Palm kernel cake (PKC) is a by-product of the palm oil industry. Malaysia is the world's largest producer of palm oil and obviously of PKC, which, with its content of 14 to 16 % crude protein and 9·5 to 10·5 MJ metabolisable energy per kg, is a good feed for ruminants(Reference Jalaludin and Ivan1) and is exported to Europe in high quantities for use in diets of dairy and beef cattle. However, PKC also contains high amounts (11 to 55 mg/kg DM) of Cu(Reference Jalaludin and Ivan1–Reference Jalaludin, Jelan and Abdulah3), which is potentially toxic to sheep due to their relative sensitivity to excessive dietary Cu as compared with cattle(Reference Underwood4). In addition, the Cu in PKC is highly soluble in the rumen(Reference Jin, Alimon and Abdulah5) and its absorption is elevated due to the absence of rumen ciliate protozoa(Reference Ivan, Veira and Kelleher6) resulting from feeding PKC(Reference Abubakr, Alimon and Yaakub7). Because the excess of absorbed Cu is accumulated in internal organs, mainly the liver, which are consumed by humans, it is important to use dietary means to decrease the dietary Cu absorption and tissue accumulation not only in sheep, but in all ruminants fed PKC regardless of their susceptibility to the chronic Cu toxicity. Several dietary supplements and their combinations (S, Mo, Fe, Zn, bentonite, etc) have been shown to decrease dietary Cu absorption. However, supplements of S plus Mo appear to be most effective(Reference Ivan, Rusihan and Alimon8). Although a high number of experiments on effects of S–Mo supplements in PKC-based diets have been conducted in Malaysia and the results presented at local conferences, only a small proportion has been published in scientific journals. In addition, no optimal amounts of supplemental S and Mo required in dietary PKC to prevent chronic Cu toxicity in ruminants have been established. Since high concentrations in the liver of both Cu and Mo could be harmful to consumers, it is important that not only the concentration of Cu, but Mo also, is monitored when dietary Mo supplements are used to decrease the Cu absorption from the dietary PKC. It was, therefore, the main objective of the present experiment to establish optimal amounts of dietary S and/or Mo needed to decrease the absorption of Cu from PKC-based diets to an acceptable level, without excessive accumulation of dietary Mo in the liver of lambs. An additional objective was to monitor potential negative effects of S–Mo supplements on the growth and feed intake of lambs. The objectives have been achieved and the results are presented in the present paper.
Materials and methods
A total of eighty Malin cross lambs, aged approximately 8 months, with body weight of 14·2 (sd 0·9) kg were used in the present 6-month feeding experiment. Of the eighty lambs, eight were randomly selected at the start of the experiment (before feeding the experimental diets), and after sampling of blood the lambs were slaughtered and their livers were removed and sampled. The concentrations of mineral elements in the plasma and liver samples of the lambs were used to establish the starting baseline concentrations.
The remaining seventy-two lambs were divided according to live weight into two blocks (large and small). Thereafter, four lambs from each block were assigned at random to nine treatment groups of eight lambs each. The treatment groups were housed in individual pens with wooden slotted flooring and automatic water drinking nipples in an open wooden sheep barn raised above the ground. Each group was fed ad libitum one of nine total mixed experimental diets (Table 1). Feed refusals were collected, weighed and sampled daily. The diets were based entirely on solvent-extracted PKC and supplemented with limestone to correct for the Ca:P imbalance in PKC, due to its relatively high P (4·37 g/kg DM) and lower Ca (2·80 g/kg DM) concentrations. Individual diets were also supplemented with sodium sulfate (Na2SO4) as the source of dietary S and/or ammonium molybdate ((NH4)6Mo7O24·4H2O) as the source of the dietary Mo. There were two levels of supplemental S; level 0 (S0) or level 1 (S1 = 1 g S/kg DM) and four levels of supplemental Mo; level 0 (Mo0), level 1 (Mo1 = 4 mg Mo/kg DM), level 2 (Mo2 = 8 mg Mo/kg DM), level 3 (Mo3 = 16 mg Mo/kg DM) and level 4 (Mo4 = 32 mg Mo/kg DM). This was in addition to the PKC content of S (approximately 2 g/kg DM) and Mo (approximately 0·8 mg/kg DM). Therefore, there were nine dietary treatments in the experiment: (1) S0Mo1, (2) S0Mo2, (3) S0Mo3, (4) S0Mo4, (5) S1Mo0, (6) S1Mo1, (7) S1Mo2, (8) S1Mo3 and (9) S1Mo4. Because lambs fed a PKC diet without a dietary S or Mo supplement could die due to Cu toxicity before a 6-month experiment is completed(Reference Ivan, Rusihan and Alimon8, Reference Alimon and Hair-Bejo9), it was decided that feeding a control PKC monodiet (PKC plus appropriate vitamins and mineral supplements) without both sodium sulfate and ammonium molybdate supplements (S0Mo0) would not be practical. Consequently, such a control diet was not included in the present experiment. The PKC was sampled and diets mixed and sampled every 10 d. The samples (including feed refusals) were dried in an oven over 2 d at 60°C, ground through a 1 mm sieve and stored at − 20°C. The PKC used in the present experiment contained (per kg DM): crude protein, 140 g; acid-detergent fibre, 443 g; Cu, 24·6 mg; Zn, 35·4 mg; Mn, 102 mg; Fe, 1·21 g; Ca, 2·80 g; P, 4·37 g; Mg, 1·83 g. The total mixed diets were bagged and kept in a cold place. All lambs were weighed on two consecutive days at the beginning and the end of the experiment, following an overnight withdrawal of food and water. The average of the two consecutive weighing was recorded and considered as the mean of the initial or final live weight. The lambs were also weighed and weights recorded at monthly intervals during the experiment. Blood samples were obtained at the beginning and the end of the experiment. Individual feed intakes were recorded daily and the lambs had free access to fresh drinking water. Care of the experimental animals was in accordance with the Malaysian standards (including Halal slaughter) and the experimental protocol was approved by the Institutional Animal Care and Use Committee.
ADF, acid-detergent fibre.
* S is sodium sulfate supplement (level 0, none; level 1, 4·4 g sodium sulfate/kg DM, equivalent to 1 g S/kg DM); Mo is ammonium molybdate supplement (level 0, none; levels 1, 2, 3 and 4, 0·013, 0·026, 0·052 and 0·103 g ammonium molybdate/kg DM, equivalent to 4, 8, 16 and 32 mg Mo/kg DM, respectively).
† Contained (per g vitamin mix): retinol, 1 mg; α-tocopherol, 35 μg.
During the second month of the experiment, one lamb from each of the S0Mo1 and S0Mo4 treatments was removed from the experiment due to decreased feed intakes, most probably resulting from the environmental stress (hot and humid local climate). Similarly, one lamb from each of the S0Mo4 and S1Mo0 treatments was removed during the third month of the experiment. The data from these lambs were removed from the records. After 3 months, two (treatments S0Mo1, S0Mo4, S1Mo0 and S1Mo4) or three (treatments S0Mo2, S0Mo3, S1Mo1, S1Mo2 and S1Mo3) lambs per treatment and after 6 months (end of the experiment) all the remaining five lambs in each treatment were slaughtered following blood sampling and their livers were removed. All blood samples were taken from the jugular vein using heparinised vacuum tubes and the plasma was collected after centrifugation at 3500 rpm for 30 min and stored at − 4°C. The livers were frozen ( − 20°C) until processing later. After thawing, the livers were sliced, blended and sampled. The samples were oven dried at 60°C until they reached cold constant weight, ground in a blender, and stored in plastic containers at − 20°C until analysed.
Crude protein in the diets and PKC samples were determined using the Kjedahl procedure, while acid-detergent fibre was determined according to Van Soest et al. (Reference Van Soest, Robertson and Lewis10). Samples of PKC, diets, plasma and livers were digested in a nitric acid–perchloric acid mixture and analysed for Cu, Fe, Zn, Ca, Mg and Mn using atomic absorption spectroscopy. Different standard solutions, including blank and five graded mineral concentrations, were prepared for each mineral element (Cu, Fe, Zn, Ca, Mg and Mn) and for each kind of sample (feed, liver and plasma). The measurements in the standard solutions were used for the calculation of mineral concentrations in the appropriate samples. The concentration of Mo in livers was determined according to Khan et al. (Reference Khan, Cloutier and Hidiroglou11).
The experiment was a randomised complete block design with the sheep group fed the same experimental diet being the experimental unit. All results were statistically analysed as two-way ANOVA using the GLM procedure of SAS (SAS Institute, Inc., Cary, NC, USA)(12) with treatment as the fixed effect and live weight group as the block. When the treatment effect was significant, Duncan's multiple-range test was used to determine the differences among treatment means and significance was declared at P < 0·05.
Results
Live weight, feed intake, daily gains and feed conversion efficiency
There were no significant differences among treatments in average live weight, dietary DM intake, daily gain and feed:gain ratio after 3 or 6 months of feeding the experimental diets (Table 2). The highest (126 g) and the lowest (105 g) average daily gains were recorded at 6 months for treatments S0Mo2 and S1Mo1, respectively. Similarly, overall 6-month feed intake (g/d per lamb) was lowest (650) for treatment S0Mo4 and highest (861) for treatment S1Mo4, while feed:gain ratio was lowest (6·07) for treatment S0Mo4 and highest (7·11) for treatment S1Mo4.
* The 3 months values are means of seven lambs for diets S0Mo1, S0Mo4, S1Mo0 and S1Mo4, and of eight lambs for diets S0Mo2, S0Mo3, S1Mo1, S1Mo2 and S1Mo3; all 6 months values are means of five lambs each; none of the differences between means were significant (P>0·05).
† For details of the diets, see Table 1.
Mineral element concentrations (μg/ml) in blood plasma
There were no effects (P>0·05) of treatments on the concentrations of Cu and Zn in blood plasma (Table 3). The initial Cu and Zn concentrations were similar to the concentrations recorded for individual treatments at the end of the experiment. The Cu concentrations ranged between 1·11 (treatment S1Mo1) and 1·52 (treatment S1Mo2), while those of Zn ranged between 1·14 (treatment S1Mo4) and 1·60 (treatments S1Mo0 and S1Mo2).
a,b,c,d Mean values within a column with unlike superscript letters were significantly different (P < 0·05).
* The initial values are means of eight lambs and the final values are means of five lambs.
† For details of the diets, see Table 1.
The highest (4·93) and lowest (2·93) plasma concentrations of Fe (P < 0·05) were obtained for treatments S0Mo1 and S1Mo1, respectively. The concentrations for treatments S0Mo2, S0Mo4, S1Mo1, S1Mo2, S1Mo3 and S1Mo4 were lower (P < 0·05) than the initial concentration and that for treatment S0Mo1. In addition, the Fe concentration for treatment S0Mo3 was lower (P < 0·05) than for treatment S0Mo1.
The plasma concentration of Ca was significantly higher initially than for all treatments at the end of the experiment. It was also higher (P < 0·05) at the end of the experiment for treatments S1Mo0 and S1Mo2 than for treatments S1Mo1 and S1Mo3, and lower (P < 0·05) for treatments S0Mo1, S0Mo2 and S0Mo4 than for treatment S1Mo0.
The plasma concentration of Mg ranged from 21·9 (treatment S1Mo3) to 30·7 (treatment S0Mo3). The concentration was higher (P < 0·05) for treatment S1Mo0 than the initial concentration and for treatments S1Mo1, S1Mo3 and S1Mo4. The rest of the differences were not significant.
Mineral element concentrations (μg/g DM) in the liver
In comparison with the initial value (376), the liver Cu concentration within the first 3 months of the experiment (Table 4) significantly increased only for treatment S1Mo0 (1258), but there were also other treatments (S0Mo1, S0Mo2 and S0Mo3) that reached values of over 1000 (1069 to 1137). One treatment (S1Mo4) showed a numerical value (161) that was apparently lower than the initial value (376), but at the end of the experiment (6 months) there were three treatments (S1Mo2, S1Mo3 and S1Mo4) with apparent values (254 to 327) being lower than the initial. The liver Cu concentrations at 6 months of the experiment for treatments S0Mo1, S0Mo2, S0Mo3 and S1Mo0 were all over the value of 1000 (1090 to 1294) and significantly higher than the initial concentration and those for the other treatments (S1Mo1, S1Mo2, S1Mo3 and S1Mo4), except that S0Mo4 that was not different (P>0·05) from any other treatments or from the initial concentration.
a,b,c Mean values within a column with unlike superscript letters were significantly different (P < 0·05).
* The initial values are means of eight lambs, the 3 months values are means of two lambs for diets S0Mo1, S0Mo4, S1Mo0 and S1Mo4, and of three lambs for diets S0Mo2, S0Mo3, S1Mo1, S1Mo2 and S1Mo3; all 6 months values are means of five lambs each.
† For details of the diets, see Table 1.
The liver concentrations of Zn at 3 months of the experiment were not different (P>0·05) among the treatments or from the initial value. However, at the end of the experiment (6 months) the initial liver Zn concentration was numerically higher than those of all treatments and different (P < 0·05) from treatment S1Mo1. Similarly, there were no differences (P>0·05) in the liver Mn concentration at 3 months of the experiment. However, at 6 months, although the initial value was not different (P>0·05) from the values of all treatments, the concentration for treatment S0Mo3 was higher (P < 0·05) than for other treatments, except for treatment S0Mo4. The liver Mo concentration at 3 months of the experiment was higher (P < 0·05) for treatment S0Mo2 (10·1) than was the initial concentration (6·00), but was not different (P>0·05) from treatments S0Mo3 and S1Mo4. At the end of the experiment (6 months) the concentration of Mo was higher (P < 0·05) for treatment S1Mo3 (9·06) than was the initial value (6·00), but the differences between the initial value and those for all other treatments were not significant.
There were no significant differences in the liver Ca concentrations (Table 5). Similarly, there were no significant differences in the concentrations of Fe and Mg at 3 months of the experiment. However, in comparison with the initial liver Fe value the concentrations for all treatments numerically increased by the end of the experiment (6 months) and the differences were significant for treatments S1Mo0, S1Mo1, S1Mo2, S1Mo3 and S1Mo4. There were no significant differences in the liver Fe concentration among treatment means. Concerning the final 6-month liver Mg concentration, the numerical values for all treatments (499 to 655) were apparently lower than the initial value (695), but the differences were significant only for treatment S1Mo1 (499). There were no significant differences in the liver Mg concentrations among the treatment means.
a,b Mean values within a column with unlike superscript letters were significantly different (P < 0·05).
* The initial values are means of eight lambs, the 3 months values are means of two lambs for diets S0Mo1, S0Mo4, S1Mo0 and S1Mo4, and of three lambs for diets S0Mo2, S0Mo3, S1Mo1, S1Mo2 and S1Mo3; all 6 months values are means of five lambs each.
† For details of the diets, see Table 1.
Discussion
The results of the present experiment clearly show that both S and Mo supplements are needed to maintain normal concentrations of Cu in the liver of sheep fed a PKC monodiet. Such supplements did not affect growth and feed intake. It has been established(Reference Bostwick13) in sheep liver that Cu concentrations of up to 500 mg/kg DM are considered normal, but that over 800 mg/kg DM hypercuprosis and stress-induced haemolytic crisis may develop. In the present experiment, treatment S1Mo2, consisting of a PKC monodiet supplemented (per kg DM) with 1 g S and 8 mg Mo (resulting in overall dietary concentrations of S and Mo of approximately 3 g and 8·8 mg/kg dietary DM, respectively) produced optimal results. The growth, feed intake and plasma Cu concentrations were normal and not affected by the supplements. More importantly, the liver concentrations of Cu and Mo were also normal and not different from the initial concentrations. In addition, treatment S1Mo1 with the same amount of dietary S (3 g/kg DM) but lower dietary Mo (4·8 mg/kg DM) produced a higher liver Cu concentration (573 mg/kg DM) than is considered normal (up to 500 mg/kg DM), while treatments S1Mo3 and S1Mo4, providing the same amount of the dietary S but more (16·8 and 32·8 mg/kg DM, respectively) dietary Mo, produced the same liver Cu concentration as treatment S1Mo2, but with elevated liver Mo concentrations. It should be pointed out that these elevated liver Mo concentrations for treatments S1Mo3 and S1Mo4 were significantly higher than the liver Cu concentration for treatment S1Mo0, while the liver Mo concentration for treatment S1Mo2 was not.
Considering that the range of Cu concentration in Malaysian PKC is from 11 to 55 mg/kg DM(Reference Jalaludin and Ivan1–Reference Jalaludin, Jelan and Abdulah3) the presently used PKC with an average Cu concentration of 25 (sd 9) mg/kg DM is close to the middle of the range and probably represents the Cu concentration in the majority of the PKC produced in Malaysia. In addition, the diets used in the present experiment were based entirely on PKC. Therefore, if we consider the S and Mo supplements in treatment S1Mo2 as optimal for preventing chronic Cu toxicity and excessive accumulation of Cu and Mo in the liver, then it would be logical to assume that the dietary supplements of approximately 1 g S and 8 mg Mo are required per kg PKC DM to be used in the diet. This would be appropriate for lambs that were not previously fed untreated PKC and having a normal liver Cu concentration. Otherwise, much higher amounts of the dietary Mo supplement might be needed.
It has been reported that during the later part of the prehaemolytic stage and the haemolytic stage of Cu toxicity, liver Cu concentrations may range from 1000 to 3000 mg/kg DM(Reference Bostwick13). In reported Cu poisoning in a sheep flock(Reference Hidiroglou, Heaney and Hartin14) the average monthly hepatic Cu concentrations in sheep that died of Cu toxicity were between 745 and 1251 mg/kg DM. To rapidly reduce death losses(Reference Hidiroglou, Heaney and Hartin14) a treatment with dietary supplements of 0·1 g ammonium molybdate and 1 g sodium sulfate per sheep per d was used, but after 4 months there were still dead sheep with high hepatic concentrations. In another case, 500 mg ammonium molybdate per kg dietary DM completely eliminated deaths of sheep from Cu toxicity within 5 months(Reference Hair-Bejo and Alimon15). In contrast, together with S the dietary Mo supplements between 4 and 23 mg/kg DM were effective to reduce hepatic Cu concentration to normal levels(Reference Ivan, Rusihan and Alimon8, Reference Kline, Hays and Cromwel16–Reference Van der Schee, Garretsen and Van der Berg18). However, the effectiveness of dietary Mo supplements may depend on the initial Cu status of the animal(Reference Gray and Daniel19) and on the dietary Cu concentration and its biological availability for absorption and utilisation. Indeed, the rumen solubility(Reference Jin, Alimon and Abdulah5) and biological availability of Cu in PKC may be quite high due to elimination of the protozoa population in the rumen by the dietary PKC(Reference Abubakr, Alimon and Yaakub7). The increase in the Cu bioavailability due to the elimination of ciliate protozoa from the rumen might amount to between 15 and 50 %(Reference Ivan, Veira and Kelleher6, Reference Ivan and Entz20). Nevertheless, supplements of 4·4 g Na2SO4 and 25·8 mg (NH4)6Mo7O24·4H2O per kg of the dietary PKC were optimal in the present experiment to maintain over the 6-month period appropriate hepatic concentrations of Cu and Mo in normal lambs.
It was established decades ago that dietary Mo in the presence of adequate S can reduce the hepatic Cu accumulation and storage(Reference Dick21–Reference Hogan, Money and Blayney25) and that both organic and inorganic S affect the absorption of Cu to a limited degree only(Reference Suttle22, Reference Suttle26). However, the present experiment showed that it is possible to feed PKC monodiets to normal lambs without Cu or Mo toxicosis when supplements of 4·4 g Na2SO4 and 25·8 mg (NH4)6Mo7O24·4H2O (or 1 g S and 8 mg Mo) per kg dietary PKC are used. In addition to high concentrations of Cu, PKC is also high in the concentrations of P and Fe. The Ca:P ratio can be easily corrected by a Ca supplement. The range of Fe concentration in PKC is between 0·8 and 6 g per kg DM (1·2 (sd 0·7) g/kg DM in the PKC used in the present experiment). Excessive dietary concentrations of Fe may result in bent legs of lambs(Reference Hidiroglou, Dukes and Ho27) and in decreased productivity of dairy cows(Reference Coup and Campbell28). Although the S plus Mo supplements in the present experiment decreased the concentration of Fe in blood plasma, the concentrations in the liver were actually increased. The increase in the hepatic Fe concentration due to S plus Mo supplements is contrary to a previous report(Reference Ivan, Rusihan and Alimon8) and the reason is presently not known. Besides the effects of dietary S and Mo supplements on the hepatic concentrations of Cu, Mo and Fe the concentrations of other measured elements (Zn, Mn, Mg and Ca) were not affected appreciably by the supplements.
In conclusion, supplements of 4–5 g Na2SO4 and 26 mg (NH4)6Mo7O24·4H2O (or 1 g S plus 8 mg Mo) per kg PKC DM mixed into the PKC used are sufficient to maintain lambs on diets containing any amount of PKC (including PKC monodiets) without an excessive hepatic accumulation of Cu and Mo, and without potential chronic Cu poisoning. Therefore, the present results suggest that any amount of PKC treated with appropriate S, Mo and Ca (to balance for excessive P concentrations in PKC) supplements can be incorporated in the diets of ruminants. This is under condition that the other dietary ingredients do not contain an excessive Cu concentration. It should be emphasised, however, that in comparison with other feeds, PKC is unique. First, PKC contains an unusually high concentration (11 to 55 μg/g DM) of Cu(Reference Jalaludin and Ivan1–Reference Jalaludin, Jelan and Abdulah3). Second, the Cu in PKC is rapidly released and highly soluble in the rumen(Reference Jin, Alimon and Abdulah5). Third, PKC reduces or eliminates protozoa from the rumen(Reference Abubakr, Alimon and Yaakub7) due to its relatively high content of oil that is toxic to rumen ciliate protozoa(Reference Ivan, Mir and Koenig29, Reference Ivan, Entz and Mir30). It has been documented(Reference Ivan, Veira and Kelleher6, Reference Ivan and Entz20, Reference Ivan31, Reference Ivan32) that elimination of protozoa from the rumen increases the dietary Cu bioavailability and accumulation in the liver of sheep. Therefore, the present results on the need of the dietary S and Mo supplements to eliminate the risk of chronic Cu toxicity due to dietary PKC cannot be extrapolated to other potential high-Cu feeds used as the dietary ingredient. In Malaysia the presently allowed up to 30 % inclusion of PKC in diets of sheep due to the potential Cu toxicity problem may be extended to any amounts of up to PKC monodiets (PKC plus appropriate vitamins and mineral supplements) for all ruminants with the condition that an appropriate dietary supplement of S plus Mo is mixed in the PKC used. However, the animal acceptability, practicability, and the ruminant production efficiency of diets containing high amounts of PKC (over 50 %) or of PKC monodiets have not been established; additional experiments are needed to elucidate the optimal and practical dietary PKC concentrations in ruminants. This would expand the safe use of PKC, which is in abundance in Malaysia, as a common feed for all ruminants.
Acknowledgements
This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors.
A. R. A. facilitated supplies, and supervised experimental work, chemical analysis and evaluation of the results, while M. I. developed the hypothesis and experimental protocol and wrote the manuscript. S. J. provided guidance and consultations throughout the course of the study. The authors thank Ms Li Juan for conducting the experimental work with lambs, chemical analysis, and the calculation and tabulation of results.
There are no conflicts of interest.