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Comparison of different piglet diets in organic agriculture using milk powder, enriched lysine, conventional potato protein or high soybean cake content

Published online by Cambridge University Press:  05 October 2020

Nele Quander-Stoll Open the ORCID record for Nele Quander-Stoll [Opens in a new window] ,
Mirjam Holinger Open the ORCID record for Mirjam Holinger [Opens in a new window] ,
Barbara Früh ,
Werner Zollitsch  and
Florian Leiber Open the ORCID record for Florian Leiber [Opens in a new window]
Nele Quander-Stoll*
Affiliation:
Department of Livestock Sciences, Research Institute of Organic Agriculture (FiBL), 5070Frick, Switzerland
Mirjam Holinger
Affiliation:
Department of Livestock Sciences, Research Institute of Organic Agriculture (FiBL), 5070Frick, Switzerland
Barbara Früh
Affiliation:
Department of Livestock Sciences, Research Institute of Organic Agriculture (FiBL), 5070Frick, Switzerland
Werner Zollitsch
Affiliation:
Institute of Livestock Sciences, BOKU–University of Natural Resources and Life Sciences, 1180Vienna, Austria
Florian Leiber
Affiliation:
Department of Livestock Sciences, Research Institute of Organic Agriculture (FiBL), 5070Frick, Switzerland
*
Author for correspondence: Nele Quander-Stoll, E-mail: nele.quander@fibl.org
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Abstract

Feeding monogastric livestock in organic agriculture is challenging due to several tradeoffs between animal welfare aspects, resource efficiency, as well as ecological and social sustainability. Organic standards may even increase such conflicts, as is currently the case with upcoming new regulations regarding restrictions of feed sources for organic pigs in Europe. In order to contribute data for balancing reasons to minimize tradeoffs, we compared four different piglet diets, each targeted to reach a high protein quality by either a high proportion of soybean cake (SOY), inclusion of milk powder (MILK), fermentatively produced lysine (LYS) or conventional potato protein (POT). All diets were designed to meet the nutritional requirements of piglets in the best possible way, however they all represented different conflicts with either organic regulations or sustainability goals. In each of five consecutive runs, respectively three litters were assigned to every dietary treatment, resulting in 15 litters per treatment in total. In each litter, seven focus animals were defined. The piglets were studied from birth until 58 days of age. They were weaned at day 46 and sold from the farm at day 58. Piglets were individually weighed at an average age of 3, 21, 43, 50 and 58 days with simultaneous assessment of body condition score (BCS) and prevalence of diarrhea. Feed intake (FI) was recorded litter wise weekly, starting from week three. Feed conversion ratio (FCR) was calculated for the period after weaning. Statistical analysis was executed using linear mixed effect models. Regarding FI, FCR and daily weight gains, no treatment effect was found. Only at day 21, BCS was lower for piglets receiving POT. Prevalence of diarrhea increased after weaning for all treatments. All four tested diets led to similar weight gains and feed conversion in the piglets. Animals fed diet POT recovered better from diarrhea compared to the other treatments. A high soybean cake content or lysine supplementation in the diet was disadvantageous with regard to the occurrence of diarrhea. LYS diet led to signs of threonine deficit, indicating that lysine addition alone may not solve the issue. The addition of milk powder provided no extra benefit. In recognition of the health benefits, the use of 5% potato protein, even if it is sourced from conventional production, must still be considered as a sustainable option for feeding organic piglets. The sustainability implications are discussed in the paper.

Keywords

Amino acid supplyanimal healthdiet compositiongrowth rateorganic pig nutrition
Type
Research Paper
Information
Renewable Agriculture and Food Systems , Volume 36 , Issue 3 , June 2021 , pp. 245 - 254
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Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press

Introduction

Since more than 10 years, the goal of using 100% organic diets has been pursued for monogastric animals in European organic regulations, but the final implementation has been repeatedly delayed. This illustrates skepticism and concerns about the feasibility of diets consisting of 100% organic feedstuffs. As long as 5% conventional components are still permitted in diets for pigs, for example conventional potato protein is used depending on availability and region. Potato protein, which is a by-product of the potato starch industry, has an advantageous amino acid profile and thus improves the protein quality. However, it is not available in organic quality in sufficient quantities. According to Sundrum et al. (Reference Sundrum, Schneider and Richter2006) and Schumacher et al. (Reference Schumacher, Fidelak, Koopmann, Weißmann, Snigula, Brüggemann, Naatjes, Simoneit and Bender2011) concerns are that an adequate supply with amino acids can no longer be guaranteed and animals may show a reduced health status and performance losses when 100% organic components will be prescribed. When the new EU regulation comes into force (January 1, 2021), conventional protein feed will only be permitted for piglets up to a live weight of 35 kg until December 31, 2025 (The Council of the European Union, 2018), and in Switzerland, according to the current guidelines for Organic Agriculture (Bio Suisse, 2020), 100% organic components will even be compulsory for piglets after the end of the transitional period (December 31, 2022).

The conditions for implementation of the 100%-rule may not be optimal: in Europe, the degree of self-sufficiency for organic protein feed is low, which leads to high nutrient imports (Früh et al., Reference Früh, Schlatter, Isensee, Maurer and Willer2015). Although the proportion of self-produced soybeans is increasing in Europe, it is not enough for achieving a high self-supply. Due to the elimination of potato protein, the import of soybean products from overseas is expected to increase (Witten et al., Reference Witten, Paulsen, Weißmann and Bussemas2014). This is in contradiction to a guiding principle of organic farming: the establishment of an almost complete nutrient cycle within an agricultural system and the use of predominantly regionally sourced components, which are preferably even produced on farm (Sundrum, Reference Sundrum2001; Zollitsch, Reference Zollitsch2007; Smith et al., Reference Smith, Gerrard and Hermansen2014). In purely plant-based organic diets, the protein content usually must be higher than in conventional diets to achieve an adequate supply with sulfur-containing amino acids, because according to European organic regulations the supplementation with free amino acids is not allowed (The Council of the European Union, 2007).

On the other hand, in order to produce meat, high quality feed protein is needed to ensure high nitrogen efficiency. The primary objective of diet formulation is to meet the nutritional requirements of the animals and thus ensure adequate growth performance and health. Provision of amino acids adequate to requirements in conventional systems shall ensure optimal nitrogen efficiency and lowest possible emissions. Thus, the ban of purified amino acids according to organic feeding standards may increase antagonisms between animal welfare, sustainability and feed efficiency. The allowance to organic pigs of eating roughage or having pasture access for well justified welfare and health reasons (Holinger et al., Reference Holinger, Früh, Stoll, Graage, Wirth, Bruckmaier, Prunier, Kreuzer and Hillmann2018) may even sharpen this problem, and with a prescription of 100% organic components the stated antagonisms are the more expected to rise. Therefore, it is of particular importance to develop diets that serve animal requirements, ecology, sustainability and organic standards in a best possible balance. Many examples of 100% organic feed rations show that it is generally possible to formulate diets without the use of non-organic feed components (Stalljohann, Reference Stalljohann2006; Baldinger et al., Reference Baldinger, Bussemas, Höinghaus, Renger and Weißmann2017; Schwediauer et al., Reference Schwediauer, Hagmüller and Zollitsch2018). However, concerning young animals, Witten et al. (Reference Witten, Paulsen, Weißmann and Bussemas2014) pointed out that a supply gap is likely to occur, due to the insufficient availability of high-quality protein components.

On the background of these multiple challenges, our aim was to assess several different options for the feeding of organic piglets. Bearing in mind the mentioned conflicts, which do not appear to be fully solvable, we considered four different diets, each of which implied one or several target conflicts or violations of standards, but was designed to fulfill nutrient requirements of piglets to the best possible degree. The aim was to assess their equivalence or failure to compete in health and weight development of piglets, in order to provide a basis for discussion of suitable organic diets, including a challenge toward the existing rules. As the basis for comparison, a current Swiss organic piglet diet was set, including 5% potato protein from conventional sources. This diet would violate regulations in due future but provide an appropriate amino acid profile. Furthermore, a diet was considered, where the potato protein was replaced mainly by soybean cake, which would increase import dependency of the system. In a third diet, milk powder was included, which should provide a high amino acid quality, but is in strong feed-food competition (Ertl et al., Reference Ertl, Knaus and Zollitsch2016). Finally, we designed a fourth diet using fermentatively produced lysine as an additive, to improve the amino acid supply, which is the usual option in conventional feed formulations, but again would violate the organic standards. Our aim was to compare these four approaches, and the null-hypothesis was that they would not differ with regard to health and growth of piglets.

Animals, materials and methods

Animals and experimental schedule

The experiment was carried out with approval by the responsible veterinary authority in Aarau, Switzerland (Approval No. AG 75701). The on-farm feeding experiment with piglets was performed on an organic pig farm in Switzerland between May 2017 and February 2018. Animals were housed and managed according to the Swiss Regulation for Organic Agriculture (Bio Suisse, 2020). Landrace × Large White crossbred sows were inseminated with semen from Duroc or Large White boars. Three days before farrowing, sows were transferred to single pens with a piglet nest. Pen size was 7.5 m2 and the concrete floor was covered with straw. Three weeks after farrowing, sows and piglets were moved to a different single pen (7.5 m2), including a larger nest for piglets and with access to a concrete outdoor run (6 m2). According to the farrowing pattern, new experimental piglets were included every 6 weeks. Duration of the suckling period was 46 days, after which the sows were separated from the piglets, which remained in the pen. After weaning, the experiment continued until the piglets were sold to a fattening farm at 58 days of age.

In five consecutive runs, a total of 445 piglets were used. Every run comprised of 12 litters, each in a separate pen. The assignment of treatments to pens rotated in every run. This allowed assigning piglets from three litters to one out of four treatments each. At an age of 3 days (±2), litters were assigned randomly to one of the four treatments and piglets were marked with experimental ear tags. Per run, three litters received the same experimental diet. From each litter seven animals were selected as focal animals and examined for their growth performance, body condition (score) and occurrence of diarrhea. Selection of the focal piglets included in the experiment was carried out randomly but was balanced for numbers of female and male animals.

Piglets were weighed and iron injections were administered at the third day of life, and male piglets were surgically castrated at an age of 5 to 12 days under anesthesia and application of analgesic drugs. Subsequently, piglets were weighed individually again at 21 (±2), 43 (±2), 50 (±2) and 58 (±2) days of age (Kern IFB 30K5DMCH scale, sensitivity: 5 g; Swiss Waagen DC GmbH, Bertschikon, Switzerland). At the same time each animal was assessed for body condition score (BCS) corresponding to Doyle et al. (Reference Doyle, Groat, Wynn and Holyoake2015). The score ranked from 1 to 3 (1 = very compromised; 2 = moderately compromised; 3 = healthy). Of particular interest was the BCS after weaning to determine whether weaning problems had occurred which might have resulted in a decrease in body condition. Piglets with a BCS below two were defined as being under-conditioned (UC). At every assessment, each animal was also scored for diarrhea (0 = no diarrhea: formed feces; 1 = slight diarrhea: pasty feces; 2 = moderate diarrhea: liquid/pasty feces; 3 = severe diarrhea: liquid/watery feces) (Almeida et al., Reference Almeida, Martins, Abrahão, Andrade, Moreno, Parazzi, Del Santo and Moretti2012). The occurrence of diarrhea was only assessed visually; no feces samples were analyzed and thus no pathogen detection was made. For the evaluation of feed intake (FI), two periods were considered separately: 25 days before and 12 days after weaning (from weaning to selling). Feed conversion ratio (FCR), i.e., ratio between average daily FI and average daily weight gain (ADG) was calculated for the second period only, when the piglets consumed no milk anymore.

Diets

Four basal piglet diets were prepared using common organic components (barley, oats, pea, soybean cake, rapeseed cake and faba bean). Different supplements were added to this basal diet, representing four different dietary treatments: The diet SOY as a purely vegetable ration without any other high-quality protein sources contained the highest proportion of soybean cake (13.4%). In the diet MILK, the use of 3% milk powder enabled a 21.6% reduction in soybean cake (compared to diet SOY). In the diet LYS, fermentatively produced lysine was added and thus the crude protein content reduced. The use of 0.24% ‘VitaLys’ enabled a soybean cake reduction of 29.1%. The used lysine preparation ‘VitaLys’ was fermentatively produced by GMO-free coryne bacteria. It was not purified and consisted of 58% pure lysine, 20% lysine-sulfate, 20% other amino acids and 2% water. Furthermore, diet LYS contained 5% sunflower cake instead of rapeseed cake. In diet POT, soybean cake was reduced and replaced with 5% conventional potato protein. All diets were adjusted for the same concentrations of lysine and methionine. This resulted in differences between the diets regarding their crude protein contents, which were slightly higher for SOY and MILK as compared to POT and LYS (Table 1).

Table 1. Composition of the four experimental diets for piglets

SID, standardized ileal digestible.

a Further components: cider vinegar, stone dust, premix, soybean oil, molasses, calcium carbonate, coal, sodium chloride, life yeast.

b Values as predicted by the feed mill.

Feed was offered to piglets starting from the third week of life. The feeders were refilled twice daily (morning and evening) to provide ad libitum feed supply. Feed leftovers were weighed back once a week to determine the weekly feed consumption on pen basis and thus the average daily FI per day and animal. For treatments SOY, MILK and LYS the sows’ feed has also been optimized to 100% organic components (one diet for all sows). Sows of POT were given a common diet consisting of 95% organic feed components and 5% conventional potato protein.

Feed analysis

Samples of the four different diets were taken from each feed batch, which was delivered from the feed mill. In order to make the samples durable, samples were dried for 24 h at 60°C in a drying cabinet. Afterward samples were analyzed for nutrient contents according to VDLUFA (2007) at the Agricultural Research Institute Speyer, Germany. Dry matter was determined at 105°C. The crude protein content was determined by the DUMAS combustion method (4.1.2). Ether extracts were analyzed according to method A of 5.1.1. The crude fiber content was determined according to 6.1.1 and ash according to 8.1. The amino acids lysine, methionine, cysteine and threonine were analyzed following method 4.11.1 of VDLUFA (2007). The metabolizable energy content (MJ ME kg−1) declared by the feed mill that produced the experimental piglet diets was used as an estimate.

Statistical analysis

The statistical analyses were conducted with software R, version 3.6.1 (R Core Team, 2017). (General) Linear mixed effects models were applied, considering diet, age/time of measurement and their interaction as fixed effects (Table 2). Nested random effects were used, which were measurement within animal within litter within run. Sow was considered as cross random effect and birth weight as covariable. Models for weight, ADG and BCS were calculated using the function ‘lmer’ from the ‘lme4’ package in R (Bates et al., Reference Bates, Mächler, Bolker and Walker2015). FI and FCR (kg FI kg−1 weight gain) were measured at the pen level, and statistical analysis was conducted using the function ‘lm’. FI and FCR were analyzed separately for the periods before and after weaning. The model residuals were examined visually for deviations from normal distribution and homoskedasticity. The variable weight was log transformed to meet model assumptions (Table 2).

Table 2. Description of statistical models

First, the full model including all fixed effects and interactions was compared to the zero model with the intercept only. Further steps were only carried out if this comparison resulted in a P-value of <0.05. Reduced models were calculated without the effect or interaction of interest. Comparing these reduced models with the full model using sum contrasts, yielded interpretable results for the main effects, even if there was a significant interaction. P-values for main effects and interactions were obtained by comparing reduced models to the full model in a parametric bootstrap approach with 1000 simulations, employing the function ‘PBmodcomp’ from the package ‘pbkrtest’ (Halekoh and Højsgaard, Reference Halekoh and Højsgaard2014). Afterward model estimates and confidence intervals were obtained with 1000 parametric bootstrap simulations for mixed models with the function ‘bootMer’ in ‘lme4’ (Bates et al., Reference Bates, Mächler, Bolker and Walker2015). Model estimates were always calculated for the full model under consideration of all fixed effects and interactions (Forstmeier and Schielzeth, Reference Forstmeier and Schielzeth2011).

The variables ‘under-conditioned piglets’ (BCS < 2) and the occurrence of diarrhea (in total and severe) were coded as binary variables and analyzed using the function ‘glmer’ (‘lme4’ package). In case of significant interactions between diet and age or a significant effect of diet, pairwise comparisons using the function ‘emmeans’ from the package ‘emmeans’ (Lenth et al., Reference Lenth, Singmann, Love, Buerkner and Herve2020) were conducted to determine which treatments differed at which time of measurement. Statistical differences were considered to be significant when P < 0.05. Only P-values <0.1 are reported.

Results

Feed intake

No difference was found for both time periods between the treatments in terms of FI (Table 3). Numerically, piglets of LYS consumed more feed after weaning. Setting the feed consumption in relation to the ADG, the best FCR (Table 3) was obtained for diet MILK with 1.78, then POT with 1.84, SOY with 1.89 and LYS scored the worst with 2.16, but without a statistically significant effect of treatment.

Table 3. Average daily feed intake and feed conversion ratio per animal

During the first survey period (days 21–46) additional milk was consumed via the mother.

1FI, average daily feed intake per animal; 2FCR, average feed conversion ratio.

Growth performance and body condition score

The comparison of the four treatments showed no difference in the piglets' body weight (Fig. 1). Results showed an interaction between diet and piglets’ age (Fig. 1). MILK and LYS showed a steeper increase in weight development. However, at the end of the experiment (58 days of age) all piglets reached similar weights. Furthermore, birth weight, which was considered as covariate in the model, had a positive effect on weight at later sampling dates.

Fig. 1. Weight development of piglets fed organic diets supplemented with either conventional potato protein (POT), lysine (LYS), milk powder (MILK) or containing a high proportion of soybean cake (SOY). Lines represent model estimates. Diet P = 0.97, Age P < 0.001, Diet × Age P < 0.001.

Correspondingly, there were no treatment effects for ADG either. An effect of time of measurement and an interaction between diet and time of measurement was found (Fig. 2). The birth weight also had a positive effect. For the BCS an influence of diet, age and an interaction between diet and age was found. This is due to POT, which had a lower BCS than MILK at 21 (±2) days of age (Table 4). The BCS increased for POT from day 21 to 58, while it remained the same for the other treatments. In addition, a positive effect of birth weight was found (P = 0.001). The proportion of UC animals was affected by an interaction between diet and age and by diet. Birth weight was correlated with a lower proportion of UC piglets (P = 0.04).

Fig. 2. Average daily weight gain of piglets fed organic diets supplemented with either conventional potato protein (POT), lysine (LYS), milk powder (MILK) or containing a high proportion of SOY. Lines represent model estimates. Diet P = 0.28, Time of measurement P < 0.001, Diet × Time of measurement P = 0.002.

Table 4. Average body condition score and prevalence of diarrhea of piglets fed different diets

1BCS, body condition score.

2 UC: proportion of under-conditioned piglets (BCS < 2).

3 DT: proportion of diarrhea-affected animals (in total, severity 1–3).

4 DS: proportion of piglets suffering from severe diarrhea.

a–b Numbers with different superscripts are significantly different between treatments at P < 0.05.

Prevalence of diarrhea

The total prevalence of diarrhea increased sharply after weaning, so that 5 days post weaning 21.2–44.4% of the animals were affected and 15.1–28.9% suffered from severe diarrhea (Table 4). For total prevalence of diarrhea, no effect of diet, but an effect of age and an interaction of diet and age was found. At the last measurement (58 (±2) days of age), prevalence of diarrhea declined, but treatments SOY, MILK and LYS had a higher proportion of diarrhea-affected animals (P < 0.001) than POT. For severe diarrhea, an effect of diet, age and interaction of diet and age was found.

Discussion

With the aim of obtaining well-balanced piglet rations for organic farming, considering growth performance, health and nutrient efficiency, we tested four different diets, which were all designed in order to fulfill the nutritional requirements and be as close as possible compliant with the organic standards as by The Council of the European Union (2018). The aim was to use widely available organic feed components to achieve the lowest possible protein content at sufficient amino acid supply. Every diet suffered from different inadequacies according to organic production standards or ecological targets: for diet POT, a conventional component (potato protein) was used, which will be banned in the near future in the EU (The Council of the European Union, 2018). Diet LYS contained a lysine additive, which is currently not allowed according to organic regulations (The Council of the European Union, 2007); diet MILK contained organic milk powder, which is allowed, but problematic from a feed–food-competition perspective (Ertl et al., Reference Ertl, Knaus and Zollitsch2016). Diet SOY consisted of plant-based components only, but the high proportion of soybean cake implies critical aspects concerning nitrogen imports, globalized land use, including socio-economic consequences in the regions of origin and transport distances, if it is not produced by the farm itself.

Compliance of the diets with sustainability targets and organic standards

Soybean cake is used in diets for pigs due to its advantageous amino acid profile (NRC, 2012). However, several studies (Meul et al., Reference Meul, Ginneberge, Van Middelaar, De Boer, Fremaut and Haesaert2012; Reckmann et al., Reference Reckmann, Blank, Traulsen and Krieter2016; Saxe et al., Reference Saxe, Hamelin, Hinrichsen and Wenzel2018) on the carbon footprint and other impact categories for soy-based pig diets emphasize the need to reduce the feeding of soybean products and rather use other protein components or isolated amino acids. Although a reduction of soybean imports would be desirable, soybean cake is one of the few components available in organic quality to enhance the amino acid profile and was used in our experiment because Swiss feed mills would offer a piglet diet in this composition if 100% organic feeding was introduced. Aiming at an appropriate amino acid supply, the protein content of diet SOY in the present study had to be higher than in all other formulations, which implied lower protein efficiency and higher nitrogen emissions (Dourmad and Jondreville, Reference Dourmad and Jondreville2007).

The use of milk powder in diet MILK reduced soybean cake content by more than 20%. Milk powder is characterized by a good amino acid composition and high digestibility. It is an optimal feed component for piglets because it also improves the acceptance of the diet and promotes the development of the digestive tract (Le Huërou-Luron et al., Reference Le Huërou-Luron, Bouzerzour, Ferret-Bernard, Ménard, Le Normand, Perrier, Le Bourgot, Jardin, Bourlieu, Carton, Le Ruyet, Cuinet, Bonhomme and Dupont2018). According to Stalljohann (Reference Stalljohann2006), milk powder is essential to optimize piglet diets without potato protein and thus make 100% organic feeding possible. Many studies showed that the use of animal sourced proteins such as milk powder in piglet diets prevented behavioral disorders (manipulative, agonistic and abnormal behavior) and led to better performance (Araújo et al., Reference Araújo, Ferreira, Renaudeau, Brustolini and Silva2010; Bouzerzour et al., Reference Bouzerzour, Morgan, Cuinet, Bonhomme, Jardin, Le Huërou-Luron and Dupont2012; Pluske et al., Reference Pluske, Turpin and Kim2018). However, since milk is a high value human food source, such a piglet diet would have negative impact with respect to feed–food-competition, which is undesirable (Schader et al., Reference Schader, Muller, El-Hage Scialabba, Hecht, Isensee, Erb, Smith, Makkar, Klocke, Leiber, Schwegler, Stolze and Niggli2015; Ertl et al., Reference Ertl, Knaus and Zollitsch2016). Due to its high price, the use of organic milk powder also increases the feed costs.

By using fermentatively produced lysine in diet LYS, it was also possible to reduce the proportion of soybean cake and to achieve a lower dietary protein content. The use of fermentatively produced amino acids has numerous advantages and would be a good supplement to regional non-soy components. All amino acids can be produced by fermentation, except for methionine, for which no economically sufficient quantities are achieved (Kumar and Gomes, Reference Kumar and Gomes2005; Leiber and Früh, Reference Leiber and Früh2014). Therefore the question arises as to whether supplementation of organic diets for monogastric livestock with isolated amino acids from fermentation should be permitted in the future in order to reduce the protein content and, subsequently, nitrogen emissions (Dourmad and Jondreville, Reference Dourmad and Jondreville2007; Garcia-Launay et al., Reference Garcia-Launay, Van Der Werf, Nguyen, Le Tutour and Dourmad2014; Liu et al., Reference Liu, Ni, Radcliffe and Vonderohe2017). According to Philippe et al. (Reference Philippe, Cabaraux and Nicks2011), per 10 g less protein per kg feed, the N excretions are reduced by about 10%. By adding isolated amino acids, the protein content can be lowered without compromising ADG or carcass quality. However, isolated amino acids, even if they are produced by fermentation, originate from a highly technological process, which is in conflict with the aim of naturalness of production (IFOAM, 2014).

The fourth experimental diet, POT, represented the common diet for piglets, which is currently dominating in European organic piglet production. Potato protein is an industrial by-product of potato starch production. It is highly digestible and contains comparably high proportions of essential, limiting amino acids such as lysine (Waglay et al., Reference Waglay, Karboune and Alli2013; Gorissen et al., Reference Gorissen, Crombag, Senden, Huub Waterval, Bierau, Verdijk and van Loon2018). Potato protein allowed for almost 60% lower inclusion of soybean cake as compared to SOY. It currently has the greatest potential for optimizing diets, but it is of conventional origin and will be phased out in the near future (The Council of the European Union, 2018).

Physiological limitations of the different diets

The experimental investigation within a feeding trial should provide information about the physiological suitability of the diets tested. This was verified by performance parameters (ADG, FI and FCR) and health traits (BCS and diarrhea occurrence).

Although diet LYS was optimized by adding lysine and the crude protein content was reduced, other amino acids probably became limiting (Nyachoti et al., Reference Nyachoti, Omogbenigun, Rademacher and Blank2006; Jayaraman et al., Reference Jayaraman, Htoo and Nyachoti2015). This resulted in a deficiency of standardized ileal digestible (SID) sulfur-containing amino acids: 0.59 relative to lysine, instead of 0.64 and threonine: 0.58 relative to lysine, instead of 0.65 to 0.7, which is recommended for piglets between 7 and 25 kg (NRC, 2012; Zhang et al., Reference Zhang, Xie, Thacker, Htoo and Qiao2013; Jayaraman et al., Reference Jayaraman, Htoo and Nyachoti2015). Methionine frequently is the second limiting amino acid for pigs and is essential for numerous processes in the body, including the maintenance and functionality of the small intestine. A deficiency in sulfur-containing amino acids can impair the growth performance and feed conversion of piglets (Fang et al., Reference Fang, Yao, Zhang, Zhao, Sun, Tian, Yu, Lin, Zhu, Jia, Zhang, Chen and Wu2010; Chen et al., Reference Chen, Li, Dai, Piao, Wu, Wang, Zhu and Zeng2014). A threonine deficit can lead to higher FI and lower ADG (Hamard et al., Reference Hamard, Sève and Le Floc'h2007; Fernández and Strathe, Reference Fernández and Strathe2009). This could explain the higher FI and the poorest FCR for LYS (Table 3). It could indicate that threonine was used for building and maintaining the gastro-intestinal tract rather than for muscle protein synthesis (Schaart et al., Reference Schaart, Schierbeek, Sophie and Stoll2005; Law et al., Reference Law, Bertolo, Adjiri-Awere, Pencharz and Ball2007; Wang et al., Reference Wang, Zeng, Mao, Wu and Qiao2010).

The FCR achieved by our experimental piglets was comparable to other studies, even if our ADG were rather below average in comparison (Baldinger et al., Reference Baldinger, Hagmüller, Minihuber, Matzner and Zollitsch2014, Reference Baldinger, Hagmüller, Minihuber, Schipflinger and Zollitsch2015; Schwediauer et al., Reference Schwediauer, Hagmüller and Zollitsch2018). The flat slope of the growth curve in the current experiment was likely due to a significant proportion of animals suffering from diarrhea (Table 4), which caused ADG to stagnate, although individual healthy animals had daily gains of 0.6–1.0 kg (data not shown).

In addition to body weight, the BCS is an important parameter for the external assessment of an animal in order to find slightly or severely emaciated animals and to take measures if necessary. A healthy piglet should have a BCS of 3.0 (Doyle et al., Reference Doyle, Groat, Wynn and Holyoake2015). The average BCS in our trial was about 2.7 in all treatments. Since a BCS of 3.0 is indicating good health (Doyle et al., Reference Doyle, Groat, Wynn and Holyoake2015), an average BCS of 2.7 conveys the impression that the animals were in a good body condition. However, the ADG stagnated due to the high incidence of diarrhea, so the question arises whether in this case the BCS was suitable as a diagnostic tool. The temporarily lower BCS in POT at an age of 21 (±2) days can be explained by the accidentally greater litter size of the sows (two piglets more). However, the proportion of UC piglets was below 3%, which can be considered to be low, as Wlcek et al. (Reference Wlcek, Hagmüller, Leeb, Stark, Ölzant and Böhm2015) recommend less than 10% UC sows and less than 4% runts in piglets.

After weaning, animals in all treatments suffered from diarrhea, with SOY and LYS tending to have higher proportions of diseased animals. For the last survey, it was noticeable that animals of POT recovered faster from diarrhea than piglets in the other treatments. As no feces samples were analyzed and therefore no pathogen detection was available which could have explained the occurrence of diarrhea, it is difficult to determine the cause of diarrhea in the feed composition. Nevertheless, the diets should be discussed with regard to their composition and in connection with the occurrence of diarrhea.

Due to allergenic proteins in soybeans (Wu et al., Reference Wu, Zhang, Dong, Cao, Li, Feng, Ding, Ma, Wang and Li2016; Zheng et al., Reference Zheng, Qin, Chen and Zhang2018), piglets can show a hypersensitivity to soy. There is little evidence for maximum inclusion rates of soybean cake, but Stoll (Reference Stoll2004) and Lindermayer et al. (Reference Lindermayer, Probstmeier and Preißinger2010) recommend limiting the use of soybean cake for piglets to 10%, respectively 12%, a threshold, which was crossed with diet SOY. This may have contributed to the occurrence of tenacious diarrhea. In case of LYS, a relative threonine deficiency could be one cause of prolonged diarrhea (Law et al., Reference Law, Bertolo, Adjiri-Awere, Pencharz and Ball2007), which underlines that adding lysine alone would offer no solution. For diet MILK, it was surprising that the proportion of diarrhea-affected animals was also quite high and that it lasted longer than in POT (Table 4). Various studies show that the type of protein source influences both the development of the digestive tract and its microflora (Bouzerzour et al., Reference Bouzerzour, Morgan, Cuinet, Bonhomme, Jardin, Le Huërou-Luron and Dupont2012; Poulsen et al., Reference Poulsen, Jonge de, Sugiharto, Nielsen, Lauridsen and Canibe2017). Animal protein sources such as milk powder in piglet diets are beneficial for intestinal development and health, especially after weaning (higher FI and feed conversion) (Vente-Spreeuwenberg et al., Reference Vente-Spreeuwenberg, Verdonk, Bakker, Beynen and Verstegen2004; Lange et al., Reference Lange de, Pluske, Gong and Nyachoti2010; Le Huërou-Luron et al., Reference Le Huërou-Luron, Bouzerzour, Ferret-Bernard, Ménard, Le Normand, Perrier, Le Bourgot, Jardin, Bourlieu, Carton, Le Ruyet, Cuinet, Bonhomme and Dupont2018). Our expectation was therefore a positive effect of milk powder. The amount of milk powder used may have been too small to have a positive effect in our feeding trial.

Due to allergenic proteins in soybeans (Wu et al., Reference Wu, Zhang, Dong, Cao, Li, Feng, Ding, Ma, Wang and Li2016; Zheng et al., Reference Zheng, Qin, Chen and Zhang2018), piglets can show a hypersensitivity to soy. There is little evidence for maximum inclusion rates of soybean cake, but Stoll (Reference Stoll2004) and Lindermayer et al. (Reference Lindermayer, Probstmeier and Preißinger2010) recommend limiting the use of soybean cake for piglets to 10%, respectively 12%, a threshold, which was crossed with diet SOY. This may have contributed to the occurrence of tenacious diarrhea. In case of LYS, a relative threonine deficiency could be one cause of prolonged diarrhea (Law et al., Reference Law, Bertolo, Adjiri-Awere, Pencharz and Ball2007), which underlines that adding lysine alone would offer no solution. For diet MILK, it was surprising that the proportion of diarrhea-affected animals was also quite high and that it lasted longer than in POT (Table 4). Various studies show that the type of protein source influences both the development of the digestive tract and its microflora (Bouzerzour et al., Reference Bouzerzour, Morgan, Cuinet, Bonhomme, Jardin, Le Huërou-Luron and Dupont2012; Poulsen et al., Reference Poulsen, Jonge de, Sugiharto, Nielsen, Lauridsen and Canibe2017). Animal protein sources such as milk powder in piglet diets are beneficial for intestinal development and health, especially after weaning (higher FI and feed conversion) (Vente-Spreeuwenberg et al., Reference Vente-Spreeuwenberg, Verdonk, Bakker, Beynen and Verstegen2004; Lange et al., Reference Lange de, Pluske, Gong and Nyachoti2010; Le Huërou-Luron et al., Reference Le Huërou-Luron, Bouzerzour, Ferret-Bernard, Ménard, Le Normand, Perrier, Le Bourgot, Jardin, Bourlieu, Carton, Le Ruyet, Cuinet, Bonhomme and Dupont2018). Our expectation was therefore a positive effect of milk powder. The amount of milk powder used may have been too small to have a positive effect in our feeding trial.

Various strategies and feed components enable 100% organic feeding in piglets. Baldinger et al. (Reference Baldinger, Hagmüller, Minihuber, Matzner and Zollitsch2014, Reference Baldinger, Hagmüller, Minihuber, Schipflinger and Zollitsch2015) showed good results with hydrothermally treated grass pea seeds and sainfoin seeds and Stalljohann (Reference Stalljohann2006) with toasted field beans and heat-treated wheat flakes. Milk powder was always included in those diets. Our investigation on the one hand also showed that it is possible to optimize piglet diets without potato protein, but on the other hand, it revealed that all three tested alternatives tended to impair piglet health more than diet POT, and it brought along various challenges regarding the ecological targets and organic standards. Given that the use of milk powder or of higher soybean proportions influence the ecological footprint in undesired ways (Schader et al., Reference Schader, Muller, El-Hage Scialabba, Hecht, Isensee, Erb, Smith, Makkar, Klocke, Leiber, Schwegler, Stolze and Niggli2015; Ertl et al., Reference Ertl, Knaus and Zollitsch2016), the two other diets, which do not comply with current or future organic standards (LYS and POT) remain to be relevant options.

Naturalness and animal welfare are crucial in organic farming, but different rearing systems for piglets must also be taken into consideration. One important option would be a prolonged suckling period. Sow's milk generally provides the best supply for piglets. According to Main et al. (Reference Main, Dritz, Tokach, Goodband and Nelssen2004), Bussemas and Weissmann (Reference Bussemas, Weißmann, Neuhoff, Halberg and Thomas2008) and Faccin et al. (Reference Faccin, Allerson, Woodworth, DeRouchey, Tokach, Dritz and Goodband2019), piglets that are allowed to suckle longer show improved health, growth performance and productivity. If piglets are supplied with high quality protein through the sow milk, piglet feed with less external input can be used (Baldinger et al., Reference Baldinger, Bussemas, Höinghaus, Renger and Weißmann2017). A greater variety in the choice of feed components would thus be an advantage of prolonged suckling and the introduction of 100% organic feeding would be easier to implement.

Conclusion

All four diets tested herein resulted in similar weight gains and feed conversion of the piglets. Piglets receiving a diet containing conventional potato protein coped better with diarrhea compared to the other treatments. Those containing high soybean cake contents or added lysine appeared to be more critical with regard to the occurrence of diarrhea. In general, the diet with lysine addition resulted in signs of threonine deficiency, indicating that only supplying the first limiting amino acid would not solve the problem. Each of four tested piglet diets either had shortcomings in ecological sustainability or did not comply with current or future organic standards, which demonstrates the dilemma of feeding monogastrics in organic agriculture. Acknowledging the health performance, the use of conventional potato protein needs to be considered as a particularly sustainable option, still.

Acknowledgements

The authors acknowledge Swiss Federal Office for Agriculture [Schweizer Bundesamt für Landwirtschaft (BLW)], contract number: 627000764; Bio Suisse; Peter Stoll, Agroscope and the involved feed mills.

References

Almeida, E, Martins, SMMK, Abrahão, AFA, Andrade, AFC, Moreno, AM, Parazzi, LJ, Del Santo, TA and Moretti, ASA (2012) Effect of probiotic on the development of piglets challenged with Escherichia coli. Brazilian Journal of Veterinary Research and Animal Science 49, 5766.CrossRefGoogle Scholar
Araújo, WAG, Ferreira, AS, Renaudeau, D, Brustolini, PC and Silva, BAN (2010) Effects of diet protein source on the behavior of piglets after weaning. Livestock Science 132, 3540.CrossRefGoogle Scholar
Baldinger, L, Hagmüller, W, Minihuber, U, Matzner, M and Zollitsch, W (2014) Sainfoin seeds in organic diets for weaned piglets – utilizing the protein-rich grains of a long-known forage legume. Renewable Agriculture and Food Systems 31, 1221.CrossRefGoogle Scholar
Baldinger, L, Hagmüller, W, Minihuber, U, Schipflinger, M and Zollitsch, W (2015) Organic grass pea (Lathyrus sativus L.) seeds as a protein source for weaned piglets: effects of seed treatment and different inclusion rates on animal performance. Renewable Agriculture and Food Systems 31, 269279.CrossRefGoogle Scholar
Baldinger, L, Bussemas, R, Höinghaus, K, Renger, A and Weißmann, F (2017) Effect of six 100% organic feeding strategies differing in external input demand on animal performance and production costs of piglets before and after weaning. Organic Agriculture 7, 267279.CrossRefGoogle Scholar
Bates, D, Mächler, M, Bolker, B and Walker, S (2015) Fitting linear mixed-effects models using lme4. Journal of Statistical Software 67, 148.CrossRefGoogle Scholar
Bio Suisse (2020) Schweizer Richtlinien für die Erzeugung, Verarbeitung und den Handel von Knospe-Bio-Produkten [Swiss Guidelines for the Production, Processing and Trade of Organic Products].Google Scholar
Bouzerzour, K, Morgan, F, Cuinet, I, Bonhomme, C, Jardin, J, Le Huërou-Luron, I and Dupont, D (2012) In vivo digestion of infant formula in piglets: protein digestion kinetics and release of bioactive peptides. British Journal of Nutrition 108, 110.CrossRefGoogle ScholarPubMed
Bussemas, R and Weißmann, F (2008) Prolonged suckling period in organic piglet production – effects on some performance and health aspects. In Neuhoff, D, Halberg, N, Thomas, A et al. (eds), 16th IFOAM Organic World Congress Modena, pp. 106109.Google Scholar
Chen, Y, Li, D, Dai, Z, Piao, X, Wu, Z, Wang, B, Zhu, Y and Zeng, Z (2014) L-Methionine supplementation maintains the integrity and barrier function of the small-intestinal mucosa in post-weaning piglets. Amino Acids 46, 11311142.CrossRefGoogle ScholarPubMed
Dourmad, JY and Jondreville, C (2007) Impact of nutrition on nitrogen, phosphorus, Cu and Zn in pig manure, and on emissions of ammonia and odours. Livestock Science 112, 192198.CrossRefGoogle Scholar
Doyle, RE, Groat, J, Wynn, PC and Holyoake, PK (2015) Physiological and nonphysiological indicators of body condition score in weaner pigs. Journal of Animal Science 93, 18871895.CrossRefGoogle ScholarPubMed
Ertl, P, Knaus, W and Zollitsch, W (2016) An approach to including protein quality when assessing the net contribution of livestock to human food supply. Animal: An International Journal of Animal Bioscience 11, 18831889.CrossRefGoogle Scholar
Faccin, JE, Allerson, MW, Woodworth, JC, DeRouchey, JM, Tokach, MD, Dritz, SS and Goodband, RD (2019) Effects of Weaning Age and Antibiotic Use on Pig Performance in a Commercial System. Kansas Agricultural Experiment Station Research Reports: Vol. 5: Iss. 8.CrossRefGoogle Scholar
Fang, ZF, Yao, K, Zhang, XL, Zhao, S, Sun, Z, Tian, G, Yu, B, Lin, Y, Zhu, B, Jia, G, Zhang, K, Chen, D and Wu, D (2010) Nutrition and health relevant regulation of intestinal sulfur amino acid metabolism. Amino Acids 39, 633640.CrossRefGoogle ScholarPubMed
Fernández, JA and Strathe, A (2009) Dietary tryptophan and threonine supply to 28 days old weaned piglets. Animal Feed Science and Technology 154, 265270.CrossRefGoogle Scholar
Forstmeier, W and Schielzeth, H (2011) Cryptic multiple hypotheses testing in linear models: overestimated effect sizes and the winner's curse. Behavioral Ecology and Sociobiology 65, 4755.CrossRefGoogle ScholarPubMed
Früh, B, Schlatter, B, Isensee, A, Maurer, V and Willer, H (2015) Report on organic protein availability and demand in Europe = Deliverable 1.2 of the CORE Organic project (ICOPP). Research Institute of Organic Agriculture (FiBL), Frick, Switzerland.Google Scholar
Garcia-Launay, F, Van Der Werf, HMG, Nguyen, TTH, Le Tutour, L and Dourmad, JY (2014) Evaluation of the environmental implications of the incorporation of feed-use amino acids in pig production using life cycle assessment. Livestock Science 161, 158175.CrossRefGoogle Scholar
Gorissen, SHM, Crombag, JJR, Senden, JMG, Huub Waterval, WA, Bierau, J, Verdijk, LB and van Loon, LJC (2018) Protein content and amino acid composition of commercially available plant-based protein isolates. Amino Acids 50, 16851695.CrossRefGoogle ScholarPubMed
Halekoh, U and Højsgaard, S (2014) A Kenward–Roger approximation and parametric bootstrap methods for tests in linear mixed models – the R package pbkrtest. Journal of Statistical Software 59, 132.CrossRefGoogle Scholar
Hamard, A, Sève, B and Le Floc'h, N (2007) Intestinal development and growth performance of early-weaned piglets fed a low-threonine diet. Animal: An International Journal of Animal Bioscience 1, 11341142.CrossRefGoogle ScholarPubMed
Holinger, M, Früh, B, Stoll, P, Graage, R, Wirth, S, Bruckmaier, R, Prunier, A, Kreuzer, M and Hillmann, E (2018) Chronic intermittent stress exposure and access to grass silage interact differently in their effect on behaviour, gastric health and stress physiology of entire or castrated male growing-finishing pigs. Physiology & Behavior 195, 5868.CrossRefGoogle ScholarPubMed
IFOAM (2014) The IFOAM Norms for Organic Production and Processing. International Federation of Organic Agriculture Movements (IFOAM), Bonn, Germany.Google Scholar
Jayaraman, B, Htoo, J and Nyachoti, CM (2015) Effects of dietary threonine:lysine ratios and sanitary conditions on performance, plasma urea nitrogen, plasma-free threonine and lysine of weaned pigs. Animal Nutrition 1, 283288.CrossRefGoogle Scholar
Kumar, D and Gomes, J (2005) Methionine production by fermentation. Biotechnology Advances 23, 4161.CrossRefGoogle ScholarPubMed
Lange de, CFM, Pluske, J, Gong, J and Nyachoti, CM (2010) Strategic use of feed ingredients and feed additives to stimulate gut health and development in young pigs. Livestock Science 134, 124134.CrossRefGoogle Scholar
Law, GK, Bertolo, RF, Adjiri-Awere, A, Pencharz, PB and Ball, RO (2007) Adequate oral threonine is critical for mucin production and gut function in neonatal piglets. American Journal of Physiology – Gastrointestinal and Liver Physiology 292, G1293G1301.CrossRefGoogle ScholarPubMed
Le Huërou-Luron, I, Bouzerzour, K, Ferret-Bernard, S, Ménard, O, Le Normand, L, Perrier, C, Le Bourgot, C, Jardin, J, Bourlieu, C, Carton, T, Le Ruyet, P, Cuinet, I, Bonhomme, C and Dupont, D (2018) A mixture of milk and vegetable lipids in infant formula changes gut digestion, mucosal immunity and microbiota composition in neonatal piglets. European Journal of Nutrition 57, 463476.CrossRefGoogle ScholarPubMed
Leiber, F and Früh, B (2014) Aspekte zur Zulassung von Aminosäurepräparaten aus fermentativer Produktion in der Tierernährung im Biologischen Landbau [Aspects for the Approval of Amino Acids from Fermentative Production for Animal Nutrition in Organic Farming]. Framework Paper of the Research Institute of Organic Farming (FiBL, Switzerland).Google Scholar
Lenth, R, Singmann, H, Love, J, Buerkner, P and Herve, M (2020) Emmeans: estimated marginal means, aka least-squares means. The American Statistician 34, 216221.Google Scholar
Lindermayer, H, Probstmeier, G and Preißinger, W (2010) Ferkelfütterung mit Heimischen Sojaprodukten – 20/15% Sojakuchen – extrudiert, 27/20% Vollfettsojabohnen- geröstet [Piglet Feeding with Local Soy Products – 20/15% Soy Cake – Extruded, 27/20% Full Fat Soybeans – Roasted]. Test report S18. State Institute for Agriculture (LfL).Google Scholar
Liu, S, Ni, JQ, Radcliffe, JS and Vonderohe, CE (2017) Mitigation of ammonia emissions from pig production using reduced dietary crude protein with amino acid supplementation. Bioresource Technology 233, 200208.CrossRefGoogle ScholarPubMed
Main, RG, Dritz, SS, Tokach, MD, Goodband, RD and Nelssen, JL (2004) Increasing weaning age improves pig performance in a multisite production system. Journal of Animal Science 82, 14991507.CrossRefGoogle Scholar
Meul, M, Ginneberge, C, Van Middelaar, CE, De Boer, IJM, Fremaut, D and Haesaert, G (2012) Carbon footprint of five pig diets using three land use change accounting methods. Livestock Science 149, 215223.CrossRefGoogle Scholar
NRC, National Research Council (2012) Nutrient Requirements of Swine, 11th revised Edition. Washington, DC: National Academies Press.Google Scholar
Nyachoti, CM, Omogbenigun, FO, Rademacher, M and Blank, G (2006) Performance responses and indicators of gastrointestinal health in early-weaned pigs fed low-protein amino acid-supplemented diets. Journal of Animal Science 84, 125134.CrossRefGoogle ScholarPubMed
Philippe, FX, Cabaraux, JF and Nicks, B (2011) Ammonia emissions from pig houses: influencing factors and mitigation techniques. Agriculture, Ecosystems and Environment 141, 245260.CrossRefGoogle Scholar
Pluske, JR, Turpin, DL and Kim, JC (2018) Gastrointestinal tract (gut) health in the young pig. Animal Nutrition 4, 187196.CrossRefGoogle ScholarPubMed
Poulsen, ASR, Jonge de, N, Sugiharto, S, Nielsen, JL, Lauridsen, C and Canibe, N (2017) The microbial community of the gut differs between piglets fed sow milk, milk replacer or bovine colostrum. British Journal of Nutrition 117, 964978.CrossRefGoogle ScholarPubMed
R Core Team (2017) R: A language and Environment for Statistical Computing. R Foundation for Statistical Computing, Vienna, Austria. Available at https://www.R-project.org.Google Scholar
Reckmann, K, Blank, R, Traulsen, I and Krieter, J (2016) Comparative life cycle assessment (LCA) of pork using different protein sources in pig feed. Archives Animal Breeding 59, 2736.CrossRefGoogle Scholar
Saxe, H, Hamelin, L, Hinrichsen, T and Wenzel, H (2018) Production of pig feed under future atmospheric CO2 concentrations: changes in crop content and chemical composition, land use, environmental impact, and socio-economic consequences. Sustainability (Switzerland) 10, 3184.CrossRefGoogle Scholar
Schaart, MW, Schierbeek, H, Sophie, RDV and Stoll, B (2005) Threonine utilization is high in the intestine of piglets. The Journal of Nutrition 135, 765.CrossRefGoogle ScholarPubMed
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 the Royal Society Interface 12, 20150891.CrossRefGoogle ScholarPubMed
Schumacher, U, Fidelak, C, Koopmann, R, Weißmann, F, Snigula, J, Brüggemann, R, Naatjes, M, Simoneit, C and Bender, S (2011) Wissenstandsanalyse zur Tiergesundheit aller Nutztierarten im Ökologischen Landbau und 100% Biofütterung [Analysis of Knowledge Status on Animal Health of All Types of Livestock in Organic Farming and 100% Organic Feeding]. BÖLN – Federal organic farming program and other forms of sustainable agriculture.Google Scholar
Schwediauer, P, Hagmüller, W and Zollitsch, W (2018) Germination of faba beans (Vicia faba L.) for organic weaning piglets. Organic Agriculture 8, 249258.CrossRefGoogle Scholar
Smith, J, Gerrard, CL and Hermansen, JE (2014) Improved Contribution of Local Feed to Support 100% Organic Feed Supply to Pigs and Poultry. ICOPP Synthesis Report.Google Scholar
Stalljohann, G. 2006. Untersuchungen zu Fütterungsstrategien für eine erfolgreiche Aufzucht ökologisch gehaltener Ferkel [Investigation on Feeding Strategies for Successful Rearing of Organic Piglets] Dissertation. Munich, LMU.Google Scholar
Stoll, P (2004) Einsatzgrenzen von Einzelfuttermitteln für Schweine. Merkblatt für die Praxis [Limits of Use of Feed Materials for Pigs. Leaflet for Practice]. ALP aktuell 2004, Nr. 15.Google Scholar
Sundrum, A (2001) Organic livestock farming: a critical review. Livestock Production Science 67, 207215.CrossRefGoogle Scholar
Sundrum, A, Schneider, K and Richter, U (2006) Possibilities and Limitations of Protein Supply in Organic Poultry and Pig Production. Final Project Report EEC 2092/91 (Organic) Revision, Nr. D 4.1 (Part 1). University of Kassel, Witzenhausen, Department of Animal Nutrition and Animal Health.Google Scholar
The Council of the European Union (2007) Council Regulation (EC) No 834/2007 of 28 June 2007 on organic production and labelling of organic products. Official Journal of the European Union 189, 123.Google Scholar
The Council of the European Union (2018) Council Regulation (EC) No 2018/848 of June 2018 on organic production and labelling of organic products and repealing Council Regulation (EC) No 834/2007. Official Journal of the European Union 150, 192.Google Scholar
VDLUFA [Association of German Agricultural Analytic and Research Institutes] (ed.) (2007) Handbuch der Landwirtschaftlichen Versuchs- und Untersuchungsmethodik (VDLUFA-Methodenbuch), Band III: Die chemische Untersuchung von Futtermitteln [Handbook of Agricultural Experimental and Analytical Methods, Volume III: The Chemical Analysis of Feedstuffs]. 3rd ed. VDLUFA-Verlag, Darmstadt, Germany.Google Scholar
Vente-Spreeuwenberg, MAM, Verdonk, JMAJ, Bakker, GCM, Beynen, AC and Verstegen, MWA (2004) Effect of dietary protein source on feed intake and small intestinal morphology in newly weaned pigs. Livestock Production Science 86, 169177.CrossRefGoogle Scholar
Waglay, A, Karboune, S and Alli, I (2013) Potato protein isolates: recovery and characterization of their properties. Food Chemistry 142, 373382.CrossRefGoogle ScholarPubMed
Wang, W, Zeng, X, Mao, X, Wu, G and Qiao, S (2010) Optimal dietary true ileal digestible threonine for supporting the mucosal barrier in small intestine of weanling pigs. The Journal of Nutrition 140, 981.CrossRefGoogle ScholarPubMed
Witten, S, Paulsen, HM, Weißmann, F and Bussemas, R (2014) Praxisbefragung zur Aminosäurelücke und praktische Möglichkeiten zur Verbesserung der Eiweißversorgung der Monogastrier in der Fütterung im Ökologischen Landbau [Practice Survey on the Amino Acid Gap and Practical Possibilities for Improving the Protein Supply of Monogastric Animals in Feeding in Organic Farming]. Thünen Working Paper.Google Scholar
Wlcek, S, Hagmüller, W, Leeb, C, Stark, H, Ölzant, F and Böhm, M (2015) Leitfaden tierwohl schwein [Guide animal welfare pig]. Bio Austria 1, 120.Google Scholar
Wu, JJ, Zhang, Y, Dong, JH, Cao, CM, Li, B, Feng, SB, Ding, HY, Ma, LY, Wang, XC and Li, Y (2016) Allergens and intestinal damage induced by soybean antigen proteins in weaned piglets. Italian Journal of Animal Science 15, 437445.CrossRefGoogle Scholar
Zhang, GJ, Xie, CY, Thacker, PA, Htoo, JK and Qiao, SY (2013) Estimation of the ideal ratio of standardized ileal digestible threonine to lysine for growing pigs (22–50 kg) fed low crude protein diets supplemented with crystalline amino acids. Animal Feed Science and Technology 180, 8391.CrossRefGoogle Scholar
Zheng, S, Qin, G, Chen, J and Zhang, F (2018) Acidic polypeptides A1a, A3 and A4 of Gly m 6 (glycinin) are allergenic for piglets. Veterinary Immunology and Immunopathology 202, 147152.CrossRefGoogle ScholarPubMed
Zollitsch, W (2007) Challenges in the nutrition of organic pigs. Journal of the Science of Food and Agriculture 87, 27472750.CrossRefGoogle Scholar
Figure 0

Table 1. Composition of the four experimental diets for piglets

Figure 1

Table 2. Description of statistical models

Figure 2

Table 3. Average daily feed intake and feed conversion ratio per animal

Figure 3

Fig. 1. Weight development of piglets fed organic diets supplemented with either conventional potato protein (POT), lysine (LYS), milk powder (MILK) or containing a high proportion of soybean cake (SOY). Lines represent model estimates. Diet P = 0.97, Age P < 0.001, Diet × Age P < 0.001.

Figure 4

Fig. 2. Average daily weight gain of piglets fed organic diets supplemented with either conventional potato protein (POT), lysine (LYS), milk powder (MILK) or containing a high proportion of SOY. Lines represent model estimates. Diet P = 0.28, Time of measurement P < 0.001, Diet × Time of measurement P = 0.002.

Figure 5

Table 4. Average body condition score and prevalence of diarrhea of piglets fed different diets