Maichomo_257-261.qxd INTRODUCTION Gastrointestinal (GIT) parasites constitute a major variable in livestock production systems, particular- ly in sheep and goats where these infections are the single greatest constraint to production in the tropics (Mukhebi, Shavulimo, Ruvuna & Rurangirwa 1985). In Kenya, haemonchosis causes an annual loss of US$ 26 million in sheep and goats, while returns could be increased by as much as 470 % by controlling the disease (Allonby 1975; Mukhebi et al. 1985). In most agro-climatic zones (ACZ) in Kenya, haemonchosis has been shown to be the leading cause of mortality in small ruminants (Kanyari 1993; Kagira & Kanyari 2001). The most important genera of nematodes in Kenya are Haemonchus, Tricho- strongylus, and Oesophagostomum (Gatongi 1995; Mwendia 1996). Losses due to GIT parasitism can be categorized as direct or indirect. Direct losses are due to acute illness and death, forced premature slaughter and rejection of parts of the carcass at meat inspection in abattoirs. Acute parasitic conditions can be rec- ognized and affected animals are generally treated 257 Onderstepoort Journal of Veterinary Research, 71:257–261 (2004) The point prevalence of gastro-intestinal parasites in calves, sheep and goats in Magadi division, south-western Kenya M.W. MAICHOMO1, J.M. KAGIRA1 and T. WALKER2 ABSTRACT MAICHOMO, M.W., KAGIRA, J.M. & WALKER, T. 2004. The prevalence of gastro-intestinal para- sites in calves, sheep and goats in Magadi division, south-western Kenya. Onderstepoort Journal of Veterinary Research, 71:257–261 Helminths cause great economic loss in livestock in Africa, and can be categorized as either direct or indirect losses. Arid and semi-arid lands (ASAL) in Kenya comprise 71 % of total land area and harbour the largest population of cattle, sheep and goats. However, little information on the distribu- tion and impact of gastro-intestinal (GIT) parasitism in these animals is available. This survey was conducted to establish the prevalence of GIT parasites infecting calves, sheep and goats and their relative importance in Magadi division, which is semi-arid. Faecal samples were obtained directly from the rectum of 109 calves, 133 goats and 20 sheep and submitted to the laboratory for faecal worm egg counts, and coccidial oocysts examination using a modified McMaster method. The sig- nificance of differences in mean egg count per gram (epg) between animal species and herds (farms) were assessed using analysis of variance. The overall prevalence of nematodes in the calves, sheep and goats was 69.2 %, 80 % and 82 %, respectively. About 10 % of sheep and goats had epgs higher than 1 000, the remainder having light to moderate infections. The overall preva- lence of coccidial oocysts in calves, sheep and goats was 30 %, 44 % and 45 %, respectively. Poor productivity in ASAL areas, where nutrition is often poor, is likely to be pronounced in the presence of parasite infections. These findings indicate that viable internal parasite control should be imple- mented in the study area in order to increase the productivity of the livestock there. Keywords: Cattle, coccidia, gastro-intestinal parasites, goats, helminthosis, sheep 1 Kenya Trypanosomiasis Research Institute, P.O. Box 362, Kikuyu, Kenya 2 University of Georgia, College of Veterinary Medicine, Athens, Georgia, 30602, United States of America Accepted for publication 15 March 2004—Editor 258 by the farmer and thus direct losses can be avoided. In contrast, sub-clinical levels of parasitism cause indirect and more subtle losses and do not induce obvious clinical signs (Barger, Siale, Banks & Le Jambre 1994). This type of parasitism is regarded as the most important cause of economic loss, as it is a flock or herd problem, unlike the acute syn- drome, and tends to affect animals on a low plane of nutrition as well as lactating does and ewes. Sub- clinical levels of parasitism reduce potential produc- tivity of sheep and reduce feed conversion (Ndarathi, Waghela & Semenye 1989; Cobon & O’Sullivan 1992; Suttle 1994). It is difficult to assess the eco- nomic effects of such subclinical infections but it is important to quantify them. In Africa, ruminants are kept mainly for their meat, milk and skins. The production systems are diverse and are mainly dependent on the local climate. In pastoral areas of Kenya, the main breeds of live- stock are of the indigenous type, which includes Zebu cattle, Red Maasai and Blackhead Somali sheep, and the East African goat. The productivity of these animals is limited mainly by the seasonal availability of feed and diseases (Semenye 1987; Baker, Lahlou-Kassi, Rege, Reynolds, Bekele, Mu- kasa-Mugerwa & Rey 1992). Up-to-date information is lacking on the magnitude of GIT parasites in live- stock maintained in traditional grazing systems in the Magadi division of Kenya, a semi arid region. Changing socio-cultural values among members of the Maasai community in the Magadi division have induced changes in their traditional lifestyle in that they now keep fewer but high-producing animals, which have been improved by cross breeding. How- ever, due to greater susceptibility to parasites, the production of such “improved” crosses may be more severely affected by sub-clinical infection than in the case of the indigenous breeds, unless parasites are controlled through a well-managed herd health program. The present survey was undertaken to determine the prevalence and intensity of internal parasites in calves, sheep and goats in Magadi divi- sion, south-western Kenya, inhabited by the Maasai community. MATERIALS AND METHODS Study area The Magadi division is in the Kajiado District of the Rift Valley Province, which is located 170 km south- west of Nairobi. The district lies between latitudes 1°10’–3°10’ S; 36°5’–37°55’ E. It occupies an area of 22 106 km² with an altitude that ranges from 650– 1 500 m above sea level. The region is mainly semi- arid with mean temperature ranges of 18–38 °C. The mean annual rainfall is 440 mm and is distrib- uted over two rainy seasons, which consists of the “long rains”, from March to May and the “short rains”, from October to December. The vegetation types include: (i) Tall grassland on deep alluvial soils (ii) Tussocky annual grassland on deep alluvial soils (iii) Shrubland on stony brecchia soils (iv) Riverine and seasonally flooded woodland (Ag- new 1996). Animal sampling and data collection A cross-sectional survey of 109 calves, 20 sheep and 133 goats from nine randomly selected herds (Munii, Mpesi, Lendulo, Nkedienye, Timoi, Kinoya, Lempaine, Sarara and Sadera) in Olkiramatian and Shompole communal group ranches (which border each other) of the Magadi division was done for two months from May to June 2002. All calves and half of the sheep and goats (randomly selected) in each herd were sampled only once. All calves were under 1 year of age while the sheep and goats were a mixture of weaners and adults. Faecal samples were obtained from the rectum and submitted to a laboratory for the determination of the number of nematode eggs per gram (epg) of faeces, using a modified McMaster technique (MAFF 1986). The presence of oocysts and Moniezia spp. ova was also recorded. Rainfall, temperature and humidity values were recorded daily from January to June 2002. Statistical analysis Data obtained was subjected to a univariate analy- sis of variance (ANOVA) to establish whether or not there were significant differences in mean (µ) epg of the animals. RESULTS Climatic data From January to June 2002, 565.2 mm of rainfall as recorded. The mean monthly temperature ranged between 21.7 °C and 34 °C and relative humidity from 56 % in the morning to 35 % in the afternoon. Gastro-intestinal parasites in calves, sheep and goats in Kenya Prevalence of nematodes Calves (Fig. 1) A total of 109 calves were sampled. The overall mean prevalence of nematodes was 69.2 %. Tricho- strongylid eggs were more common (59.6 %) than Strongyloides (27.4 %). Munii’s herd had the high- est mean epg of 250 while Mpesi’s had the lowest mean epg of 23 (Table 1). Goats (Fig. 2) A total of 133 goats were sampled. The highest prev- alence was recorded in the animals in the Munii and Sarara herds while it was lowest in those in the Kinoya herd. The overall prevalence of nematodes was 82 %. Trichostrongylids and Strongyloides affected 72 % and 43 % of the goats, respectively. Mean epg values were highest in Munii and lowest in Kinoya herds (Table 1). Sheep Since only 20 sheep were sampled, the prevalence of nematodes was not assessed per herd. However, the overall flock prevalence was 80 %, with a mean epg of 326. Trichostrongylids and Strongyloides affected 75 % and 45 % of the sheep, respectively. 259 M.W. MAICHOMO, J.M. KAGIRA & T. WALKER ����� ������ � ��� � ������� ��� � ���� ������� ����� � �� � � � � � � � � ���� �� �� �� �� � ���� �� �� �� �� � � �� � � � � � � � � ����� ��� �� ��� ���� ������ � ������� ������ ������ �������� ������� � ��� ! �"� ������ ��������� �� �������� ������� � ��� ! �"� ������ ��������� �� FIG.1 Prevalence of nematodes in calves from five herds in Magadi division FIG. 2 Prevalence of nematodes in six herds of goats in Magadi division � � �� � �� � � �#� �� $� �� %� �� �� � �&�� �$&�'' $��&����� (����� �� ������� ������������ ������������������������� ��� � � �� � �� � � �$� �� %� �� �� � )�����* �"��!�� � � % � )�����* �"��!�� FIG. 3 Percentage of animals shedding various ranges of nem- atode eggs FIG. 4 Percentage of animals infected by a given number of parasites 260 Gastro-intestinal parasites in calves, sheep and goats in Kenya Intensity of nematodes (Fig. 3) Most animals were lightly infected with ranges between 25 and 499 epg. Some sheep and goats, however, did have an epg above 1000. Other GIT parasites Coccidial oocysts and Moniezia spp. ova were also observed in some of the faecal samples. The over- all prevalence of oocysts in the calves, goats and sheep was 30 %, 44 % and 45 %, respectively. The coccidial oocysts were not identified to genus level. Moniezia spp. eggs, which were also not identified to species level, were observed in 8 %, 10 % and 5 % in the cattle, sheep and goats, respectively. Mixed infections The percentage of animals infected by a given number of GIT parasites, namely Trichostrongylid, Strongyloides, Moniezia spp. and coccidia are shown in Fig. 4. Most of the animals were infected with one or two species of parasites. Statistical analysis Significant differences between the numbers of epg of Trichostrongylid and Strongyloides were obtained (P = 0.000) with the former being higher (µ = 314, range 0–6 300) than the latter (µ = 106, range 0– 7 500). ANOVA results indicated that there were host differences in trichostrongylid epg levels (P = 0.006, µ = 122 in calves, 469 in goats and 320 in sheep), as well as sex differences in the animals with higher values in males (P = 0.0068). The host- level difference for Strongyloides epg levels were also significant (P = 0.0656), with goats having higher burdens (µ = 173) than calves (µ = 117.5) and sheep (µ = 20.8). The Munii and Nkedienye herds, located in wetter areas, had larger numbers of animals infected with GIT parasites. DISCUSSION Livestock keeping is the most viable and self-sus- taining enterprise in the pastoral community of Ma- gadi division and is therefore their most important means of livelihood. For effective management of animal helminths, information on their epidemiology is essential (Herlich 1978). A previous study on hel- minthoses in small ruminants in this region (Mwen- dia 1996) revealed a lower mean epg level in the same season (after long rains) than those obtained in the present study. This could be due to the changing lifestyle of the local Maasai people from nomadic to sedentary, with emphasis on quality and economical beef production, necessitated by an increase in the human population and cost of living. Indeed, the prevalence of nematodes on herds in sedentary herds (Munii and Nkedienye) was higher than those of nomadic ones. The increase in hel- minthoses that was found could also be explained by an increase in the rainfall, being 562.6 mm in the first 6 months of 2002 compared to a total of 330 mm within the same period in 1994 (Mwendia 1996). However, faecal egg counts that were obtained in sheep in the present study were low compared to those reported in sheep in the highlands (Maingi 1996). The reason for this is believed to be the high temperatures and dry conditions in the pastoral areas, which lead to desiccation of nematode eggs and larvae. Inadequate nutrition, however, which is common in this area, may exacerbate the course of nematode infection. The animals are generally mal- nourished and suffer from other diseases, and are thus not resistant to nematode infection. Although the nematode eggs in this study were not identified to species level, Haemonchus contortus and Tricho- strongylus colubriformis are considered to be the parasites most responsible for helminthoses in small ruminants in highlands and pastoral areas of Kenya, respectively (Gatongi 1995; Maingi, 1996; Mwendia 1996). Sheep and goats had higher burdens when com- pared to calves. Cattle have been shown to have low nematode burdens up to 10 months of age, while the heaviest burdens are detected in 1.5 to 3-year- old animals, thereafter declining to even lower bur- dens (Kaufman & Pfister 1990). In the current study, most of the calves were about 1 year old. Since the study area has a high prevalence of trypanosomo- sis (Roderick, 1995), it is possible that animals suf- TABLE 1 Mean epg of total nematodes in calves, sheep and goats from different herds in Magadi division Mean epg Herds Calves Sheep Goats Kinoya – 25 86 Lempaine – 451 205 Lendulo 49 – – Mpesi 23 – – Munii 250 – 1 118 Nkedienye 208 – 114 Sadera – – 780 Sarara – 502 537 Timoi 55 – – 261 M.W. MAICHOMO, J.M. KAGIRA & T. WALKER fering from both helminthoses and trypanosomosis will be more seriously affected. Studies in cattle and goats have shown that the pathogenicity of H. con- tortus is increased in animals with concomitant ex- perimental infection with Trypanosoma congolense (Griffin, Allonby & Preston 1981; Kaufman, Dwinger, Hallebeck, Van Dijk & Pfister 1992). Mixed parasitic infections in hosts is the rule rather than the exception in most grazing systems as was demonstrated by the concurrent presence of up to four parasite genera. The occurrence of mixed infec- tions may lead to decreased production due to the synergistic effect of each parasite, although this depends on the proportion of pathogenic species. The prevalence of coccidia in herds sampled ranged between 30 % and 45 %. This is comparable to reports by Kanyari (1993) in sheep and goats. Some Eimeria species are considered pathogenic to the three host species studied. Although coc- cidiosis is regarded as a disease of housed or con- fined animals, lack of grazing pasture during the dry season may increase the “stocking rate” of animals on the few pastures remaining, a situation that may lead to a proliferation of oocysts. It is concluded that gastrointestinal parasites that can cause economic losses are present in livestock in the study area. 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