Introduction
Recent studies with swine have indicated that replacing a portion of
the inorganic trace minerals with chelated forms can improve performance. Veum et
al. (1995) reported that replacing 15 to 36% of the supplemental inorganic
zinc, iron, copper, and manganese with chelated metal proteinates increased
gain and gain:feed in nursery pigs. Supplementing sows with a mixture of zinc,
copper, and manganese proteinate improved reproductive performance compared
with sows supplemented with only inorganic trace minerals (Mirando et al.,
1993). There has been increasing environmental concerns recently regarding
excretion of zinc in swine waste. Chelated forms of zinc may exhibit greater
bioavailability than commonly used inorganic forms of zinc. Therefore, use of
zinc proteinate in swine diets may allow for a lower inclusion rate in the diet
and thus, reduced excretion of zinc in waste. The present study was conducted
to determine the effects of: 1) zinc level and 2) replacing 25 to 50% of
supplemental inorganic zinc with zinc proteinate on performance, immune
response, and zinc status of nursery pigs.
Materials and Methods
One hundred ninety-two crossbred weanling pigs (3-weeks-old) were
allotted to 24 pens based on weight, sex, and litter origin. Pens were randomly
assigned to treatments. Each pen contained 8 pigs and each treatment consisted
of 4 replicate pens. Treatments consisted of: 1) 50 ppm supplemental zinc (100%
zinc sulfate (ZnSO4)), 2) 50 ppm supplemental zinc (25% zinc
proteinate (ZnP), 75% ZnSO4), 3) 50 ppm supplemental zinc (50% ZnP,
50% ZnSO4), 4) 150 ppm supplemental zinc (100% ZnSO4), 5)
150 ppm supplemental zinc (25% ZnP, 75% ZnSO4), 6) 150 ppm
supplemental zinc (50% ZnP, 50% ZnSO4). Zinc proteinate (Bioplex
zinc) was provided by Alltech, Inc.
The nursery phase lasted a total of 35 days. A two-phase diet system
was used. Phase 1 diet was fed for the first 14 days following weaning and the
phase 2 diet was fed the last 21 days of the nursery period. Pigs were weighed
and feed intake was determined weekly.
Blood samples were obtained from 8 pigs per treatment on days 14 and 28
for determination of plasma zinc concentrations and alkaline phosphatase
activity. In vivo cellular immune response was investigated on day 32 of the
study using a phytohemagglutinin (PHA) skin test. Eight pigs per treatment were
injected subcutaneously with 0.1 ml PHA (150 µg/ml). Skin thickness was
measured using calipers at 0, 6, 12, 24, and 48 hours after injection.
Thirty-six pigs were killed at the end of the study and samples of liver, bone,
and pancreas were collected for zinc analysis.
Results and Discussion
Pigs supplemented with 50 ppm of zinc gained faster (P < .05)
and consumed more (P < .10) feed than pigs supplemented with 150 ppm
of zinc during the first 14 days of the study (Table 1). Zinc level did not
affect gain, feed intake, or gain:feed during phase 2 or for the entire nursery
period. In pigs fed 50 ppm of zinc, replacing a portion of the ZnSO4
with ZnP tended to improve gains and feed intakes during phase 1. In the 150
ppm zinc treatments, pigs that received 50% of their supplemental zinc from ZnP
had a higher (P < .05) gain and gain:feed than pigs fed 25% of zinc
from ZnP over the entire nursery period.
Alkaline phosphatase, a zinc dependent enzyme, was not affected by zinc
level or source. Plasma zinc concentrations were higher in pigs supplemented
with 150 ppm compared to those supplemented with 50 ppm of zinc. Source of zinc
did not affect plasma zinc concentrations. Liver, bone, and pancreas zinc
concentrations were higher (P < .05) in pigs supplemented with 150
ppm of zinc. In pigs fed the higher zinc level, replacing 25 or 50% of the
ZnSO4 with ZnP resulted in decreased zinc concentrations in bone but not in
liver or pancreas. In vivo cellular immune response was not significantly affected by
zinc level or source. However, pigs receiving ZnP tended to have a greater
skinfold thickness response to PHA administration than pigs receiving only ZnSO4.
|
Treatment |
|
|||||
|
50 ppm zinc |
150 ppm zinc |
|
||||
|
ZnSO4 |
25% ZnP |
50% ZnP |
ZnSO4 |
25% ZnP |
50% ZnP |
SE |
Gain, kg/d |
|
|
|
|
|
||
Day 0 - 14 |
.271 ab |
.287 a |
.296 a |
.251 b |
.240 b |
.277 ab |
.013 |
Day 15 - 35 |
.498 ab |
.536 a |
.495 ab |
.515 ab |
.480 b |
.527 ab |
.018 |
Total |
.408 ab |
.437 a |
.416 ab |
.411 ab |
.385 b |
.429 a |
.013 |
Intake, kg/d |
|
|
|
|
|
|
|
Day 0 - 14 |
.407 a |
.425 ab |
.461 b |
.416 a |
.394 a |
.415 a |
.015 |
Day 15 - 35 |
.886 a |
1.004 b |
.948 ab |
.912 a |
.916 a |
.928 ab |
.029 |
Total |
.697 a |
.775 b |
.756 ab |
.716 ab |
.711 a |
.725 ab |
.021 |
Gain:Feed |
|
|
|
|
|
|
|
Day 0 - 14 |
.664 |
.678 |
.643 |
.606 |
.609 |
.669 |
.031 |
Day 15 - 35 |
.562 ab |
.535 ab |
.523 a |
.566 ab |
.524 ab |
.568 b |
.015 |
Total |
.585 ab |
.565 ab |
.552 ab |
.575 ab |
.542 a |
.592 b |
.015 |
Summary
Results of this study indicate that 50 ppm of supplemental zinc is
adequate for growth and immunity in nursery pigs. Replacing 25 or 50% of the
supplemental inorganic zinc with zinc proteinate tended to improve gain and
feed intake of pigs receiving 50 ppm of added zinc.
References
Mirando, M.A., D.N. Peters, C.E. Hostetler, W.C. Becker, S.S. Whiteaker, and
R.E. Rompala. 1993. Dietary supplementation of proteinated trace minerals influences
reproductive performance of sows. J. Anim. Sci. 71 (Suppl. 1):180.
Veum, T.L., D.W. Bollinger, and M. Ellersieck. 1995. Proteinated trace minerals and
condensed fish protein digest in weanling pig diets. J. Anim. Sci. 73 (Suppl.
1):186.