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BMJ Open logoLink to BMJ Open
. 2023 May 26;13(5):e073287. doi: 10.1136/bmjopen-2023-073287

Uptake of four or more doses of sulfadoxine pyrimethamine for intermittent preventive treatment of malaria during pregnancy in Zambia: findings from the 2018 malaria in pregnancy survey

Danny Sinyange 1,2, Nawa Mukumbuta 1, Lwito Salifya Mutale 2, Hudson Mumbole 3, Busiku Hamainza 3, Cephas Sialubanje 1,
PMCID: PMC10231002  PMID: 37236665

Abstract

Objective

To determine the prevalence and predictors of the uptake of four or more doses of sulfadoxine pyrimethamine (IPTp-SP 4+) in Zambia.

Design

A cross-sectional study using secondary data from the malaria in pregnancy survey (Malaria Indicator Survey) data set conducted from April to May 2018.

Setting

The primary survey was conducted at community level and covered all the 10 provinces of Zambia.

Participants

A total of 3686 women of reproductive age (15–45 years) who gave birth within the 5 years before the survey.

Primary outcome

Proportion of participants with four or more doses of IPTp-SP.

Statistical analysis

All analyses were conducted using RStudio statistical software V.4.2.1. Descriptive statistics were computed to summarise participant characteristics and IPTp-SP uptake. Univariate logistic regression was carried out to determine association between the explanatory and outcome variables. Explanatory variables with a p value less than 0.20 on univariate analysis were included in the multivariable logistic regression model and crude and adjusted ORs (aORs) along with their 95% CIs were computed (p<0.05).

Results

Of the total sample of 1163, only 7.5% of participants received IPTp-SP 4+. Province of residence and wealth tertile were associated with uptake of IPTp-SP doses; participants from Luapula (aOR=8.72, 95% CI (1.72 to 44.26, p=0.009)) and Muchinga (aOR=6.67, 95% CI (1.19 to 37.47, p=0.031)) provinces were more likely to receive IPTp-SP 4+ compared with to those from Copperbelt province. Conversely, women in the highest wealth tertile were less likely to receive IPTp-SP 4+ doses compared with those in the lowest quintile (aOR=0.32; 95% CI (0.13 to 0.79, p=0.014)).

Conclusion

These findings confirm a low uptake of four or more doses of IPTp-SP in the country. Strategies should focus on increased coverage of IPTp-SP in provinces with much higher malaria burden where the risk is greatest and the ability to afford healthcare lowest.

Keywords: EPIDEMIOLOGY, Health Services Accessibility, PUBLIC HEALTH, Maternal medicine


Strengths and limitations of this study.

  • Use of a large data set from the 2018 malaria in pregnancy survey with a nationally representative sample reduced selection bias and increased external validity and generalisability of the findings.

  • Use of multistage random sampling technique reduced selection bias and increased validity of the findings.

  • Inclusion into analysis only women of reproductive age who gave birth after the new IPTp-SP policy was introduced reduced information bias and increased internal validity of the study.

  • Use of secondary data limited the choice of variables to be included in the analysis.

  • Exclusion of participants with incomplete data could have reduced the power of the study.

Introduction

Globally, there are an estimated 247 million cases of malaria reported from 84 malaria-endemic countries, with the majority (95%) being reported from the WHO African Region. Sub-Saharan Africa is disproportionately affected, accounting for an estimated 350–500 million cases, 1–3 million deaths, 10 000 maternal and 200 000 neonatal deaths per year.1 2 With an estimated 125 million pregnant women being at risk of contracting malaria globally, malaria in pregnancy (MIP) remains an important preventable cause of adverse maternal, neonatal health outcomes worldwide.1 3 4 Out of an estimated 50 million annual pregnancies in malaria-endemic countries around the world each year, more than 50% of these live in the tropical areas of Africa where there is a high transmission of Plasmodium falciparum. 5 6

Malaria is a parasitic disease caused by a protozoon of the genus Plasmodium. Although there are species of malaria that infect humans—P. falciparum, P. malariae, P. ovale, P. vivax and P. knowlesi—two main species, P. falciparum and P. vivax, pose the greatest risk and contribute to adverse outcomes. P. falciparum is the deadliest malaria parasite and the most prevalent on the African continent.6 7 Malaria parasites contribute to adverse pregnancy and birth outcomes due to their preferential accumulation in placental intervillous spaces, putting pregnant women and their babies at an increased risk. MIP is associated with anaemia, miscarriage, premature birth, stillbirth, congenital infection, low birth weight (lbw), maternal, foetal and perinatal death; one in four women have evidence of placental infection at the time of delivery.6–8 Moreover, evidence from previous studies shows that lbw is associated with a marked increase in infant mortality, high rates of cognitive impairment, learning disability and behavioural problems.8–11

Zambia is a sub-Saharan African country with a high malaria burden with an approximate 5.2 million annual malaria cases and an estimated 200 000 pregnancies being at risk of malaria.12 The Zambia National Malaria Elimination Centre (NMEC) in line with WHO strategic framework of malaria prevention and control during pregnancy has developed and is implementing an MIP policy which includes the provision of four or more doses of intermittent preventive treatment of malaria during pregnancy with sulfadoxine pyrimethamine (IPTp-SP).13 Other interventions are insecticide treated nets (ITNs), in-door residual spraying and case management.

IPTp-SP and ITN interventions are being implemented as part of antenatal care (ANC) services14 and involve administration of sulfadoxine pyrimethamine (SP) (comprising three tablets containing 500 mg/25 mg SP, giving the total required dosage of 1500 mg/75 mg SP) as direct observed therapy to pregnant women. The first IPTp-SP dose is administered during the second trimester, 13–16 gestation weeks, followed by monthly doses until delivery for at least four doses. ANC has been identified to provide a good platform for regular and close contact between pregnant women and skilled health personnel for improved service delivery and monitoring. Zambia follows the 2016 WHO ANC model which recommends a minimum of eight ANC contacts with the first contact scheduled to take place in the first trimester, two contacts in the second trimester and five contacts scheduled in the third trimester.14 15

Administration of IPTp-SP is based on the assumption that every pregnant woman living in a high malaria transmission area has malaria parasites. The parasites live in blood or placenta, whether or not she has symptoms and signs of malaria.16 17 Previous studies in Zambia and elsewhere have provided evidence on the effectiveness of IPTp-SP on improved maternal and newborn health outcomes. In Zambia, administration of two or more doses of IPTp-SP showed a decrease in low birth weight among paucigravid and multigravid women compared with one dose.11 A study conducted in Mali18 showed that addition of a third dose of IPTp-SP led to a reduced risk of placental malaria, lbw and preterm births in all gravidae, compared with the standard two dose regimen. A systematic review and meta-analysis on intermittent preventive therapy for malaria during pregnancy using two versus three or more doses of SP and risk of lbw in Africa by Kayentao and colleagues19 showed that three or more doses were associated with a 3.3% reduction in lbw, 3.1% reduction in placental malaria and 1.4% reduction in moderate-to-severe maternal anaemia.

However, the 2018 Malaria Indicator Survey (MIS) report20 shows that the proportion of pregnant women receiving four or more doses of IPTp-SP is low at 5%. The reasons for the low coverage of IPTp-SP are not clear. Limited studies have been conducted on the predictors of the uptake of four or more doses of SP in Zambia. The reasons for the low coverage of IPTp-SP are not clear. Limited studies have been conducted on the predictors of the uptake of four or more doses of SP in Zambia.

Objectives

The aim of this study was to determine the prevalence and predictors of the uptake of four or more doses of IPTp-SP in Zambia. Information is required to inform policy and programming to improve uptake of SP in the country.

Methods

Study design

The present study is a secondary analysis of the 2018 MIS done in Zambia. It was a cross-sectional survey conducted from April to May, 2018. The survey is periodically done to assess the malaria burden and coverages of key malaria interventions such as vector control, parasite clearance, health promotion, enhanced surveillance, monitoring, evaluation and research, health system capacity, financing and case management in the general population including MIP. The MIS 2018 was the latest comprehensive data set that was representative of the whole country and readily accessible at the time of writing the manuscript.

Study site

The study used the 2018 MIS survey data which covered all the 10 provinces of Zambia, making it nationally representative. The country is divided into 10 provinces that are further divided into districts. For statistical purposes, each district is subdivided into census supervisory areas which are in turn subdivided into enumeration areas (EAs). The listing of EAs has information on the number of households and the populations. Zambia is a sub-Saharan African country located in south-central Africa with a surface area of 752 614 square kilometres. Lusaka, the capital city, is located in the south-central part of the country.21 The topography is characterised by a high plateau, river valleys and water bodies. The country derives its name from the Zambezi River, which drains all but a small northern part of the country. It has a tropical climate with the rainy season occurring during October to April. The climate is suitable for mosquito breeding and malaria transmission takes place throughout the year but peaks during the rainy season.22 23 Zambia’s population as of 8 September 2022 was 19 610 769. The male population was 9 603 056 and the female population was 10 007 713.24

Study participants and procedures

Study participants were women of reproductive age who participated in the 2018 MIS. The country conducts MIS surveys every 2–3 years to provide updates on malaria interventions and disease burden in the country. A total of 3686 women of reproductive age who gave birth in the past 5 years participated in the 2018 MIS. From this sample, a total of 1381 were included in our analysis.

Inclusion criteria

To be included in the study, participants needed to be:

  • Pregnant women who were pregnant in the past 2 years and 5 months after the new 2016 policy on the fourth dose IPTp-SP was implemented.

  • All women aged between 15 and 49 years from all the 10 provinces.

Women who did not give consent and those who did not complete the individual questionnaires were not included in the analysis.

Sample size estimation

The study participants in the main survey were selected using a two-stage cluster sampling technique which is based on a nationally representative sample of 4177 households from 179 standard EAs randomly selected from all 10 provinces. Based on these criteria, at least 2176 households were required in the rural domain. For further details on the 2018 MIS sampling technique and sample size determination see the 2018 MIS published report by the Zambian Ministry of Health.

Assumptions for the sample size determination were:

  • 95% CI.

  • 80% power.

  • Design effect of 2.50.

  • Z-score of 1.96.

  • 10% relative SE.

  • Margin of error of 2%.

  • 20% adjustment for non-response.

The estimated minimum sample size in this study was determined by the formula below:

n= z2xp(1p)(DEFF)d2 =1141 (25)

where n is the calculated sample size, z=1.96 is the statistic that defines the level of confidence required, p=0.05 is a prevalence of uptake of IPTp-SP among pregnant women in Zambia, expressed as a proportion of that population, D=0.02 is the desired level of precision, DEFF=2.5 is the design effect.25

Variables

The variables for the study were as follows:

  • Outcome variable: uptake of four or more doses of IPTp-SP.

  • Predictor variables: sociodemographic variables (age, parity, place and province of residence, religion, educational level, wealth index).

  • Basic knowledge about malaria.

  • Knowledge about malaria treatment.

The predictor variables were selected based on thorough literature review. In this study uptake means receiving any dosage of SP during pregnancy, with each dose being given at least 1 month apart starting from the second trimester of gestation, until the time of delivery as directly observed therapy.

Data sources and processing

The merged 2018 MIS data set comprising women of reproductive age (15–49 years) was extracted into the Microsoft Office Excel sheet 2013 using the data extraction tool. We subset women 15–49 years of age who were eligible to complete the questionnaire. From the eligible women, we subsetted women who consented. Further, a subset of women who completed the questionnaire and delivered in 2016 or later (after the new IPTp policy) was done using the lubridate library in RStudio. This was determined by using the age of the youngest child (ie, if a child was less than 881 days).

Statistical analysis

RStudio statistical software V.4.2.1. was used for all the analyses. Descriptive statistical analysis was carried out first on socio-demographics to obtain frequencies and proportions. The proportion of missing values on the outcome was calculated. The correlation among the predictor variables was explored. Thereafter, univariate logistic regression was carried out and explanatory variables whose p values were less than 0.2 were presented in table 1. The estimators with a p value level of 0.20 chose the adjusted estimate more frequently when confounding is present and so produced less bias than the estimators with a p value level of 0.05.26 Then, a backward selection approach using stepwise method with a p value of 0.2 threshold was used to select explanatory variables to be included in the multivariable logistic regression for further analysis of the association to obtain adjusted ORs. We also compared Akaike’s Information Criteria (AIC), Bayesian Information Criteria (BIC) and pseudo-R2 between the multivariable model which included all variables (full model) and the model after backward selection approach (reduced model) for model fit. To account for the differences in sampling probabilities across the clusters and strata, sample weighting was used to adjust for the cluster sampling design using ‘svy’ function in RStudio and ‘svyset’ command to match the multistage cluster sampling design method. Results from univariable and multivariable analysis were presented as crude and adjusted ORs along with their 95% CIs, respectively (p value<0.05).

Table 1.

Predictors for the adequate uptake of IPTp-SP (≥4 doses) during pregnancy in Zambia

Variable n (weighted) n (%) cOR 95% CI P value aOR 95% CI P value
Overall 1163 87 (7.5)
Age group (years)
15–24 542 46 (8.5) 1.00 1.00
25–34 441 31 (7.0) 0.67 0.37 to 1.21 0.181 0.54 0.26 to 1.08 0.083
35+ 180 10 (5.5) 0.58 0.24 to 1.35 0.202 0.58 0.23 to 1.51 0.266
Education level†
Primary 542 50 (9.2) 1.00 1.00
Secondary+ 396 18 (4.6) 0.30 0.15 to 0.61 0.001* 0.55 0.27 to 1.11 0.093
Residence
Rural 927 70 (7.6) 1.00
Urban 219 17 (7.2) 0.22 0.11 to 0.44 <0.001*
Province
Copperbelt 44 2 (4.6) 1.00 1.00
Central 89 3 (3.4) 2.15 0.28 to 16.78 0.463 2.03 0.27 to 15.48 0.493
Eastern 210 11 (5.2) 1.72 0.32 to 9.35 0.528 1.15 0.19 to 7.00 0.878
Luapula 196 36 (18.4) 13.57 2.98 to 61.77 0.001* 8.72 1.72 to 44.26 0.009*
Lusaka 70 0 (0.0)
Muchinga 83 13 (15.7) 11.50 2.32 to 56.95 0.003* 6.67 1.19 to 37.47 0.031*
North-Western 84 4 (4.8) 2.32 0.38 to 14.08 0.359 2.08 0.32 to 13.34 0.441
Northern 111 16 (14.4) 8.94 1.86 to 42.87 0.006 4.13 0.73 to 23.42 0.109
Southern 80 1 (1.3) 0.82 0.07 to 9.59 0.873 1.40 0.11 to 17.90 0.794
Western 196 1 (0.5) 0.53 0.05 to 6.13 0.608
Wealth tertile
Low 438 50 (11.4) 1.00 1.00
Middle 259 16 (6.2) 0.35 0.17 to 0.72 0.005* 0.52 0.19 to 1.45 0.212
High 466 21 (4.5) 0.10 0.10 to 0.20 <0.001* 0.32 0.13 to 0.79 0.014*
Exposure to media messages
No 607 54 (8.9) 1.00
Yes 556 33 (5.9) 0.49 0.28 to 0.85 0.011*
Knowledge about malaria prevention†
Not knowledgeable 180 22 (12.2) 1.00
Knowledgeable 920 60 (6.5) 0.44 0.23 to 0.86 0.016*

Note: AIC, BIC and pseudo-R2 are 417.7, 490.2 and 0.09 for the reduced model, and 436.7, 496.3 and 0.08 for the model which included all the variables (full model) in the table, respectively.

*Significant at 5% level.

†The observations do not add up to the overall sample because the variables have missing values.

AIC, Akaike’s Information Criteria; aOR, adjusted OR; BIC, Bayesian Information Criteria; cOR, crude OR.

The missing values were imputed using the multiple imputation by chain equation methods. The study explored the proportions of missing values and compared the estimates from the full data models and the imputed models to see whether there was an observed difference. The multiple imputation was carried on multivariable analysis only.26

Patient and public involvement

The study design was determined by the research team. Participants and the public were not directly involved in the conceptualisation and design of the study. Selection of study participants for the 2018 MIS was done in collaboration with the provincial and district health managers. The public were involved in the participant recruitment for the primary survey. However, since the study used secondary data from the 2018 MIS, patients and the public were not directly involved in the selection of the variables to be included in the analysis. Rather, the team from Levy Mwanawasa Medical University and NMEC decided and agreed on the variables to be included in the analysis. Consequently, permission for access to the data set used for the analysis was granted by the NMEC in consultation with the Ministry of Health. After analysis and report writing, the research team held a dissemination meeting and study findings were shared with key stakeholders, including the Levy Mwanawasa Medical University School of Public Health, Ministry of Health and Zambia National Public Health Institute. A final report was also written and shared with the funding organisation.

Results

Participants

A summary of the recruitment algorithm of study participants is shown below. A total of 4044 women of reproductive age were eligible to complete the questionnaire. Out of these, 3686 (91%) completed the questionnaire; 358 (9%) did not provide consent and were excluded from the study. A total of 1381 (34%) participants comprising women who delivered after the new IPTp-SP policy was introduced were included into the final sample for analysis (online supplemental figure 1).

Supplementary data

bmjopen-2023-073287supp001.pdf (221.5KB, pdf)

Demographic characteristics of respondents

Majority (68.9%) of study participants were in the age group 15–29 years; almost one-third (30.8%) were in the age group 30–44 years and 0.3% were aged above 45 years. Close to half (48.9%) had completed primary education, 28.2% had secondary school education and 2.8% had gone up to higher education. Most respondents (81.3%) lived in rural areas. With regard to province of residence, 19.1% were from Luapula, 18.0% from Eastern, 17.2% from Western and 4.1% from Copperbelt provinces. One-fifth (21.9%) of the study participants were in lowest wealth tertile; 15.6% were in the middle tertile. Concerning religion, more than half (56.8%) of study participants were protestants followed by Catholics (22.2%); Muslims constituted 0.1% of the respondents. Majority (97.3%) attended ANC and most (92.5%) took less than four doses of IPTp-SP. Majority (71.3%) took three doses of IPTp-SP, 14.5% took two doses, 7.5% took IPTp-SP 4+ doses, 6.9% took only one dose. The proportions of IPTp-SP uptake increased from IPTp-SP 1 to IPTp-SP 3 and drastically dropped at IPTp-SP 4+. More than half (52.5%) of the study participants had three or more children and 22.2% had two children. Concerning knowledge on malaria prevention measures, most (76.4%) were knowledgeable and only 45.0% were exposed to media messages (table 2).

Table 2.

Socio-demographic and clinical characteristics of the study participants (N=1381)

Variable N (%)
Age (years)
15–24 678 (49.1)
25–34 497 (36.0)
35+ 205 (14.8)
Missing 1 (0.1)
Residence
Rural 1123 (81.3)
Urban 258 (18.7)
Province
Central 93 (6.7)
Copperbelt 56 (4.1)
Eastern 249 (18.0)
Luapula 264 (19.1)
Lusaka 87 (6.3)
Muchinga 95 (6.9)
North-Western 90 (6.5)
Northern 120 (8.7)
Southern 90 (6.5)
Western 237 (17.2)
Wealth tertile
Low 578 (41.8)
Middle 302 (21.9)
High 501 (36.3)
Education level
Primary 675 (48.9)
Secondary+ 428 (31.0)
Missing 278 (20.1)
Religion
Christian 1092 (79.1)
Non-Christian 289 (20.9)
Parity
1 348 (25.2)
2 307 (22.2)
3+ 725 (52.5)
Missing 1 (0.1)
Got antenatal care
Yes 1344 (97.3)
No 35 (2.5)
Missing 2 (0.2)
IPTp-SP uptake*
1 80 (6.9)
2 167 (14.3)
3 829 (71.3)
4+ 87 (7.5)
Exposure to media message
No 759 (55.0)
Yes 622 (45.0)
Missing
Knowledge about malaria prevention
Not knowledgeable 241 (17.5)
Knowledgeable 1055 (78.4)
Missing 85 (6.1)
Basic malaria knowledge
Incorrect 351 (25.4)
Correct 945 (68.4)
Missing 85 (6.2)

*The proportions excludes the missing values.

Predictors for the uptake of adequate doses of IPTp-SP (4+ doses)

The overall uptake of adequate (4+) doses of IPTp-SP was 7.5%. The uptake of 4+ doses of IPTp-SP decreased by level of education ranging from 9.2% for women with primary education to 4.6% for women with higher education. The same trend was observed across age groups, that is, decrease from 8.5% in the 15–24 years age group to 5.5% in the age group of 35 and above years. The women from rural areas had higher (7.6%) uptake of adequate doses compared with women from urban areas (7.2 %). The uptake of adequate doses of SP was highest for women in the low wealth tertile (11.4 %). Also, women who were not exposed to media messages had higher uptake of SP (8.9%) compared with those who were exposed to media messages (5.9%) (table 1).

The results of univariate logistic regression analysis (crude ORs) show that a woman’s education level, place of residence, province, wealth tertile, exposure to media messages and knowledge about malaria prevention were significantly associated with the adequate uptake of IPTp-SP. While age group showed no evidence of association with adequate uptake of IPTp-SP. The results in table 1 show significant lower odds of taking an adequate IPTp-SP among women with at least secondary level of education (0.30, 95% CI 0.15 to 0.61, p value=0.001) compared with those with primary level of education. Luapula and Muchinga provinces show significant higher odds of taking an adequate IPTp-SP (13.57, 95% CI 2.98 to 61.77, p value=0.001 and 11.50, 95% CI 2.32 to 56.95, p value=0.003, respectively) compared with those from Copperbelt. However, this may be due to chance given the low sample size in Copperbelt province which is a reference. This is evidenced by the wide 95% CI, which increases uncertainty.

Women in the middle and high wealth tertile show significant lower odds of taking adequate IPTp-SP (0.35, 95% CI 0.17 to 0.72, p value=0.005 and 0.10, 95% CI 0.10 to 0.20, p value<0.001, respectively) compared with those in low wealth tertile. Women who were exposed to media messages had significant lower odds of taking an adequate IPTp-SP (0.49, 95% CI 0.28 to 0.85, p value=0.011) compared with those who were not exposed. Women who had knowledge about malaria prevention had significant lower odds of taking an adequate IPTp-SP (0.44, 95% CI 0.23 to 0.86, p value=0.016) compared with those who had none.

Using a backward selection method with p value threshold of 0.2, the reduced (final) model retained age group, education level, province and wealth quintile. Therefore, after adjusting for age group, education level and wealth quintile, Luapula and Muchinga provinces still showed significant higher (though reduced) odds of taking an adequate IPTp-SP (8.72, 95% CI 1.72 to 44.26, p value=0.009 and 6.67, 95% CI 1.19 to 37.47, p value=0.031, respectively) compared with those from Copperbelt. And after adjusting for age group, education level and province, only women in the higher wealth tertile had significant lower odds of taking an adequate IPTp-SP (0.32, 95% CI 0.13 to 0.79, p value=0.014) compared with those in low wealth tertile.

Comparing AIC, BIC and pseudo-R2 we have 417.7, 490.2 and 0.09 for the reduced model, and 436.7, 496.3 and 0.08 for the full model, respectively. This suggests that the reduced model is better fitted compared with the full model. This is because the AIC and BIC are lower, and pseudo-R2 is higher for the reduced model compared with the full model. The proportion of missing values was highest under the education level variable which accounted for 20.1%. Comparing estimates of the full data model from multivariable analysis and the imputed multivariable analysis, there is not much difference in the estimates apart from the fact that the 95% CI are narrower in some instances in the imputed model compared with the full data model. However, estimates from multiple imputation are only valid when data is at least missing at random (table 1).

Discussion

The study aimed to determine the predictors of IPTp-SP uptake for four or more doses in Zambia. Our findings show that uptake of four or more doses of IPTp-SP was low at 7.5%. The place and province of residence were significantly associated with adequate uptake of IPTp-SP doses. Women who were residents of Luapula and Muchinga provinces had higher odds of taking adequate doses with reference to those in the Copperbelt province. Conversely, women in the highest wealth tertile were significantly less likely to receive IPTp-SP 4+ doses compared with those in the lowest tertile.

Our findings show an association between IPTp-SP uptake and place of residence. Women from rural provinces such as Muchinga and Luapula showed higher odds of IPTp-SP uptake than those from urban provinces of Copperbelt and Lusaka. The observed variation in the odds of IPTp-SP uptake between the urban and rural provinces could be due to differences in the malaria prevalence among these provinces. For example, Luapula province has a high malaria prevalence of 63% compared with 3% in Lusaka and Southern provinces. The province is rural with many water bodies, enhancing malaria transmission. These factors also make malaria transmission likely to be longer and more intense compared with other provinces. Thus, the province continues to report the largest malaria burden in the country. Women in provinces with low prevalence of malaria may not take adequate IPTp-SP due to low perceived risk.27 28 On the contrary, women from regions of high level of malaria transmission, may take adequate doses of IPTp-SP due to higher risk perception. In these regions, emphasis on SP uptake during awareness messages could be higher due to the higher risk of contracting malaria. This finding suggests that women in rural areas may consider themselves at higher risk of contracting malaria compared with those in urban areas. Exploratory studies are required to investigate the reasons for variations in uptake of IPTp-SP among different provinces. These findings corroborate those from studies conducted in Uganda28 and Tanzania29 30 which showed that variations in IPTp-SP uptake were related to differences in malaria transmission in the regions. The study in Tanzania showed that residents of the Central, Eastern, Southern, Lake regions, Southern highlands and Southwest highlands were significantly associated with the optimal uptake of SP doses compared with the residents of Zanzibar and Northern zones where malaria transmission was low. Similarly, the Uganda study showed that pregnant women residing in Eastern and Coastal regions had higher odds of optimal uptake of SP.

Our findings show that participants who had knowledge about malaria prevention and exposure to media messages had less odds of receiving adequate IPTp-SP doses. These findings contradict the study conducted by Mutanyi et al 31 which showed that maternal knowledge on IPTp-SP positively influenced the uptake of the intervention in Tanzania, Cameroon, Zambia and Ghana. The difference between these findings and the current study could be that our study did not assess specifically the knowledge about IPTp-SP and its benefits. Rather, the study focused on knowledge about malaria prevention in general. This calls for more awareness on malaria interventions in general and about the recommended doses of IPTp-SP during pregnancy.

Moreover, our findings showed no significant association between education level and uptake of IPTp-SP. However, unadjusted analysis showed that women who had secondary level education and above had less odds of taking four or more doses of IPTp-SP compared with those who attained primary education. Our findings contrast previous studies and surveys. Literally, one would expect that having a secondary educational level or higher may be of influence on the uptake of the recommended doses of IPTp-SP compared with women with a lower education level. A study which compared MIS results of 12 countries in sub-Saharan Africa32 found that women with higher education had higher odds of reporting receiving three or more doses of IPTp-SP. The differences in the findings could be as a result of using different methods. It could also be due to selection bias; a large proportion of our study participants were those with primary level education who mainly resided in rural areas.

This study found that women in the highest and middle wealth tertile had less odds of taking four or more doses of IPTp-SP compared with those in the lowest wealth tertile. This finding contradicts previous studies33 34 which revealed that wealth index has a significant effect on uptake of IPTp-SP. These studies showed that the chances of completing the recommended dose of IPTp-SP increased with increase in wealth index.34 For example, a study conducted in Senegal found that women in richer or middle wealth tertile were more likely to use the recommended doses of IPTp-SP.34 The reason for the difference between our findings and these studies could be due to confounding by place of residence. Our findings show that most study participants who took four or more doses of IPTp-SP were from the rural areas who are mostly in the low wealth tertile. The other reason could be the fact that IPTp-SP is provided for free in Zambia.

There was no significant association noted between age and taking four or more doses of IPTp-SP. However, the adjusted analysis showed that, compared with the youthful mothers (15–24 years), those aged between 25 and 34 years were less likely to take four or more doses of IPTp-SP. This finding contradicts previous studies34 35 which revealed that younger women are less likely to use health services due to inadequate access to information and communication channels used for IPTp-SP promotion which are necessary for the uptake of IPTp-SP. For example, a study conducted in Ghana35 reported low uptake of the recommended dose of IPTp-SP among the youth. Many youth often hide their pregnancies and start their ANC late, when they cannot take the recommended doses before delivery.

This study further reports that the uptake of four or more doses of IPTp-SP during pregnancy is still low at 7.5%. Most women (71.3%) took up to the third dose of IPTp-SP during pregnancy. This finding could be due to lack of awareness about the new guidelines on the fourth dose. More emphasis is needed on the new guidelines and taking at least three or more doses of IPTp-SP. Health messages should focus on and emphasise the new policy on four or more doses in the country. This finding is similar to other studies in sub-Saharan Africa which reported low uptake of the recommended doses of IPTp-SP36 and suggests an urgent need for strategies to increase IPTp-SP coverage for improved maternal and newborn health outcomes in the region. This may contribute to the achievement of the ambitious Sustainable Development Goals and the target of reducing maternal mortality rate from 319 to 70 per 100 000 live births.36–42

Study limitations

This study has potential limitations. First, we did not collect the data, but used secondary data from the 2018 MIS. This prevented the team from having control over the measurement and selection of the variables. Some important variables that would have been of interest such as distance from the health facility to the communities where people live, stocks of SP, timing of ANC and number of times the woman attended ANC were not contained in the data set and thus could not be analysed. Further, the MIS data were cross-sectional, the associations in this study cannot guarantee causation or directionality.

Despite these limitations, we believe our findings have provided important information on the low coverage of four or more doses of IPTp-SP and the associated factors. In addition, use of nationally representative data from the 2018 MIS that covered all the provinces increases the generalisability of our findings.

Conclusion

These findings confirm low uptake of four or more doses of IPTp-SP in Zambia at 7.5% and that province and place of residence and wealth tertile affect IPTp-SP uptake. Strategies and interventions should focus on increased coverage of IPTp-SP from the current very low levels, with emphasis on provinces with much higher malaria burden where the risk is greatest and the ability to afford healthcare lowest. Interventions should include dissemination messages on the new policy of four or more doses of IPTp-SP and the benefits of strengthening the linkage between IPTp-SP programme with ANC services.

Supplementary Material

Reviewer comments
Author's manuscript

Acknowledgments

We thank the Lusaka District Health Management Team who provided field research assistants and study participants. We thank the Field Epidemiology Training Program staff from Levy Mwanawasa Medical University, School of Public Health for their support; Professor Victor Mukonk, Dean School of Public Health for facilitating the MSc. Field Epidemiology programme at the university; Ms Heilmann Elizabeth Susan for her support in RStudio; US CDC staff and Dr Paul Pyschus for their invaluable support during the development of this research idea. Special thanks go to the National Malaria Elimination Centre management for granting access to the Malaria Indicator Survey (MIS) data set.

Footnotes

Contributors: DS, CS and NM contributed to the conception of the study and literature search. DS conducted the extraction, analysis and drafted the manuscript. CS, NM, BH, LSM and HM contributed to the coordination study activities. CS, NM and BH contributed to the revision of the manuscript. All authors read and approved the manuscript. DS had access to the data, controlled the decision to publish and is the study guarantor.

Funding: Presidential Malaria Initiative and Centers for Disease Control and Prevention.

Competing interests: None declared.

Patient and public involvement: Patients and/or the public were involved in the design, or conduct, or reporting, or dissemination plans of this research. Refer to the Methods section for further details.

Provenance and peer review: Not commissioned; externally peer reviewed.

Supplemental material: This content has been supplied by the author(s). It has not been vetted by BMJ Publishing Group Limited (BMJ) and may not have been peer-reviewed. Any opinions or recommendations discussed are solely those of the author(s) and are not endorsed by BMJ. BMJ disclaims all liability and responsibility arising from any reliance placed on the content. Where the content includes any translated material, BMJ does not warrant the accuracy and reliability of the translations (including but not limited to local regulations, clinical guidelines, terminology, drug names and drug dosages), and is not responsible for any error and/or omissions arising from translation and adaptation or otherwise.

Data availability statement

Data are available upon reasonable request. Data are available upon reasonable request from the corresponding author and with permission of the ERES ethics review board.

Ethics statements

Patient consent for publication

Not applicable.

Ethics approval

Ethical approval and waiver of consent was given by ERES converge IRB (Ref No. 2021-Nov-004). Permission to conduct the study and access to the 2018 MIS data set was granted by the National Health Research Authority (NRFA) Ref No. NHRA000023/04/03/2022) and the Ministry of Health, respectively. The data set was then secured as soft copy in the computer. No information regarding names of study participants was obtained and used; the data set was only used for the purpose of this study and it was not given to any other person or organisation. No harm was inflicted to the participants, the study used secondary data and there was no direct contact with study participants.

References

  • 1. WHO . Malaria; 2023. Available: Malaria (who.int) [Accessed 10 Apr 2023].
  • 2. WHO . World malaria report 2020: 20 years of global progress and challenges; 2021. Available: Worldmalariareport2020:20yearsofglobalprogressandchallenges(who.int) [Accessed 10 Apr 2023].
  • 3. WHO . World malaria report 2020: tracking progress and gaps in the global response to malaria; 2023. Available: World malaria report 2022 (who.int) [Accessed 10 Apr 2023].
  • 4. Bauserman M, Conroy AL, North K, et al. An overview of malaria in pregnancy. Semin Perinatol 2019;43:282–90. 10.1053/j.semperi.2019.03.018 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 5. Dellicour S, Tatem AJ, Guerra CA, et al. Quantifying the number of pregnancies at risk of malaria in 2007: a demographic study. PLoS Med 2010;7:e1000221. 10.1371/journal.pmed.1000221 Available: 10.1371/journal.pmed.1000221 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 6. Gnémé A, Guelbéogo WM, Riehle MM, et al. Plasmodium species occurrence, temporal distribution and interaction in a child-aged population in rural Burkina Faso. Malar J 2013;12:67. 10.1186/1475-2875-12-67 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 7. Desai M, ter Kuile FO, Nosten F, et al. Epidemiology and burden of malaria in pregnancy. Lancet Infect Dis 2007;7:93–104. 10.1016/S1473-3099(07)70021-X [DOI] [PubMed] [Google Scholar]
  • 8. Greenwood AM, Armstrong JR, Byass P, et al. Malaria chemoprophylaxis, birth weight and child survival. Trans R Soc Trop Med Hyg 1992;86:483–5. 10.1016/0035-9203(92)90078-q [DOI] [PubMed] [Google Scholar]
  • 9. Steketee RW, Nahlen BL, Parise ME, et al. The burden of malaria in pregnancy in malaria-endemic areas. Am J Trop Med Hyg 2001;64:28–35. 10.4269/ajtmh.2001.64.28 [DOI] [PubMed] [Google Scholar]
  • 10. Corbett SS, Drewett RF. To what extent is failure to thrive in infancy associated with poorer cognitive development? A review and meta-analysis. J Child Psychol Psychiatry 2004;45:641–54. 10.1111/j.1469-7610.2004.00253.x [DOI] [PubMed] [Google Scholar]
  • 11. Mace KE, Chalwe V, Katalenich BL, et al. Evaluation of sulphadoxine-pyrimethamine for intermittent preventive treatment of malaria in pregnancy: a retrospective birth outcomes study in Mansa, Zambia. Malar J 2015;14:69. 10.1186/s12936-015-0576-8 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 12. Chaponda EB, Chandramohan D, Michelo C, et al. High burden of malaria infection in pregnant women in a rural district of Zambia: a cross-sectional study. Malar J 2015;14:380. 10.1186/s12936-015-0866-1 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 13. Zambia National Malaria Elimination . National malaria elimination strategic plan 2017-2021. 2017. Available: Malaria Elimination Strategy — Zambia National Malaria Elimination Centre (nmec.org.zm) [Accessed 12 Apr 2023].
  • 14. Ministry of Health . ANC guidelines for a positive pregnancy experience. 2018. Available: ANC guidelines for a positive pregnancy experience | WHO | Regional Office for Africa [Accessed 13 Apr 2023].
  • 15. Sialubanje C, Kaiser JL, Ngoma T, et al. Postnatal care services in rural Zambia: a qualitative exploration of user, provider, and community perspectives on quality of care. BMC Pregnancy Childbirth 2023;23:39. 10.1186/s12884-023-05350-w Available: 10.1186/s12884-023-05350-w [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 16. Sikambale C, Halwindi H, Baboo KS. Factors influencing utilization of intermittent presumptive treatment of malaria (IpTp) services by pregnant women in Sesheke District of Western province Zambia. Med J Zambia 2013;40:24–32. [Google Scholar]
  • 17. Zakama AK, Ozarslan N, Gaw SL. Placental malaria. Curr Trop Med Rep 2020;7:162–71. 10.1007/s40475-020-00213-2 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 18. Diakite OSM, Kayentao K, Traoré BT, et al. Superiority of 3 over 2 doses of intermittent preventive treatment with sulfadoxine-pyrimethamine for the prevention of malaria during pregnancy in Mali: a randomized controlled trial. Clin Infect Dis 2011;53:215–23. 10.1093/cid/cir374 [DOI] [PubMed] [Google Scholar]
  • 19. Kayentao K, Garner P, van Eijk AM, et al. Intermittent preventive therapy for malaria during pregnancy using 2 vs 3 or more doses of sulfadoxine-pyrimethamine and risk of low birth weight in Africa: systematic review and meta-analysis. JAMA 2013;309:594–604. 10.1001/jama.2012.216231 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 20. Ministry of Health, Central Statistics Office, PATH, PMI USAID, CDC, UNICEF, and WHO . MIS 2018: Zambia malaria indicator survey 2018; 2018. Available: https://www.malariasurveys.org/documents/Zambia_MIS2018_FINAL-withSigs_20190415.pdf [Accessed 10 Apr 2023].
  • 21. Central Statistical Office (Zambia), ICF International, Ministry of Health (Zambia), University Teaching Hospital (Zambia), University of Zambia . Zambia demographic and health survey 2018-2019. Fairfax, United States of America: ICF International; 2020. Available: Zambia Demographic and Health Survey 2018-2019 | GHDx (healthdata.org) [Google Scholar]
  • 22. US President’s Malaria Initiative (PMI) . Zambia. 2022. Available: Zambia - PMI [Accessed 14 Apr 2023].
  • 23. Riedel N, Vounatsou P, Miller JM, et al. Geographical patterns and predictors of malaria risk in Zambia: Bayesian geostatistical modelling of the 2006 Zambia national malaria indicator survey (ZMIS). Malar J 2010;9:37. 10.1186/1475-2875-9-37 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 24. Zambia Statistics Agency . 2022 census; 2022. Available: https://www.zamstats.gov.zm/2022-census [Accessed 14 Apr 2023].
  • 25. Pourhoseingholi MA, Vahedi M, Rahimzadeh M. Sample size calculation in medical studies. Gastroenterol Hepatol Bed Bench 2013;6:14–7. [PMC free article] [PubMed] [Google Scholar]
  • 26. Rubin DB. Inference and missing data. Biometrika 1976;63:581–92. 10.1093/biomet/63.3.581 Available: 10.1093/biomet/63.3.581 [DOI] [Google Scholar]
  • 27. Okoli CI, Hajizadeh M, Rahman MM, et al. Decomposition of socioeconomic inequalities in the uptake of intermittent preventive treatment of malaria in pregnancy in Nigeria: evidence from demographic health survey. Malar J 2021;20:300. 10.1186/s12936-021-03834-8 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 28. Okethwangu D, Opigo J, Atugonza S, et al. Factors associated with uptake of optimal doses of intermittent preventive treatment for malaria among pregnant women in Uganda: analysis of data from the Uganda demographic and health survey, 2016. Malar J 2019;18:250. 10.1186/s12936-019-2883-y [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 29. Mchwampaka WM, Tarimo D, Chacky F, et al. Factors affecting uptake of ≥ 3 doses of sulfadoxine-pyrimethamine for malaria prevention in pregnancy in selected health facilities, Arusha region, Tanzania. BMC Pregnancy Childbirth 2019;19:440.:440. 10.1186/s12884-019-2592-0 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 30. Gross K, Alba S, Glass TR, et al. Timing of antenatal care for adolescent and adult pregnant women in South-Eastern Tanzania. BMC Pregnancy Childbirth 2012;12:16. 10.1186/1471-2393-12-16 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 31. Mutanyi JA, Onguru DO, Ogolla SO, et al. Determinants of the uptake of intermittent preventive treatment of malaria in pregnancy with Sulphadoxine Pyrimethamine in Sabatia sub County, Western Kenya. Infect Dis Poverty 2021;10:106.:106. 10.1186/s40249-021-00887-4 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 32. Darteh EKM, Dickson KS, Ahinkorah BO, et al. Factors influencing the uptake of intermittent preventive treatment among pregnant women in sub-Saharan Africa: a Multilevel analysis. Arch Public Health 2021;79:182. 10.1186/s13690-021-00707-z [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 33. Burger R. School effectiveness in Zambia: the origins of differences between rural and urban outcomes. Development Southern Africa 2011;28:157–76. 10.1080/0376835X.2011.570064 [DOI] [Google Scholar]
  • 34. Mbengue MAS, Bei AK, Mboup A, et al. Factors influencing the use of malaria prevention strategies by women in Senegal: a cross-sectional study. Malar J 2017;16:470. 10.1186/s12936-017-2095-2 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 35. Atenkperiga Ayiisi E. Knowledge and utilization of intermittent preventive treatment (IPT) for malaria control among pregnant women attending Antenatal clinics in the Sunyani West District of Ghana. SJPH 2017;5:254. 10.11648/j.sjph.20170503.24 [DOI] [Google Scholar]
  • 36. Odjidja EN, Kwanin C, Saha M. Low uptake of intermittent preventive treatment in Ghana; an examination of health system bottlenecks. Health Syst Policy Res 2017;4. 10.21767/2254-9137.100079 [DOI] [Google Scholar]
  • 37. Dun-Dery F, Meissner P, Beiersmann C, et al. Uptake challenges of intermittent preventive malaria therapy among pregnant women and their health care providers in the upper West region of Ghana: a mixed-methods study. Parasite Epidemiol Control 2021;15:e00222. 10.1016/j.parepi.2021.e00222 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 38. Blystad A, Moland KM, Munsaka E, et al. Vanilla bisquits and lobola bridewealth: parallel discourses on early pregnancy and schooling in rural Zambia. BMC Public Health 2020;20:1485. 10.1186/s12889-020-09555-y [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 39. Massar K, Sialubanje C, Maltagliati I, et al. Exploring the perceived effectiveness of applied theater as a maternal health promotion tool in rural Zambia. Qual Health Res 2018;28:1933–43. 10.1177/1049732318794207 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 40. Sialubanje C, Sitali DC, Mukumbuta N, et al. Perspectives on factors influencing transmission of COVID-19 in Zambia: a qualitative study of health workers and community members. BMJ Open 2022;12:e057589. 10.1136/bmjopen-2021-057589 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 41. Sialubanje C, Mukumbuta N, Ng’andu M, et al. Perspectives on the COVID-19 vaccine uptake: a qualitative study of community members and health workers in Zambia. BMJ Open 2022;12:e058028. 10.1136/bmjopen-2021-058028 [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 42. Sialubanje C, Kaiser JL, Ngoma T, et al. Postnatal care services in rural Zambia: a qualitative exploration of user, provider, and community perspectives on quality of care. BMC Pregnancy Childbirth 2023;23:39. 10.1186/s12884-023-05350-w [DOI] [PMC free article] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplementary data

bmjopen-2023-073287supp001.pdf (221.5KB, pdf)

Reviewer comments
Author's manuscript

Data Availability Statement

Data are available upon reasonable request. Data are available upon reasonable request from the corresponding author and with permission of the ERES ethics review board.


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