Herders' knowledge on mineral nutrition and implication on sheep and goat productivity in Marsabit South District, Kenya
M I Lengarite, P N Mbugua*, C K Gachuiri* and L W Kabuage*
Kenya Agricultural Research Institute, KARI-Marsabit, P.O Box 147, Marsabit, Kenya
moslengarite@hotmail.com
* Department of Animal production, Faculty of Veterinary Medicine, University of Nairobi, Kenya
Abstract
A cross-sectional survey was undertaken in Merille location, Marsabit South
district of northern Kenya to assess indigenous knowledge on mineral
nutrition of sheep and goats. Questionnaires were administered to herders
randomly selected from three purposively selected pastoral settlements.
Information was collected on indicators of mineral adequacy and
deficiencies, mineral nutrition practices and health and production
characteristics of sheep and goats.
The results showed that herders
could identify mineral deficiencies (81.3%) and adequacies (87.0%) in their
herds using indigenous knowledge. The indicators of mineral adequacy were
healthy appearance, shiny skin and fatness, while those of mineral
deficiencies were poor health conditions, rough coat, pica and slow growth
in sheep and goats. Eighty five percent of respondents observed mineral
deficiencies to dry season pastures, while 45.7% observed mineral
deficiencies in the wet season. Ninety four percent of respondent used local
supplementary remedies such as grazing animals on salty plants, facilitating
access by stock to saline water and natural salt licks. Halophyte plants,
such as Lycium europaeum, Salsola dendriodes, and Salvadora persica
species, which are mostly found in the riverine, emerged as the most
prominent salt supplements for herds. Traditional indicators of low
productivity, which included general poor health, pica, and diarrhea among
others were different (P<0.05) between sites. The herders indigenous
knowledge on mineral nutrition demonstrated by the herders need to be
recognized and form part of mineral nutrition interventions in the area.
The riverine ecosystem rich in mineral resources
of salt lick, halophyte plants and salty waters, and perceived to be
declining, need to be protected and sustainably utilized.
Key words: feed, migration, pastoralism, rangelands, survey, traditional knowledge, water
Introduction
Local knowledge is an important asset for
smallholder farmers who operate differently in diverse crop and livestock
production systems in the tropics (Komwihangilo et al 2007). Pastoral
producers in the arid and semi-arid lands of northern Kenya, rely mostly on
the indigenous knowledge system in the management of their flocks/herds of
sheep and goats. The traditional lifestyle involves seasonal migration of
herds in search of pasture and water (Langill and Ndathi 2002). Migratory
pastoralism remains the most important land use system allowing full
exploitation of resources that are unequally distributed in space and time
(Ellis et al 1988) as well as managing risks. Seasonal movement of herds is
a common feature in pastoral system and affects livestock production and
rangeland utilization (Schwartz et al 1991).
The pastoral herding system has
implication on feed, mineral and water availability for the animals
(Kaufmann 1998). It enables the animals to access wide rangeland areas and
exposes them to different soils, forages and water sources. Consequently,
the animals are able to obtain mixed diets that provide a wide range of
nutrients (Schillhorn van Veen and Loeffler 1990). This system of production is however
gradually changing, from migratory to sedentary pastoralism in vicinities
proximal to trading settlements (Harry 1999). The shift to sedentary herding
system, which is characterized by limited mobility, influences small
ruminant productivity.
Several studies conducted in the
rangelands of northern Kenya, indicate that sheep and goats are the most
dominant livestock species kept by sedentary pastoralists. DeVries and
Pelant (1987) noted that sedentary households keeping a significant
proportion of sheep and goats are likely to adapt more readily to a
sedentary lifestyle. Traditionally, grazing distance in sheep and goats are
adjusted to allow the frequent watering regime. This limits small ruminant
mobility, thus they have access to poor quality pastures near permanent
water sources. The reduced degree of mobility is likely to expose small
ruminants to nutrient deficiencies, including minerals, which can adversely
affect herd productivity.
Pastoral sheep and goat producers
recognize the value of mineral nutrition as exemplified by their efforts to
move animals to areas with natural salt licks, salty plants and saline water
sources (Kariuki and Letitiya 1998). Consumption of salty plants and saline
water sources are used as traditional remedies to deworm sheep and goats (Lengarite
and Mbuvi 2004). Soil licks in specific localities of the lowlands are also
collected for supplementing sheep and goats in high altitude areas. Mobile
herds have been observed by pastoralists to have high craving for soil licks
and saline waters than sedentary herds. In the low lands of northern Kenya,
indigenous mineral supplementation strategies are commonly used to correct
mineral deficiencies in camel herds (Kuria et al 2004). The
information gathered on indigenous knowledge on mineral nutrition will
contribute to mineral nutrition interventions for semi-sedentary small
ruminant herds, in Marsabit South district.
The objectives of the
study were: (i) To assess herders knowledge on mineral nutrition in sheep
and goat production; (ii) To establish the traditional indicators on
perceived mineral inadequacies and adequacies; (iii) Identify traditional
mineral sources and supplementary remedies.
Materials and Methods
The study was
conducted in Merille location (1o39’-55’N, 37o64’-85’E,
409m asl) of Marsabit South District in northern Kenya. The area is
inhabited by Rendille and Arial pastoral communities and is a major market
outlet for livestock in the district. The area is characterized by an arid
climate with an annual mean, rainfall of 275mm (Xiaogang 2005) and
temperatures ranging between 28-42oC. The annual precipitation is
distributed between two seasons, the short rains occurring from November to
December and the long rains from March to May.
The landscape of
the area is characterized by basement hill outcrops, prominent seasonal
river originating from Mathew ranges, and the sedimentary plain sloping
towards the east. The seasonal riverine valley forms an integral grazing
ecosystem for small ruminants throughout the year. The soil texture derived
from basement system of rocks range from deep sandy, sandy loam to stony
sandy loam (Touber 1991). The major vegetation types found in the area
are riverine woodland, dwarf shrubs and shrub grass land. The dominant
vegetation along the riverine includes Acacia tortilis, Cordia
sinensis, Salvadora persica and under storey of annual grasses and
herbs. In the sedimentary plains and hills, the woodland vegetation consists
of Acacia and Commiphora communities and dwarf shrubs of
Indigofera spinosa, Sericocomopsis hildebrandtii and Barleria
acanthoides.
Systematic random
sampling survey technique was used to gather data on indigenous knowledge on
mineral nutrition. The survey involved administering questionnaires to 60
households in three purposively selected pastoral settlements in the study
area. The pastoral settlements (sampling units) had roughly the same
households, about (30-40). In each settlement a list was compiled and 20
households were randomly selected to participate in the survey. The
proportion of the 20 households selected in each of the settlement
represented about (50-60%) of the households. The three pastoral
settlements, namely Kamotonyi, Lorora and Salt lick (located on the south,
west and eastern part of the location, respectively) represented the main
semi-sedentary settlements, spatially spread and use different grazing areas
of Merille location. The grazing areas correspond to the settlements.
To estimate herd
productivity, data on herd characteristics, which included annual market
sales, age at first breeding, annual number of young stock (360-720 day old)
owned and number showing low performances were collected.
Data analysis
The data was coded in
MS Excel and the variables with normal distribution analyzed using
statistiXL version 1.7 (MS excel 2007). The normally distributed
multivariate data was subjected to one way analysis of variance and means
between study sites were compared using student Newman Keuls test.
Results and Discussion
The flock
characteristics are shown in Table 1. The mean flock/herd size per household
was 65±7.8 and 46±7 for goats and sheep respectively. The herds were mainly
dominated by goats (59%), with a sheep to goat ratio of 1:1.4. The higher
number of goats could be attributed to the higher fecundity of goats
compared to sheep. Also goats, are better adapted to survive on low quality
feed resources than sheep. The mean age at first breeding was 400 and 444
days for sheep and goats, respectively. The observed mean age at first
mating of 444 days in goats, was comparable to the mean age of 438 days
reported in pastoral goats in southern Ethiopia (Tolera and Abebe 2007).The
recommended age of first breeding in meat sheep and goats was 12 months (Mbogo
2007). Sheep and goats in the study area delayed in the attainment of the
first breeding age, resulting to low flock/herd reproductive performance.
The mean market
off-take for goats was 24.3% which was higher (P< 0.05) than that of sheep
(22.1%). The off take (proportion of sheep and goats sold per herd/flock in
a year), was lower than those earlier estimated (34.2% and 41.4% in sheep
and goats), in Marsabit district (Schwartz et al 1991). However, the
off-take rate of sheep and goats in the area was higher than the national
small ruminant off-take rate of 14 % (Kiptarus 2007). Household herd size
plays an important role in determining herd offtake rates (McPeak 1999). In
Marsabit district, pastoral households with large herds participate more
actively in livestock markets (Barrett et al 2005). The most marketed age
class was animals between 360 and 720 days of age with an overall mean of
40.2% and 42.4% of respondents in sheep and goats, respectively. The
(360-720 days) age category dominated the local small ruminant meat market
in Merille. The high offtake of sheep and goats in Merille could be
attributed to large herd sizes and functional local market. Of the
sheep and goats marketed, 54.3 and 54.5% comprise of male, while 45.7 and
45.6% were in the female categories respectively. Pastoral households
usually retain breeding female animals, and prefer to sell male animals,
which constitute the non-producing component of the small ruminant
population (Njiru 1983).
Traditional grazing system of
small ruminants
It is a common practice
among pastoralists to designate forage resources routinely used during
favorable periods as primary grazing sites (Ndikumana et al 2000). The
semi-sedentary settlements have commonly preferred grazing areas with
specific vegetation types. The mean number of grazing sites used by
households was 3.7 (Table 2). In the dry season small ruminant herds cover
considerable distance, with a mean radius of 9.7 km, and shorter distances
of 4.6 km in the wet season (Table 2). The grazing radius was strongly
influenced (P<0.05) by season and the study area. In the wet season
increased forage availability results into shorter grazing distance while
poor quality forages in the dry season forces the animals to travel longer
distances. Sanon et al (2007) in the study of grazing behavior of sheep,
cattle and goats, observed that animals spent more time walking to the
grazing sites in the dry season than rainy season.
Study sites varied in
grazing distances, with animals in Kamotonyi settlement covering longer
distances as compared to Lorora and Salt lick due to lack of suitable
pasture and overgrazing around the Kamotonyi. Grazing animals followed
specific routes and used different vegetation types. In a single grazing
bout herds used a mean of three vegetation types in the dry season and two
in the wet season. The number of vegetation types covered was higher in the
dry season than wet season, ascribed to longer distances traveled to grazing
sites. To overcome the poor condition of pastures in the dry season, herders
resort to graze animals in distant pastures and travel through more
vegetation types.
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Means along a row for study area (abc) or column for
season (df) with different superscripts are significant (P<0.05).
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Traditional indicators of
perceived mineral deficiencies and adequacies
Perceived mineral
adequacies and deficiencies were observed by 87% and 81.3% of respondents,
respectively (Table 3). A high proportion of respondents (85%) associated
mineral deficiencies to dry season pastures, while only about 45.7% observed
mineral deficiencies in the wet season.
The traditional
indicators of mineral adequacy in sheep and goats were given as healthy
appearance, shiny skin, fatness, fast growth and high milk yield. However,
the indicator on milk yield was valued in goats and fast growth rate only in
sheep. The key indicators of mineral adequacy were healthy appearances
(82.8%, 84.5%) and a shiny skin (55.2%, 35%) for sheep and goats
respectively (Table 4). Fatness was a lesser indicator of mineral adequacy
and was indicated by 24.1% and 13.8% of respondents for sheep and goats
respectively.
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*Not valued as indicator by herders |
During the dry season, a
decline in the quantity and quality of available pasture was assumed to
result in low mineral consumption and thereby perceived deficiency. Herders
perceive that animals exposed to good pastures were less vulnerable to
disease attack. The improved health status and skin appearances observed
mostly in the wet season, were attributed to adequate diet and salt
consumption. In northern Kenya, pastoral communities such as the Samburu
place great value on natural salt claiming that it improves health, prevent
illness and has curative properties for worms (Kariuki and Letitiya 1998).
Conversely the
indicators of mineral deficiencies in sheep and goats were poor health,
rough skin coat, pica and slow growth in young stock (Figure 1). Poor health
was a strong indicator of mineral deficiency status of herds. About 74.3%
and 86.4% of respondents attributed poor health to mineral inadequacies in
sheep and goats, respectively. Pica was ranked second by 35.6% and 30.4% of
respondents in sheep and goats respectively. Rough hair coat as an indicator
was third reported by 28% and 33.1% of respondents in sheep and goats
respectively. Perceived slow growth was less attributed to mineral
deficiencies in sheep and goats (Figure 1). It can be concluded that healthy
appearance and shiny skin were the key indicators of mineral adequacy.
Disease incidences such as contagious caprine pleuropneumonia (CCPP) and
parasite infestation such as ectoparasites and helminths were among the
major health problems affecting pastoral herds in Kenya (Kosgey et al 2008)
The deficiency of minerals in the diet may accentuate parasitic infestation
leading to severe clinical signs of diseases (Szefer and Nriagu
2007).
Sources of minerals and practices
of mineral supplementation
Two
percent of the respondents in the study area supplemented sheep and goats
with commercial minerals formulations. However, 94% of respondents used
local supplement remedies such as grazing on salty plants, facilitating
access by the stock to saline water and salt lick. Salty
plants emerged as the main mineral source for sheep and goats in the study
area, mostly the Lycium europaeum, Salsola dendriodes, and Salvadora
persica species. Salty forage plants are good natural sources of
minerals and animals at the same time access water in green forages (Dinucci
and Zeremariam 2003). However, halophyte plants are characterized by high
accumulation of minerals in the above ground tissues, which limit their use
in animal feeding (Al-Dakheel et al 2008).
Approximately 93% of respondents reported a high abundance of local
supplementary sources of salty plants, salty wells and salt licks within the
riverine area while 42.5% reported availability in the bush shrub land
grazing areas (Table 5). Due to their ability to tap retained underground
moisture, most salty plants are found within the seasonal riverine area.
Merille riverine valley seasonally becomes flooded with waters originating
from the Mathew ranges on the west. The waters carry salt and sediment and
upon drying they form natural salt licks along the riverbed.
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Mineral supplementary
sources
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Area of abundance (local sources) |
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Ten salty
plants were identified by herders, who however noted that the abundance of
these plants was declining (Table 6). Important salty plants (Figure 2)
browsed by sheep and goats were Salvadora persica (SP)
Dactyloctenium aegyptium (DA), Indigofera hochstetteri (IH),
Salsola dendroides (SD) Bauhimia taitenis (BT) and
Lycium europaeum (LE). The Rendille herders in the
Marsabit district have been reported to move camels to access salt rich
plants such as Salsola dendroides (Kauffmann 1998). Analysis of salty
plants by Kuria (2004) in south west Marsabit showed that Lycium
europaeum, Salsola dendriodes, Salvadora persica, Indigofera hochstetteri
and Dactyloctenium spp. had sodium levels of 24, 54, 15, 1 and 28 gkg-1DM,
respectively. Except for Indigofera hochstetteri, which was low in
Na, these plants accumulate sodium and levels surpass sheep and goats (Na)
requirement of 1g Na/Kg DM.
Watering herds/flocks in
the salty wells was one way of providing minerals to sheep and goats during
the dry season. Direct ingestion of soil from natural salt licks may
supplement the intake of some minerals (Mayland and Wilkinson 1996).
However, in the study area, natural salt lick was not an important local
mineral supplement compared to salty plants and water sources.
A study conducted in Peru confirmed that natural licks had higher
concentration of minerals than non-salt lick soils (Montenegro 2004). It
appears that salty plants and water sources satisfied the salt
supplementation needs of herds in the area. Where naturally occurring salt
content is high, the salt component of the mineral supplements need to be
substituted with other palatable stimulators such as molasses (McDowell
1996).
Herders in the study
area have wealth of knowledge on mineral nutrition as indicated by their
ability to identify rich sources of minerals. Indicators of a rich mineral
source varied among respondents, with soil type (66%) identified as major
indicator of rich mineral resources of an area. Drinking water was second
(45%) and the vegetation type found in an area. third (40%). The natural
salt lick (29.7%) was the least indicator of rich mineral sources. The
semi-sedentary herds grazing on salty plants and drinking salty waters had
less preference for salt licks. Herders perceive that soils influence the
type of vegetation and water found in an area.
Traditionally, soils are classified by use of color. White colored
soils are linked to high salt content and availability of natural salt licks
and salty waters. Respondents also perceive that various type of drinking
water vary in taste, level of sediments and salt content.
In the study area,
herders recognized the mineral value of forage plants, drinking water and
natural salt lick. However, over the last 20 years, the number of accessible
salty water sources and salty plants have both declined by 40 % (Table 6).
The most preferred forage plants and natural salt licks have also declined
by about 17.6% and 25% respectively. Natural salt licks found along watering
points provide animals with minerals (Njoro 2003). The general decline in
the availability of key mineral sources could be ascribed to overgrazing in
the semi-sedentary settlements, and reduced accessibility of natural salt
licks and salty waters found in specific localities.
Proportion of small ruminants
(360 to 720 days old) with low productivity
Growing sheep and goats
are an important class of small ruminants that dominate in herd market
offtake and form the foundation of future sheep and goat herd. The
proportions of growing animals in a herd are generally indicators of herd
productivity. Young animals were perceived to succumb to diseases with
under-nutrition and mineral inadequacies leading to loss of weight. The
traditional indicators of reduced productivity in young sheep and goats were
poor health, slow growth, weight loss, pica, skin diseases and diarrhea.
These indicators were significantly different (P<0.05) between study sites.
There were more sheep and goats with low productivity, based on these
indicators, in Lorora than in other areas (Tables 7 and 8).
A higher proportion of
growing sheep (42.6% ) had poor health, 41% had diarrhea, 24% had suffered
from skin diseases, 25.4% showed pica, 26% loss of weight and 9.1%
showed stunted growth (Table 7). In the young goats, about 33.8% showed poor
health, 20% stunted growth, 17% loss of weight, 20.2% pica condition, 12.3%
skin diseases and 23% had diarrhea incidences (Table 8).
The survey showed that a
high proportion of sheep (42%) and goats (34%) suffered from poor health.
Perceived retarded health and diarrhea were the main factors responsible for
low production of sheep and goats. Poor health is the key limiting factor to
productivity of sheep and goats in the tropics (Kosgey et al 2008).
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abMeans in a row with
different superscripts are different (P<0.05) |
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Table 8:
Mean (±SE) annual
percentages of goats (360 to 720 days old) in a flock observed with
poor health and production |
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Study site |
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Variable |
Kamotonyi |
Lorora |
Salt lick |
Mean |
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Poor health |
37.2±7.5a |
49.8±6.5a |
14.5±4.1b |
33.8 |
|
Stunted growth |
20.0±7.7a |
36.3±5.3a |
4.0±2.3ab |
20.1 |
|
Loss of weight |
18.5±6.0a |
24.1±5.2a |
7.4±2.8ab |
16.7 |
|
Pica |
14.6±3.7a |
28.6±4.9b |
17.5±5.6a |
20.2 |
|
Skin diseases |
8.8±2.9a |
22.4±6.0b |
5.6±2.3a |
12.3 |
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Diarrhea |
22.8±5.5a |
28.4±4.6b |
17.8±5.0a |
23.0 |
|
abMeans
in a row with different superscripts are different (P<0.05) |
Incidences of perceived
loss of weight and pica, affected growing sheep and goats respectively. The incidence of pica was associated to mineral, protein and energy
deficiencies (Underwood and Suttle 1999). Low productivity in growing sheep
and goats can be associated to poor nutrition, which includes minerals, and
diseases.
Conclusions and recommendations
-
Small ruminant owners, through local knowledge, recognize the
value of minerals and can detect mineral deficiencies and adequacies in
their herds/flocks. Through this knowledge, mineral deficiencies and
adequacies were reported to occur mostly in dry and wet season respectively.
-
The indicators of mineral deficiencies as perceived by
herders, in growing sheep and goats, were low productivity namely poor
health, pica, diarrhea, loss of weight and stunted growth. Conversely,
healthy appearance and shiny skin coat were the key indicators of mineral
adequacy. Thus, traditional indicators were distinct for mineral deficiency
and adequacy and in sheep and goats.
-
Halophyte plants emerged as key local salt supplement for
sheep and goats in the area. The riverine
ecosystem that was demonstrated to be rich in mineral resources of salt
lick, halophyte plants and salty waters needsto be protected and sustainably
utilized.
-
Mineral deficiencies mainly affecting herds/flocks in the dry
season need to be addressed.
-
It can be concluded that local knowledge demonstrated by the
herders should from part of mineral nutrition interventions.
Acknowledgements
The authors acknowledge KASAL for financial and technical support and thank
the coordination team lead by Director KARI, Dr.D.Miano and Dr.M.Younan.
We also thank the local community elders for their welcome spirit and
pastoral households for accepting to participate in the survey.
We appreciate the herders experienced in the local
flora and Mr. Hussein Walaga of KARI-Marsabit for
botanical identification of salty plants.
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Received 30 November 2011; Accepted 26 January 2012; Published 2 April 2012
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