fresh water (e.g. single-cell proteins (SCP), duckweed) or fertilisers (N-fixing grain and shrub legumes), (b) exploit side streams more efficiently (residues of food, biofuel or wood production) and (c) increase the use of fibrous feeds not suitable for monogastrics (wood, shrubs). They may also offer additional benefits such as modification of lipids in ruminant products (lupins, camelina, microalgae) and mitigation of methane emissions (lipid-rich feeds, tropical shrubs).

Introduction

Ruminant-based food production faces currently multiple and global challenges such as needs to respond to the growing human population and food security, but also to the pollution of environment and the accelerating climate change. The animal production sector is also heavily criticised due to food-feed competition, that is, the feeding of human-edible materials to animals and the use of arable land to produce animal feed instead of producing human-edible food directly. Recently increasing interest in biofuel production tightens up the competition on the use of arable land.

Ruminants are often criticised for the lower feed conversion efficiency relative to monogastric livestock, but taking into account differences in the feed rations modifies the ranking order. Indeed, to produce the same amount of animal protein products (meat, milk or eggs) much less human-edible feed is needed in ruminant systems than in monogastric systems (6 v. 16 kg of human-edible feed dry matter (DM) per kilogram of protein products; Mottet et al., Reference Mottet, de Haan, Falcuccia, Tempioa, Opioa and Gerbera2017). The strengths inherent to ruminant animals in food production chain could be further developed by more diverse and efficient exploitation of side streams and increased exploitation of fibrous feeds not suitable for the nutrition of humans and monogastric livestock. To improve the food system sustainability and to reach climate change targets, changes in feed and animal production alone are not adequate. Changes in food consumption as regard to wastage and balanced dietary choices are also needed (Röös et al., Reference Röös, Bajželj, Smith, Patel, Little and Garnett2017). According to Schader et al. (Reference Schader, Muller, El-Hage Scialabba, Hecht, Isensee, Erb, Smith, Makkar, Klocke, Leiber, Schwegler, Stolze and Niggli2015), feeding animals solely based on food industry by-products and grasslands combined with changes in human dietary patterns (reductions of animal products) have potential to decrease the environmental load of food production drastically. For example, greenhouse gas emissions, nitrogen (N) and phosphorus (P) load, as well as land and fresh water use could decrease up to 18% to 46%.

Almost half of worldwide bovine milk production takes place in the temperate areas of Europe and Northern America (FAOSTAT, 2016) under intensive (high inputs including concentrate, high milk yield) or extensive production systems (high forage, low inputs, moderate or low milk yield). At the present, the ruminant milk and meat production in Europe relies largely on imported soya bean (Glycine max) from South America (Lindberg et al., Reference Lindberg, Lindberg, Teräs, Poulsen, Solberg, Tybirk, Przedrzymirska, Sapota, Olsen, Karlson, Jóhannsson, Smárason, Gylling, Knudsen, Dorca-Preda, Hermansen, Kruklite and Berzina2016). Soya bean together with cereals and maize (Zea mays), lucerne (Medicago sativa) or grass forage are typical dietary ingredients in the intensive farming of the temperate zones. However, the highest cattle populations are in the tropical and subtropical climate zones, the number of cattle in Brazil and India alone comprising 15% and 13% of global cattle population, respectively (FAOSTAT, 2016). In the tropics, the forages are typically of poor nutritive value in terms of low protein and high-fibre content that limits the efficiency of animal production. Local protein sources are thus sought both in the temperate as well as tropical areas.

Enteric methane emissions from ruminants significantly contribute to the environmental footprint of agriculture (Herrero et al., Reference Herrero, Henderson, Havlík, Thornton, Conant, Smith, Wirsenius, Hristov, Gerber, Gill, Butterbach-Bahl, Valin, Garnett and Stehfest2016). Ruminal methane production also represents a substantial loss of feed energy. Appropriate forage supplementation and feed choices to improve forage and total diet digestibility have significantly more potential to increase ruminant performance and mitigate methane emissions in the extensive than in the intensive ruminant production systems (Knapp et al., Reference Knapp, Laur, Vadas, Weiss and Tricarico2014; Herrero et al., Reference Herrero, Henderson, Havlík, Thornton, Conant, Smith, Wirsenius, Hristov, Gerber, Gill, Butterbach-Bahl, Valin, Garnett and Stehfest2016). Modern intensive agriculture is a significant source of N emissions as well. Globally, about 50% of the N fertiliser applied to conventional cropping systems is not utilised by plants, but lost to the environment as ammonia (NH3), nitrate (NO3 ) and nitrous oxide (N2O; Coskun et al., Reference Coskun, Britto, Shi and Kronzucker2017). Legumes with biological N2 fixation (Watson et al., Reference Watson, Reckling, Preissel, Bachinger, Bergkvist, Kuhlman, Lindström, Nemecek, Topp, Vanhatalo, Zander, Murphy-Bokern and Stoddard2017) may offer an environmentally sound and sustainable nutrient source to ruminants. Furthermore, the N use efficiency of ruminants is mainly determined by diet N content (Huhtanen et al., Reference Huhtanen, Nousiainen, Rinne, Kytölä and Khalili2008) indicating the potential to reduce N leakages by dietary N optimisation.

The feasibility of using alternative feeds for ruminants depends among others on the feed value of novel feeds, animal production responses and feed costs compared to the conventional feeds. In addition, the environmental footprint of feed and animal production, and the economic value of novel feeds in alternative uses such as energy production are of great importance. The objective of this article is to review the nutritive value of some currently underutilised or novel feeds for ruminants in the temperate zones (intensive and extensive farming) and in the tropics (extensive farming). In addition, the effects of these feeds on ruminant milk production and quality (milk, protein and fat yields and milk fatty acid composition) as well as meat production (average daily gains (ADG) and meat composition) are examined and compared to more conventional feeds. The environmental load of novel feeds is evaluated based on requirements for arable land and for fresh water during the feed production and their possible effects on methane and nitrogen emissions of ruminants. This review comprises a quantitative evaluation of replacing traditional feeds by alternative ones on ruminant milk production as well as a comparative estimation of time delay for novel feeds to enter readily on the market together with their future potential to increase sustainable production and utilisation in ruminant nutrition.

Intensive and extensive ruminant production in the temperate zones: protein and energy supplements

By-products of food and bioenergy industries

Numerous food and biofuel industry side streams are already used as major components of ruminant diets such as hulls and feed meals from milling industry, distillery and brewery by-products, meals and expellers from plant oil production, molasses and pulps from sugar processing, etc. (Feedipedia, 2018; Luke, 2018). Biofuel by-products as ruminant feeds have been reviewed in detail by Makkar et al. (Reference Makkar, Cooper, Weber, Lywood and Pinkney2012). Recent attempts have aimed at utilising such side streams that have not previously been used. Wadhwa and Bakshi (Reference Wadhwa and Bakshi2013) estimated that nearly 50% of all fruits and vegetables in the European Union go to waste with losses occurring during agricultural production, processing, distribution and by consumers. Vegetable residues may be composted and used as soil amendments but with only a limited added value. One option to add value to these products is to preserve them by sun drying (Wadwha et al., Reference Wadhwa, Bakshi and Makkar2015) or ensiling (Orosz and Davies, Reference Orosz and Davies2015) and feed to livestock. Vegetable and fruit residues are challenging raw materials for ensiling as they are easily perishable and typically moist (Wadwha et al., Reference Wadhwa, Bakshi and Makkar2015; Table 1; Supplementary Table S1). Solid-state fermentation of the fruit and vegetable wastes in combination with other non-competing human food biomass could possibly (a) enrich them with proteins and other nutrients, (b) improve feed quality and (c) enhance ensilability (Wadwha et al., Reference Wadhwa, Bakshi and Makkar2015).

Table 1 Chemical composition of some alternative and common feeds for ruminants

EE=ether extract.

1 References in Supplementary Table S1.

2 Tannins g/kg dry matter (DM).

3 Crude fibre.

The production of fruit and vegetable residues is often seasonal, and in many cases they are produced by small or medium size companies, resulting in rather small batches. To be able to recycle these residues back into the food chain requires high hygienic quality of the products and good stability to allow efficient logistics. Some of the major constraints in the use of fruit wastes are the presence of antinutritional factors such as pesticides, mycotoxins, heavy metals and dioxins (Wadhwa et al., Reference Wadhwa, Bakshi and Makkar2015). There are, however, positive experiences as, for example, ensiled tomato and olive by-products have been successfully used in the diets of dairy goats (Arco-Pérez et al., Reference Arco-Pérez, Ramos-Morales, Yáñez-Ruiz, Abecia and Martín-García2017) and ensiled apple pomace up to 30% in the diets of lactating dairy cows (Wadhwa et al., Reference Wadhwa, Bakshi and Makkar2015).

By-products of oilseed crops such as soya bean and rapeseed meals and expellers are widely used as supplementary protein for dairy cows. One of the less used oilseed crops is an ancient plant camelina (Camelina sativa). Camelina has a moderate seed yield potential (Table 2) that combined with low-nutrient requirements and a good resistance to diseases, pests and drought makes it adapted also to low-input farming (Heuzé et al., Reference Heuzé, Tran and Lebas2017b). Camelinaseed oil is an economically interesting on-farm raw material for biofuel production (Keske et al., Reference Keske, Hoag, Brandess and Johnson2013) to increase farmers’ energy independence. Camelinaseed oil is also fit for human consumption (Heuzé et al., Reference Heuzé, Tran and Lebas2017b). Camelina expeller contains lipids with significant amounts of essential fatty acids 18:2n-6 and 18:3n-3 (Bayat et al., Reference Bayat, Kairenius, Stefański, Leskinen, Comtet-Marre, Forano, Chaucheyras-Durand and Shingfield2015), but it is also relatively abundant in CP and essential amino acids (AA) (Table 1). However, ruminal degradability of camelina protein in situ (76%) was higher than that of soya bean (58%) or rapeseed (52%; Lawrence and Anderson, Reference Lawrence and Anderson2015). Feeding unprocessed or processed camelinaseeds to ruminants has sometimes, but not always, decreased DM intake (Table 3; Supplementary Table S2; Table 4; Supplementary Table S3) that may be related to glucosinolates (Lawrence et al., Reference Lawrence, Anderson and Clapper2016). Nevertheless, replacing various conventional protein feeds in ruminant diets with camelina expeller has resulted in comparable milk and protein yields (Table 3) or ADG (Table 4).

Table 2 The suitability for local production of some common and alternative feeds in different production systems, potential yields in Europe, the need of land or water for feed production, and other main environmental aspects regarding crop and ruminant production

TInt=intensive temperate production; TExt=extensive temperate production; DM=dry matter; Yes=suitable; (Yes)=suitable with some restrictions such as species or cultivars (pulses, grass and wheat) or the proximity of the seaside (seaweed).

4 Table 5.

5 Yield potential in tropical areas; Heuzé et al. (Reference Heuzé, Tran, Edouard, Renaudeau, Bastianelli and Lebas2016b).

Table 3 The effect of some alternative protein feeds on milk production of ruminants

E=expeller; S=seed; DMI=dry matter intake; CS=cottonseeds; RSM=rapeseed meal; SBM=soya bean meal; SBS=soya bean seeds; SFM=sunflowerseed meal; WLS=white lupin seeds.

1 Isonitrogenous substitution rate (SR) of control protein feed by alternative protein feed.

2 Change (%) due to alternative protein feed compared to control protein feed.

3 Number of diet comparisons.

4 References shown in Supplementary Table S2.

5 Concentrate intake.

6 Not reported.

Table 4 The effect of some alternative feeds on the average daily gains (ADG) of ruminants

OM= organic matter.

1 Substitution rate of control feed by alternative feed.

2 Effect of alternative feed on dry matter intake (DMI) or ADG: Dec=decrease; –=no effect; Inc=increase; nr=not reported.

3 References shown in Supplementary Table S3.

Feeding camelina expeller results in high concentrations of trans-11 18:1 and cis-9,trans-11 18:2, unaltered or slightly decreased 18:0 and cis-9 18:1 concentrations and a significant decrease in total saturated fatty acids in dairy cow (Halmemies-Beauchet-Filleau et al., Reference Halmemies-Beauchet-Filleau, Kokkonen, Lampi, Toivonen, Shingfield and Vanhatalo2011 and Reference Halmemies-Beauchet-Filleau, Shingfield, Simpura, Kokkonen, Jaakkola, Toivonen and Vanhatalo2017), in sheep (Szumacher-Strabel et al., Reference Szumacher‐Strabel, Cieślak, Zmora, Pers‐Kamczyc, Bielińska, Stanisz and Wójtowski2011) and in goat milk (Cais-Sokolińska et al., Reference Cais‐Sokolińska, Pikul, Wójtowski, Danków, Teichert, Czyżak‐Runowska and Bagnicka2015) as well as in sheep meat (Table 4). Besides beneficially modifying lipids in ruminant milk and meat, camelina lipids at inclusion rate of 6% in the diet DM decreased ruminal methane and carbon dioxide production of dairy cows by 29% and 34%, respectively (Bayat et al., Reference Bayat, Kairenius, Stefański, Leskinen, Comtet-Marre, Forano, Chaucheyras-Durand and Shingfield2015). However, caution should be exercised in the dosage of lipids as the reduction in methane emissions due to the dietary polyunsaturates may be accompanied with lowered DM intake and milk yield (Bayat et al., Reference Bayat, Kairenius, Stefański, Leskinen, Comtet-Marre, Forano, Chaucheyras-Durand and Shingfield2015).

Grain legume seeds

Grain legumes such as faba bean (Vicia faba), pea (Pisum sativum) and lupins (Lupinus sp.) are old crops cultivated in all arable continents. There are three major modern lupine species bred to animal feed namely white (Lupinus albus), blue (Lupinus angustifolius) and yellow lupin (Lupinus luteus). In the short-term, grain legumes are presumably the most promising alternatives to soya bean (Glycine max) and rapeseed in the temperate areas because their cultivation practices are already available and implemented (Figure 1). However, grain legume seeds are edible by humans as well. Therefore, the utilisation of human-inedible feeds for ruminants and/or feeds the production of which require less or not at all arable land should be encouraged to improve further the sustainability of food production system in the longer term.

Figure 1 Rough overview of some feeds for ruminants with respect to time to enter readily on the market, extent of production today and potential to increase utilisation in ruminant nutrition sustainably in future (small red bubble=limited; medium-sized blue bubble=moderate; large green bubble=high). Data adapted in part from FAOSTAT (2016), Kruus and Hakala (Reference Kruus and Hakala2016) and USDA (2016).

The unique capacity of leguminous plants in conjunction with rhizobium symbionts to biologically fix and utilise atmospheric N enables that inorganic N-fertilisers with rising prices and high requirement of energy in manufacturing are not required. Indeed, the emissions of a potent greenhouse gas N2O from legume cultivation are generally lower than those from N-fertilised crops (1.3 v. 3.2 kg/ha; Watson et al., Reference Watson, Reckling, Preissel, Bachinger, Bergkvist, Kuhlman, Lindström, Nemecek, Topp, Vanhatalo, Zander, Murphy-Bokern and Stoddard2017). The seed yield potential of grain legumes under optimal conditions is similar or exceeding that of conventional protein crops (Table 2). These advantages make legumes increasingly attractive in the intensive farming in addition to current wide spread use in the low-input and organic farming.

A prerequisite for the spread of grain legume production is the profitability relative to other crops. This is influenced, for example, by yields, volatile producer prices, incentives and production costs. Though the producer prices of grain legume seeds are on average 1.1 to 2.0 times higher than that of wheat in Europe (FAOSTAT, 2016), the competitiveness against more common crops such as wheat is uncertain mainly due to inconsistent DM yields and high seed costs. However, the incentives for protein feeds and reducing the seed costs by producing the seed on-farm can improve the competitiveness of grain legume cultivation. The cultivation of grain legumes is more challenging than that of cereals and grasses as they are sensitive to lodging and due to pests and pathogens they require efficient crop rotation (van Krimpen et al., Reference Van Krimpen, Bikker, Van der Meer, Van der Peet-Schwering and Vereijken2013). Nevertheless, the plant breeding may be able to overcome these agronomical constraints if given enough attention and resources.

Grain legume seeds differ in the chemical composition, the CP content ranging from 240 (peas) to 400 g/kg DM (soya beans). Soya beans have in general the highest ether extract (EE) content, whereas faba beans and peas contain significant amounts of starch and lupin seeds NDF (Table 1). The main storage carbohydrate of lupins is pectin instead of starch (White et al., Reference White, Staines and Staines2007). Lupin seeds contain more EE than faba beans and peas (Table 1) with cis-9 18:1 and 18:2n-6 as major fatty acids (White et al., Reference White, Staines and Staines2007). The protein in grain legume seeds, faba beans and lupin seeds in particular, is low in methionine (Table 1), which is often the limiting AA for the lactation performance of dairy cows (e.g. Pisulewski et al., Reference Pisulewski, Rulquin, Peyraud and Verite1996).

The feasibility of the use of alternative grain legumes in ruminant diets is determined not only by their chemical composition, but also by the rate and extent of degradation of nutrients in the rumen. The degradability of faba bean, pea and lupin protein in the rumen is often over 80% (Watson et al., Reference Watson, Reckling, Preissel, Bachinger, Bergkvist, Kuhlman, Lindström, Nemecek, Topp, Vanhatalo, Zander, Murphy-Bokern and Stoddard2017) that is significantly higher than those of soya bean or rapeseed expellers. In addition, the heat-treatment of faba beans, peas or lupin seeds to lower ruminal degradability has seldom improved animal performance (White et al., Reference White, Staines and Staines2007; Watson et al., Reference Watson, Reckling, Preissel, Bachinger, Bergkvist, Kuhlman, Lindström, Nemecek, Topp, Vanhatalo, Zander, Murphy-Bokern and Stoddard2017). It is plausible that the high-protein degradability in the rumen together with suboptimal AA profile in the undegraded protein of alternative grain legume seeds limit their production responses in high-yielding ruminants. Faba beans contain also antinutritional factors such as vicine and convicine (Heuzé et al., Reference Heuzé, Tran, Delagarde, Lessire and Lebas2016a), lupins quinolizidine alkaloids (Wasilewko and Buraczewska, Reference Wasilewko and Buraczewska1999) and peas lectins and tannins (Heuzé et al., Reference Heuzé, Tran, Giger-Reverdin, Noblet, Renaudeau, Lessire and Lebas2017a). However, ruminants are not susceptible to most of them because of microbial metabolism and degradation in the rumen (Watson et al., Reference Watson, Reckling, Preissel, Bachinger, Bergkvist, Kuhlman, Lindström, Nemecek, Topp, Vanhatalo, Zander, Murphy-Bokern and Stoddard2017).

Replacing protein in soya bean meal partially or completely with faba beans, blue lupin, white lupin or peas has resulted in rather similar bovine lactation performances (Watson et al., Reference Watson, Reckling, Preissel, Bachinger, Bergkvist, Kuhlman, Lindström, Nemecek, Topp, Vanhatalo, Zander, Murphy-Bokern and Stoddard2017; Table 3). Furthermore, the milk fat concentration of medium chain saturates has been lower and those of cis-9 18:1 and 18:2n-6 higher in cows fed white lupins seeds relative to soya bean meal (White et al., Reference White, Staines and Staines2007). In contrast, the milk production responses of alternative grain legumes are often inferior compared to the rapeseed meal in dairy cow nutrition (Watson et al., Reference Watson, Reckling, Preissel, Bachinger, Bergkvist, Kuhlman, Lindström, Nemecek, Topp, Vanhatalo, Zander, Murphy-Bokern and Stoddard2017; Table 3). Substitution of rapeseed meal with faba beans has typically decreased milk protein yield and increased milk urea concentration and the proportion of N excreted in urine suggesting less efficient use of protein in faba beans than in rapeseed (Puhakka et al., Reference Puhakka, Jaakkola, Simpura, Kokkonen and Vanhatalo2016; Table 3), thus leading to increased N emissions from animals.

Partial or total replacement of soya bean or rapeseed protein by faba beans, lupin seeds or peas has not significantly altered ADG or meat chemical composition in growing sheep or cattle (Table 4). Besides replacing protein in ruminant diets, starchy faba beans and peas (Table 1) and lupins with higher metabolisable energy content than cereals (Watson et al., Reference Watson, Reckling, Preissel, Bachinger, Bergkvist, Kuhlman, Lindström, Nemecek, Topp, Vanhatalo, Zander, Murphy-Bokern and Stoddard2017) have potential in replacing cereals as well. Indeed, the substitution of cereal grains by grain legumes in dairy cow diets generally increases milk production (White et al., Reference White, Staines and Staines2007; Watson et al., Reference Watson, Reckling, Preissel, Bachinger, Bergkvist, Kuhlman, Lindström, Nemecek, Topp, Vanhatalo, Zander, Murphy-Bokern and Stoddard2017). Furthermore, starch in peas and faba beans has lower degradability in the rumen than cereal starch (Watson et al., Reference Watson, Reckling, Preissel, Bachinger, Bergkvist, Kuhlman, Lindström, Nemecek, Topp, Vanhatalo, Zander, Murphy-Bokern and Stoddard2017) that lowers the risk for acidosis.

Biorefining of forage crops

Interest in using grass biomass as a raw material for green biorefineries has arisen recently (McEniry and O’Kiely, Reference McEniry and O’Kiely2014; Hermansen et al., Reference Hermansen, Jørgensen, Lærke, Manevski, Boelt, Jensen, Weisbjerg, Dalsgard, Danielsen, Asp, Amby-Jensen, Sorensen, Jensen, Gylling, Leindedam, Lübeck and Fog2017). Grass is effective in converting solar radiation into chemical forms of energy and it grows well in humid temperate areas with a capacity for higher biomass and CP production compared to most annual crops (Table 2). Further, existing technology is available for its cultivation, harvesting and ensiling (Wilkinson and Rinne, Reference Wilkinson and Rinne2018). When preserved as silage, the grass biomass can be refined all year round although losses in the protein and water soluble carbohydrates will take place during the fermentation process compared to the parent herbage.

Typically the first step in a green biorefinery process is liquid–solid separation resulting in a liquid fraction containing the soluble components of grass and a fibrous solid fraction. The yield of the fractions depends on the technical solutions of the process, but it is also greatly affected by the raw material characteristics. The ensiling process can even serve as a pretreatment for the biorefinery process, and it may be further improved by using fibrolytic enzymes at the time of harvest as it has increased the liquid yield (Rinne et al., Reference Rinne, Winquist, Pihlajaniemi, Niemi, Seppälä and Siika-aho2017). In the simplest approach, grass juice can be used as a liquid feed to enrich the diet with highly nutritive forage-based component and it is readily consumed by dairy cows and monogastric animals (Rinne et al., Reference Rinne, Keto, Siljander-Rasi, Stefanski and Winquist2018), or the fibre fraction can be used as a feed for ruminants (Savonen et al., Reference Savonen, Franco, Stefanski, Mäntysaari, Kuoppala and Rinne2018). Grass fibre is less lignified than, for example, woods and straw, and milder processes can be used to hydrolyse it (Niemi et al., Reference Niemi, Pihlajaniemi, Rinne and Siika-aho2017). The hydrolysed sugars can further be used for a variety of purposes including direct use as feeds, and as substrates for lactic acid fermentation or SCP production. Green biorefineries have potential to improve local nutrient self-sufficiency, provide new business opportunities for rural communities and to produce ecosystem services such as improved soil structure, carbon sequestration and biodiversity. The high costs related to transportation and processing have to date prevented the development of commercial green biorefineries on a large scale (Xiu and Shahbazi, Reference Xiu and Shahbai2015).

Intensive and extensive ruminant production in the temperate zones: fibrous feeds

Grain legumes as forage

Harvesting grain legume stands as whole crop silage enables the utilisation of nutrients in stems and leaves as well and extending the cultivation in areas where the length of growing season may limit complete seed ripening. Although yield potential and organic matter digestibility (OMD) of grain legume stands are high (Rinne et al., Reference Rinne, Dragomir, Kuoppala, Smith and Yáñez-Ruiz2014; Table 2), data on the effects of grain legume whole crop silages on ruminant performance and product quality is limited. In milk production, white lupin silage resulted in lower total DM intakes, but almost similar bovine lactation performance to maize silage as basal forage (Kochapakdee et al., Reference Kochapakdee, Moss, Lin, Reeves, McElhenney, Mask and Santen2004). In meat production, animal performance has been similar or better when white lupin or pea silages have replaced partially or completely grass silage in cattle or sheep diets (Table 4). Due to their lower fibre concentration relative to grass silage, legume silages may lower ruminal methane emissions (Hristov et al., Reference Hristov, Oh, Firkins, Dijkstra, Kebreab, Waghorn, Makkar, Adesogan, Yang, Lee, Gerber, Henderson and Tricarico2013).

Compared to sole cropping, the bi-cropping of grain legumes and cereals may enhance and stabilise DM yields, reduce weeds and plant diseases and improve N-fixation (Hauggaard-Nielsen et al., Reference Hauggaard-Nielsen, Jørnsgaard, Kinane and Jensen2008). As a forage, grain legume–cereal crop mixtures complement the nutritive value of each other providing an appropriate balance between readily fermentable nutrients and N in the rumen (Watson et al., Reference Watson, Reckling, Preissel, Bachinger, Bergkvist, Kuhlman, Lindström, Nemecek, Topp, Vanhatalo, Zander, Murphy-Bokern and Stoddard2017). Replacing half of the grass silage DM with faba bean–wheat silage had no effect on DM intake or bovine milk, fat and protein yields or feed N conversion efficiency to milk protein (Lamminen et al., Reference Lamminen, Kokkonen, Halmemies-Beauchet-Filleau, Termonen, Vanhatalo and Jaakkola2015). Whole crop faba bean–wheat or pea–wheat silages have successfully replaced grass silage in beef production as well (Table 4). Due to the lower costs of N fertilisers and good yield potential, grain legume silages seem to provide a viable alternative for maize and grass silages both in the intensive and extensive production systems (Table 2). The feeding value and ruminal methane emissions of diets containing forage legumes (lucerne, clovers) have been reviewed elsewhere (Dewhurst, Reference Dewhurst2013).

Temperate wood-derived products

Wood is the most abundant source of carbohydrates worldwide. Principal components of wood are cellulose (400 to 450 g/kg DM) and hemicelluloses (200 to 300 g/kg DM, Sjöström, Reference Sjöström1993). Agroforestry approaches in ruminant nutrition are less common in the temperate areas compared to the tropics or the Mediterranean area. There are, however, some applications where, for example, willow (Salix sp.) production for wood chips and the grazing of ruminants are combined to provide additional benefits such as improved microclimate for the animals, self-medication and soil carbon sequestration, although the potential of the untreated wood-based materials to provide energy and nutrients to high-yielding dairy cows is limited (Smith et al., Reference Smith, Leach, Rinne, Kuoppala and Padel2012 and Reference Smith, Kuoppala, Yáñez-Ruiz, Leach and Rinne2014). Indeed, the in vitro digestibility of DM of untreated wood of various tree species was poor with a range from 0.002 to 0.035 (Millett et al., Reference Millett, Baker, Feist, Mellenberger and Satter1970).

A variety of technologies have been used over decades to improve the digestibility of wood-derived lingo-cellulosic materials. The key is to break the link between the lignin and the cell wall carbohydrates, particularly hemicelluloses, in order to improve the digestibility of ligno-cellulose by rumen microbes. Most pulping and papermaking residues have undergone at least partial delignification. Depending on the process, the residue may contain different proportions of hemicellulose and/or cellulose with or without lignin. The digestibility of pure cellulose is rather high and corresponds to the digestibility of typical ruminant feeds such as cereal grains and good quality forages. Saarinen et al. (Reference Saarinen, Jensen and Alhojärvi1959) determined the in vivo digestibility of 40 wood pulps produced by various pulping methods and reported a range in digestibility from 0.27 to 0.90 depending on the lignin content. The in vivo digestibility of bleached (lignin erased and the pulp whitened) chemical pulp fines from mixed hardwood was 0.78 for DM and 0.86 for carbohydrates (Millett et al., Reference Millett, Baker, Feist, Mellenberger and Satter1973), indicating that the materials have a high energy value for ruminants.

Although wood-derived cellulose can be used as a feed for ruminants, it has higher value as, for example, paper raw material. In contrast, hemicelluloses are a by-product of pulping that are typically burned, and interest of using them as feeds has arisen. Hemicelluloses are not homogeneous compounds but a group of mixed polysaccharides. They can be divided into four groups according to their main type of sugars: xylans, xyloglucans, mannans and β-glucans. Spruce (Picea sp.) and pine (Pinus sp.; softwood) contain somewhat less hemicelluloses than birch (Betula sp.; hardwood) and hemicellulose composition differs between species (Saarinen et al., Reference Saarinen, Jensen and Alhojärvi1959). Glucomannans and galactomannans are the principal hemicelluloses of coniferous trees (spruce and pine) and xylans in deciduous trees (birch) while β-glucans are restricted to grasses.

Hemicelluloses in a liquid form are often called wood molasses or wood sugar concentrates. They have successfully been used as diet components for ruminants at up to 10% of DM intake (Zinn et al., Reference Zinn1990 and Reference Zinn1993; Herrick et al., Reference Herrick, Hippen, Kalscheur, Anderson, Ranatunga, Patton and Abdullah2012). An in vitro gas production experiment revealed that hot water and pressure extracted galactoglucomannan and xylan were readily used as fermentation substrates by rumen microbes of dairy cows fed a grass silage and cereal based diet but arabinogalactan was not (Rinne et al., Reference Rinne, Kautto, Kuoppala, Ahvenjärvi, Willför, Kitunen, Ilvesniemi and Sormunen-Cristian2016). In an in vivo digestibility trial, the OMD of the hot water and pressure extracted galactoglucomannan was 0.591 (Rinne et al., Reference Rinne, Kautto, Kuoppala, Ahvenjärvi, Willför, Kitunen, Ilvesniemi and Sormunen-Cristian2016).

Bark is another component of wood that has limited value in the pulp and sawmill industry. Although wild ruminants consume bark voluntarily, the energy value of it is so low that incorporating it into dairy cow diets resulted in the reduction of milk production (P. Kairenius et al., unpublished results). Thus, some processing would be needed to improve the digestibility of bark. Wood-derived feeds typically have very low N and P concentrations. If the basal diet were high in these nutrients, wood-derived feeds could dilute diets and subsequently increase, for example, the N use efficiency of lactating dairy cows as it is mainly determined by N intake (Huhtanen et al., Reference Huhtanen, Nousiainen, Rinne, Kytölä and Khalili2008). Wood-derived feeds may also provide a source of feed in the case of lack of other feeds, for example, in crisis situations. In general, they may fit best in the diets of animals with low-energy requirements rather than in dairy cow diets in the intensive production systems.

Extensive ruminant production in the tropics: protein supplements

Fodder trees and shrubs

Low-quality forages such as rice (Oryza sativa) straw and pangola (Digitaria eriantha) grass low in protein and high in NDF and ADF are common in ruminant nutrition in the tropics (42, 691 and 424 g/kg DM for rice straw (Heuzé and Tran, Reference Heuzé and Tran2015b) and 5 to 12, 610 to 790 and 350 to 420 g/kg DM for pangola grass (Tikam et al., Reference Tikam, Phatsara, Mikled, Vearasilp, Phunphiphat, Chobtang, Cherdthong and Südekum2013), respectively). Thus, the basal diet is typically much lower in protein and higher in fibre compared to that used in the intensive ruminant production of the temperate zones. In Asian tropics, rice straw is commonly supplemented with cassava (Manihot esculenta) chip rich in soluble carbohydrates but poor in CP (750 to 850 g/kg DM and 20 to 30 g/kg DM, respectively; Wanapat and Kang, Reference Wanapat and Kang2015) and soya bean meal. However, the high price of soya bean meal limits its use in smallholder farming.

Leaves of local fodder trees and shrubs such as cassava, leuceana (Leucaena leucocephala), moringa (Moringa oleifera) and sesbania (Sesbania sesban) often contain almost as much CP as NDF (Table 1), the concentration of former being roughly half of that in soya bean meal. Supplementing the rice straw-based diets with these alternative protein sources increases DM intake, improves microbial protein synthesis in the rumen and the efficiency of rumen fermentation with a shift towards propionate (Table 5; Supplementary Table S4), thus potentially mitigating methane production. These beneficial changes may be due to certain natural secondary compounds present in these alternative feeds, namely condensed tannins and saponins (Wanapat et al., Reference Wanapat, Kang and Polyorach2013).

Table 5 Effect of using tropical fodder tree and shrubs supplementation on feed intake, rumen volatile fatty acid production and milk yield in ruminants fed rice straw based diets

DM=dry matter; TVFA=total volatile fatty acids; C2=acetate; C3=propionate; C4=butyrate; Dec=decrease; –=no effect; Inc=increase; RLS60=40% rice straw+60% leucaena silage fed ad libitum; FHM+CH=75 g flemingia hay meal+75 g cassava hay.

1 References shown in Supplementary Table S5

Combined food–feed production system to provide a year round feeding calendar and to enrich smallholder farming environment is illustrated in Supplementary Figure S1. Under the proposed system, two grass types with (a) erect and tall growth habit and (b) semi-prostrate or prostrate growth habit are used to maximise the biomass production under zero-grazing and grazing, respectively. Roots from cassava can be utilised as a carbohydrate source while the whole top is dried to provide protein (Wanapat, Reference Wanapat2009; Wanapat et al., Reference Wanapat, Foiklang, Ampapon, Mapato and Cherdthong2017). In addition, the leaves of fodder trees and shrubs such as leguminous leucaena, flemingia (Flemingia macrophylla), and moringa are harvested in intervals and used fresh or preserved for later use. The intercropping of cassava with leguminous crops, for example, common bean (Phaseolus calcaratus) and cowpea (Vigna unguiculata), has potential to improve soil fertility and to increase biomass yield (Wanapat, Reference Wanapat2009; Wanapat et al., Reference Wanapat, Foiklang, Ampapon, Mapato and Cherdthong2017). Crop residues such as rice straw, corn stover and sugar cane top are also exploited in ruminant feeding.

Jatrophas

Jatrophas are drought-resistant shrubs or small trees native to American tropics and widely distributed in the tropical and subtropical regions around the world. Jatropha genus includes more than 175 species, Jatropha curcas being one of the most studied species in animal feeding. Jatropha is an interesting biofuel crop due to the high EE concentration of its kernels (570 to 600 g/kg DM; Makkar et al., Reference Makkar, Cooper, Weber, Lywood and Pinkney2012), and the de-fatted kernel residue, jatropha kernel meal, is a good source of nutrients with CP concentration of 620 to 770 g/kg DM (Table 1). In comparison to soya bean protein, jatropha is deficient in lysine, but richer in other essential AA (Table 1; Makkar et al., Reference Makkar, Cooper, Weber, Lywood and Pinkney2012).

The majority of jatropha species are highly toxic to both ruminants and monogastrics due to phorbol esters (1 to 3 mg/g kernel meal; Makkar et al., Reference Makkar, Cooper, Weber, Lywood and Pinkney2012), but they can successfully be detoxified. The complete detoxification is absolutely necessary to avoid animal mortality (Elangovan et al., Reference Elangovan, Gowda, Satyanarayana, Suganthi, Rao and Sridhar2013). In addition, the high concentration of antinutritional factors (trypsin inhibitors, lectin and phytate) may limit the use of jatropha especially for monogastrics unless deactivated by heat treatment and supplemented with phytase enzyme. When completely detoxified, the substitution of soya bean by jatropha has not impaired the DM intake or ADG of sheep and goats (Table 4). Though the yield potential is high (Table 2), the inconsistency of yields of current cultivars is the major restriction for the spread (Heuzé et al., Reference Heuzé, Tran, Edouard, Renaudeau, Bastianelli and Lebas2016b).

All production systems of ruminants worldwide: alternative protein and fibrous feeds

The major advantages of SCP, seaweed and duckweed are the independence of production from arable land and of weather conditions as well as the high and continuous harvests (Nasseri et al., Reference Nasseri, Rasoul-Amini, Morowvat and Ghasemi2011; van der Spiegel et al., Reference Van der Spiegel, Noordam and Fels‐Klerx2013; Table 2). However, cultivation, harvesting, preservation (especially drying) and application in feed in a large scale needs further research (van Krimpen et al., Reference Van Krimpen, Bikker, Van der Meer, Van der Peet-Schwering and Vereijken2013) to lower the production cost of these novel feeds to competitive level. In the long-term, microalgae and duckweed have perhaps the greatest potential to become viable local protein and fibre sources for ruminants worldwide (Table 2; Figure 1).

Single-cell protein

Single-cell protein consists of microbial cells from yeast, bacteria, fungi or microalgae. These micro-organisms can utilise a wide variety of inexpensive feedstocks and wastes as sources of carbon, nutrients and energy for growth to produce biomass rich in protein. The protein content of SCP varies due to culture conditions, species and strains (Lindberg et al., Reference Lindberg, Lindberg, Teräs, Poulsen, Solberg, Tybirk, Przedrzymirska, Sapota, Olsen, Karlson, Jóhannsson, Smárason, Gylling, Knudsen, Dorca-Preda, Hermansen, Kruklite and Berzina2016) but is in the same order as in soya bean expeller (Table 1). The major constraints are the risk for allergens and the accumulation of heavy metals, pesticides and toxins especially if grown on polluted and contaminated substrates, generally high-nucleic acid content (bacteria and yeasts >fungi >microalgae; 60 to 120, 70 to 100, 30 to 80 g/kg DM, respectively) and economical and efficient mass-scale production and harvesting (Nasseri et al., Reference Nasseri, Rasoul-Amini, Morowvat and Ghasemi2011; Lindberg et al., Reference Lindberg, Lindberg, Teräs, Poulsen, Solberg, Tybirk, Przedrzymirska, Sapota, Olsen, Karlson, Jóhannsson, Smárason, Gylling, Knudsen, Dorca-Preda, Hermansen, Kruklite and Berzina2016). Dietary nucleic acids and their derivatives are rapidly degraded in the rumen and certain end-products can be re-used as sources of carbon and N for bacterial growth (McAllan, Reference McAllan1982), but the N in nucleic acids is not as easily available as that of true protein or ammonia.

The basic stages of SCP production process include (a) medium preparation, (b) fermentation or photosynthesis and (c) harvesting and downstream processing like washing, cell disruption, protein extraction and purification (Ravindra, Reference Ravindra2000). The SCP concept was introduced already during the First World War primarily as a human food (Lindberg et al., Reference Lindberg, Lindberg, Teräs, Poulsen, Solberg, Tybirk, Przedrzymirska, Sapota, Olsen, Karlson, Jóhannsson, Smárason, Gylling, Knudsen, Dorca-Preda, Hermansen, Kruklite and Berzina2016). However, the higher production costs of SCP linked to challenges in efficient and economical cell recovery in relation to more conventional foods and feeds is perhaps the main reason why SCP has not reached widespread commercial use so far. Established processes include the use of yeasts Candida lipolytica and Candida tropicalis with alkanes as substrate (product called Toprina), bacterium Methylophilus methtlotrophus with methane as substrate, bacterium Pseudomonas methylotrophus (Pruteen) with methanol as substrate, filamentous fungus Peacilomyces variotii grown on sulphite spent liquor of forest industry sidestream (Pekilo) and yeast Kluveromyces marxianus grown on whey (Nasseri et al., Reference Nasseri, Rasoul-Amini, Morowvat and Ghasemi2011). The reasons why the SCP concept could become more common and economically viable in future are the rising ecoawareness and the need to intensify nutrient and resource utilisation combined with the sharp price rises caused by the prospect of protein scarcity (Lindberg et al., Reference Lindberg, Lindberg, Teräs, Poulsen, Solberg, Tybirk, Przedrzymirska, Sapota, Olsen, Karlson, Jóhannsson, Smárason, Gylling, Knudsen, Dorca-Preda, Hermansen, Kruklite and Berzina2016).

Microalgae

Microalgae are a diverse group of unicellular or simple multicellular microorganisms with widely varying nutritive composition (Table 1). As animal feed, microalgae have several potential uses. Species high in lipids, such as 22:6n-3-enriched Schizochytrium sp., can be used to modify ovine (Bichi et al., Reference Bichi, Hervás, Toral, Loor and Frutos2013) or bovine (Boeckaert et al., Reference Boeckaert, Vlaeminck, Dijkstra, Issa-Zacharia, Van Nespen, Van Straalen and Fievez2008) milk fat healthier for humans in terms of increased trans-11 18:1, cis-9,trans-11 18:2 and n-3 content. Algal 22:6n-3 supplementation has increased also the n-3 content of ruminant meat (Meale et al., Reference Meale, Chaves, He and McAllister2014), but no effects were found on methane production (Moate et al., Reference Moate, Williams, Hannah, Eckard, Auldist, Ribaux, Jacobs and Wales2013). In turn, microalgae or defatted microalgae residues high in CP (e.g. Spirulina platensis and Chlorella vulgaris), or high in carbohydrates can substitute conventional protein (Lamminen et al., Reference Lamminen, Halmemies-Beauchet-Filleau, Kokkonen, Simpura, Jaakkola and Vanhatalo2017) or energy feeds (van Emon et al., Reference Van Emon, Loy and Hansen2015), respectively.

The AA composition of microalgae generally compares favourably to soya bean meal (Becker, Reference Becker2013) and rapeseed meal (Feedipedia, 2018; Luke, 2018), but may vary significantly between species (Table 1). However, in comparison to rapeseed meal and soya bean meal, microalgae protein is often lower in histidine, which is typically the first AA limiting milk production on grass silage and cereal-based diets (e.g. Vanhatalo et al., Reference Vanhatalo, Huhtanen, Toivonen and Varvikko1999). The protein degradability of many microalgae species is suggested to be higher than that of rapeseed (Costa et al., Reference Costa, Quigley, Isherwood, McLennan and Poppi2016; Lamminen et al., Reference Lamminen, Halmemies-Beauchet-Filleau, Kokkonen, Simpura, Jaakkola and Vanhatalo2017), soya bean and cottonseed meals (Costa et al., Reference Costa, Quigley, Isherwood, McLennan and Poppi2016), but this can possibly be affected by the growing and harvesting conditions of microalgae (Lodge-Ivey et al., Reference Lodge-Ivey, Tracey and Salazar2014). Compared to the conventional protein or energy feeds, large doses of microalgae or defatted microalgae residue may impact negatively on feed intake of ruminants depending on microalgae composition (van Emon et al., Reference Van Emon, Loy and Hansen2015; Costa et al., Reference Costa, Quigley, Isherwood, McLennan and Poppi2016; Lamminen et al., Reference Lamminen, Halmemies-Beauchet-Filleau, Kokkonen, Jaakkola and Vanhatalo2016 and Reference Lamminen, Halmemies-Beauchet-Filleau, Kokkonen, Simpura, Jaakkola and Vanhatalo2017). The palatability of microalgae can possibly be improved by feed processing, for example, pelleting (Hintz et al., Reference Hintz, Heitman, Weir, Torell and Meyer1966). Compared to rapeseed meal, microalgae have not affected milk yield, but decreased the milk protein yield of dairy cows in late lactation, which together with decreasing N utilisation for milk production suggests that the protein value of microalgae is possibly slightly lower than that of rapeseed meal (Lamminen et al., Reference Lamminen, Halmemies-Beauchet-Filleau, Kokkonen, Simpura, Jaakkola and Vanhatalo2017), but similar to soya bean protein (Table 3).

The local on-farm production of microalgae in ponds or in closed photoreactors connected to animal drinking water system could lower the energy inputs of feed drying, preservation and transportation making microalgae cultivation in future a viable concept also in the extensive farming. Indeed, microalgae have successively been distributed through drinking water (Panjaitan et al., Reference Panjaitan, Quigley, McLennan and Poppi2010) to growing cattle grazing low quality grasses to improve microbial protein production in the rumen and diet digestibility (Panjaitan et al., Reference Panjaitan, Quigley, McLennan, Swain and Poppi2015). In addition, microalgal-derived renewable biofuels have high potential to replace fossil fuels of diminishing reserves in future. The cost for the biofuels production from microalgae is not yet competitive with fossil fuels, but with advancing technologies and possible government incentives it may soon become profitable (Milano et al., Reference Milano, Ong, Masjuki, Chong, Lam, Loh and Vellayan2016) thus providing defatted microalgae residues for livestock in a mass-scale.

Seaweeds

Seaweeds are complex multicellular organisms growing in salt water or a littoral zone of marine environment (van der Spiegel et al., Reference Van der Spiegel, Noordam and Fels‐Klerx2013). They can be of many different shapes, sizes, colours and composition. Fresh seaweed contains very large amounts of water (700 to 900 g/kg DM) and needs to be consumed quickly or preserved by, for example, drying or ensiling. Brown algae (Phaeophyceae) are of lesser nutritional value than red (Rhodophyceae) and green algae (Chlorophyceae) due to lower CP content (up to 140 v. up to 500 and 300 g/kg DM, respectively). The protein content of marine seaweeds varies between seasons, but in situ rumen degradable protein remains unaffected with high inherent variability between algal species (24% to 51% of CP; Tayyab et al., Reference Tayyab, Novoa-Garrido, Roleda, Lind and Weisbjerg2016). Protein in all seaweeds is typically deficient in essential AA except for methionine (Makkar et al., Reference Makkar, Tran, Heuzé, Giger-Reverdin, Lessire, Lebas and Ankers2016; Table 1).

Seaweeds are low in cellulose (about 40 g/kg DM) but rich in specific complex carbohydrates (e.g. alginate, laminarin and fucoidan). Step-wise increase in the levels of seaweeds in the diet may enable rumen microbes to adapt and utilise these compounds (Makkar et al., Reference Makkar, Tran, Heuzé, Giger-Reverdin, Lessire, Lebas and Ankers2016). Seaweeds concentrate heavy metals and minerals from seawater and contain several times the ash content of land plants that limits their gross energy value and requires regular monitoring (van der Spiegel et al., Reference Van der Spiegel, Noordam and Fels‐Klerx2013; Makkar et al., Reference Makkar, Tran, Heuzé, Giger-Reverdin, Lessire, Lebas and Ankers2016).

Makkar et al. (Reference Makkar, Tran, Heuzé, Giger-Reverdin, Lessire, Lebas and Ankers2016) have recently reviewed in detail the nutritive value of seaweed indicating that some species have the potential to contribute to the protein and energy needs of ruminants (e.g. Macrocystis pyrifera, Palmaria palmatata, Laminaria digitata, Ulva lactuca), while others contain a number of bioactive compounds, which could be used as prebiotics for enhancing production and health status of animals (e.g. Ascophyllum nodosum). Moreover, some seaweed species have shown potential to mitigate ruminal methane production in vitro depending on the basal diet (Maia et al., Reference Maia, Fonseca, Oliveira, Mendonça and Cabrita2016). The seaweeds used for animal feeding can be cultivated or harvested in the wild (Table 4; Makkar et al., Reference Makkar, Tran, Heuzé, Giger-Reverdin, Lessire, Lebas and Ankers2016; Tayyab et al., Reference Tayyab, Novoa-Garrido, Roleda, Lind and Weisbjerg2016) serving to mitigate nutrient loading and to counteract eutrophication processes (Lindberg et al., Reference Lindberg, Lindberg, Teräs, Poulsen, Solberg, Tybirk, Przedrzymirska, Sapota, Olsen, Karlson, Jóhannsson, Smárason, Gylling, Knudsen, Dorca-Preda, Hermansen, Kruklite and Berzina2016). However, high collection rates in the wild have impaired the equilibrium of coastal ecosystems (Makkar et al., Reference Makkar, Tran, Heuzé, Giger-Reverdin, Lessire, Lebas and Ankers2016). In addition, increased cultivation of seaweeds may promote increased production of bromoform, a metabolic by-product of seaweeds that causes the depletion of atmospheric ozone layer (Carpenter and Liss, Reference Carpenter and Liss2000).

Duckweeds

Duckweeds are monocotyledonous, small floating plants with no stems or true leaves of the botanical family Lemnaceae comprising of four genera (Lemna, Spirodela, Wolffia and Wolfiella). Duckweeds are found worldwide, but they grow best in stagnant water between 17.5°C and 30°C (Heuzé and Tran, Reference Heuzé and Tran2015a) and may have a 50% biomass increase every two days (van Krimpen et al., Reference Van Krimpen, Bikker, Van der Meer, Van der Peet-Schwering and Vereijken2013). Thus, duckweed is a potential novel nutrient source for herbivores worldwide. Only few studies have been performed on duckweed in ruminants (van der Spiegel et al., Reference Van der Spiegel, Noordam and Fels‐Klerx2013). Overall, duckweed is consumed well in both dried and fresh forms (Heuzé and Tran, Reference Heuzé and Tran2015a) and it can supply a significant proportion of protein and other nutrients to animals with no significant adverse effects on performance (Cheng and Stomp, Reference Cheng and Stomp2009; Zetina-Cordoba et al., Reference Zetina-Cordoba, Ortega-Cerilla, Ortega-Jimenez, Herrera-Haro, Sanchez-Torres-Esqueda, Reta-Mendiola, Vilaboa-Arroniz and Munguia-Ameca2013).

The duckweed protein is much lower in essential AA histidine, methionine and lysine compared to that of soya bean and rapeseed expeller (Table 1) that may limit duckweed’s production responses relative to them. Estimates of ruminal protein degradability vary widely between 50% and 80% (Heuzé and Tran, Reference Heuzé and Tran2015a). Duckweed contains significant amounts of ash and NDF (Table 1), but has low-lignin content (57 g/kg DM; Heuzé and Tran, Reference Heuzé and Tran2015a). It has therefore potential to substitute also forage (Zetina-Cordoba et al., Reference Zetina-Cordoba, Ortega-Cerilla, Ortega-Jimenez, Herrera-Haro, Sanchez-Torres-Esqueda, Reta-Mendiola, Vilaboa-Arroniz and Munguia-Ameca2013) and minerals (particularly P; van der Spiegel et al., Reference Van der Spiegel, Noordam and Fels‐Klerx2013) in ruminant diets. Nevertheless, high oxalic acid content may restrict the use of duckweed for livestock (van der Spiegel et al., Reference Van der Spiegel, Noordam and Fels‐Klerx2013).

Similarly to microalgae, local on-farm production of duckweed, for example, in ponds may offer a viable concept for ruminant feed production in future. Nutrient scavenging from field runoffs, manure and greywater by duckweeds has potential to reinforce circular economy practices at farm level and to decrease the environmental footprint of ruminant-based food production systems. The very high growth rate (van Krimpen et al., Reference Van Krimpen, Bikker, Van der Meer, Van der Peet-Schwering and Vereijken2013) enables that duckweed could be regularly harvested and fed to animals as fresh. Feeding fresh duckweed also limits the costs related to drying and preservation on-farm. Due to much bigger particle size relative to microalgae, simple mechanical harvesting of duckweed is feasible.

Conclusions

In the short term, the seeds and whole crop forages of N-fixing grain legumes as well as by-products from food and biofuel industries have the greatest potential to replace or supplement traditional crops in ruminant rations in the intensive and extensive production systems in the temperate zones (summarising Figure 1). Lipid-rich camelina expeller, as an example, beneficially modifies the fatty acid composition of ruminant products with potential to mitigate simultaneously enteric methane formation, whereas the oil fraction of seeds could be used as an on-farm biofuel to increase the energy independence of farmers. In the tropics, the leaves of fodder trees and shrubs (e.g. cassava, Leucaena sp., Flemingia sp.) are good protein supplements for ruminants especially in the extensive production systems where the potential to improve diet digestibility and to mitigate enteric methane emissions is the highest. Combined food–feed production system to improve animal productivity and the efficiency of nutrient recycling as well as to decrease footprint on environment is recommended to smallholders (summarising Supplementary Figure S1), whereas detoxified jatropha meals could be suited for larger-scale feed and animal production in the tropics.

In the long term, microalgae and duckweed of high-yield potentials may become economically competitive local protein and fibre sources, respectively, for ruminants worldwide (Figure 1). This is due to the independence of their production from arable land and weather conditions while animal performance and product quality remain comparable to the traditional feeds. Microalgal derived renewable biofuels have a high potential to replace fossil fuels of diminishing reserves in future, thus providing defatted microalgae residues for intensive livestock farming in a mass-scale. Furthermore, on-farm production of microalgae connected to animal drinking water system could lower energy inputs of feed drying, preservation and transportation making microalgae competitive feed ingredient also in extensive farming. Exploitation of vast nutrient reserves in forests both in the temperate and tropical zones warrants further research on their feed value, the breaking of lignin-linkages of wood material and subsequent animal production responses.

Under the climatic conditions changing at an accelerating pace, the ruminant-based livestock systems in both temperate and tropical environments are very flexible in the types of biomasses that can be used as feeds. Despite the environmental footprint of ruminants, their importance in food production system cannot be ignored because of their unique ability to naturally consume fibrous vegetable material not exploitable to humans and other monogastrics and convert it to milk and meat of high nutritive value. Transition to ruminant diets comprising fibrous feed sources supplemented exclusively on alternative and novel feeds has great potential to improve sustainability of ruminant-derived food production, which will not compete with human-edible food materials.

Acknowledgements

This review is presented in The International Symposium on the Nutrition of Herbivores (ISNH) 2018 in Clermont-Ferrand, France. The authors thank organising committee for the invitation.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S1751731118002252

References

Arco-Pérez, A, Ramos-Morales, E, Yáñez-Ruiz, DR, Abecia, L and Martín-García, AI 2017. Nutritive evaluation and milk quality of including of tomato or olive by-products silages with sunflower oil in the diet of dairy goats. Animal Feed Science and Technology 232, 5770.Google Scholar
Bayat, AR, Kairenius, P, Stefański, T, Leskinen, H, Comtet-Marre, S, Forano, E, Chaucheyras-Durand, F and Shingfield, KJ 2015. Effect of camelina oil or live yeasts (Saccharomyces cerevisiae) on ruminal methane production, rumen fermentation, and milk fatty acid composition in lactating cows fed grass silage diets. Journal of Dairy Science 98, 31663181.Google Scholar
Becker, EW 2013. Microalgae for human and animal nutrition. In Handbook of microalgal culture: applied phycology and biotechnology (2nd edition, ed. A Richmond and Q Hu), pp. 461503. Wiley-Blackwell, Chicester, UK.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
Cais‐Sokolińska, D, Pikul, J, Wójtowski, J, Danków, R, Teichert, J, Czyżak‐Runowska, G and Bagnicka, E 2015. Evaluation of quality of kefir from milk obtained from goats supplemented with a diet rich in bioactive compounds. Journal of the Science of Food and Agriculture 95, 13431349.Google Scholar
Carpenter, LJ and Liss, PS 2000. On temperate sources of bromoform and other reactive organic bromine gases. Journal of Geophysical Research 105, 2053920547.Google Scholar
Cheng, JJ and Stomp, AM 2009. Growing duckweed to recover nutrients from wastewaters and for production of fuel ethanol and animal feed. Clean–Soil, Air, Water 37, 1726.Google Scholar
Coskun, D, Britto, DT, Shi, W and Kronzucker, HJ 2017. Nitrogen transformations in modern agriculture and the role of biological nitrification inhibition. Nature Plants 3, 17074.Google Scholar
Costa, DFA, Quigley, SP, Isherwood, P, McLennan, SR and Poppi, D 2016. Supplementation of cattle fed tropical grasses with microalgae increases microbial protein production and average daily gain. Journal of Animal Science 94, 20472058.Google Scholar
Dewhurst, RJ 2013. Milk production from silage: comparison of grass, legume and maize silages and their mixtures. Agricultural and Food Science 22, 5769.Google Scholar
Elangovan, AV, Gowda, NKS, Satyanarayana, ML, Suganthi, RU, Rao, SBN and Sridhar, M 2013. Jatropha (Jatropha curcas) seed cake as feed ingredient in the rations of sheep. Animal Nutrition and Feed Technology 13, 5767.Google Scholar
FAOSTAT 2016. Food and agriculture data. Retrieved on 22 April 2018 from http://www.fao.org/faostat/en/#home.Google Scholar
Feedipedia 2018. Animal Feed Resources Information System. Retrieved on 27 April 2018 from http://www.feedipedia.org/.Google Scholar
Halmemies-Beauchet-Filleau, A, Kokkonen, T, Lampi, AM, Toivonen, V, Shingfield, KJ and Vanhatalo, A 2011. Effect of plant oils and camelina expeller on milk fatty acid composition in lactating cows fed diets based on red clover silage. Journal of Dairy Science 94, 44134430.Google Scholar
Halmemies-Beauchet-Filleau, A, Shingfield, KJ, Simpura, I, Kokkonen, T, Jaakkola, S, Toivonen, V and Vanhatalo, A 2017. Effect of incremental amounts of camelina oil on milk fatty acid composition in lactating cows fed diets based on a mixture of grass and red clover silage and concentrates containing camelina expeller. Journal of Dairy Science 100, 305324.Google Scholar
Hauggaard-Nielsen, H, Jørnsgaard, B, Kinane, J and Jensen, E 2008. Grain legume-cereal intercropping: the practical application of diversity, competition and facilitation in arable and organic cropping systems. Renewable Agriculture and Food Systems 23, 312.Google Scholar
Hermansen, JE, Jørgensen, U, Lærke, PE, Manevski, K, Boelt, B, Jensen, SK, Weisbjerg, MR, Dalsgard, TK, Danielsen, M, Asp, T, Amby-Jensen, M, Sorensen, CA.G, Jensen, MV, Gylling, M, Leindedam, J, Lübeck, M and Fog, E 2017. Green biomass – protein production through bio-refining. DCA Report No. 093. Aarhus University, Denmark. 68 p. Retrieved on 25 November 2017 from www.dca.au.dk.Google Scholar
Herrero, M, Henderson, B, Havlík, P, Thornton, PK, Conant, RT, Smith, P, Wirsenius, S, Hristov, AN, Gerber, P, Gill, M, Butterbach-Bahl, K, Valin, H, Garnett, T and Stehfest, E 2016. Greenhouse gas mitigation potentials in the livestock sector. Nature Climate Change 6, 452461.Google Scholar
Herrick, KJ, Hippen, AR, Kalscheur, KF, Anderson, JL, Ranatunga, SD, Patton, RS and Abdullah, M 2012. Lactation performance and digestibility of forages and diets in dairy cows fed a hemicellulose extract. Journal of Dairy Science 95, 33423353.Google Scholar
Heuzé, V and Tran, G 2015a. Duckweed. Retrieved on 26 July 2017 from https://www.feedipedia.org/node/15306.Google Scholar
Heuzé, V and Tran, G 2015b. Rice straw. Retrieved on 15 December 2017 from https://feedipedia.org/node/557.Google Scholar
Heuzé, V, Tran, G, Delagarde, R, Lessire, M and Lebas, F 2016a. Faba bean (Vicia faba). Retrieved on 26 July 2017 from http://www.feedipedia.org/node/4926.Google Scholar
Heuzé, V, Tran, G, Edouard, N, Renaudeau, D, Bastianelli, D and Lebas, F 2016b. Jatropha (Jatropha sp.) kernel meal and other jatropha products. Retrieved on 23 April 2018 from https://www.feedipedia.org/node/620.Google Scholar
Heuzé, V, Tran, G, Giger-Reverdin, S, Noblet, J, Renaudeau, D, Lessire, M and Lebas, F 2017a. Pea seeds. Retrieved on 26 July 2017 from http://www.feedipedia.org/node/264.Google Scholar
Heuzé, V, Tran, G and Lebas, F 2017b. Camelina (Camelina sativa) seeds and oil meal. Retrieved on 26 July 2017 from http://www.feedipedia.org/node/4254.Google Scholar
Hintz, HF, Heitman, H, Weir, WC, Torell, DT and Meyer, JH 1966. Nutritive value of algae grown on sewage. Journal of Animal Science 25, 675681.Google Scholar
Hristov, AN, Oh, J, Firkins, JL, Dijkstra, J, Kebreab, E, Waghorn, G, Makkar, HPS, Adesogan, AT, Yang, W, Lee, C, Gerber, PJ, Henderson, B and Tricarico, JM 2013. Special topics—mitigation of methane and nitrous oxide emissions from animal operations: I. A review of enteric methane mitigation options. Journal of Animal Science 91, 50455069.Google Scholar
Huhtanen, P, Nousiainen, JI, Rinne, M, Kytölä, K and Khalili, H 2008. Utilization and partition of dietary nitrogen in dairy cows fed grass silage-based diets. Journal of Dairy Science 91, 35893599.Google Scholar
Keske, CM, Hoag, DL, Brandess, A and Johnson, JJ 2013. Is it economically feasible for farmers to grow their own fuel? A study of Camelina sativa produced in the western United States as an on-farm biofuel. Biomass and Bioenergy 54, 8999.Google Scholar
Knapp, JR, Laur, GL, Vadas, PA, Weiss, WP and Tricarico, JM 2014. Invited review: enteric methane in dairy cattle production: quantifying the opportunities and impact of reducing emissions. Journal of Dairy Science 97, 32313261.Google Scholar
Kochapakdee, S, Moss, BR, Lin, J, Reeves, DW, McElhenney, WH, Mask, P and Santen, EV 2004. Evaluation of white lupin, temperate corn, tropical corn, and hybrid pearl millet silage for lactating cows. In Proceedings of the 10th International Lupin Conference, Wild and Cultivated Lupins from the Tropics to the Poles, 19–24 June 2002, Laugarvatn, Iceland, pp. 300–307.Google Scholar
Kruus, K and Hakala, T 2016. The making of bioeconomy transformation. VTT Technicak Research Centre of Finland Ltd. Retrieved on 15 November 2017 from https://makingoftomorrow.com/wp-content/uploads/2017/02/The-Making-of-Bioeconomy-Transformation-2017.pdf.Google Scholar
Lamminen, M, Halmemies-Beauchet-Filleau, A, Kokkonen, T, Jaakkola, S and Vanhatalo, A 2016. Microalgae as a substitute for soya bean meal in the grass silage based dairy cow diets. In Proceedings of 5th EAAP International Symposium on Energy and Protein Metabolism and Nutrition, 12–15 September 2016, Krakow, Poland, pp. 285–287.Google Scholar
Lamminen, M, Halmemies-Beauchet-Filleau, A, Kokkonen, T, Simpura, I, Jaakkola, S and Vanhatalo, A 2017. Comparison of microalgae and rapeseed meal as supplementary protein in the grass silage based nutrition of dairy cows. Animal Feed Science and Technology 234, 295311.Google Scholar
Lamminen, M, Kokkonen, T, Halmemies-Beauchet-Filleau, A, Termonen, T, Vanhatalo, A and Jaakkola, S 2015. Partial replacement of grass silage with faba bean whole-crop silage in the diet of dairy cows. In Proceedings of the 18th Symposium of the European Grassland Federation, Grassland and forages in high output dairy farming systems, 15–17 June 2015, Wageningen, The Netherlands, pp. 446–448.Google Scholar
Lawrence, RD, Anderson, JL and Clapper, JA 2016. Evaluation of camelina meal as a feedstuff for growing dairy heifers. Journal of Dairy Science 99, 62156228.Google Scholar
Lawrence, RL and Anderson, JL 2015. Ruminal degradation and intestinal digestibility of camelina and carinata meal compared with other protein sources. Journal of Dairy Science 98 (suppl. 2), 459.Google Scholar
Lindberg, JE, Lindberg, G, Teräs, J, Poulsen, G, Solberg, , Tybirk, K, Przedrzymirska, J, Sapota, GP, Olsen, ML, Karlson, H, Jóhannsson, R, Smárason, , Gylling, M, Knudsen, MT, Dorca-Preda, T, Hermansen, JE, Kruklite, Z and Berzina, I 2016. Nordic alternative protein potentials: mapping of regional bioeconomy opportunities. Nordic Council of Ministers. Retrieved on 26 July 2017 from http://www.nordic-ilibrary.org/environment/nordic-alternative-protein-potentials_tn2016-527.Google Scholar
Lodge-Ivey, SL, Tracey, LN and Salazar, A 2014. Ruminant nutrition symposium: the utility of lipid extracted algae as a protein source in forage or starch-based ruminant diets. Journal of Animal Science 92, 13311342.Google Scholar
Luke (Natural Resources Institute Finland) 2018. Feed tables and nutrient requirements. Retrieved on 27 November 2018 from www.luke.fi/feedtables.Google Scholar
Maia, MRG, Fonseca, AJM, Oliveira, HM, Mendonça, C and Cabrita, ARJ 2016. The potential role of seaweeds in the natural manipulation of rumen fermentation and methane production. Scientific Reports 6, 32321.Google Scholar
Makkar, HP, Cooper, G, Weber, JA, Lywood, W and Pinkney, J 2012. Biofuel co-products as livestock feed. Opportunities and challenges. Food and Agriculture Organization, Rome, Italy.Google Scholar
Makkar, HP, Tran, G, Heuzé, V, Giger-Reverdin, S, Lessire, M, Lebas, F and Ankers, P 2016. Seaweeds for livestock diets: a review. Animal Feed Science and Technology 212, 117.Google Scholar
McAllan, AB 1982. The fate of nucleic acids in ruminants. Proceedings of the Nutrition Society 41, 309316.Google Scholar
McEniry, J and O’Kiely, P 2014. Chapter 11: developments in grass-/forage-based biorefineries. In Advances in biorefineries - biomas and waste supply chain exploitation, Woodhead Publishing Series in Energy: Number 53 (ed. K Waldron), Library of Congress Control Number: 2014931606, pp. 335–363, Woodhead Publishing, Cambridge, UK.Google Scholar
Milano, J, Ong, HC, Masjuki, HH, Chong, WT, Lam, MK, Loh, PK and Vellayan, V 2016. Microalgae biofuels as an alternative to fossil fuel for power generation. Renewable and Sustainable Energy Reviews 58, 180197.Google Scholar
Millett, MA, Baker, AJ, Feist, WC, Mellenberger, RW and Satter, LD 1970. Modifying wood to increase its in vitro digestibility. Journal of Animal Science 31, 781788.Google Scholar
Millett, MA, Baker, AJ, Feist, WC, Mellenberger, RW and Satter, LD 1973. Pulp and papermaking residues as feedstuffs for ruminants. Journal of Animal Science 37, 599607.Google Scholar
Meale, SJ, Chaves, AV, He, ML and McAllister, TA. 2014. Dose–response of supplementing marine algae (Schizochytrium spp.) on production performance, fatty acid profiles, and wool parameters of growing lambs. Journal of Animal Science 92, 22022213.Google Scholar
Moate, PJ, Williams, RO, Hannah, MC, Eckard, RJ, Auldist, MJ, Ribaux, BE, Jacobs, JL and Wales, WJ 2013. Effects of feeding algal meal high in docosahexaenoic acid on feed intake, milk production, and methane emissions in dairy cows. Journal of Dairy Science 96, 31773188.Google Scholar
Mottet, A, de Haan, C, Falcuccia, A, Tempioa, G, Opioa, C and Gerbera, P 2017. Livestock: on our plates or eating at our table? A new analysis of the feed/food debate. Global Food Security 14, 18.Google Scholar
Nasseri, AT, Rasoul-Amini, S, Morowvat, MH and Ghasemi, Y 2011. Single cell protein: production and process. American Journal of Food Technology 6, 103116.Google Scholar
Niemi, P, Pihlajaniemi, V, Rinne, M and Siika-aho, M 2017. Production of sugars from grass silage after steam explosion or soaking in aqueous ammonia. Industrial Crops and Products 98, 9399.Google Scholar
Orosz, S and Davies, DR 2015. Short and long term storage of wet by-products fed by ruminants. In Proceedings of XVII International Silage Conference, 1–3 July 2015, Piracicaba, Brazil. pp. 200–242.Google Scholar
Panjaitan, T, Quigley, SP, McLennan, SR and Poppi, DP 2010. Effect of the concentration of Spirulina (Spirulina platensis) algae in the drinking water on water intake by cattle and the proportion of algae bypassing the rumen. Animal Production Science 50, 405409.Google Scholar
Panjaitan, T, Quigley, SP, McLennan, SR, Swain, AJ and Poppi, DP 2015. Spirulina (Spirulina platensis) algae supplementation increases microbial protein production and feed intake and decreases retention time of digesta in the rumen of cattle. Animal Production Science 55, 535543.Google Scholar
Pisulewski, PM, Rulquin, H, Peyraud, JL and Verite, R 1996. Lactational and systemic responses of dairy cows to postruminal infusions of increasing amounts of methionine. Journal of Dairy Science 79, 17811791.Google Scholar
Puhakka, L, Jaakkola, S, Simpura, I, Kokkonen, T and Vanhatalo, A 2016. Effects of replacing rapeseed meal with fava bean at 2 concentrate crude protein levels on feed intake, nutrient digestion, and milk production in cows fed grass silage–based diets. Journal of Dairy Science 99, 79938006.Google Scholar
Ravindra, P 2000. Value-added food: single cell protein. Biotechnology Advances 18, 459479.Google Scholar
Rinne, M, Dragomir, C, Kuoppala, K, Smith, J and Yáñez-Ruiz, D 2014. Novel feeds for organic dairy chains. Organic Agriculture 4, 275284.Google Scholar
Rinne, M, Kautto, O, Kuoppala, K, Ahvenjärvi, S, Willför, S, Kitunen, V, Ilvesniemi, H and Sormunen-Cristian, R 2016. Digestion of wood-based hemicellulose extracts as screened by in vitro gas production method and verified in vivo using sheep. Agricultural and Food Science 25, 13–21. Retrieved on 15 December 2017 from http://ojs.tsv.fi/index.php/AFS/article/view/46502.Google Scholar
Rinne, M, Keto, L, Siljander-Rasi, H, Stefanski, T and Winquist, E 2018. Grass silage for biorefinery – palatability of silage juice for pigs and cows. Submitted to XVIII International Silage Conference, 24–26 July 2018, Bonn, Germany.Google Scholar
Rinne, M, Winquist, E, Pihlajaniemi, V, Niemi, P, Seppälä, A and Siika-aho, M 2017. Fibrolytic enzyme treatment prior to ensiling increases press-juice yield from grass silage. In Proceedings of the 8th Nordic Feed Science Conference, 13–14 June 2017, Uppsala, Sweden.Department of Animal Nutrition and Management Swedish University of Agricultural Sciences. Report 296. pp. 71–76. Retrieved on 15 December 2017 from http://www.slu.se/globalassets/ew/org/inst/huv/nfsc/nfsc-2017-proceedings.pdf.Google Scholar
Röös, E, Bajželj, B, Smith, P, Patel, M, Little, D and Garnett, T 2017. Protein futures for Western Europe: potential land use and climate impacts in 2050. Regional Environmental Change 17, 367377.Google Scholar
Saarinen, P, Jensen, W and Alhojärvi, J 1959. On the digestibility of high yield chemical pulp and its evaluation. Acta Agralia Fennica 94, 4164.Google Scholar
Savonen, O, Franco, M, Stefanski, T, Mäntysaari, P, Kuoppala, K and Rinne, M. 2018. Grass silage for biorefinery - dairy cow responses to diets based on solid fraction of grass silage. Nordic Feed Science Conference, 12–13 June 2018, Uppsala, Sweden.Google Scholar
Schader, C, Muller, A, El-Hage Scialabba, N, Hecht, J, Isensee, A, Erb, K-H, Smith, P, Makkar, HPS, Klocke, P, Leiber, F, Schwegler, P, Stolze, M and Niggli, U 2015. Impacts of feeding less food-competing feedstuffs to livestock on global food system sustainability. Journal of Royal Society Interface 12, 20150891.Google Scholar
Sjöström, E 1993. Wood chemistry: fundamentals and applications (293 p. Academic Press, San Diego, CA, USA.Google Scholar
Smith, J, Kuoppala, K, Yáñez-Ruiz, D, Leach, K and Rinne, M 2014. Nutritional and fermentation quality of ensiled willow from an integrated feed and bioenergy agroforestry system in UK. In Proceedings of Maataloustieteen Päivät 2014, 8–9 January 2014, Helsinki, Finland. 9 p. Retrieved on 15 December 2017 from http://www.smts.fi/MTP_julkaisu_2014/Posterit/064Smith_ym_Nutritional_and_fermentation_quality_of_ensiled_willow.pdf.Google Scholar
Smith, J, Leach, K, Rinne, M, Kuoppala, K and Padel, S 2012. Integrating willow-based bioenergy and organic dairy production – the role of tree fodder for feed supplementation. In Proceedings of the 2nd IFOAM Animal Husbandry Conference, 12–14 September 2012, Hamburg, Germany. vTi Agriculture and Forestry Research, Special Issue 362. pp. 417–420. Retrieved on 15 December 2017 from http://orgprints.org/21758/1/Smith_2OAHC%20proceedings_2012.pdf.Google Scholar
Szumacher‐Strabel, M, Cieślak, A, Zmora, P, Pers‐Kamczyc, E, Bielińska, S, Stanisz, M and Wójtowski, J 2011. Camelina sativa cake improved unsaturated fatty acids in ewe’s milk. Journal of the Science of Food and Agriculture 91, 20312037.Google Scholar
Tayyab, U, Novoa-Garrido, M, Roleda, MY, Lind, V and Weisbjerg, MR 2016. Ruminal and intestinal protein degradability of various seaweed species measured in situ in dairy cows. Animal Feed Science and Technology 213, 4454.Google Scholar
Tikam, K, Phatsara, C, Mikled, C, Vearasilp, T, Phunphiphat, W, Chobtang, J, Cherdthong, A and Südekum, KH 2013. Pangola grass as forage for ruminant animals: a review. SpringerPlus 2, 604609.Google Scholar
USDA 2016. Oil crops yearbook 2016. Retrieved on 15 November 2017 from http://usda.mannlib.cornell.edu/MannUsda/homepage.do.Google Scholar
Van der Spiegel, M, Noordam, MY and Fels‐Klerx, HJ 2013. Safety of novel protein sources (insects, microalgae, seaweed, duckweed, and rapeseed) and legislative aspects for their application in food and feed production. Comprehensive Reviews in Food Science and Food Safety 12, 662678.Google Scholar
Van Emon, ML, Loy, DD and Hansen, SL 2015. Determining the preference, in vitro digestibility, in situ disappearance, and grower period performance of steers fed a novel algae meal derived from heterotrophic microalgae. Journal of Animal Science 93, 31213129.Google Scholar
Vanhatalo, A, Huhtanen, P, Toivonen, V and Varvikko, T 1999. Response of dairy cows fed grass silage diets to abomasal infusions of histidine alone or in combinations with methionine and lysine. Journal of Dairy Science 82, 26742685.Google Scholar
Van Krimpen, MM, Bikker, P, Van der Meer, IM, Van der Peet-Schwering, CMC and Vereijken, JM 2013. Cultivation, processing and nutritional aspects for pigs and poultry of European protein sources as alternatives for imported soybean products (No. 662). Wageningen UR Livestock Research, Lelystad, The Netherlands.Google Scholar
Wadhwa, M and Bakshi, MPS 2013. Utilization of fruit and vegetable wastes as livestock feed and as substrates for generation of other value-added products. FAO Publication 2013/04. H.P. Makkar Technical Editor. Retrieved on 15 December 2017 from http://www.fao.org/docrep/018/i3273e/i3273e.pdf.Google Scholar
Wadhwa, M, Bakshi, MP and Makkar, HP 2015. Waste to worth: fruit wastes and by-products as animal feed. CAB Reviews 10, 126.Google Scholar
Wanapat, M 2009. Potential uses of local feed resources for ruminants. Tropical Animal Health and Production 41, 10351049.Google Scholar
Wanapat, M, Foiklang, S, Ampapon, T, Mapato, C and Cherdthong, T 2017. Feeding strategy on farms to improve livestock productivity and reduce methane production. In Proceedings of the 2nd International Conference on Animal Nutrition and Environment, 1–4 November 2017, Khon Kaen, Thailand, pp. 14–29.Google Scholar
Wanapat, M and Kang, S 2015. Cassava chip (Manihot esculenta Crantz) as an energy source for ruminant feeding. Animal Nutrition 1, 266270.Google Scholar
Wanapat, M, Kang, S and Polyorach, S 2013. Development of feeding systems and strategies of supplementation to enhance rumen fermentation and ruminant production in the tropics. Journal Animal Science and Biotechnology 4, 32.Google Scholar
Wasilewko, J and Buraczewska, L 1999. Chemical composition including content of amino acids, minerals and alkaloids in seeds of three lupin species cultivated in Poland. Journal of Animal and Feed Sciences 81, 112.Google Scholar
Watson, CA, Reckling, M, Preissel, S, Bachinger, J, Bergkvist, G, Kuhlman, T, Lindström, K, Nemecek, T, Topp, CFE, Vanhatalo, A, Zander, P, Murphy-Bokern, D and Stoddard, F 2017. Chapter four-grain legume production and use in European agricultural systems. Advances in Agronomy 144, 235303.Google Scholar
White, CL, Staines, VE and Staines, MvH 2007. A review of the nutritional value of lupins for dairy cows. Australian Journal of Agricultural Research 58, 185202.Google Scholar
Wilkinson, JM and Rinne, M 2018. Review. Highlights of progress in silage conservation and future perspectives. Grass and Forage Science 73, 4052.Google Scholar
Xiu, S and Shahbai, A 2015. Development of green bioefinery for biomass utilization: a review. Trends in Renewable Energy 1, 415.Google Scholar
Zetina-Cordoba, P, Ortega-Cerilla, ME, Ortega-Jimenez, E, Herrera-Haro, JG, Sanchez-Torres-Esqueda, MT, Reta-Mendiola, JL, Vilaboa-Arroniz, J and Munguia-Ameca, G 2013. Effect of cutting interval of Taiwan grass (Pennisetum purpureum) and partial substitution with duckweed (Lemna sp. and Spirodela sp.) on intake, digestibility and ruminal fermentation of Pelibuey lambs. Livestock Science 157, 471477.Google Scholar
Zinn, RA 1990. Feeding value of wood sugar concentrate for feedlot cattle. Journal of Animal Science 68, 25982602.Google Scholar
Zinn, RA 1993. Comparative feeding value of wood sugar concentrate and cane molasses for feedlot cattle. Journal of Animal Science 71, 22972302.Google Scholar
Figure 0

Table 1 Chemical composition of some alternative and common feeds for ruminants

Figure 1

Table 2 The suitability for local production of some common and alternative feeds in different production systems, potential yields in Europe, the need of land or water for feed production, and other main environmental aspects regarding crop and ruminant production

Figure 2

Table 3 The effect of some alternative protein feeds on milk production of ruminants

Figure 3

Table 4 The effect of some alternative feeds on the average daily gains (ADG) of ruminants

Figure 4

Figure 1 Rough overview of some feeds for ruminants with respect to time to enter readily on the market, extent of production today and potential to increase utilisation in ruminant nutrition sustainably in future (small red bubble=limited; medium-sized blue bubble=moderate; large green bubble=high). Data adapted in part from FAOSTAT (2016), Kruus and Hakala (2016) and USDA (2016).

Figure 5

Table 5 Effect of using tropical fodder tree and shrubs supplementation on feed intake, rumen volatile fatty acid production and milk yield in ruminants fed rice straw based diets

Supplementary material: File

Halmemies-Beauchet-Filleau et al. supplementary material

Halmemies-Beauchet-Filleau et al. supplementary material 1

Download Halmemies-Beauchet-Filleau et al. supplementary material(File)
File 405.5 KB