African pastoralists are currently facing challenges such as frequent droughts and floods, as well as high poverty levels(Reference Little, Mahmoud and Cappock1). These factors have further been exacerbated by government policy frameworks that promote sedentary livelihood systems. Sedentarization is a process where pastoralists shift from nomadic or semi-nomadic livestock production to permanent settlement and adopt new livelihoods through agriculture, trade, or part- and full-time urban occupation(Reference Fratkin, Roth and Nathan2). While intended to promote improved health and nutrition through market integration and access to health care, the result is high population pressure in permanent settlements, political insecurity and economic stratification, leading to settled and semi-settled households, especially in rangeland areas(Reference Fujita, Roth and Nathan3). A change from nomadic to sedentary lifestyle has been observed among the Fulani in West Africa, who keep livestock as well as practise limited cultivation during their migration(Reference Ndambi, Hemme and Latacz-Lohmana4).
In Marsabit County, Kenya, frequent droughts have pushed many members of the Gabra community out of traditional livestock monoculture(Reference Nyamori and Odhiambo5). In addition, increased population pressure has led to settlement around the water points, which also act as trading centres and relief food distribution points(Reference Fratkin6). This kind of settlement has resulted in rapid changes in food availability as well as food preferences(Reference Little, Mahmoud and Cappock1). Generally, 59 to 64 % of communities living in marginal areas of Marsabit County, especially in Maikona Division, are considered food poor(Reference Nyamori and Odhiambo5). The result of this is high vulnerability to malnutrition among women who are left in the settlement to care for children and the aged(7). Currently, most arid and semi-arid land (ASAL) policies in Kenya encourage sedentism as a solution to food insecurity(8). However, a study conducted in Marsabit County showed dietary inadequacies among settled Rendille women(Reference Shell-Duncan and Yung9). Currently, there are limited data on dietary intake, Fe deficiency, anaemia and infection among Gabra women in both settled and semi-settled households. Neither the Kenya Demographic and Health Surveys(10, 11) nor the Kenya National Micronutrient Survey(12) covered Marsabit District.
The objective of the present study was to evaluate the effect of settlement on the nutrition and health status (Fe deficiency and anaemia) of pastoralist Gabra women of reproductive age. We tested the hypothesis that there are no differences in dietary intake, body composition, Fe status and infection between settled and semi-settled Gabra women. Understanding women's health and nutrition is significant because its consequences affect both the woman and her infants(Reference Merchant13). Gabra women have high maternal mortality rate, currently estimated at 599/100 000 live births compared with the national estimate of 590/100 000 live births(Reference Mace and Sear14), that may be influenced by nutritional status. The study results may assist policy makers in designing food programmes and nutrition and health interventions suited to pastoral conditions in northern Kenya.
Materials and methods
Design and study population
A cross-sectional survey was conducted among settled and semi-settled Gabra women in Kalacha Location in northern Kenya. The study excluded women younger than 15 years and older than 49 years, as well as pregnant women and women with clinically acute or chronic illness due to infection or inflammation.
Sampling procedure
A systematic sampling method described by Mugenda and Mugenda(Reference Mugenda and Mugenda15) was used in which a sampling interval of four was found by dividing the total number of households by the sample size of each settlement. Starting with respondent number four and skipping every four names, 224 women (140 settled and eighty-four semi-settled women) aged 15–49 years were recruited. Only one adult woman was selected per household for administration of the survey instruments after giving consent. The consent was translated into the local Gabra language and was read to the respondents, who were asked to provide oral consent. One hundred women gave consent to blood sampling. One blood sample was smudged and consequently discarded, leaving ninety-nine samples (forty-one from settled and fifty-eight from semi-settled women). Blood sample size was low because some women declined to give blood due to fear they would be tested for HIV, despite the fact that the consent form stated this test would not be conducted. However, the sample size achieved for biochemical evaluation was above one-third of the overall sample size required to make generalizations of a population, as reported in the 1999 micronutrient survey in Kenya(12).
Questionnaire
Information on marital status, age, household size, education levels, livestock numbers and income levels (in Kenya shillings (KES), categorized as 1 = KES 101–1000, 2 = KES 1001–2000, 3 = KES 2001–5000, 4 = KES 5001–10 000 and 5 = KES >10 001) was collected by the first author using a structured questionnaire. The dependency ratio was calculated by dividing the total number of household members by the number of employed members of the household. Livestock numbers were converted into Tropical Livestock Units (TLU) following the method of Fujita et al. (Reference Fujita, Roth and Nathan3). A 24 h dietary recall was conducted to estimate nutrient intake following methods used by Maruapula and Chapman-Novakofski(Reference Maruapula and Chapman-Novakofski16). This allowed us to test the hypothesis of no difference in nutrient intake between settled and semi-settled women. Food estimation and conversion into actual weights were done according to Gibson and Ferguson(Reference Gibson and Ferguson17). Volumes of local household utensils such glasses, cups, plates and spoons were measured using a measuring cup graduated both for weights and volumes. To convert to actual measurements for analysis purposes, the volume of water equivalent to the volume of the actual free-flowing food or drink was measured using a measuring cylinder, and then converted into weight equivalents of the actual food or beverage consumed (1 litre was assumed to be equivalent to 1 kg for free-flowing food). Mixed foods, especially githeri (dry maize mixed with beans then cooked), whose ingredients could not be quantified during the survey were later cooked in the mixing ratio reported by respondents. The study revealed three mixing ratios (beans to maize) in Kalacha, namely 1:0·75; 1:0·5 and 1:1. In each cooked ratio, three scoops of a standard measuring cup were randomly made with thorough mixing after every scoop. The beans and maize were separated and their weights determined using a digital scale (model BA3105; Sartorius AG, Gottingen, Germany). Graduated food models made from rubber sponge borrowed from the Department of Nutrition at Egerton University were used to estimate the weight of solid foods. The results were then compared with nutrient standards provided in the Nutrisurvey program(Reference Erhardt18) and the Kenya Food Composition Tables(Reference Sehmi19).
Anthropometric assessment
Weight of the women was measured to the nearest 0·1 kg using a SECA scale (model 7621019009; SECA, Hamburg, Germany). Height was measured by use of a locally improvised stadiometer to the nearest 1·0 mm(Reference Kigutha20).
Blood sampling and biochemical analysis
The blood sampling was conducted by a qualified clinical officer from Marsabit District Hospital and was supervised by the lead author. To conduct this procedure, a puncture site on the left ring finger or middle finger was disinfected using methylated spirit. The ring finger was pricked using a sterile disposable lancet, and the first drop was discarded(21). The second drop was filled into a micro cuvette by capillary action, then placed in a HemoCue® analyser (model 0402012008; HemoCue AB, Angelholm, Sweden) for 15s and readings taken. The instrument was calibrated daily. Two more drops of whole free-flowing capillary blood were collected onto a standardized filter paper (903; Whatman catalogue no. 10534612), allowed to dry for 3–4 h and then stored frozen at −20°C(Reference Ahmed, Mahmuda and Sattar22, Reference Shell-Duncan and McDade23). Dried blood spots (DBS) were analysed for C-reactive protein (CRP), an acute-phase protein that indicates recent infection, and transferrin receptor (TfR) using enzyme-linked immunoassay following the method of Brindle et al. (Reference Brindle, Fujita and Shofer24) that has previously been validated by McDade and Shell-Duncan(Reference McDade and Shell-Duncan25) and Shell-Duncan and McDade(Reference Shell-Duncan and McDade23). TfR is a sensitive indicator of Fe status that is not influenced by infection(21). α1-Acid glycoprotein (AGP), also called orosomucoid, which provides a measure of chronic infection, was measured from DBS using an enzyme immunoassay kit (GenWay catalog no. 40-288-22927F; BioTek Instruments Inc., Winooski, VT, USA) as validated by Brindle et al. (Reference Brindle, Fujita and O'Connor26).
Data analysis
Data were analysed using the SPSS statistical software package version 12 and results presented as frequencies, means and standard deviations. The t test and the χ 2 test were used to determine population differences. Confidence level was set at 95 % for all analyses (P ≤ 0·05). The Nutrisurvey for Windows program(Reference Erhardt18) was used to analyse nutrient intakes and the results were compared with Recommended Nutrient Intakes (RNI)(27) and the Kenya Food Composition Table(Reference Kigutha20). BMI was calculated as weight in kilograms divided by the square of height in metres(28) and used to classify chronic energy deficiency (CED) using the cut-off values established by Ferro-Luzzi et al. (Reference Ferro-Luzzi, Sette and Franklin29).
An Hb value of <12 mg/dl was considered anaemic(Reference Ahmed, Mahmuda and Sattar22). Established cut-off values for biochemical markers of Fe and inflammation in DBS were used to identify women with abnormal values: TfR > 5·0 mg/l, AGP > 1·0 g/l and CRP > 2·0 mg/l. TfR, which is a sensitive indicator of Fe status, has been found to be capable of detecting Fe deficiency in the presence of anaemia (Fe-deficiency anaemia (IDA)) as well as pre-anaemic Fe deficiency (Fe-deficiency erythropoiesis (IDE))(Reference Geissler and Singh30). It was therefore possible to identify women who were Fe replete, and those with IDE, with IDA and with anaemia caused by a non-specific immune response to infection involving Fe sequestration, i.e. anaemia of chronic disease (ACD). This was done using the multiple criteria model, based on having two or more of the four Fe status indices outside the cut-off values(Reference Wander, Shell-Duncan and McDade31, Reference Asobayire, Adou and Davidson32). Fe replete was defined as normal Hb (<12 mg/dl), normal TfR (<5·0 mg/l) and normal CRP (<2·0 mg/l)/AGP (<1·0 g/l). IDE was defined as normal Hb and elevated TfR. IDA was defined as low Hb and elevated TfR, whereas ACD was defined as low Hb, normal TfR, elevated CRP and/or AGP(Reference Asobayire, Adou and Davidson32). CRP is an indicator of acute infection, increasing and reaching a maximum 24 h after the initial infection occurs(Reference Asobayire, Adou and Davidson32). AGP indicates the presence of chronic infection, reaching a maximum between 2 and 5 d; because it rises and declines more slowly than CRP it provides information about recent illness as well. Combined measures of these acute-phase proteins, as outlined by Thurnham and Northrop-Clewes(Reference Thurnham and Northrop-Clewes33), were used to classify the illness of individuals as follows: (i) healthy, no raised acute-phase proteins; (ii) chronic illness, raised AGP only; (iii) current infection, raised CRP and raised AGP; and (iv) recently ill (acute), raised CRP with normal AGP.
Ethical approval
Ethical approval was obtained from the Kenya Medical Research Institute/National Review and Ethics Committee and Institutional Review Boards of the University of Washington.
Results
Population characteristics
Table 1 summarizes the characteristics of the study population. The mean age of settled women was significantly (P = 0·024) higher than that of semi-settled women. A significantly (P = 0·043) higher number of semi-settled women were married compared with settled women. There were more widows in settled households than in semi-settled households. About 4·3 % of women in settled households were either divorced or separated compared with none of the semi-settled women. This could have been one of the major determinants of sedentarization, since mothers with no livestock have to rely on relief food for livelihood sustenance. The main religions were Christian, Islam and traditional. Education standards were low. The majority of semi-settled women had significantly (P = 0·003) lower formal education attendance than their settled counterparts. The mean TLU was significantly (P < 0·001) higher in semi-settled households than in settled households although it had no correlation with nutritional status. There were significant (P = 0·054) differences in household income, with the majority falling in the income range of KES 101–1000 ($US 1 = KES 84), mainly from sale of their livestock. The mean BMI of settled women was not significantly different (P = 0·168) from that of semi-settled women (Table 1). Interestingly, for the ninety-nine women who were evaluated for Fe status, BMI was significantly (P = 0·028; two-tailed) higher among settled women (19·5 kg/m2) than among semi-settled women (18·2 kg/m2). Table 2 gives a summary of classification of the respondents based on CED. The prevalence of CED varied little between women in settled and semi-settled households (49 % v. 52 %, respectively).
TLU, Tropical Livestock Units; KES, Kenyan shillings ($US 1 = KES 84).
CED, chronic energy deficiency.
CED based on BMI range(Reference Ferro-Luzzi, Sette and Franklin29): severe (Grade III), BMI < 16·00 kg/m2; moderate (Grade II), BMI = 16·00–16·99 kg/m2; mild (Grade I), BMI = 17·00–18·49 kg/m2.
*Lowest class in terms of social status.
Nutrient intakes from 24 h dietary recall
Table 3 summarizes nutrient intakes from the 24 h dietary intakes survey. Mean energy intake was significantly (P < 0·001) higher among the settled women compared with their semi-settled counterparts. The high mean energy intake observed in settled households could be due to easy access to both purchased and relief foods. Settled women also had easy access to shops and cereal grinding mills that offer a variety of foods in terms of carbohydrate types, compared with semi-settled women. However, the high levels of CED suggest that these high intakes may not be typical. Means also do not reflect variation, and it is useful therefore to also examine the percentages who met nutritional adequacy (Table 4). Significantly more settled women met the RNI for energy (P < 0·001), but overall a substantial number of women in both communities did not meet the RNI for energy. The mean protein intake was also significantly (P = 0·005) higher for settled women compared with semi-settled women and significantly (P = 0·012) more of the former met the RNI for protein(34). The major food sources of protein were beans, peas, meat and milk. Low protein intake may be explained by a lack of milk due to prevailing drought. Significant differences were observed in Fe intake (P < 0·001) between settled and semi-settled women, although intake in both groups fell substantially below the RNI. Vitamin C, which enhances the absorption of non-haem forms of Fe found in plant foods, was also very low in the diets of both groups of women, attributable to a lack of vegetables and fruits in the diets of most women. Finally, the dietary intake of vitamin A, which also influences Fe metabolism, was not significantly different between women from the two communities, but substantially lower than the RNI. Overall, the micronutrient intakes of many Gabra women were below the RNI(27), as found previously in Rendille women in Marsabit(Reference Shell-Duncan and Yung9) and nationally in Kenya(35).
RNI, Recommended Nutrient Intake.
*1 kcal = 4·184 kJ.
Biochemical status of iron and infection among settled and semi-settled Gabra women
Table 5 summarizes the results of biochemical analyses of blood samples. Mean Hb was significantly (P = 0·043) higher among settled women than among semi-settled women. The prevalence of anaemia was 39 % among settled women and 60 % among semi-settled women. There were no significant differences in mean TfR (P = 0·062), CRP (P = 0·319) and AGP (P = 0·584) between settled and semi-settled women. Overall, 43 % of the Gabra women presented with elevated TfR, indicating Fe deficiency. Of the women in settled and semi-settled households, 68 % and 48 % respectively had normal TfR.
TfR, transferrin receptor; AGP, α1-acid glycoprotein; CRP, C-reactive protein.
Cut-offs(Reference Shell-Duncan and Obiero47): Hb = 12 mg/dl; TfR = 5·0 mg/l; AGP = 1·0 g/l; CRP = 2·0 mg/l.
Biochemical assessment of illness
Combined measures of acute-phase proteins, as outlined by Thurnham and Northrop-Clewes(Reference Thurnham and Northrop-Clewes33), were used to classify the illness of Gabra women (Fig. 1). Only 59 % of settled and 46 % of semi-settled women were classified as healthy (no raised acute-phase proteins). Chronic illness (raised AGP only) was the most common type of illness among Gabra women and more common among semi-settled (41 %) than settled women (29 %). However, more settled (7·3 %) than semi-settled (5·2 %) women were identified as having a current infection (raised CRP and raised AGP). About 7 % and 5 % of semi-settled and settled women respectively were found to be recently ill (raised CRP with normal AGP).
Multiple criteria model to estimate overall prevalences of anaemia in settled and semi-settled Gabra women
Figure 2 gives the percentages of women falling into the various categories of anaemia. Using the multiple criteria model, only 43 % and 40 % of settled and semi-settled women respectively were Fe replete. About 18 % of settled women compared with 20 % of semi-settled women were in IDE status. Fifteen per cent of settled women compared with 25 % of their semi-settled counterparts were suffering from IDA. ACD was more prevalent in semi-settled women (36 %) than in settled women (24 %), but high in both groups. Overall, among Gabra women, chronic infection appeared to be the leading cause of anaemia followed by Fe deficiency.
Discussion
The purpose of the present study was to examine the effect of settlement on the nutrition and health status of Gabra pastoral women of reproductive age. While most ASAL policies promote settlement of pastoralists as a means of promoting numerous benefits, including improved health and nutrition, our study among Gabra women showed that settlement is associated with mixed outcomes and limited improvements. Our study results showed high levels of CED in both communities (49 % among settled and 52 % among semi-settled women), suggesting that food insecurity remains a significant problem. A comprehensive cross-sectional nutrition assessment conducted in Marsabit suggested an alarming malnutrition situation among lactating mothers, with a global acute malnutrition rate of 46 % and a severe wasting rate of 12 %, higher than WHO's 15 % emergency threshold(Reference Kuria36). The present results also concur with those of the Kenya Demographic and Health Survey, where more than 50 % of women were suffering from CED(11). The 24 h dietary recalls showed high mean energy intake among Gabra women in both communities, but many did not meet the RNI. The prevalence rates of CED among Gabra women were higher than those found among nomadic and semi-settled Rendille communities in northern Kenya but lower than those of women in India and Ethiopia(Reference Shell-Duncan and Yung9) (Table 2). This may be attributed to still low income levels (Table 1) against high absolute poverty in the area. Currently, the proportion of persons living below the poverty line stands at 80 % in Marsabit County(37).
Semi-settled women had higher rates of micronutrient deficiencies and anaemia than their settled counterparts. Most settled women did not meet their dietary requirements with respect to vitamin A (percentage of adequacy: 0·7 %), vitamin C (2·1 %) and Fe (10·6 %). Most semi-settled women also did not meet their dietary requirements with respect to energy (16·7 %), protein (32·1 %), vitamin A (1·2 %), vitamin C (1·2 %) and Fe (3·6 %). According to Jackson(Reference Jackson38), infection can occur in the presence of malnutrition as the primary aetiological factor (e.g. malaria) or as a secondary feature due to nutritionally driven impaired immune response. The leading type of anaemia was ACD, followed by IDA. Only 43 % and 40 % of settled and semi-settled women were Fe replete. Infection, in particular chronic infection, was high among Gabra women, and more prevalent in semi-settled (41 %) than settled women (29 %). Based on biochemical analyses of acute-phase proteins, only 59 % of settled and 46 % of semi-settled women were found to be healthy.
For IDE and IDA, one possible cause could be inadequate dietary intake of Fe. A study done by Faruk et al. (Reference Faruk, Ismat and Abeda39) on urban pregnant Bangladesh women found that low serum vitamin A levels (<30 μg/dl) were associated with lower Hb levels in women with inadequate intakes compared with those who had adequate intakes. Further, the pregnant women with low serum vitamin A levels had a greater risk (OR = 1·8; 95 % CI 1·2, 2·8) of also being anaemic. With extremely low dietary vitamin A intake, anaemia due to vitamin A deficiency could not be ruled out in the Gabra pastoral population. Dietary Fe deficiency may provoke symptoms of folate deficiency resulting in asystematic progression to megaloblastic anaemia(Reference Machlin40). Consumption of vitamin C together with Fe-rich food sources may enhance absorption of non-haem Fe if taken within an hour of each other. With extremely low vitamin C intake (Table 2), inadequate absorption of dietary Fe prompting IDE and IDA in the Gabra women cannot be ruled out. Trials conducted in rural Mexican adults dependent on maize and legume diets established, through isotope studies, that consumption of 25 mg of vitamin C is needed twice daily with meals in order to double Fe absorption(Reference Fernald41). The low observed Fe intake could be attributable to an over-reliance on cereal-based diets (data not shown), where 96 % of the women in both settlements were being provided cereal-based relief food during the time of the present study. Cereals tend to contribute to intake of Fe absorption inhibitors such as phytates, leading to low bioavailable Fe.
The methods adopted in the present study have several advantages. Sample collection was relatively painless and non-invasive. Whole-blood samples did not require processing in the field as DBS samples require no cold chain (refrigeration or freezing) at field level for 4 weeks, hence aiding storage and transport. This was very appropriate in our study where the population was sparsely distributed and there were limited resources available. The method was previously validated in Marsabit among Rendille women and was used in the present study to evaluate biochemical Fe status among the Gabra women.
Some of the limitations of the study should also be considered. The 24 h dietary recall was taken for 1 d, and may not represent typical intake. Households participating in the food survey may have modified the usual foods in their diet; hence the intake data might not have accurately represented the habitual diet. Prevailing drought and food relief distribution could also have modified diets, as respondents may have equated the study to impending food relief distribution. However, well-trained, local surveyors emphasized the need to maintain usual diets and all of the households in both settlements participated in the food survey. Northern regions of Kenya are subject to extreme seasonality in rainfall and food supplies, and therefore experience seasonality in dietary intake, nutritional status and morbidity(Reference Fujita, Roth and Nathan3, Reference Shell-Duncan42). Future research should therefore monitor the health and nutrition of Gabra women longitudinally. Nevertheless, the present results provide compelling evidence that food insecurity, dietary intake and chronic infection remain pressing health concerns for both settled and semi-settled Gabra women.
Conclusions and recommendations
The present study has shown that Fe deficiency is occurring in the context of overall dietary inadequacy among pastoralist Gabra women of reproductive age. While settled women had better dietary intake, nutritional status and Fe status than semi-settled women, Fe deficiency and ACD were high in both groups. Fe deficiency and CED are also occurring against a high background level of chronic infection. Numerous studies have documented that Fe supplementation in the absence of disease control measures can increase morbidity, particularly from bacterial and protozoal diseases(Reference Shankar, Goodman and Stoltzfus43–Reference Sazawal, Black and Ramsan46). Therefore, vertical programmes that address Fe deficiency through means such as supplementation may require additional interventions aimed at strengthening food security and containing infectious disease among pastoral women. Government and development and donor agencies need to be proactive with regard to poor maternal nutrition. The approach needs complex, multifaceted and intersectoral interventions based on long time periods to tackle the wide range of social and environmental determinants of health; a decisive move in this direction may help reduce the poverty and health challenges observed in the present study.
Acknowledgements
Sources of funding: The study was funded by Kenya Agricultural Research Institute through the World Bank-funded Kenya Agricultural Productivity Project (KARI/KAPP). Conflicts of interest: No conflicts of interest exist. Authors’ contributions: A.O.A. was the lead scientist for the present research; B.S.-D. and J.P.T. were university supervisors during thesis work at Egerton University. All authors have seen and approved the submitted manuscript. Acknowledgements: The authors thank the University of Washington, Seattle for support with blood sample analysis. They also appreciate the support from local leaders and thank the women for their patience and cooperation during administration of the questionnaires.