| Livestock Research for Rural Development 15 (2) 2003 | Citation of this paper |
During short-term (9 to 11 weeks) dry-season feeding in central Mali, liveweight changes in mature zebu oxen (Bos indicus) were measured to evaluate diets based on natural pasture hay and supplemented with a range of levels and types of feeds available to smallholder farmers.
Among the feeds tested cottonseed residues had the greatest effect on cattle daily liveweight change (DLWC) which was described as a curvilinear function of the amount of cottonseed residue (CR) offered over levels ranging from 0 to 4 kg.hd-1.d-1; DLWC=1.34-1.42(0.674CR). Each 1 kg.d-1 increment in offer of cowpea haulm increased DLWC by between 0.04 and 0.15 kg.hd-1.d-1. A mixture of 60% hay and 40% molasses with urea added at 10 g.kg-1 increased average daily weight gain by 0.19 kg.hd-1.d-1, compared with diets based on untreated hay. In on-farm trials, supplementation of intake from grazed natural pasture with hay ensiled with urea reduced weight loss from an average of 0.18 kg.hd-1.d-1 to 0.03 kg.hd-1.d-1 over a 2-month period at the end of the dry season.
The benefit derived from limited quantities of cottonseed residue can be increased by restricting individual animal intake and feeding more animals. Improvement of feed self-sufficiency on smallholder farms should focus on production of legume feeds with increased nitrogen content.
Livestock
production in many tropical environments is constrained by low feed availability and low
feed quality during a prolonged dry season (Leng 1984).
In the semi-arid zone of Mali such problems are illustrated by weight losses of
15-25% in mature cattle during the dry season (Wilson 1986; Bartholomew et al 1995). Dry season feed constraints are further manifest
in a reduction in the number and size of cattle offered for slaughter between April and
June each year (Direction Nationale de l’Elevage 1989) and, as supply declines,
through an increase in the unit price of beef (Delgado and Staatz 1980). Given adequate feed resources it is possible to
avoid seasonal weight loss in cattle. In short-term feeding of mature zebu castrates,
weight gains of between 0.5 and 0.9 kg.d- 1 have been shown to be
possible, both in experimental conditions (Calvet et al 1969; Calvet and Valenza 1973;
Traore et al 1973) and on smallholder farms (Bartholomew et al 1992). However, such weight gains have been heavily
dependent on the use of purchased concentrate feedstuffs or agro-industrial by-products. Supplies of these are limited and high demand
elevates prices (Baur et al 1987).
Identification
of feeding regimes that will allow small farmers to reduce their dependence on external
supplies of concentrate feedstuffs has the potential to increase the viability of
livestock production enterprises, to increase dry season beef supplies and increase
household income. However, little information
exists on livestock performance response to a range of supplementary feeds available to
smallholder farmers. The experiments described in this paper were undertaken to provide
information on productivity of cattle fed a basal diet of natural pasture hay,
supplemented with varying levels of agro-industrial by-products and home-grown legume
residues, and to identify more efficient dry-season feeding practices for small farmers.
The
effects of supplementation of a basal diet of natural pasture hay with different levels of
agro-industrial by-products, cowpea haulm (the dry residue remaining after hand-harvest of
cowpea grains) and urea-treatment of hay on the liveweight changes of mature male zebu
castrates were assessed in feeding trials carried out in four successive hot dry-seasons
in the semi-arid zone of Mali. Experiments 1 and 2, each of 77 days duration, were
researcher-managed and carried out on-station. Experiments
3 and 4 were conducted on smallholder farms with day-to-day management of livestock
carried out by cooperating farmers, over feeding periods of 65 days in each case.
The
animals used for the experiments were mature male castrate zebu cattle (Bos indicus), typically oxen at the end of their
working career. Eighteen of each experimental group were zebu Maure, of provenance
northern Mali or Mauritania, and eighteen were zebu Peul (white Fulani), originating from
the Niger delta area of Mali. All the animals
were purchased in markets within their respective zones of origin and were trekked to the
experimental site (between 100 and 200 km). For up to two weeks after arrival, until the
beginning of the trial, the cattle were grazed on dry natural pasture during the day and
enclosed at night. During this pre-experimental period all animals were weighed and
ear-tagged, vaccinated against rinderpest and contagious bovine pleuro-pneumonia and
subject to a deworming treatment with "Dovenix"(a)
(Nitroxinil) and injected with "Berenil"(a) (Diminazene) for control of any trypanosome
infestation. Subsequent veterinary attention was given to individual animals as necessary,
for external parasite control and for some cases of jaw abscesses. Average liveweights at
the beginning of experiment 1 were 269 (±21.8 SD) kg for Maure and 263 (±21.7 SD) kg for
Peul animals. The average liveweight of each group at the beginning of experiment 2 was
302 (± 24.7 SD) kg and 277 (±22.6 SD) kg for Maure and Peul, respectively. Throughout each trial the animals were housed in
individual pens covered by a straw shade. All feeding and watering was made on an
individual basis and drinking water was available ad
libitum throughout the experiments.
In
both trials the basal roughage offered was a mixture of grasses from natural pasture
harvested as dry standing hay in February-April. The predominant species in the hay were Pennisetum pedicellatum, Schoenfeldia gracilis, Loudetia togoensis and Cenchrus biflorus.
This hay was fed in rations that included molasses
and urea or dried cowpea haulms and cottonseed residues in pellet form containing 45%
cotton seed cake, 50% cotton seed husks and 5% salt.
In experiment 1, three “hay presentation” treatments were supplemented
with the cottonseed residue supplement offered at 2 or 4 kg.d-1. These main-treatment feeding levels were arranged
in a 3 x 2 factorial layout to give a total of six feeding regimes. The “hay presentation” treatments
consisted of unchopped hay offered either alone, with 2 kg.d-1 of cowpea haulm,
or mixed with molasses and urea in proportions of 40% molasses and 60% hay, with urea
added at 10 g.kg-1 of the mixture. In
all treatments hay, or hay mixed with molasses and urea, was offered ad libitum to an average refusal level of 15%. In experiment 2, feeding treatments were cowpea
haulm offered at 1 or 2 kg.d-1 and cottonseed residue offered at 0, 1 or 2 kg.d-1. Cowpea and cottonseed feeding treatments were
combined factorially to provide six levels of supplementation to natural pasture hay
offered unchopped and ad libitum to a refusal of
a mean 25%.
Feeds
were provided for each animal in an individual feed trough, consisting of one half of a
225 Liter barrel cut longitudinally, partitioned to allow separate estimation of intake of
hay and one supplementary feed. In treatments
that included cowpea haulm in addition to cottonseed residue, the latter was offered in a
bucket adjacent to the main feed trough. The daily allowance of each feed, according to
treatment, was provided by mid-morning each day throughout the experiments. In both trials
levels of offer were based on air-dry feed weights. Feed intakes were estimated daily for
each animal throughout the feeding period by measure of the amount of feed offered to each
animal and of the feed refusal from the previous day.
Samples of refused and offered feeds were collected on four days each week
throughout the experiments, and were dried in a forced-air oven at 100 °C to allow
estimation of oven-dry weights of feed intakes. A sample of each offered feed was taken on
one day each week for chemical analysis. Samples were bulked by treatment and sub-sampled
for chemical analysis for estimation of nitrogen content of feeds by micro-Kjeldahl
digestion. For experiment 1, estimates of
metabolizable energy (ME) intake were derived from measured DM intakes of each ration
component and from standard figures for the materials used (Boudet 1978; MAFF 1975) as
follows; 2.1, 8.2, 11.2 and 12.7 MJ.kg-1 feed for hay, cowpea haulm, cottonseed
residues and molasses respectively.
In
on-station trials animals were ranked by weight within breed and blocked in groups of six.
Feeding treatments were allocated at random within each block. Each ration treatment was
thus replicated six times to allow analysis of the effects of treatments on intake and
liveweight change in a randomized block layout. In
both experiments the animals were weighed weekly and animal mean daily liveweight change
was calculated by linear regression of the weight of individual animals at successive
weighings against time. The calculated regression coefficients were subject to analysis of
variance for estimation of the effect of different supplementation treatments on mean
daily liveweight change. An additional comparison of performance of the different breeds
in experiments 1 and 2 was made by "t" test of the mean daily liveweight gain of
each breed, averaged over feeding treatments and replications.
In
experiment 2 the body condition of each animal was assessed at the beginning and end of
the trial using the 9-point scale described by Nicholson and Butterworth (1986).
In
an on-farm evaluation (experiment 3) 14 cooperating farmers constructed above-ground
mud-brick silos to ensile urea-treated natural pasture hay and used the material produced
as supplementary feed for their work oxen during the late dry season (April-June). Each farmer ensiled approximately 600 kg of
natural pasture hay, harvested as dry standing-crop. This material was similar in species
composition and quality to the hay used in experiments 1 and 2. The hay was mixed 1:1 (w/w) with water in which
fertilizer-grade urea had been dissolved at 40 g urea per kg of water to give a urea
inclusion rate of 4% of dry hay. Following
treatment the hay was covered with grass matting and the silo was sealed with a 20 cm
layer of mud and fermented for approximately 14 days. A total of 30 work oxen (ten per
treatment) on 14 smallholdings were subsequently fed over a period of 65 days in one of
the following ways; (1) with grazed pasture (in the form of dry standing natural pasture
hay) alone, (2) with grazed pasture and urea-treated hay offered at 6 kg.hd-1.d-1
or, (3) with grazed pasture supplemented with 6 kg.hd-1.d-1 of
urea-treated hay and 0.5 kg.hd-1.d-1 of cottonseed residue. All
animals were grazed on village common-land and had similar access to grazed feed. In the following dry season these procedures were
repeated (experiment 4), except that cottonseed residue allowance was increased from 0.5
to 1.0 kg.hd-1.d-1. Average
liveweight of oxen at the beginning of each feeding period was 281 (±58.5 SD) kg in
experiment 3 and 289 (±61.7 SD) kg in experiment 4.
Feeding
treatments were allocated to specific animals after discussion with the group of farmers
and it was then left to each farmer-owner to apply the designated treatments, with
periodic oversight from technical staff. Measurement
of treatment effect was limited to twice-monthly weighing of animals. In on-farm trials feeding treatments were
distributed across farms and were replicated ten times.
Estimation of mean daily liveweight change was made using the regression procedure
adopted for on-station experiments. Comparison of the effects of feeding treatment on
weight change was made by analysis of the calculated regression coefficients of liveweight
against time for each animal in a completely randomized design of ten replicates.
Feeding
treatment effects on feed intakes and liveweight changes are summarized in Tables 1 and 2
for experiments 1 and 2 respectively. Since
there was no significant interaction effect (P>0.05) between feeding treatments in
either experiment only main treatment means are presented.
Table 1. Effect
of form of presentation of hay and of level of supplementation with cottonseed residue on
main-treatment mean daily feed intakes and liveweight changes in zebu castrates
(Experiment 1). |
|||||
|
Hay
DM intake, kg.d-1 |
Total
DM intake, kg.d-1 |
ME
intake, MJ.d-1 |
Nitrogen
intake, g.d-1 |
Weight
change, kg.d-1 |
Presentation
of hay |
|
|
|
|
|
Hay
alone |
3.93 |
6.72 |
39.9 |
114.4 |
0.87 |
Hay
+ molasses + urea |
4.86 |
9.64 |
70.1 |
157.3 |
1.06 |
Hay
+ 2 kg.d-1 cowpea haulm |
3.00 |
7.76 |
54.0 |
143.9 |
0.95 |
SEM |
0.220*** |
0.269** |
1.42*** |
3.24*** |
0.041** |
Level
of supplementation |
|
|
|
|
|
2
kg.d-1 cottonseed residue |
4.23 |
7.50 |
46.0 |
110.9 |
0.86 |
4
kg.d-1 cottonseed residue |
3.63 |
8.58 |
63.3 |
166.2 |
1.06 |
SEM |
0.180* |
0.220*** |
1.16*** |
2.65*** |
0.033*** |
Asterisks
indicate levels of F probability derived from analysis of variance tables and follow the
convention (***) P<0.001, (**) P<0.01 and (*) P<0.05 |
|||||
For
experiment 1, average nitrogen contents of the ration components were 4.5, 9.5, 16.9 and
34.4 g.kg-1 feed, for hay, molasses-urea treated hay, cowpea haulm, and
cottonseed residues respectively. Dry matter content of the materials fed was 974 g.kg-1
for hay and cowpea haulm, 963 g.kg-1 for cottonseed residues, and 822 g.kg-1
for molasses treated hay. Mean DM intakes of
cottonseed supplement were 3.67 kg.hd-1.d-1 and 1.92 kg.hd-1.d-1
respectively for the 4 and 2 kg.hd-1.d-1 levels of offer.
Differences in cottonseed residue intake according to the form of presentation of hay were
not significantly different (P>0.05). Cowpea
haulm was readily consumed by the animals to which it was offered and its intake was not
significantly (P>0.05) affected by level of cottonseed residue feeding. Mean daily intake of cowpea was 1.90 kg DM.hd-1,
from 2 kg.hd-1.d-1 of air-dry (1.95 kg DM) material offered. The
amount of hay consumed was influenced by its form of presentation and by level of intake
of cottonseed supplement (Table 1). An average intake of 1.90 kg DM.hd-1.d-1
of cowpea haulm reduced daily hay intake by a mean of 0.93 kg.hd-1
(P<0.001). In contrast, an increase in mean DM intake of cottonseed supplement from
1.92 kg.hd-1.d-1 to 3.67 kg.hd-1.d-1,
decreased mean hay intake by only 0.60 kg.hd-1.d-1 (P<0.05). Increase in offer of cottonseed supplement
from 2 kg.hd-1.d-1 to 4 kg.hd-1.d-1 decreased
hay intake by averages of 0.34, 0.50 and 0.99 kg.hd-1.d-1 on hay
alone, hay mixed with molasses and urea, and hay plus cowpea haulm treatments
respectively. This interaction between treatments was not significant (P>0.05).
Supplementation
with cowpea haulm resulted in an average increase in total intake of 1.03 kg DM.hd-1.d-1,
compared with hay supplemented with cottonseed residues only. The advantage of the
additional cowpea was more apparent with the 2 kg.hd-1.d-1 level of
cottonseed input, by an increase of 1.36 kg DM.hd-1.d-1 in total
intake, compared with the higher level of cottonseed supplementation which showed only a
0.71 kg DM.hd-1.d-1 increase in intake attributable to the
additional cowpea input. Total nitrogen
intake was highest with diets based on molasses-urea treated hay, but the dietary nitrogen
concentration was greatest with diets supplemented with cowpea haulm. The lowest nitrogen
concentration was observed with offered rations of hay and 2 kg.hd-1.d-1 of
cottonseed residue, at 14.4 g.kg-1 feed and the highest with hay, 4 kg.hd-1.d-1
of cottonseed residue and 2 kg.hd-1.d-1 of cowpea haulm, at
28.1 g.kg-1 feed.
In
experiment 2 average nitrogen contents of the ration components were 5.5, 15.9 and 38.0
g.kg-1 feed, for natural pasture hay, cowpea haulm and cottonseed residues
respectively. Dry matter content of feeds was 935 g.kg-1 for natural pasture
hay, 933 g.kg-1 for cowpea haulm and 915 g.kg-1 for cottonseed
residues. Levels of refusal of cowpea haulm
and cottonseed residues were on average less than 30 g DM.d-1, and intakes
therefore reflect closely the amounts of these feeds offered. Average daily DM intake of
cowpea haulm was 0.93 and 1.81 kg.hd-1 at levels of offer of 1 and 2 kg.hd-1.d-1
respectively. For cottonseed residues DM intakes were 0.88 and 1.81 kg.hd-1.d-1
at feeding levels of 1 and 2 kg.hd-1.d-1. Addition of cottonseed residue to the diet
increased hay intake above the level obtained without residue feeding by a mean 35.7% with
0.88 kg.hd-1.d-1 of cottonseed intake, and by 38.3% with an average
daily intake of 1.81 kg DM.hd-1 of cottonseed residue (Table 2). On average
over cowpea feeding treatments, the addition of 1 kg.hd-1 of cottonseed residue
each day increased daily feed intake by 45.8%, and 2 kg.hd-1 of cottonseed
residue increased daily feed intake by 71.9%, in comparison with rations without
cottonseed residue supplementation (P<0.001). An increase in the amount of cowpea
offered, from 1 to 2 kg.hd-1d-1, increased mean total daily feed
intake by only 10.7% (P<0.01). Through a combined effect of increased DM intake and
increased nitrogen content in diets, the mean daily nitrogen intake was doubled by
addition of 1 kg.hd-1 of cottonseed residue, and tripled with 2 kg.hd-1,
compared with the average nitrogen intake on rations without cottonseed residue. An
increase in cowpea intake from 0.93 to1.81 kg DM.hd-1.d-1, in
contrast, resulted in a mean increase of 18% in daily nitrogen intake. (Table 2.)
Table 2. Effect
of level of supplementation of natural pasture hay with cottonseed residue and cowpea
haulm on main-treatment mean dietary nitrogen concentration, daily feed intakes and
liveweight changes in zebu castrates (Experiment 2). |
|||||
|
Hay DM intake, kg.d-1 |
Total DM
intake, kg.d-1 |
Nitrogen
intake, g.d-1 |
Nitrogen
in feed, g.kg-1 |
Weight
change, kg.d-1 |
Cottonseed
residue offered |
|||||
0 kg.d-1 |
2.77 |
4.13 |
38.5 |
9.4 |
-0.15 |
1
kg.d-1 |
3.76 |
6.02 |
80.4 |
13.5 |
0.43 |
2 kg.d-1 |
3.83 |
7.10 |
118.4 |
17.1 |
0.67 |
SEM |
0.231** |
0.237*** |
1.34*** |
0.33* |
0.046*** |
Cowpea
haulm offered |
|||||
1 kg.d-1 |
3.62 |
5.43 |
72.6 |
12.7 |
0.24 |
2
kg.d-1 |
3.29 |
6.01 |
85.6 |
13.9 |
0.39 |
SEM |
0.189 NS |
0.193* |
1.10*** |
0.40*** |
0.038** |
Liveweight
changes
In
experiment 1 all the diets produced increases in liveweight (Table 1). The highest mean
daily liveweight gain (DLWG) of 1.12 kg.hd-1.d -1 was obtained with
animals fed on molassed hay and 4 kg.hd-1.d -1 of cottonseed residue
and the lowest (0.72 kg. hd-1.d -1) with those fed on untreated hay
and only 2 kg.d-1 of cottonseed supplement. Addition of the molasses-urea mix
to feeds increased daily liveweight gains by means of 18.4 and 10.8%, compared with diets
consisting of hay and cottonseed alone or of hay, cowpea haulm and cottonseed residues. The marginal benefit of supplementation with cowpea
haulm in addition to 2 kg.d-1 of cottonseed residue was an increase in
liveweight gain of 0.07 kg.d-1 for each 1 kg of cowpea haulm.
In experiment 2 animals fed on diets that did not include some supplementation with cottonseed residue lost weight throughout the trial. With 2 kg.d-1 of cowpea haulm supplementation the daily weight loss was 0.05 kg, equivalent to a total loss of just under 4 kg in 77 days, but with only 1 kg of cowpea haulm per day the mean total loss during the feeding period was just over 19 kg, at an average loss of 0.25 kg.d-1. In contrast the inclusion of 1 kg.d-1 of cottonseed residue produced an average gain of 33 kg over the liveweight at the start of the trial, representing a net gain of 45 kg in comparison with the treatments without cottonseed residue supplementation. The average gain from use of a further 1 kg.d-1 of cottonseed residue, to a total of 2 kg.d-1, was approximately 18 kg, or 0.24 kg.d-1 (Table 2).
Differences
in breed performance were small in experiment 1 with an average of 0.94 kg.d-1
for Maure animals and 0.97 kg.d-1 for Peul (P>0.05). In experiment 2 the average daily weight change of
the two breeds over 77 days of feeding in experiment 1 was 0.38 kg.d-1 for
Maure and 0.25 kg.d-1 for Peul animals, but again the difference was not
significant (P>0.05).
In
experiment 1 differences in DLWG were almost equally well explained by variations in
estimated total DM intake (DMI) as by variations in total metabolizable energy intake
(MEI). The relationships of total DM intake and ME intake to DLWG were as follows:
DLWG
= 0.081 (±0.0139) DMI + 0.306 (r2
= 0.50, P<0.001)
DLWG = 0.008 (±0.0014) MEI +
0.505 (r2 = 0.51, P<0.001)
There
was no evidence of a consistent relationship between dietary N concentration or total N
intake and DLWG. By contrast, in experiment 2
variation in daily liveweight change (DLWC) was better described by change in total daily
nitrogen intake (NI) than by levels of total feed intake (DMI).
DLWC
= 0.0104 ("±0.0008)
NI - 0.511 r2 = 0.84 (P<0.001)
DLWC = 0.226 (±"0.0221)
DMI - 0.979 r2 = 0.76 (P<0.001)
In
the mature oxen studied one unit change in body condition was associated with a weight
change of approximately 21 kg. Within the
range of body condition observed (points 2-7 on the 0-9 scale), total weight change (WC)
and body condition change (C) approximated a linear relation;
WC
= 21.3 ("±3.66) C + 8.21 r2
= 0.50 (P<0.001)
The
effect of treatments on weight change is shown in Table 3.
Feeding of urea-treated hay to supplement intake from grazed pasture produced, at
best, a very slight increase in weight over the feeding period and on average reduced the
rate of daily weight loss, compared with pasture alone, by 0.15 kg.hd-1. As in experiments 1 and 2, addition of cottonseed
residue to the diet had the greatest impact on weight change.
Table 3. Effect of 65 days
supplementation with 4% urea-treated hay and with cottonseed residue on mean daily weight
change (kg) of zebu oxen in village receiving a basal diet of natural pasture by grazing |
||
Supplementary
feed |
Weight
change (Expt.
3) |
Weight
change (Expt.
4) |
No
supplement
|
-0.15 |
-0.20 |
Urea-treated
hay
|
0.04 |
-0.10 |
Urea-treated
hay + 0.5 kg cottonseed residue |
0.05 |
|
Urea-treated
hay + 1 kg cottonseed residue |
|
0.24 |
SEM |
0.016*** |
0.050*** |
In
experiment 1 zebu castrates were shown to be able to gain weight at a rate of 0.72 kg.d-1
on a diet based on natural pasture hay supplemented with 2 kg.d-1 of cottonseed
residue. Addition of dry cowpea haulm to this diet increased daily weight gain, but not
sufficiently to justify its use economically; partial-budget analysis of the results
showed that the marginal value of cowpea hay in weight gain was approximately half of its
value in direct sale (Baur et al 1987). Feeding
levels for experiment 2 were selected in order to investigate the effect of reduction in
cottonseed residue supplementation and its substitution by cowpea, and thus to evaluate
feeding practices adoptable by smallholder farmers using home-grown forages as a primary
source of supplementation to low quality roughages. As expected therefore, the absolute
performance levels observed in experiment 2 were lower than in the earlier trial. In
similar treatments (hay supplemented with 2 kg.d-1 of cowpea haulm and 2 kg.d-1
of cottonseed residue) weight gain (0.74 v 0.85 kg.d-1) and feed conversion
efficiency (9.7 v 8.6 kg DMI.kg-1 gain) were lower than the earlier trial, but
still within norms reported in other work with similar animals (Calvet and Valenza 1973).
There
was a marked contrast between the trials in weight change response to level of nitrogen
intake. This effect may reflect a response to increase in nitrogen concentration from
sub-optimal levels, and an associated increase in N intake in experiment 2. With diets based on molasses-urea treated hay,
productivity in relation to estimated energy intake was consistent with expectations based
on feeding standards (MAFF 1975). With other feeding treatments, particularly those
consisting of hay and cottonseed residue alone, performance was higher than apparent
energy intakes would predict. The inconsistency may serve to emphasize comments by Preston
(1985) and Chenost and Kayouli (1997) that feeding standards based on assigned nutritive
values may be misleading when applied to unconventional or poor quality feedstuffs. Under
such circumstances there is little substitute for in
vivo assessment of their value in a ration (Orskov 1986). These observations should have particular
resonance in sub-sahelian Africa, where poor quality hay or crop residue is often the
principal feed resource and where facilities for feed analyses are often either not
available or are prohibitively expensive. The
results of the experiments reported show that DM intake may be as good an indicator of
animal performance as estimated feed value. In resource-limited research systems simple
intake trials may therefore serve as an effective means of assessing the usefulness of
novel feeds or ration combinations. Combining
results from the two trials suggests that the relation of liveweight change to total feed
DM intake follows a curvilinear form;
DLWC
= 0.53 (±"0.069) DMI - 0.02 (±"0.005) DMI2 - 1.79 (r2 =
0.80)
In a comparison of Maure and Peul animals up to two years of age, under experimental conditions, no difference between performance of the two breeds was observed (ILCA/IER 1978). In contrast, observations made in-village with mature animals of both breeds, showed a mean liveweight gain of Maure cattle 62% greater (P<0.01) than that of Peul animals (Bartholomew et al 1992). Breed performance in experiment 1 showed no significant or substantial difference between Maure and Peul, but it is possible that any difference in productivity between breeds was obscured by confounding of breed and age in this trial. Results from experiment 2 reflected the in-village observations with mean daily weight change of Maure animals showing a 52% advantage over the Peul, although this difference was not statistically significant (P>0.05). In view of its potential practical and economic significance, further research into relative breed performance, particularly with older animals of the type used for fattening, appears to be justified.
Cottonseed
residue (CR) was fed at levels ranging from 0 to 4 kg.d-1 in experiments
carried out both on-station and on-farm. In
spite of differences in levels of cowpea supplementation and treatment of roughage with
urea, the impact of cottonseed supplementation on weight gains was quite consistent across
experiments. The following relation between cottonseed residue intake and daily weight
gain was derived from the combined results;
DLWC
= 1.339-1.423(0.674CR) r2=0.90
The
diminishing-response nature of the relation shows the possibility for increasing the
benefit derived from limited supplies of cottonseed residue; for example, a reduction in
supplementation level from 4 to 2 kg.d-1, would reduce the average growth rate
of an animal from 1.04 to 0.69 kg.d-1 but with a fixed supply would allow
supplementation of twice the number of animals and offer a potential increase in daily
gain of over 32%, without unduly compromising individual animal performance.
On-farm
trials with “no supplementation” treatments, served to emphasize that the real
benefit of dry season feed supplementation for cattle is compounded of the weight gained
during the experimental period and of the weight that would have been lost during the same
period in the absence of supplementation. Over
a ten-week feeding period the average net weight increase from supplementation with 1 kg.d-1
of cottonseed residue is therefore estimated at 41 kg, and at 64 kg with supplementation
at 2 kg.d-1, compared with animals maintained on natural pasture hay alone.
The
results demonstrate the inadequacy of traditional supplementation practice using dry
cowpea residues (average 16.4 g N.kg-1 feed) for fattening livestock. In
contrast, feeding cottonseed residue supplement with high nitrogen content (38.0 g N.kg-1
feed), even in relatively small quantity, was effective in increasing overall ration
nitrogen content and liveweight gain. This illustrates the potential value of a legume
forage of high nitrogen content and suggests that forage production research targeted at
smallholders should focus on identification of legumes, or on improved harvest or storage practices, that will
maintain a high nitrogen content up to harvest and through dry-season storage. If farmers
can be encouraged to produce even limited quantities (on the order of 200 kg DM.hd-1)
of high quality (N content of 25 g.kg-1) legume forage for supplementary
feeding they should be able to increase livestock production while minimizing their burden
of forage production.
Urea-treated
hay as a sole source of supplement may be useful for reduction in dry-season weight loss
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the technique merits further investigation in conjunction with other feed sources as a
possible means of maximizing the benefit of small quantities of legume hay or
agro-industrial by-product.
This
work was carried out by a joint ILCA-INRZFH team working under the auspices of Projet
Sectoriel de l'Elevage 688-0218, financed jointly by USAID and the Government of the
Republic of Mali.
a Mention
of trade names or commercial products in this article is solely for the purpose of
providing specific information and does not imply recommendation or endorsement by the
U.S. Department of Agriculture.
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Received 27 January 2003, Accepted 19 February 2003