Abstract
This study investigated the effect of the inclusion of extruded linseed and hazelnut skin on fatty acid (FA) metabolism in finishing lambs. Forty lambs were divided into 4 groups and fed for 60 d with: a conventional cereal-based diet, or the same diet with 8% of extruded linseed, or 15% of hazelnut skin, or 4% of linseed plus 7.5% of hazelnut skin as partial replacement of maize. Dietary treatments did not affect growth performances, carcass traits, and ruminal fermentation. The combined effect of linseed and hazelnut skin enriched the intramuscular fat with health promoting FA. Particularly, increases in α-linolenic acid (3.75-fold), and very long-chain n-3 poly-unsaturated FA (+ 40%) were attributed to the supplementation with linseed, rich in α-linolenic acid. In addition, increases in rumenic (+ 33%), and vaccenic (+ 59%) acids were attributed to hazelnut skin tannins modulating ruminal biohydrogenation and accumulating intermediate metabolites. The simultaneous inclusion of linseed and hazelnut skin can be a profitable strategy for enriching the intramuscular fat of lambs with health promoting FA, without adverse effects on ruminal fermentation and animal performance.
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Discover the latest articles, news and stories from top researchers in related subjects.Introduction
Improvements in the purchasing power of consumers has led to an increasing demand for healthy animal products1. Following public health policies, this should imply a reduction in their content of saturated fatty acids (SFA) and an increase of unsaturated ones (UFA), to lower the incidence of cardiovascular and metabolic diseases2.
Meat, together with milk and dairy products, are the main sources of SFA in human diet3. However, some animal feeding strategies (e.g., diet supplementation with oil seeds or plant oils) can be used to enhance UFA in meat at the expense of SFA, offering consumers an opportunity to modify SFA and UFA intake without relevant changes in eating habits4. Dietary linseed has been demonstrated to be capable of reducing SFA in meat while increasing the accumulation of potentially health-promoting n-3 polyunsaturated fatty acids (PUFA)5,6.
In addition to healthier animal products, consumers’ demand also requires livestock production systems to be environmentally sustainable7. In this respect, the inclusion of agro-industrial by-products, not edible by humans, in animal diets may be a strategy to reduce their costly disposal and the feed to food competition. Their use as feed may also improve economic sustainability by reducing feeding cost8,9.
Hazelnut (Corylus avellana L.) accounted for 11% of dried fruit global production in 2022/202310. Hazelnut kernels are mainly employed in confectionary and chocolate industries11, where they are peeled during the roasting process, generating a considerable amount of skin to get rid of it12. Hazelnut skin is a fibrous by-product suitable for ruminant feeding, with a relatively high content of oleic acid (OA)13,14,15. Moreover, this skin is a source of phenolic compounds, particularly tannins, known to modulate rumen biohydrogenation (BH) and therefore reduce the accumulation of SFA and increase unsaturated FA in animal products16,17. A previous study with lambs fed 15% of hazelnut skin in replacement of maize found interesting results on health-promoting fatty acids (FA) in meat [i.e., a higher content of vaccenic acid (VA) and PUFA] without negative effects on growth performance14.
Thus, given the positive effects of both linseed and hazelnut skin in lamb diets, we hypothesized that a combination of these two ingredients could improve meat FA profile, thanks to the n-3 PUFA provided by linseed and the modulatory BH action of hazelnut skin tannins. It would also lower diet cost, presumably without negative consequences on animal performance.
The work by Mele et al.18, feeding lambs with diets including olive cake and linseed, might provide further support for this hypothesis, as olive cake and hazelnut skin have some similar chemical characteristics. They both contain phenolic compounds and a relatively high proportion of OA. In that assay, the reduction of the diet cost was accompanied by a higher proportion of PUFA in lamb meat without any adverse effects on animal performance.
To test our hypothesis, we conducted an experiment with lambs fed a typical concentrate-based diet for growth, in which maize and soybean meal were partially replaced with linseed and/or hazelnut skin. We studied some animal performance and rumen fermentation parameters, as well as the FA composition of rumen and abomasum digesta, and longissimus dorsi (LD) muscle.
Material and methods
Animals and diets
Experimental procedures with animals were conducted in accordance with European Union (Council Directive 2010/63/EU) legislation for the protection of animals used for experimental and other scientific purposes, being approved by the Research Ethics Committees of the University of Catania (protocol number: 82427) and conducted in accordance with ARRIVE guidelines.
Forty Valle del Belice × Comisana male lambs (2-months of age; initial body weight 17.3 kg ± SD 3.17) were selected from a local dairy sheep farm. The lambs had been weaned at the age of 45 days and fed a commercial weaning concentrate for lambs (composed of maize, wheat bran, extracted soybean meal, dehydrated alfalfa, urea, and minerals) until the start of this trial. They were taken to the experimental farm of the University of Catania, housed in individual pens (1.5 m2) with straw litter, and divided into four groups balanced for the initial body weight (BW). Each group received one of the following treatments (diets formulated to have comparable levels of energy and protein; see Table 1 for details):
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Control (C diet; 10 lambs): lambs received a typical maize-barley based concentrate for lamb growth.
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Linseed (L diet; 10 lambs): lambs received the control diet, with 8% of extruded linseed as partial replacement of maize and extracted soybean meal. Extruded linseed was purchased from Mazzoleni S.p.A. (Cologno al Serio, Bergamo, Italy) following the European regulation (CE n° 183/2005). During the trial, one animal from this group died due to reasons not linked to the experimental diet.
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Hazelnut (H diet; 10 lambs): lambs received the control diet, with 15% of hazelnut skin as partial replacement of maize. The level of inclusion of the by-product was chosen on the basis of previous results (see Priolo et al.14). Hazelnut skin was supplied by Dalma Mangimi S.p.A. (Marene, Cuneo, Italy).
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Linseed + Hazelnut (L + H diet; 10 lambs): lambs received the control diet, with 4% of extruded linseed and 7.5% hazelnut skin as partial replacement of maize.
Experimental diets were pelleted (3 mm pellet diameter) to avoid feed selection. The animals were gradually adapted to them by progressive replacement of their commercial weaning diet over 5 day-period. Clean drinking water was always available.
Voluntary feed intakes were determined by weighing the amounts of fresh matter offered and refused by each lamb every 2–3 days. Intake was then corrected for dry matter (DM) as described below.
All animals were weighed weekly throughout the trial (Spider 3, Mettler Toledo, Columbus, OH, USA).
On day 60 on feeding trial, diets and water were removed 3 h before slaughter. Lambs were weighted and taken to a commercial abattoir (80 km far from the University farm) where they were immediately slaughtered following European regulation (Council Regulation n. 1099/2009).
Samplings and measurements at slaughter
Individual whole ruminal and abomasal contents were collected within 10 min of slaughter and homogenized. After measuring the pH (Orion 9106; Orion Research Incorporated, Boston, MA, USA), one sample (approx. 120 mL) of each content was immediately frozen with dry ice, and then freeze-dried, and stored at – 80 °C. Another sample of rumen digesta was filtered through four cheesecloth layers and then centrifuged at 3122×g for 5 min (MPW-54; MPW Med. Instruments, Warsaw, Poland). Five mL of fluid was acidified with 5 mL of 0.2 N HCl for ammonia analysis19. For volatile fatty acid (VFA) determinations, another aliquot of rumen fluid (0.8 mL) was added to 0.5 mL of a deproteinizing solution (2% metaphosphoric acid containing 0.4% crotonic acid (Sigma–Aldrich, St. Louis, USA) as an internal standard, w/v in 0.5 N HCl). These ruminal samples for ammonia and VFA were stored at – 80 °C prior to laboratory analyses.
Following evisceration, carcasses were stored at 4 °C. After a 24-h post-mortem period, the carcasses were weighed, halved, and the LD muscle was subsequently excised from each right half. A portion of LD (approximately 100 g) was vacuum-packed and stored at – 80 °C until analysis.
Chemical analyses
Samples of the feedstuff, which had been collected during the trial, were prepared (ISO 6498:2012) and analyzed for dry matter (DM; ISO 6496:1999), ash (ISO 5984:2022), and crude protein (ISO5983-2:2009). The neutral and acid detergent fibres (aNDF and ADF) concentrations were sequentially determined using an Ankom2000 fibre analyzer (Ankom Technology Methods 13 and 12, respectively; Ankom Technology Corp., Macedon, NY, USA); the former was assayed with sodium sulfite and α-amylase, and both aNDF and ADF were expressed with residual ash.
Total phenolic compounds and total tannins in feedstuffs were quantified following the Folin-Ciocalteu method developed by Makkar et al.20, with adaptations made by Luciano et al.21. Briefly, grounded feeds were extracted using acetone 70% (v/v). The concentration of total phenolic compounds was determined using Folin-Ciocalteu reagent (1 N) and sodium carbonate 20% (w/v). Total non-tannin phenols were treated with polyvinylpyrrolidone (PVPP) in order to precipitate tannins. Total tannins were calculated as the difference between total phenols and total non-tannin phenols. Phenolic compounds and tannins were quantified using tannic acid (Sigma–Aldrich) as a reference standard and they were expressed as mg TA equivalents/g DM.
Ammonia concentration in ruminal fluid centrifuged samples was measured spectrophotometrically (UV-1601; Shimadzu Corporation, Milan, Italy) according to Reardon et al.19. Ruminal VFA were determined by gas chromatography (ThermoQuest, Milan, Italy) following indications by Priolo et al.14.
Longissimus dorsi muscle was deprived of any visible fat (i.e., of the intermuscular fat), finely minced with a knife, weighted, and then homogenized with a solution of chloroform and methanol (2:1, v/v). After the evaporation of these solvents in a rotary evaporator system (Rotavapor R-114, Büchi, Flawil, Switzerland), total intramuscular fat (IMF) was determined gravimetrically.
Fatty acid composition analyses
Feedstuff fatty acids were extracted using chloroform22 and converted to fatty acid methyl esters (FAME) with 2% (v/v) sulfuric acid in methanol23, using tridecanoic acid (13:0; Sigma-Aldrich) as an internal standard.
Rumen and abomasum digesta FA were directly converted to FAME by using a combined basic and acid methylation24, with nonadecanoic acid (19:0; Sigma–Aldrich) as an internal standard.
Intramuscular fat was dissolved in a mixture of hexane and 2-propanol (4:1, v/v), and 50 mg of lipids were methylated using 1 mL of sodium methoxide in methanol 0.5 N and 2 mL of hexane25. Nonadecanoic acid (19:0) was used as an internal standard.
Fatty acid methyl esters of feeds, rumen, and abomasum digesta, and muscle were separated with a gas chromatograph (ThermoQuest, Milan, Italy) equipped with a flame ionization detector (FID) and 100 m high-polar fused silica capillary column (100 m × 0.25 mm i.d.; film thickness 0.25 μm; SP-2560 fused silica, Supelco, Bellafonte, PA, USA). Total FAME were determined using a temperature gradient program at a split ratio of 1:80 and helium as carrier gas at a constant flow of 1 mL/min (for more details, see Priolo et al.14). The isomers t10 18:1 and t11 18:1 were further resolved in a separate analysis under isothermal condition at 165°C (adapted from Shingfield et al.23).
Peaks were identified based on retention time comparisons with commercially available standard mixture of FAME (Nu-Chek Prep Inc., Elysian, MN, USA; Larodan Fine Chemicals, Malmo, Sweden).
Calculations and statistical analysis
Average daily gain was estimated as the regression slope of BW against time, using the REG procedure of the SAS software package (version 9.4; SAS Institute Inc., Cary, NC, USA).
The BH estimates (BHFAx) of OA (c9 18:1), linoleic acid (LA; c9c12 18:2), and α-linolenic acid (αLNA; c9c12c15 18:3) in ruminal and abomasal digesta were calculated using the equations by Oliveira et al.26. These estimates are based on the difference of each of these FA between diet and ruminal or abomasal digesta contents (i.e., its disappearance), and are calculated as shown below:
The BH completeness in rumen and abomasum was also estimated27: the higher the values of completeness in rumen and abomasum, the more complete BH resulting in 18:0 production (or, the lower the values, the higher the accumulation of BH intermediates).
We also calculated an atherogenic index following the formula proposed by Ulbricht and Southgate28:
All statistical analyses were conducted with the SAS software package. Data were analyzed with ANOVA to test the effect of the dietary treatments, using the MIXED procedure of SAS and considering the individual lambs as the experimental units. Means were separated through the pairwise differences (“pdiff”) option of the least squares means (“lsmeans”) statement of the MIXED procedure. They were adjusted for multiple comparisons using Bonferroni’s correction. Differences were declared significant at P < 0.05 and considered a trend toward significance at 0.05 ≤ P < 0.10. Least squares means are reported throughout the manuscript.
Ethics approval
Experimental procedures with animals were conducted in accordance with European Union (Council Directive 2010/63/EU) legislation for the protection of animals used for experimental and other scientific purposes, being approved by the Research Ethics Committees of the University of Catania (protocol number: 82427).
Results
Animal performance
As shown in Table 2, DM intake was not affected by the treatments (P > 0.10). However, lambs fed the control diet ingested less total FA than the other lambs (P < 0.001), while aNDF and crude protein intakes were similar (P > 0.05). Concerning individual FA, L + H lambs consumed a greater quantity of 16:0 than the C lambs (P < 0.001). The daily intake of stearic acid (SA; 18:0) was higher in L + H, followed by L and finally by C and H (P < 0.001). Lambs fed L and L + H ingested more LA than C and H lambs (P = 0.001). The intake of αLNA was greater in L followed by L + H, while it was lower in C and H (P < 0.001). The H lambs consumed more OA compared to all the other lambs (P < 0.001). On the other hand, the inclusion of hazelnut skin or linseed, either individually or in combination, did not influence BW, average daily gain (ADG), feed conversion ratio (FCR), carcass weight, carcass yield, or IMF.
Rumen fermentation
Table 3 shows the effects of diet on ruminal fermentation. Ruminal pH, and ammonia and total VFA concentrations were not affected (P > 0.10) and, concerning molar proportion of individual VFA, only valerate showed significative effects (P = 0.011), being highest in L and lowest in L + H.
Fatty acid composition of the ruminal digesta
As shown in Table 4, the partial replacement of maize and soybean meal with linseed and hazelnut skin reduced the proportions of atherogenic FA (12:0, 14:0, and 16:0) compared to the C (P < 0.05). Odd (13:0, 15:0, and 17:0) and branched chain FA (15:0 anteiso and iso FA, but not 17:0 anteiso) (OBCFA) showed lower proportions when lambs were fed L, H, and L + H (P < 0.001). In line with this, the summation of OBCFA was significantly higher in C lambs compared to all the others (P < 0.001).
Diet did not affect SA and VA proportions in the rumen liquor (P > 0.10). The concentration of OA was higher in H than in the other treatments (P < 0.001), with a twofold increase compared to C. The proportion of t10 18:1 showed significant effect (P = 0.023), but Bonferroni’s adjustment reduced it to a tendency to differences between C and treatments with hazelnut skin (i.e., H and L + H). The LA content was significantly greater in rumen fluid from control animals compared to all other treatments (P = 0.002), while the rumen digests from H-fed lambs showed lower rumenic acid (RA; c9t11 18:2) concentration than C and L (P = 0.005). The proportion of αLNA in L was 10.7-fold higher than in H, 6.5-fold than in C, and 1.6-fold than in L + H (P < 0.001). Concerning FA groups (summations), no effect of diet was found on SFA and monounsaturated FA (MUFA; P > 0.10), but feeding H lowered PUFA proportion compared to C and L (P = 0.007). The ratio of t10/t11 18:1 was not affected by treatments (P > 0.10).
Fatty acid composition of the abomasal digesta
The FA composition of the abomasal digesta is shown in Table 5. In general, the effects of dietary treatments were similar to those observed in the rumen. In fact, proportions of FA with 17 or fewer carbons, OA, t10 18:1, VA, LA, αLNA, SFA, MUFA, OBCFA, and t10/t11 ratio followed the same pattern between diets as in the rumen. However, there were a few variations, lambs fed L + H tended to have a higher SA proportion than C lambs (P = 0.05), and RA was not significantly affected by dietary inclusion of linseed and/or hazelnut skin (P > 0.10). The summation of total PUFA showed significant variation (P = 0.032), but Bonferroni’s adjustment reduced it to a tendency (P < 0.10) to differences only between C and H.
Biohydrogenation indices
Biohydrogenation indices for OA, LA, and αLNA, estimated with rumen and abomasum data, are given in Table 6. Only the BH index of αLNA in the rumen, which had higher values in L + H compared to H, and of the OA in the abomasum, which was higher in L compared to C, showed statistically significant differences (P = 0.026 and 0.009, respectively). Regarding the index of BH completeness, there was a significant effect of dietary treatments in the calculations with rumen data (P = 0.005), with a higher value in H compared to C and L. When the index of BH completeness was calculated with abomasum data, the value in H was higher than that in the control (P = 0.010).
Intramuscular fatty acid composition
Table 7 reports the effects of the diet on intramuscular FA composition. Feeding lambs with H reduced the proportions of 15:0 compared to C and L (P = 0.009), while 16:0 and c9 16:1 concentrations were lower in H than in C (P = 0.010 and 0.018, respectively). Consumption of hazelnut skin (H and L + H) resulted in a lower concentration of 17:0 compared to C (P = 0.001), while its inclusion, as well as that of linseed reduced the proportion of 17:0 anteiso (P < 0.001) but not of 17:0 iso (P > 0.10). Consequently, the OBCFA was higher in IMF of C lambs compared to H and L + H (P < 0.001). Although SA concentration was significantly affected by diet (P = 0.042), Bonferroni’s adjustment for multiple comparisons did not discriminate experimental groups. Oleic acid concentration was not affected by diet (P > 0.10), and the accumulation of VA and RA was higher in the muscle of lambs in the L + H treatment than in the control (P < 0.05). Animals in the L treatment had more t10 18:1 content than H and L + H, but not than C (P = 0.001). Lambs fed hazelnut skin had higher concentration of LA in muscle than L and L + H (P = 0.006). When compared to C and H, the αLNA proportion was 4.9-fold higher in L and 3.75-fold higher in L + H (P < 0.001). As for FA groups, the replacement of maize with hazelnut skin (H) tended to increase the proportion of PUFA compared to all other treatments, including the combination L + H (P = 0.080). Nevertheless, SFA and MUFA were not modified by diet inclusion of H and/or L (P > 0.10). Feeding linseed (L and L + H) lowered the proportion of PUFA n-6 in muscle compared to H (P = 0.004), while increased PUFA n-3 compared to L + H, and followed by C and H with the lowest values (P < 0.001). Consequently, the PUFA n-6/n-3 ratio was significantly higher in C and H lambs compared to L + H and L (P < 0.001). Although no dietary treatment was significantly different from the control, the atherogenic index tended to be higher in L + H compared to H (P = 0.061). The dietary inclusion of H lowered the desaturase index [calculated as c9 17:1 / (17:0 + c9 17:1)], but the other treatments (i.e., L and L + H) did not differ from the control (P = 0.021).
Discussion
Maize and soybean are both widely used for food, feed, and fuel production29. Their substitution in animal diets by agro-industrial by-products may reduce not only the food-feed-fuel competition but also the feeding cost of ruminant production. In this study, we partially replaced dietary maize and soybean meal, which are common dietary ingredients for growing lambs in intensive systems30,31, with the by-product hazelnut skin and with linseed. Our aim was to test the hypothesis that a combination of these two ingredients may improve meat FA composition without having a negative impact on lambs’ performance. In addition, the inclusion of the by-product would, if not reduce the cost of the diet, at least maintain it despite the high price of the linseed.
The experiment included, besides the control, one treatment with the L + H combination and two individual treatments with either L or H. However, since there are numerous papers in the literature on the effect of supplementing the diet of lambs with αLNA (e.g., Andrés et al.5; Bessa et al.6; Nguyen et al.32), results related to linseed feeding will be discussed only briefly. On the other hand, there are very few scientific studies on the use of hazelnut skin as feed for ruminants15,33 and, to the best of our knowledge, only one on its use as feed for growing lambs14. Therefore, results about the effects of the dietary inclusion of hazelnut skin will be discussed in more detail. In any case, this section will focus particularly on the L + H treatment, in order to either accept or reject our hypothesis.
Animal performance and ruminal fermentation
Previous studies have shown that the inclusion of up to 10% extruded linseed in the diet of lambs did not affect intake and growth performance4 and carcass characteristics34. Priolo et al.14 reported that growth and intake were similar in lambs fed 15% hazelnut skin or a conventional diet, but the former showed a higher FCR. Our results for the combination of L + H were consistent with these findings, although differences in FCR did not reach statistical significance (P = 0.118). Only animals fed the H diet showed a tendency (P = 0.058) to have a higher FCR than the control, which could be in line with lower values, although only numerically, of ADG and IMF in this H treatment. However, the combination L + H compensated for the numerical worsening in terms of ADG, FCR, and IMF caused by the hazelnut skin. Different batches of hazelnut skin may explain small divergences in animal performance. Indeed, a common problem of all agro-industrial by-products is the variability of their chemical composition, including the content of tannins9,13. High contents of these compounds can be a limiting factor in their use. For example, according to Shakeri35, the inclusion of 30% of pistachio by-products in the diet of lambs (corresponding to 22.8 g tannic acid equivalents/kg DM) had a negative effect on growth performance. However, when four different tannin extracts were supplemented at a concentration of 40 g/kg DM to lambs’ diet, adverse impact on animal performance was observed only with the chestnut extract and not with the other treatments36. Therefore, it is difficult to establish the threshold at which tannins may cease to be beneficial and become harmful. This threshold will depend not only on interactions between doses, tannin types and basal diets, but also on the use of different standards and methods of tannin analysis37,38.
Regarding effects on ruminal fermentation, the literature is still unclear. For instance, in dairy cows, while Martin et al.39 reported that increasing linseed levels in a maize silage-based diet enhanced propionate and reduced butyrate and acetate, in contrast to total VFA production and individual molar concentrations observed by Doreau et al.40. In lambs, 15% hazelnut skin reduced the proportion of butyrate and valerate, without affecting other rumen fermentation parameters14. This is very similar to present results, but no significant variation was observed in butyrate (P = 0.130). Under in vitro conditions, Niderkorn et al.41 also reported that a substrate containing 8.2% hazelnut skin and sainfoin reduced the concentration of valerate. In the present experiment, only valerate concentration was lower in L + H compared to L. This reduction in valerate would be consistent with the studies cited above. Although it was not supported by a reduction in ammonia, it would reflect the known inhibition of ruminal protein degradation by tannins42.
Fatty acid metabolism
Ruminant-derived foods are rich in SFA and poor in n-3 PUFA43, due to rumen microbial BH of dietary UFA44. On this basis, linseed has been extensively studied to increase the concentration of health promoting FA, such as very long-chain n-3 PUFA, RA, and VA32,45, in meat18,34. Dietary tannins have also been used to this aim, as they can impair the extent of BH and favor the accumulation of UFA16,46. Thanks to its polyphenol content, hazelnut skin has been successfully incorporated into ruminant diets to modulate the rumen microbiota47 and the FA profile of foods14,15,33.
Partial replacement of maize with L + H resulted in an improvement of the meat UFA composition, with increases in αLNA, very long-chain n-3 PUFA, VA, and RA. Supplementation with linseed, rich in αLNA, led us to expect higher contents of both αLNA18 and very long-chain n-3 PUFA32,34 in meat. However, the latter is not always observed (e.g., Mele et al.18, Urrutia et al.4). In the present study, proportions of eicosapentaenoic acid (EPA, 20:5 n-3), docosapentaenoic acid (DPA, 22:5 n-3), and docosahexaenoic acid (DHA, 22:6 n-3) in muscle were significantly higher in lambs fed L or L plus H diets. This points to the effect of linseed but also to a potential influence of hazelnut skin tannins on the activity of elongase enzymes, responsible for the conversion of αLNA in EPA, DPA, and DHA in animal tissues48. The presence of very long-chain n-3 PUFA in animal products may have health benefits for consumers, including anti-inflammatory or cardiovascular properties49. Furthermore, the high proportion of total n-3 PUFA lowered the n-6/n-3 ratio below 4, which is the value recommended for the prevention of cardiovascular diseases50. Yet, some studies suggest that strategies to improve meat fat healthiness should increase total PUFA, including n-3 and n-651. Both n-3 and n-6 are considered in the atherogenic index, which was not different from that of the control animals.
Other UFA with beneficial effects on human health, such as anticarcinogenic and antitumoral2,52, are RA and VA. The highest proportion of these FA was detected in L + H lambs. Rumenic acid comes from two sources. The first, and minor, one is BH of dietary LA53. However, the supply of LA in the L + H diet was lower than in the C, and the BH indices of LA in the rumen and abomasum were similar between treatments. The second origin is in the muscle, due to desaturation of VA, another intermediate of rumen BH, by stearoyl-CoA desaturase23. Nevertheless, rumen and abomasum VA concentrations did not differ among treatments and the desaturation index [calculated as c9 17:1/(17:0 + c9 17:1) ratio according to Bessa et al.43] was also similar, except in H lambs. Concentrations of VA were significantly higher in the intramuscular fat of L + H lambs. This is in line with findings reported by Priolo et al.14 when feeding lambs with 15% hazelnut skin, and by Berthelot et al.54 when linseed was used. We do not have a solid explanation for certain apparent inconsistencies between some of these results. However, it is important to note that direct comparisons of the results observed in the rumen, abomasum and muscle cannot be made. In fact, ruminal digestion processes are dynamic, but the sampling for FA profile can only be performed at a specific point in time, which obliges to cautious interpretation. The abomasal FA profile derives from a continuous flow of what actually comes out of the rumen and can be transferred to the intramuscular fat55. Finally, meat FA profile is the result of the whole feeding and metabolic processes. Although a greater consistency between abomasum and muscle FA profiles may be expected, variations due to lipid metabolism in muscle (e.g., desaturation reactions) cannot be ignored.
Moreover, it is probably worth mentioning that the higher concentration of RA, VA, and n-3 PUFA in L + H lambs would made the intramuscular fat comparable to that of grass-fed animals56, with a greater accumulation of these FA that are typical of lambs fed on pasture.
Regarding other trans 18:1 FA, t10 18:1 was the main trans FA in all treatments, consistent with the very low forage:concentrate ratio of diets used in intensive systems57. On the other hand, grazing or forage rich diets result in higher contents of t11 18:1 (VA) in animal products56, more comparable to values in lambs fed L + H. Low forage diets are known to alter rumen microbiota and lead to a shift of the BH pathways, with the formation of t10 at the expense of t11 18:1, which is called the “trans-10 shift”27. The accumulation of a large amount of t10 18:1 in animal products is associated to a higher risk of coronary heart diseases58 and therefore undesirable. In the present study, the increase in intramuscular t10 18:1 in response to linseed supplementation (in line with Bessa et al.6) was decreased by the incorporation of tannin-containing hazelnut skin (in line with Carreño et al.59 and Frutos et al.16), although the t10/t11 18:1 ratio was not statistically affected in ruminal and abomasal digesta. Regarding other trans 18:1, diets containing linseed and/or hazelnut skin (L, H, and L + H) showed higher proportions of t6 + 7 + 8, and t9 18:1 in meat, even though this was not observed in rumen and abomasum. These trans-18:1 can derive from numerous BH pathways, including OA isomerization60. In our experiment, L, H, and L + H diets provided more OA than the control, but its intramuscular accumulation did not differ among treatments. This may be accounted for by two counteracting processes: biohydrogenation of OA, as indicated by the BH index, and desaturase activity converting SA in OA in the muscle.
With regard to PUFA, despite the high amount supplied by linseed, their content in meat of L + H was not as high as expected. Nevertheless, according to the scientific literature, dietary linseed might enhance (e.g., Urrutia et al.4) or not (e.g., Andrés et al.5, Berthelot et al.54, Realini et al.34) total PUFA proportion in meat. Comparisons between studies are difficult due to interactions of types of lipid source and basal diets with ruminal BH processes6. In our work, only lambs fed the H diet tended to reduce BH and have higher meat PUFA proportion, which agrees with the results previously observed by Priolo et al.14 under similar conditions. However, although there was no significant difference in intramuscular fat (P = 0.124), the numerical value in H (1.91%) was lower than in the other 3 treatments, where it was very stable (2.40, 2.41, and 2.42% for C, L, and L + H). When we quantified FA in muscle (Suppl. Table S1), we confirmed that L + H had more PUFA than C and H (192 vs. 142 and 146 mg/100 g of muscle, respectively). Furthermore, considering that L and C lambs had no different content of PUFA, it may be hypothesized that tannins supplied by H probably protected PUFA supplied by L from ruminal BH, resulting in a greater accumulation of PUFA in the muscle of L + H. Quantification of FA in muscle (Suppl. Table S1) also confirmed the most relevant results observed as proportions, such as higher contents of total n-3 PUFA, VA, and RA (Table 7).
Finally, odd- and branched-chain FA, which originate from cellular membranes of ruminal bacteria61, have been demonstrated to be sensitive to the presence of dietary UFA62 and tannins27. This would explain the lower concentrations that we detected in lambs fed diets containing linseed and/or tannin-containing hazelnut skin, not only in rumen and abomasum, but also in muscle. This effect attributable to tannins had been found in vitro and in vivo when hazelnut skin is included in the diet14,33.
Conclusion
The inclusion of 4% of extruded linseed and 7.5% of hazelnut skin as a partial replacement of maize (L + H treatment) can be a profitable strategy for improving the fatty acid profile of the meat of fattening lambs, without adverse effects on ruminal fermentation and animal performance. The combined effects of linseed and hazelnut skin allow the enrichment of intramuscular fat with health promoting FA, such as α-linolenic acid, very long-chain n-3 PUFA, rumenic acid, and vaccenic acid. Our results suggest that tannins in hazelnut skin modulate the BH process of dietary PUFA provided by linseed, protecting them from complete biohydrogenation and favoring accumulation of desirable intermediates. Moreover, hazelnut skin tannins hinder the occurrence of the trans-10 shift in the rumen. The use of hazelnut skin as feed may be a good strategy to reduce not only the feed-food-fuel competition but also the cost of ruminant diets. Further research would be interesting to assess other quality traits of the meat of lambs fed with n-3 PUFA sources and hazelnut skin, such as oxidative stability during shelf-life and organoleptic characteristics.
Data availability
The datasets used and/or analysed during the current study available from the corresponding author on reasonable request.
Abbreviations
- αLNA:
-
α-Linolenic acid
- aNDF:
-
Amylase neutral detergent fibre
- ADF:
-
Acid detergent fibre
- ADG:
-
Average daily gain
- BH:
-
Biohydrogenation
- BW:
-
Body weight
- C:
-
Control treatment
- DM:
-
Dry matter
- DHA:
-
Docosahexaenoic acid
- DPA:
-
Docosapentaenoic acid
- EPA:
-
Eicosapentaenoic acid
- FA:
-
Fatty acid
- FAME:
-
Fatty acid methyl ester
- FCR:
-
Feed conversion ratio
- FID:
-
Flame ionization detector
- H:
-
Hazelnut skin treatment
- IMF:
-
Intramuscular fat
- L:
-
Linseed treatment
- LA:
-
Linoleic acid
- LD:
-
longissimus dorsi
- L + H:
-
Linseed + hazelnut skin treatment
- MUFA:
-
Monounsaturated fatty acid
- OA:
-
Oleic acid
- OBCFA:
-
Odd- and branched-chain fatty acid
- PUFA:
-
Polyunsaturated fatty acid
- RA:
-
Rumenic acid
- SA:
-
Stearic acid
- SFA:
-
Saturated fatty acid
- UFA:
-
Unsaturated fatty acid
- VA:
-
Vaccenic acid
- VFA:
-
Volatile fatty acid
References
Ederer, P., Baltenweck, I., Blignaut, J. N., Moretti, C. & Tarawali, S. Affordability of meat for global consumers and the need to sustain investment capacity for livestock farmers. Anim. Front. 13, 45–60 (2023).
Givens, D. I. Milk and meat in our diet: Good or bad for health?. Animal 4, 1941–1952 (2010).
Vissers, L. E. T. et al. Fatty acids from dairy and meat and their association with risk of coronary heart disease. Eur. J. Nutr. 58, 2639–2647 (2019).
Urrutia, O. et al. Effects of addition of linseed and marine algae to the diet on adipose tissue development, fatty acid profile, lipogenic gene expression, and meat quality in lambs. PLoS ONE 11, e0156765 (2016).
Andrés, S. et al. Effects of linseed and quercetin added to the diet of fattening lambs on the fatty acid profile and lipid antioxidant status of meat samples. Meat Sci. 97, 156–163 (2014).
Bessa, R. J. B. et al. Effect of lipid supplements on ruminal biohydrogenation intermediates and muscle fatty acids in lambs. Eur. J. Lipid Sci. Technol. 109, 868–878 (2007).
Moran, D. & Blair, K. J. Review: Sustainable livestock systems: Anticipating demand-side challenges. Animal 15, 100288 (2021).
Kasapidou, E., Sossidou, E. & Mitlianga, P. Fruit and vegetable co-products as functional feed ingredients in farm animal nutrition for improved product quality. Agriculture 5, 1020–1034 (2015).
Salami, S. A. et al. Sustainability of feeding plant by-products: A review of the implications for ruminant meat production. Anim. Feed Sci. Technol. 251, 37–55 (2019).
International Nut Council. International Nut and Dried Fruits. Nuts and Dried Fruits. Statistical Yearbook 2022/2023. (Reus, Spain, 2023).
Fallico, B., Arena, E. & Zappalà, M. Roasting of hazelnuts. Role of oil in colour development and hydroxymethylfurfural formation. Food Chem. 81, 569–573 (2003).
Charron, M. Exploiting the potential of hazelnut by-products in a confectionary food company. (University of Parma, 2019).
Musati, M. et al. Temperate nuts by-products as animal feed: A review. Anim. Feed Sci. Technol. 305, 115787 (2023).
Priolo, A. et al. Fatty acid metabolism in lambs fed hazelnut skin as a partial replacer of maize. Anim. Feed Sci. Technol. 272, 114794 (2021).
Renna, M. et al. Evaluating the suitability of hazelnut skin as a feed ingredient in the diet of dairy cows. Animals 10, 1653 (2020).
Frutos, P. et al. Ability of tannins to modulate ruminal lipid metabolism and milk and meat fatty acid profiles. Anim. Feed Sci. Technol. 269, 114623 (2020).
Vasta, V. et al. Invited review: Plant polyphenols and rumen microbiota responsible for fatty acid biohydrogenation, fiber digestion, and methane emission: Experimental evidence and methodological approaches. J. Dairy Sci. 102, 3781–3804 (2019).
Mele, M. et al. The use of stoned olive cake and rolled linseed in the diet of intensively reared lambs: Effect on the intramuscular fatty-acid composition. Animal 8, 152–162 (2014).
Reardon, J., Foreman, J. A. & Searcy, R. L. New reactants for the colorimetric determination of ammonia. Clin. Chim. Acta 14, 403–405 (1966).
Makkar, H. P. S., Blümmel, M., Borowy, N. K. & Becker, K. Gravimetric determination of tannins and their correlations with chemical and protein precipitation methods. J. Sci. Food Agric. 61, 161–165 (1993).
Luciano, G. et al. Feeding lambs with silage mixtures of grass, sainfoin and red clover improves meat oxidative stability under high oxidative challenge. Meat Sci. 156, 59–67 (2019).
Sukhija, P. S. & Palmquist, D. L. Rapid method for determination of total fatty acid content and composition of feedstuffs and feces. J. Agric. Food Chem. 36, 1202–1206 (1988).
Shingfield, K. J. et al. Effect of dietary fish oil on biohydrogenation of fatty acids and milk fatty acid content in cows. Anim. Sci. 77, 165–179 (2003).
Alves, S. P., Santos-Silva, J., Cabrita, A. R. J., Fonseca, A. J. M. & Bessa, R. J. B. Detailed dimethylacetal and fatty acid composition of rumen content from lambs fed lucerne or concentrate supplemented with soybean oil. PLoS One 8, e58386 (2013).
Christie, W. W. A simple procedure for rapid transmethylation of glycerolipids and cholesteryl esters. J. Lipid Res. 23, 1072–1075 (1982).
Oliveira, M. A., Alves, S. P., Santos-Silva, J. & Bessa, R. J. B. Effects of clays used as oil adsorbents in lamb diets on fatty acid composition of abomasal digesta and meat. Anim. Feed Sci. Technol. 213, 64–73 (2016).
Alves, S. P., Francisco, A., Costa, M., Santos-Silva, J. & Bessa, R. J. B. Biohydrogenation patterns in digestive contents and plasma of lambs fed increasing levels of a tanniferous bush (Cistus ladanifer L.) and vegetable oils. Anim. Feed Sci. Technol. 225, 157–172 (2017).
Ulbricht, T. L. V. & Southgate, D. A. T. Coronary heart disease: Seven dietary factors. The Lancet 338, 985–992 (1991).
Costantini, M. & Bacenetti, J. Soybean and maize cultivation in South America: Environmental comparison of different cropping systems. Clean. Environ. Syst. 2, 100017 (2021).
Broderick, G. A. Review: Optimizing ruminant conversion of feed protein to human food protein. Animal 12, 1722–1734 (2018).
Stern, M. D., Ziemer, C. J., Getz, W. R., Simms, R. H. & Glenn, B. P. By-product feeds as energy sources for ruminants. Prof. Anim. Sci. 11, 51–66 (1995).
Nguyen, D. V., Malau-Aduli, B. S., Cavalieri, J., Nichols, P. D. & Malau-Aduli, A. E. O. Supplementation with plant-derived oils rich in omega-3 polyunsaturated fatty acids for lamb production. Vet. Anim. Sci. 6, 29–40 (2018).
Campione, A. et al. Effect of feeding hazelnut skin on animal performance, milk quality, and rumen fatty acids in lactating ewes. Animals 10, 588 (2020).
Realini, C. E., Bianchi, G., Bentancur, O. & Garibotto, G. Effect of supplementation with linseed or a blend of aromatic spices and time on feed on fatty acid composition, meat quality and consumer liking of meat from lambs fed dehydrated alfalfa or corn. Meat Sci. 127, 21–29 (2017).
Shakeri, P. Pistachio by-product as an alternative forage source for male lambs: Effects on performance, blood metabolites, and urine characteristics. Anim. Feed Sci. Technol. 211, 92–99 (2016).
Valenti, B. et al. Fatty acid metabolism in lambs supplemented with different condensed and hydrolysable tannin extracts. PLoS ONE 16, e0258265 (2021).
Álvarez del Pino, M. C., Hervás, G., Mantecón, Á. R., Giráldez, F. J. & Frutos, P. Comparison of biological and chemical methods, and internal and external standards, for assaying tannins in Spanish shrub species. J. Sci. Food Agric. 85, 583–590 (2005).
Kardel, M., Taube, F., Schulz, H., Schütze, W. & Gierus, M. Different approaches to evaluate tannin content and structure of selected plant extracts—Review and new aspects. J. Appl. Bot. Food Qual. 86, 154–166 (2013).
Martin, C. et al. Increasing linseed supply in dairy cow diets based on hay or corn silage: Effect on enteric methane emission, rumen microbial fermentation, and digestion. J. Dairy Sci. 99, 3445–3456 (2016).
Doreau, M., Aurousseau, E. & Martin, C. Effects of linseed lipids fed as rolled seeds, extruded seeds or oil on organic matter and crude protein digestion in cows. Anim. Feed Sci. Technol. 150, 187–196 (2009).
Niderkorn, V. et al. In vitro rumen fermentation of diets with different types of condensed tannins derived from sainfoin (Onobrychis viciifolia Scop.) pellets and hazelnut (Corylus avellana L.) pericarps. Anim. Feed Sci. Technol. 259, 114357 (2020).
Patra, A. K. & Saxena, J. Exploitation of dietary tannins to improve rumen metabolism and ruminant nutrition. J. Sci. Food Agric. 91, 24–37 (2011).
Bessa, R. J. B., Alves, S. P. & Santos-Silva, J. Constraints and potentials for the nutritional modulation of the fatty acid composition of ruminant meat. Eur. J. Lipid Sci. Technol. 117, 1325–1344 (2015).
Jenkins, T. C., Wallace, R. J., Moate, P. J. & Mosley, E. E. Board-Iinvited Review: Recent advances in biohydrogenation of unsaturated fatty acids within the rumen microbial ecosystem. J. Anim. Sci. 86, 397–412 (2008).
Toral, P. G., Monahan, F. J., Hervás, G., Frutos, P. & Moloney, A. P. Review: Modulating ruminal lipid metabolism to improve the fatty acid composition of meat and milk. Challenges and opportunities. Animal 12, s272–s281 (2018).
Khiaosa-Ard, R. et al. Evidence for the inhibition of the terminal step of ruminal α-linolenic acid biohydrogenation by condensed tannins. J. Dairy Sci. 92, 177–188 (2009).
Daghio, M. et al. A diet supplemented with hazelnut skin changes the microbial community composition and the biohydrogenation pattern of linoleic acid in the rumen of growing lambs. Ital. J. Anim. Sci. 20, 1256–1263 (2021).
Scollan, N. D. et al. Manipulating the fatty acid composition of muscle and adipose tissue in beef cattle. Br. J. Nutr. 85, 115–124 (2001).
Calder, P. C. New evidence that omega-3 fatty acids have a role in primary prevention of coronary heart disease. J. Public Health Emerg. 1 (2017).
McAfee, A. J. et al. Red meat consumption: An overview of the risks and benefits. Meat Sci. 84, 1–13 (2010).
Salter, A. M. Dietary fatty acids and cardiovascular disease. Animal 7, 163–171 (2013).
Fan, H. et al. Trans-vaccenic acid reprograms CD8+ T cells and anti-tumour immunity. Nature 1–10. https://doi.org/10.1038/s41586-023-06749-3 (2023).
Shingfield, K. J., Bernard, L., Leroux, C. & Chilliard, Y. Role of trans fatty acids in the nutritional regulation of mammary lipogenesis in ruminants. Animal 4, 1140–1166 (2010).
Berthelot, V., Bas, P. & Schmidely, P. Utilization of extruded linseed to modify fatty composition of intensively-reared lamb meat: Effect of associated cereals (wheat vs. corn) and linoleic acid content of the diet. Meat Sci. 84, 114–124 (2010).
France, J. & Siddons, R. C. Determination of digesta flow by continuous market infusion. J. Theor. Biol. 121, 105–119 (1986).
Nuernberg, K., Fischer, A., Nuernberg, G., Ender, K. & Dannenberger, D. Meat quality and fatty acid composition of lipids in muscle and fatty tissue of Skudde lambs fed grass versus concentrate. Small Rumin. Res. 74, 279–283 (2008).
Sterk, A. et al. Effects of forage type, forage to concentrate ratio, and crushed linseed supplementation on milk fatty acid profile in lactating dairy cows. J. Dairy Sci. 94, 6078–6091 (2011).
Ferlay, A., Bernard, L., Meynadier, A. & Malpuech-Brugère, C. Production of trans and conjugated fatty acids in dairy ruminants and their putative effects on human health: A review. Biochimie 141, 107–120 (2017).
Carreño, D., Hervás, G., Toral, P. G., Belenguer, A. & Frutos, P. Ability of different types and doses of tannin extracts to modulate in vitro ruminal biohydrogenation in sheep. Anim. Feed Sci. Technol. 202, 42–51 (2015).
Mosley, E. E., Powell, G. L., Riley, M. B. & Jenkins, T. C. Microbial biohydrogenation of oleic acid to trans isomers in vitro. J. Lipid Res. 43, 290–296 (2002).
Vlaeminck, B., Fievez, V., Cabrita, A. R. J., Fonseca, A. J. M. & Dewhurst, R. J. Factors affecting odd- and branched-chain fatty acids in milk: A review. Anim. Feed Sci. Technol. 131, 389–417 (2006).
Maia, M. R. G., Chaudhary, L. C., Figueres, L. & Wallace, R. J. Metabolism of polyunsaturated fatty acids and their toxicity to the microflora of the rumen. Antonie van Leeuwenhoek 91, 303–314 (2007).
Acknowledgements
Authors would like to thank Dalma Mangimi SpA (Via Sperina Alta 18, Marene, Italy) for providing hazelnut skin.
Funding
M. Musati and A. Natalello benefit from PON “Ricerca E Innovazione” 2014–2020 research contract (Azione IV.5—E69J21011360006 and Azione IV.6—CUP E61B21004280005, respectively) supported by Ministero dell’Università e della Ricerca, Rome, Italy. This work has been supported by the project “LIVE HAZE—Hazelnut industrial by-product inclusion in livestock chains in Italy” funded by the MUR Progetti di Ricerca di Rilevante Interesse Nazionale (PRIN) Bando 2020—grant 2020244EWW. This manuscript reflects only the authors’ views and opinions, neither the European Union nor the European Commission can be considered responsible for them.
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Martino Musati: formal analysis, visualisation, data curation, writing—original draft. Pilar Frutos: supervision, visualization, writing—original draft. Antonino Bertino: formal analysis, writing—review and editing. Gonzalo Hervás: validation, data curation, writing—review and editing. Giuseppe Luciano: conceptualization, supervision, investigation, writing—review and editing. Claudio Forte: conceptualization, investigation, writing—review and editing. Alessandro Priolo: conceptualization, investigation, writing—review and editing. Massimiliano Lanza: writing—review and editing. Marco Bella: writing—review and editing. Luisa Biondi: investigation, writing—review and editing. Antonio Natalello: conceptualization, supervision, investigation, writing—review and editing.
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Musati, M., Frutos, P., Bertino, A. et al. Dietary combination of linseed and hazelnut skin as a sustainable strategy to enrich lamb with health promoting fatty acids. Sci Rep 14, 10133 (2024). https://doi.org/10.1038/s41598-024-60303-3
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DOI: https://doi.org/10.1038/s41598-024-60303-3
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