Mugunieri_279-284.qxd


INTRODUCTION

Dairy production in Kenya is dominated by small-
holder farmers who contribute about 85 % of total
milk produced (Peeler & Omore 1997). It is esti-
mated that the dairy herd in Kenya comprises about
3 million head of cattle, of which 2.5 million are
owned by smallholders numbering about 650 000
(MoA 1996). This implies that this sector employs
many people who derive a regular source of income
and have a balanced nutrition. The sector is a cat-
alyst for economic development and, when com-
pared to other agricultural activities, it has higher
financial returns (McIntire, Bourzat & Pingali 1992).

Dairy cattle production constraints have been exten-
sively described by various authors (Stotz 1983;
Moll, Lohding & Young 1984; Maloo, Thorpe, Ngumi
& Perry 1994; Peeler & Omore 1997). These stud-
ies have identified livestock diseases as one of the
major constraints to dairy production in Kenya. Major
diseases cited are tick-borne diseases (TBDs) and
trypanosomosis. Some field studies have attempted
to ascertain the actual incidence and impact of TBDs
on dairy production (Gitau, O’Callaghan, McDermott,
Omore, Odima, Mulei & Kilungu 1994; Maloo et al.
1994). However, there exists only very limited infor-
mation that measures the losses associated with
trypanosomosis and the benefits that can accrue
after its effective control (Mbogoh & Mukhebi 1997).
This study provides some information on the losses
associated with trypanosomosis among dairy farm-
ers in western Kenya which could be used in
designing sustainable strategies for managing the
disease in future control programmes in this region.

279

Onderstepoort Journal of Veterinary Research, 72:279–284 (2005)

Association of trypanosomosis risk with
dairy cattle production in western Kenya

G.L. MUGUNIERI* and G.O. MATETE

KARI – Trypanosomosis Research Center, P.O. Box 362, Kikuyu 00902, Kenya

ABSTRACT

MUGUNIERI, G.L. & MATETE, G.O. 2005. Association of trypanosomosis risk with dairy cattle pro-
duction in western Kenya. Onderstepoort Journal of Veterinary Research, 72:279–284

Dairy cattle reared in western Kenya are exposed to medium to high levels of trypanosomosis risk.
The social background, farm characteristics and dairy cattle productivity of 90 and 30 randomly
selected farmers from medium- and high-risk trypanosomosis areas, respectively, were compared.
All the 120 farmers were visited between July and August 2002. Data analysis was performed using
descriptive statistics and analysis of variance. The results showed that increased trypanosomosis
risk represented by an increase in disease prevalence in cattle of 1 % to 20 % decreased the densi-
ty of dairy cattle by 53 % and increased the calving interval from 14 to 25 months. The increased risk
was also associated with a significant increase in cattle mortalities and in a lactation period of 257
to 300 days. It was concluded that removal of the trypanosomosis constraint on dairy production
would lead to expansion of dairying since the domestic demand for dairy products is expected to
increase.

Keywords: Dairy cattle, Kenya, production, trypanosomosis risk

* Author to whom correspondence is to be addressed. E-mail:
ketri@africaonline.co.ke

Accepted for publication 14 June 2005—Editor



MATERIALS AND METHODS

Study area

The study region was stratified into two zones hav-
ing different levels of trypanosomosis risk based on
the prevalence of the disease in cattle for the period
1996–1999. It was assumed that the trypanosomo-
sis risk prevailing between these years influenced
production decisions of the subsequent years under
study. Following the outbreak of bovine trypanoso-
mosis in western Kenya in the late 1980s (Angus
1996), the Kenya Trypanosomiasis Research
Institute (KETRI) initiated routine trypanosomosis
surveillance studies in this region, under a larger
programme that was funded by the Department for
International Development (DfID) of the United King-
dom (KETRI 1994). Under this programme cattle,
randomly sampled in selected villages on a quarter-
ly basis, were screened for the presence of trypan-
osome parasites, using the standardized protocols
for the microhaematocrit centrifugation-buffy coat
technique, and thick and film blood smears (Woo
1969). On the basis of this data, this investigation
categorized the study region into zones of medium
and, from which farmers were sampled for data col-
lection. A sampling frame consisting of dairy farmers
in each zone was constructed with the assistance
of local animal health and provincial administration
staff and village elders. The medium risk zone con-
sisted of three administrative divisions with an esti-
mated area of about 377 km2 and had 238 dairy
farmers. The high-risk zone comprised one admin-
istrative division with an area of about 92 km2 and
had 39 dairy farmers. From this list of farmers, 120
were randomly sampled, 90 being from the medium-
risk zone and 30 from the high-risk area. The sam-
ple size was determined by resource availability.
Information on each of these trypanosomosis risk
zones is given in Table 1.

Data collection

Each of the 120 farms was visited once between
July and August 2002. During the visit, a compre-
hensive pre-tested questionnaire was administered.
Data were collected on the individual farmer and
farm characteristics, cattle nutrition and grazing
management, farm enterprises, farm inputs and rev-
enues, and general livestock management issues.
A detailed account of each commodity produced on
the farm listing all inputs and their costs, outputs
and prices was tabulated. Data on the management
practices were verified by physical inspection of
assets and farm records at the time of the interview.
All the farmers under survey were enrolled under

the National Dairy Development Project (NDDP),
and farm kept records detailing milk production, fer-
tility performance and mortalities.

Data analysis

Descriptive statistics were used to describe and
summarize dairy cattle density and productivity indi-
cators. Analysis of variance was used to compare
productivity of livestock under different levels of try-
panosomosis risk. Productivity analysis was based
on the premise that improved livestock health man-
agement may increase productivity of cattle (CARD
1989; Mugunieri, Omiti & Irungu 2004). The impact
of trypanosomosis risk on the success that cattle
keepers have achieved while engaging in dairy pro-
duction can be obtained by:

(a) Comparing the peak milk output per animal
under different trypanosomosis risk

All other factors being equal between the two zones,
the peak milk output per animal was taken as a
proxy for productivity of animals reared by farmers
under varying trypanosomosis risk levels. The meas-
urements of milk production were obtained from the
records kept by farmers, all of whom were enrolled
under the NDDP. The peak milk output average (for
all animals kept) was compared across the two try-
panosomosis risk levels.

(b) Calculating the calving rate under different
trypanosomosis risk conditions

This study estimated the ratio of births to the num-
ber of adult females in the herd in each calendar
year between 1999 and 2002. This was named the
“calving rate” (CR).

CR = LB/AF, where CR = calving rate, LB = number
of births in a specified period and AF = number of
adult females in the herd in a specified time period.

(c) Comparing dairy cattle densities under
different trypanosomosis risk

The number of dairy animals per farmer was esti-
mated over a period of 3 years (1999, 2000 and
2001). The average of the annual means for the 3
years expressed as total livestock units (TLU) was
taken as the average number of dairy animals per
farmer. The computation of the TLU was based on
figures in ILCA (1990). This was then multiplied by
the total number of farmers engaging in dairying to
yield the approximate total number of dairy animals
for each region. The ratio between this computed
value and size (area) of the region in km2 gave an

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Association of trypanosomosis risk with dairy cattle production in Kenya



indicator of the dairy cattle density (DCD) per km2

for each trypanosomosis risk region.

RESULTS AND DISCUSSION

Farmer and farm characteristics under varying
trypanosomosis risk

The farmer and farm characteristics across the two
trypanosomosis risk zones are given in Table 2.

Farmers were on average 47 years old and owned
6.6 acres of land. There were no significant differ-
ences in distances to the nearest market and artifi-
cial insemination or breeding bull services across
the two trypanosomosis risk zones.

There were no significant differences in the number
of visits made to attend to TBDs. There was also
100 % positive response with regard to use of aca-
ricides in the management of ticks. This implied that
TBDs may not have been confounding factors in
variation in productivity and practices between the
two risk zones. Trypanosomosis treatment visits
were also not significantly different between the two
risk areas, but there appeared to have been a more
rigorous application of insecticides for vector con-
trol in the high-risk areas. It was difficult to compare
the costs incurred in treatment of these ailments as

farmers were served by different cadres of veteri-
nary personnel who charged different fees even for
similar recorded cases.

The predominant grazing system practised in the
high-risk trypanosomosis area was a small-scale,
intensive grazing system, alternatively called the
zero-grazing system. This system was used by
28 % and 87 % of farmers in the medium- and high-
risk areas, respectively. The remainder of the farm-
ers used the semi-intensive system that is also
called the paddock-grazing management (Peeler &
Omore 1997).

The zero-grazing system was developed in Kenya
to solve the constraint of land scarcity and improve
milk production (De Jong 1996). It is a capital and
labour intensive system where exotic breeds and
their crosses are kept under intensive grazing,
mainly for commercial dairy purposes. Animals are
confined in housing units where they are stall fed
with fodder cut from the field. Manufactured feeds
are also widely used, especially at milking. On the
other hand, under the paddock system, exotic cat-
tle breeds and their crosses graze on natural pas-
tures usually supplemented with cultivated fodder.
Purchased inputs such as manufactured feeds and
veterinary services are widely employed in the pro-
duction process. It appears that increased trypano-
somosis risk necessitated investments in capital-

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G.L. MUGUNIERI & G.O. MATETE

TABLE 1 Summary information on study divisions

Division Year Villages Mean number of Average annual Ascribed Dairy farmers 
(size km2) sampled per cattle sampled per prevalence trypanosomosis population 

visit* visit (%) risk size

Malakisi 1996 4 48.7 (24.39) 0.25 (0.50) Medium 82
(101.4) 1997 4 73.5 (7.76) 4.75 (5.62)

1998 3 57.7 (14.84) 2.67 (1.15)
1999 4 70.0 (14.10) 6.75 (1.71)

Matayos 1996 4 59.2 (18.94) 4.50 (4.20) Medium 78
(173.7) 1997 4 55.5 (24.37) 3.00 (2.16)

1998 4 53.7 (26.92) 5.75 (2.87)
1999 4 105.2 (42.18) 3.00 (1.15)

Amagoro 1996 4 64.5 (19.82) 21.00 (19.35) High 39
(91.7) 1997 8 61.2 (32.65) 19.50 (11.86)

1998 8 52.4 (24.30) 18.00 (12.52)
1999 8 68.6 (27.34) 26.00 (15.06)

Funyula 1996 3 83.3 (51.14) 4.00 (3.46) Medium 70
(101.4) 1997 4 38.7 (21.53) 7.00 (2.71)

1998 4+ 50.0 4.50 (4.12)
1999 4 100.0 (49.21) 3.75 (1.26)

Values in parenthesis are standard deviations Sources: Angus 1996; KETRI 1999
* Four visits made per year
+ Data for one visit only



intensive grazing systems in the form of construction
of dairy cattle housing units, when an opportunity
existed to use the less capital-intensive system by
utilizing the most abundant resource (land). The use
of the zero-grazing system when land was not a
constraint, acted as an insurance against increased
production risk by minimizing animal-tsetse contact.
This implied that dairying became an enterprise for
households with higher income, which was support-
ed by the fact that off-farm income of dairy farmers
in high-risk trypanosomosis areas was significantly
higher.

Dairy cattle density, calving rate and milk
productivity

The average dairy herd size was 3.2 animals (SD =
2.4) (Table 3), computed as the three-year average

of the annual means that were derived for the years
1999, 2000 and 2001.

The herd consisted mainly of mature cows, heifers
and calves. The DCD was 1.5 TLU in the medium-
risk areas compared to 0.98 TLU in the high-risk
zone. The mean peak milk output per animal (com-
puted as the mean of peak milk yield attained per
cattle) was significantly higher (P < 0.05) for the
high-risk trypanosomosis area. Based on the com-
putation of the calving rate, an average of 0.8 births
per female per year was recorded for the medium-
risk trypanosomosis areas as compared to 0.5 births
per female per year for the high-risk areas. This
translated to a calving interval of 14 months for the
medium-risk as compared to 25 months for the high-
risk areas. Consequently, the average lactation peri-
od for cattle in the medium-risk area was significant-

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Association of trypanosomosis risk with dairy cattle production in Kenya

TABLE 2 Farm and farmer characteristics under varying trypanosomosis risk

Trypanosomosis risk
Characteristic (means/frequency)

Medium risk (n = 90) High risk (n = 30)

Land size (acres) 7.86 7.80
Household size (number) 8.43 11.03
Crop gross margin per acre per year 427 503
Off-farm income per month (Kshs) 2 083* 8 303*
Pasture feed size (acres) 1.76 1.36
Years of experience in dairying 8.90 5.80
Mature female dairy animals 2.45+ 1.80+

Household head age (years) 50.7 46.7
TBDs treatment visits (2001/02) 3.06 3.83
Trypanosomosis treatment visits (2001/02) 3.42 3.43
Trypanocidal drugs use (% frequency of farmers who used dugs) 58 63
Insecticide applied on cattle (% frequency of farmers who used pour-on) 28 60

Values with the same superscript are significantly different between groups (P = 0.05)

TABLE 3 Relation between dairy cattle density indicators and trypanosomosis risk

Level of trypanosomosis risk
Characteristic

Medium High

Size of region (km2) 539.3 91.7
Households in the region (no.) 34 951 7 617
Population in the region 165 103 33 954
Population density (persons per km2) 306.1 370.3
Dairying households (approximate) 230 39
Mean HH dairy cattle numbers (3-year average for means) 3.56* (SD + 2.5; n = 93) 2.30* (SD + 2.10; n = 29)
Dairy animals (approximate) 819 90
Dairy cattle density (DCD) (no. per km2) 1.5 0.98
Household undertaking dairying (%) 0.70 0.50
Peak milk output (l/day) 7.3* (SD + 4.0) 9.6* (SD + 4.6)
Lactation period (days) 257.64+ (SD + 32.95) 300+ (SD + 73.93)
Calving ratio (CR) 0.83* (SD + 0.25) 0.47* (SD + 0.30)
Deaths per farmer per year (3-year average) 0.009* (SD + 0.05) 0.052* (SD + 0.12)

Values with the same superscript are significantly different between groups (P = 0.05)



ly shorter. The average mortalities per farmer were
significantly higher in the high-risk area.

The differences in the peak milk output per day
attained between the two trypanosomosis risk zones
could be due to two factors. This could be a proxy
of the quality of animals reared between the two
zones. Alternatively, the quality of animals could
have been the same but differences in productivity
could be due to the intensive production systems
employed by farmers in the high-risk area. The
longer lactation period and higher mortality rates in
the high-risk areas may have been due to the impact
of the disease. This is in concordance to the knowl-
edge that increase in trypanosomosis risk often pro-
longs the calving interval due to abortions, early
embryonic deaths and silent heat (Swallow 2000).
Other factors that might influence the calving inter-
val, such as physical access to breeding services
(artificial insemination and bulls), were not signifi-
cantly different.

CONCLUSION

The dairy sector in Kenya is the most developed in
eastern and central Africa, making the country self
sufficient in major dairy products, except in periods
of drought (Omiti & Muma 2001). However, it is pro-
jected that by the year 2010, demand for dairy prod-
ucts will outstrip supply if urgent measures to sus-
tain growth in production are not undertaken (Peeler
& Omore 1997). Expanding production in areas with
potential that are currently under-exploited provides
one of the avenues to increase production. Trypano-
somosis is one of the major constraints limiting pro-
duction in these areas. This study has shown that
trypanosomosis risk alters the grazing management
system used and makes dairy farming expensive.
Increased trypanosomosis risk represented by an
increased prevalence of 1 % to 20 % decreased the
density of dairy animals by about 53 % and was
associated with an increase of calving interval from
about 14 to 25 months among the dairy farmers.

The most common method used for the control of
tsetse flies by dairy farmers was insecticide applica-
tion (pour-on preparations) on their cattle. Trypano-
cidal drugs were the main control method used in
management of the disease. Farmers stocked these
drugs, which animal health personnel used for treat-
ing their animals. The private use of drugs to control
trypanosomosis has become popular among the
farmers in most trypanosomosis-endemic areas of
Kenya (ILRAD 1994; Mugunieri & Murilla 2003). In
addition, the use of insecticide-treated cattle has

also become very common, unlike the use of artifi-
cial baits (traps and targets), which have not gained
popularity in the absence of concerted support from
governmental or non-governmental organizations
(Eisler, Torr, Machila, Coleman & Morton 2002). It
is suggested that this contrast reflects, at least in
part, the differences in public and private benefits.
On the one hand, use of drugs confers an entirely
private benefit, which is immediately effective even
when a single farmer treats a single cow. On the
other, the benefits of artificial baits are largely pub-
lic and only realized when large numbers of individ-
uals work in a concerted manner over a large area
for a relatively long period. Application of insecticides
on cattle has a mix of public and private benefits.
Capitalizing on the perceived private and visible
benefits of insecticide-treated cattle; this approach
can be promoted for wide application to complement
the use of drugs in the management of trypanoso-
mosis. It is recommended that appropriate means
of promoting its use by farmers and rural communi-
ties should be devised by the government. This will
not only ameliorate the risk imposed by trypanoso-
mosis on farmers currently undertaking dairying, but
will see expansion of the enterprise to ensure that
the country remains self-sufficient in the dairy prod-
ucts.

ACKNOWLEDGEMENTS

The World Bank under the Kenya Agricultural Re-
search Institute-Agricultural Research Fund Pro-
gram funded this research. This article is published
with permission of the Center Director, KARI-TRC.

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