Hostname: page-component-8448b6f56d-dnltx Total loading time: 0 Render date: 2024-04-24T05:38:48.633Z Has data issue: false hasContentIssue false
  • English
  • Français

Ramadan during pregnancy and birth weight of newborns

Published online by Cambridge University Press:  01 February 2018

Ary I. Savitri ,
Dwirani Amelia ,
Rebecca C. Painter ,
Mohammad Baharuddin ,
Tessa J. Roseboom ,
Diederick E. Grobbee  and
Cuno S. P. M. Uiterwaal
Ary I. Savitri*
Affiliation:
Julius Center for Health Sciences and Primary Care, University Medical Center Utrecht, Utrecht, The Netherlands
Dwirani Amelia
Affiliation:
Budi Kemuliaan Hospital, Jl. Budi Kemuliaan No. 25, Jakarta Pusat 10110, Indonesia
Rebecca C. Painter
Affiliation:
Department of Obstetrics and Gynecology, Academic Medical Center, Meibergdreef 9, 1105 AZ Amsterdam, The Netherlands
Mohammad Baharuddin
Affiliation:
Budi Kemuliaan Hospital, Jl. Budi Kemuliaan No. 25, Jakarta Pusat 10110, Indonesia
Tessa J. Roseboom
Affiliation:
Department of Obstetrics and Gynecology, Academic Medical Center, Meibergdreef 9, 1105 AZ Amsterdam, The Netherlands Department of Clinical Epidemiology, Biostatistics and Bioinformatics, Academic Medical Center, Meibergdreef 9, 1105 AZ Amsterdam, The Netherlands
Diederick E. Grobbee
Affiliation:
Julius Center for Health Sciences and Primary Care, University Medical Center Utrecht, Utrecht, The Netherlands
Cuno S. P. M. Uiterwaal
Affiliation:
Julius Center for Health Sciences and Primary Care, University Medical Center Utrecht, Utrecht, The Netherlands
*
*Corresponding author: A. I. Savitri, email aryisavitri@gmail.com

Abstract

Previous studies suggest that Ramadan exposure during pregnancy might affect the health of women and their babies, particularly through the effect of fasting. This study aimed to evaluate the association between Ramadan exposure and fasting during pregnancy on the birth weight of newborns. This study concerned 1351 pregnant women from a prospective cohort in Jakarta, Indonesia. Ramadan exposure was based on the actual overlap between Ramadan and pregnancy. Women's fasting behaviour was recorded among 139 women who came for antenatal care between 10 July 2013 and 7 August 2013, and those who had fasted for at least 1 d (n 110) were classified as exposed to Ramadan fasting. Furthermore, a 24 h dietary recall was performed and repeated 1 month later. Birth weight of newborns who were exposed to Ramadan during pregnancy did not significantly differ from those who were not, both in the total and trimester-specific analysis. Maternal fasting did not seem to affect the birth weight of newborns (−72 (95 % CI −258, 114) g; P = 0·44), although there was a non-significant trend towards lower birth weight with fasting in the second and third trimester. Women who fasted had significantly lower total energy, macronutrient and water intake as compared with women who did not. Women's intake was also lower during Ramadan (regardless of their fasting behaviour) as compared with 1 month later. Lifestyle changes that occur with Ramadan and fasting during pregnancy are associated with lower reported energy intake. We cannot conclude on the effect of fasting on birth weight due to low statistical power.

Keywords

RamadanFastingPregnancyBirth weight
Type
Research Article
Information
Journal of Nutritional Science , Volume 7 , 2018 , e5
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s) 2018

An adverse fetal environment could have serious consequences on health outcomes in offspring. Exposures such as suboptimal maternal diet, smoking and stress could inhibit fetal growth and development, which further cause lower birth weight and other poor birth outcomes( Reference Abu-Saad and Fraser 1 Reference Wu, Imhoff-Kunsch and Girard 3 ). Studies on the long-term impact of fetal growth restriction, as represented by lighter weight at birth, showed a greater risk of later chronic diseases, including CHD, stroke, type 2 diabetes, hypertension, and other cognitive and emotional problems( Reference Barker 4 Reference Roseboom, Painter and van Abeelen 8 ).

During the month of Ramadan when daytime fasting is obligated to every adult Muslim, various degrees of behavioural changes may occur among pregnant Muslim women. Meal frequencies are usually reduced to two times per d; one large meal when breaking the fast in the evening and another smaller meal during sahoor at dawn. Many seasonal meals which consist of sugary and fatty foods are commonly served during this month( Reference Bakhotmah 9 Reference Alwasel, Harrath and Aljarallah 13 ). Physical activities and sleeping pattern are also affected, as people tend to be more active at night. Ramadan lasts for 29–30 d and shifts forward by approximately 11 d each year, since it is based on the Islamic lunar calendar( Reference Trepanowski and Bloomer 11 Reference Leiper, Molla and Molla 14 ).

Three out of every four pregnant Muslim women are exposed to Ramadan( Reference Almond and Mazumder 15 ). According to the Islamic rule, pregnant women, together with breastfeeding mothers, are exempted from the obligation to fast during Ramadan. They are permitted to postpone their fasting until after delivery or to feed one poor person for each day they do not fast. However, many women choose to fast during pregnancy to share the spiritual experience with their family. The proportion of fasting pregnant Muslim women varies globally, ranging from 50–70 % (in Iran, The Netherlands)( Reference Ziaee, Kihanidoost and Younesian 16 Reference Arab and Nasrollahi 18 ) to 70–90 % (in England, Singapore, USA, Gambia and Yemen)( Reference Almond and Mazumder 15 , Reference Ewijk RJG, Painter and Roseboom 19 Reference Robinson and Raisler 21 ).

Despite its widespread adherence, evidence on the health effects of Ramadan fasting during pregnancy (both maternal and fetal) is still limited. Dietary intake and weight gain of fasting pregnant women were reported to be less than in the non-fasting( Reference Kiziltan, Karabudak and Tuncay 22 , Reference Khoshdel, Kheiri and Hashemi-Dehkordi 23 ). Metabolic alterations associated with fasting have also been reported, which include reduction in serum glucose and insulin levels( Reference Mirghani, Weerasinghe and Ezimokhai 24 ) and elevation in serum TAG, cortisol and leptin concentrations( Reference Dikensoy, Balat and Cebesoy 25 , Reference Hızlı, Yılmaz and Onaran 26 ). Several studies showed no association between Ramadan exposure during pregnancies with birth weight, or the risk of low birth weight( Reference Ziaee, Kihanidoost and Younesian 16 Reference Arab and Nasrollahi 18 , Reference Kiziltan, Karabudak and Tuncay 22 , Reference Hızlı, Yılmaz and Onaran 26 Reference Faris and Al-Holy 31 ). On the contrary, several other studies reported a lower birth weight with Ramadan exposure( Reference Savitri, Yadegari and Bakker 32 , Reference Almond and Mazumder 33 ). Many of these studies, however, did not differentiate Ramadan exposure (as overlap between pregnancy and the month of Ramadan) from actual fasting exposure, which potentially leads to dilution of effects.

In the present study, we used data from a large prospective cohort of Indonesian Muslim pregnant women to evaluate both the effect of Ramadan exposure during pregnancy and maternal fasting on the birth weight of newborns. Maternal dietary intakes were evaluated during and after Ramadan, both in the fasting and non-fasting women, in an attempt to seek for possible explanatory factors.

Materials and methods

Study population

The present study was conducted within a cohort of pregnant women in Budi Kemuliaan Hospital, Jakarta, Indonesia, a private municipal hospital that specialised in maternal and child health care, training (midwives), education and research. Recruitment of participants took place from July 2012 until October 2014. Muslim pregnant women who were paying antenatal care visits to the hospital were asked to participate and provided a written informed consent. Women were examined and interviewed by the midwives according to the standard clinical care and followed on the subsequent antenatal care visits until delivery. Pregnancies that ended with preterm birth were excluded since they intrinsically had less chance to be exposed to Ramadan and were more likely to result in lower-birth-weight babies.

Ramadan and fasting exposure

The present study coincided with three Ramadan months, which occurred on 21 July–18 August 2012, 10 July–7 August 2013, and 29 June–27 July 2014. Pregnancies were classified as being exposed to Ramadan if the women's last menstrual period coincided with Ramadan or if Ramadan started after the women's last menstrual period and before delivery. All pregnancies that overlapped with Ramadan in any number of days were all classified as exposed. These exposed pregnancies were, further, classified according to the trimesters when the exposure occurred. They were consecutively classified as being exposed in the first, second and third trimester if Ramadan started between the 1st and 93rd day, the 94th to 186th day, and at 187th day or later of the pregnancy.

Maternal fasting behaviour was measured using a self-administered questionnaire in women who came to the hospital for antenatal care during Ramadan in 2013 (10 July 2013–7 August 2013). Women were classified as being exposed to Ramadan fasting if she had fasted for at least 1 d during Ramadan. Fasted women were also classified according to their trimester when they fasted.

Dietary assessment

Assessment of women's dietary intakes was done by a nutrition officer using a single 24 h dietary recall, both in the fasting and non-fasting women and was repeated 1 month later. A 24 h dietary recall is a retrospective method of dietary assessment in which every individual is interviewed about his or her food and beverage consumption during the previous 1 d or 24 h. A computerised data analysis system (Nutrisurvey, 2007; Indonesian version) was used to convert food intake into nutrient intake based on the portion sizes, preparation of recipes and food tables. The system is a translation from a German nutrition software package (EBISpro), which has been adapted to the local food tables.

Outcome measurement

Newborn birth weight was investigated in relation to both Ramadan exposure and maternal fasting. Birth weight was measured using a standard infant scale (Tanita).

Data analysis

Maternal and babies’ characteristics were tabulated by Ramadan exposure and Ramadan fasting exposure separately, for both descriptive purposes and for initial evaluation for possible confounding. First, we compared the birth weight of newborns with Ramadan exposure during pregnancy with the unexposed. Second, within the Ramadan-exposed newborns, we examined the effect of maternal fasting on birth weight. A trimester-specific analysis was done to investigate if the effect differs according to the timing of exposure.

We used linear regression analysis to analyse the association between Ramadan exposure and maternal fasting on newborn birth weight. Univariable analyses were first performed and followed by multivariable analyses for adjustment for confounders. Potential confounders were secondhand smoking exposure, monthly family income and maternal education (as proxy for socio-economic status), pre-pregnancy BMI, gestational duration and parity. Secondhand smoking was used instead of active smoking because few (<1 %) of these pregnant women smoke. Family income was asked to the women as an estimate range. Women's education was categorised as low if the women had finished elementary or junior high school, middle if they had finished senior high school, or high if they attained education from university. Pre-pregnancy BMI was calculated as women's self-reported pre-pregnancy weight in kg divided by the square of height in metres. Women's weight was measured at each antenatal care visit and at the day of delivery using a standard weight scale (Camry). Gestational durations were measured as the difference between the last menstrual date and the date of delivery. Women's parity was classified into nulli- or multiparity. Results are expressed as β coefficients from linear regression with 95 % CI and corresponding P values. Statistical significance were considered to be a two-sided P < 0·05. All analyses were done with SPSS version 21.0 for Windows (SPSS Inc.).

Results

The initial number of pregnant women in the total cohort was 2252. Thirty-five women withdrew their consent (drop outs), 168 women experienced miscarriage, and 282 women could not be contacted for their pregnancy outcomes (loss to follow-up). After excluding the women with missing data on their last menstrual period and/or date of delivery (n 113), miscoded gestational durations (n 11), twin pregnancies (n 28), non-Muslim mothers (n 65) and preterm births (n 199), the cohort included 1351 women for analysis. The flowchart of the study population is shown in Fig. 1.

Fig. 1. Overview of the study population.

The baseline characteristics of women based on their exposure to Ramadan during their pregnancy and their fasting status are shown in Table 1. The majority of women in this study were exposed to Ramadan during their pregnancy. Gestational duration was on average 4 d longer with Ramadan exposure. Women who were exposed to Ramadan had a slightly higher pre-pregnancy BMI as compared with the unexposed, although not statistically significant. The exposed and unexposed women were similar with respect to age, education, family income, secondhand smoking exposure, parity, pregnancy weight gain and babies’ sex.

Table 1. Baseline characteristics of women based on Ramadan exposure and their fasting status

(Numbers of subjects and percentages; mean values with their standard errors; medians and interquartile ranges)

IDR, Indonesian Rupiah.

* Independent-samples t test.

Skewed data.

Mann–Whitney test.

§ χ2 Test.

ǁ Fisher's exact test.

There were 139 women who came to the hospital between 10 July and 7 August 2013, from whom data about fasting behaviour were collected. As compared with Ramadan-exposed women who did not come to the hospital during the month, these women had higher gestational age (24·0 v. 19·0 weeks; P < 0·01). There were 110 (79 %) women who fasted to some extent during Ramadan and twenty-nine (21 %) women who did not fast at all. Among women who fasted, the median number of days fasted was 14 d. Fasting women had significantly higher pre-pregnancy BMI and less pregnancy weight gain than the non-fasting. There were also fewer fasting women in the lowest income category. The two groups were not different with respect to age, education, secondhand smoking exposure, parity, gestational duration and babies’ sex.

The Ramadan-unexposed pregnancies consisted of all pregnancies in the cohort that did not overlap with Ramadan and were taken as the reference group. Birth weight of Ramadan-exposed babies was on average 3107·5 (sd 545·7) g while that of unexposed was 3022·4 (sd 545·7) g. In Table 2, we show the association between Ramadan exposure during pregnancy and newborn birth weight. Newborn birth weight was not different between Ramadan-exposed and -unexposed groups, neither in crude nor in adjusted analysis. Similarly, Ramadan exposure in the first and second trimesters did not influence newborn birth weight. With exposure in the third trimester, birth weight was shown on average 73 g higher in the crude analysis and model 1, but this association was reduced in the fully adjusted analysis.

Table 2. Total and trimester-specific associations between Ramadan exposure during pregnancy and the birth weight of newborns

(Regression coefficients and 95 % confidence intervals)

* P < 0·05.

Linear regression coefficients indicated the difference in birth weight (g) compared with the reference category.

Model 1 is adjusted for secondhand smoking exposure, family income categories and maternal education categories.

§ Model 2 is adjusted for as model 1 and for pre-pregnancy BMI, gestational duration and parity.

Within women who were exposed to Ramadan during their pregnancy, comparison of their newborns' birth weight was made according to the fasting status. Average birth weight of babies who were exposed to Ramadan fasting during pregnancy was 3201·5 (sd 377·6) g and 3190·6 (sd 606·7) g in babies who were not. As shown in Table 3, birth weight of newborns of the fasted women was not significantly different from those who did not fast, both in the crude and adjusted analysis. Although not statistically significant, trimester-specific analysis shows a trend towards reduced birth weight with fasting, especially in women who fasted in the second and third trimesters. Furthermore, within fasted women, we also explored if birth weight differed according to fasting intensity. Fig. 2 shows a boxplot that illustrates the association between tertiles of fasting days with newborn birth weight. The first tertile of fasting days consists of women who fasted for 1 to 8 d, while the second and third tertiles include women who fasted for 10 to 23 and 24 to 30 d.

Table 3. Total and trimester-specific associations between maternal fasting during pregnancy and the birth weight of newborns*

(Regression coefficients and 95 % confidence intervals)

* Linear regression coefficients indicated the difference in birth weight (g) compared with the reference category.

Model 1 is adjusted for secondhand smoking exposure, family income categories and maternal education categories.

Model 2 is adjusted for as model 1 and for pre-pregnancy BMI, gestational duration and parity.

Fig. 2. Boxplot showing the relationship between tertiles of fasting days and birth weight. Tertile 1 (n 33), tertile 2 (n 40) and tertile 3 (n 35). The horizontal lines represent medians, the boxes interquartile ranges, the whiskers are minima and maxima and the circles are outliers.

During Ramadan, we performed a 24 h dietary recall in ninety-six women. There were forty-two women who were fasting and fifty-four women who were not fasting at the day of the interview. The median of gestational age was not different between the fasting and non-fasting women (33 v. 30 weeks; P  =  0·46). Table 4 shows the comparison of intake between these two groups. Women who were fasting reported significantly lower percentage of energy intakes from protein than the non-fasting. They reported lower total energy and protein intake, although borderline statistically significant. They also, in general, reported lower intakes of carbohydrates, water, vitamin A, Na and K, although none was statistically significant. There was no difference in consumption of fat, dietary fibre, PUFA, cholesterol, carotene, vitamin E, vitamin B1, vitamin B2, vitamin B6, folic acid, vitamin C, Ca, Mg, P, Fe and Zn, as well as percentage of energy from fat and carbohydrates.

Table 4. Maternal dietary intake on one Ramadan day based on fasting status*

(Mean values with their standard errors; medians and interquartile ranges)

% TE, percentage of total energy.

* Results are based on estimation using 24 h nutrition recall. P values are based on Student's t test or the Mann–Whitney U test in the case of skewed data.

Skewed data. Medians and interquartile ranges.

In Table 5, we compared dietary intake of the fasting women during Ramadan with their intake 1 month later. There were fifteen women who could be re-interviewed for this purpose. During Ramadan, fasting women reported significantly less consumption of water, fat and vitamin A, and had a lower percentage of energy intake from carbohydrates. Water and fat intakes were significantly lower than 1 month later by on average 570 and 16 g while carbohydrate intake was approximately 50 g lower. Intakes of total energy, carbohydrates, vitamin C, Na, Ca and P, as well as percentage of energy from protein and fat were not significantly different.

Table 5. Maternal dietary intake on one Ramadan day as compared with 1 month after Ramadan within fasting women*

(Mean values with their standard errors; medians and interquartile ranges)

% TE, percentage of total energy.

* Results are based on estimation using 24 h nutrition recall. P values are based on the paired-samples t test or Wilcoxon signed-ranks test in the case of skewed data.

Skewed data. Medians and interquartile ranges.

In Table 6, we compared the dietary intake of the non-fasting women on 1 d of Ramadan with 1 month later. There were twenty-seven women who were accessible for this analysis. As compared with 1 month later, these women reported a consumption of significantly less water and had a lower percentage of energy intakes from protein. Intakes of all other nutrients were similar during Ramadan as compared with 1 month later.

Table 6. Maternal dietary intake on one Ramadan day as compared with 1 month later in women who were not fasting*

(Mean values with their standard errors; medians and interquartile ranges)

% TE, percentage of total energy.

* Results are based on estimation using 24 h nutrition recall. P values are based on the paired-samples t test or Wilcoxon signed-ranks test in the case of skewed data.

Skewed data. Medians and interquartile ranges.

Discussion

Approximately 81 % of all women in our study had Ramadan exposure at any time during their pregnancies and about 79 % of them fasted to some extent during the month. Ramadan exposure during pregnancy was not significantly associated with newborn birth weight. Furthermore, within the Ramadan exposed, babies’ birth weight of the fasted women was not significantly different from that of the babies of non-fasted women. In the present study, we showed that fasted women reported a significantly lower intake of total energy, macronutrients and water as compared with women who did not fast. Women's intakes were also generally lower during Ramadan as compared with 1 month later, both in the fasted and non-fasted group.

To the best of our knowledge, we are the first to study the effect of Ramadan during pregnancy on birth weight by looking both on the effects of Ramadan overlap and maternal fasting behaviour. We are also among the first to evaluate women's dietary intake during and after Ramadan, both in the fasting and non-fasting group.

There were some limitations of the present study. First, interviews about women's fasting behaviour were limited only to women who came to the hospital during the period of data collection. The relatively small number of women analysed in the association between fasting and babies’ birth weight could limit statistical power, thus requiring cautious interpretation of the findings. Women with available data on fasting behaviour were at a later stage of gestation as compared with women without. Furthermore, women with available data on nutritional intake were also at a later gestational age (24 v. 19 weeks; P < 0·01) and had lower pre-pregnancy BMI (22·2 v. 23·2 kg/m2; P  =  0·05) as compared with women without nutritional data. The average pregnancy weight gain was not different in women with available nutrition data as compared with those without (12·9 v. 12·3 kg, P  =  0·88). The difference in gestational age could be caused by the fact that women at later gestational age had more visits to the hospital, while we can only speculate about the difference in BMI. Gestational diabetes mellitus, notably, could confound the relationship between Ramadan fasting and newborn birth weight; however, we could not adjust for it in the analysis due to the absence of gestational diabetes mellitus screening in our cohort. Furthermore, the use of single 24 h dietary recall as nutritional assessment may give some disadvantages since it relies on subjects' memory, cooperation and communication ability, and it may not have captured the day-to-day variation in nutrient intake.

We are aware of the possibility of reverse causation, where babies with longer gestational duration (and therefore higher birth weight) had higher chance to be exposed to Ramadan. We dealt with it by restricting the analyses to the full-term babies. Although we had excluded the preterm babies, we still found that pregnancies with Ramadan overlap were on average 4 d longer than those without (Table 1). Thus, gestational length was an important potential confounder to be adjusted for in our main analysis.

Several other possible confounders were included in our model as those variables were found to be associated both with the exposure and with the outcome. Secondhand smoking exposure, lower family income and low maternal education were slightly more common in the non-fasting women. Fasting women also had a significantly higher pre-pregnancy BMI and lower gestational weight gain than the non-fasting. These women may feel healthier and therefore more prone to fast. In the previous studies, several maternal characteristics have been shown to predict maternal fasting during Ramadan, such as pre-pregnancy BMI, parity, maternal age and socio-economic status( Reference Kavehmanesh and Abolghasemi 17 , Reference Savitri, Yadegari and Bakker 32 , Reference Joosoph, Abu and Yu 34 , Reference Petherick, Tuffnell and Wright 35 ).

Our finding of no significant difference in birth weight of babies with or without Ramadan overlap during pregnancy is in accordance with several previous studies( Reference Almond and Mazumder 15 , Reference Cross, Eminson and Wharton 27 , Reference Alwasel, Abotalib and Aljarallah 36 ). These studies were, however, mostly based on registry data with limited information on women's religion and might therefore have included non-Muslim women in their analysis. Our finding of no significant difference in babies’ birth weight in the fasting women as compared with the non-fasting women is also in line with several earlier studies( Reference Ziaee, Kihanidoost and Younesian 16 Reference Arab and Nasrollahi 18 , Reference Hızlı, Yılmaz and Onaran 26 , Reference Ozturk, Balat and Ugur 29 , Reference Shahgheibi, Ghadery and Pauladi 30 ), although different from our previous study among pregnant Muslim women in Amsterdam (The Netherlands). In the previous study, a lower birth weight was found with maternal fasting in the first trimester( Reference Savitri, Yadegari and Bakker 32 ). The difference in the finding could be attributed to the contrast in cultural and dietary habits of these women, who were mostly of Turkish and Moroccan background. Variation in the climate, duration and the number of fasting days could also influence the degree of exposure.

Our dietary assessments showed that women who were fasting during Ramadan in general reported lower percentage of total energy intake from protein, intake of total energy and macronutrients, as well as water, vitamin A, Na and K as compared with the non-fasting women. The differences in women's intakes were unlikely to be caused by the difference in their gestational age since women in both groups had similar gestational age at the interview. This result is in accordance with findings from previous studies on dietary intake of pregnant women during Ramadan which found significantly lower energy intake among women who fasted as compared with those who did not( Reference Kiziltan, Karabudak and Tuncay 22 ), and lower energy intake during Ramadan as compared with outside Ramadan( Reference Al-Hourani and Atoum 37 ). In contrast, our result is different from a study conducted among Saudi families which reported weight gains due to higher consumption of carbohydrates and fat-rich food during Ramadan( Reference Bakhotmah 9 ).

Ramadan also appeared to influence dietary intakes of women both in the fasting and non-fasting groups. It was shown by lower intakes of total energy, carbohydrates, fat and water during Ramadan as compared with intakes of the same women 1 month later, both in the fasting and non-fasting groups. More substantial changes of the intake during Ramadan as compared with 1 month later, however, were evident among fasting women. We suggest that in the non-fasting women, dietary habits were also influenced by their fasting families, as seen by the reduction of the frequency and/or the portion size of women's meals. Furthermore, as compared with the Indonesian estimated average requirement for pregnant women, we found that the mean intakes of protein and fat of women in our study consistently exceeded the recommendation, while carbohydrate intakes were generally lower than recommended. The estimated average requirements for protein, fat and carbohydrate are 43–52, 40–42 and 270–285 g, respectively( 38 , Reference Muhilal and Hardiansyah 39 ).

Despite the nutrition restriction during Ramadan, a significant reduction of (secondhand) smoke exposure is expected since Muslims are not allowed to smoke during daylight( Reference Aveyard, Begh and Sheikh 40 , Reference Ghouri, Atcha and Sheikh 41 ). This temporary change may, to some extent, influence the birth weight of Ramadan-exposed babies. Furthermore, Ramadan is followed afterwards by several days of Eid celebration. During this celebration, people gather with family and friends and usually have meals with high fat and sugar contents. Eid celebration, which is less likely to be experienced by women who did not have Ramadan in their pregnancy, may enable the exposed pregnant women to compensate.

Our study showed that women who were exposed to Ramadan and did not fast had the highest weight gain during pregnancy (17·6 (se 1·6) kg), as compared with women who fasted (11·6 (se 0·9) kg) and Ramadan-unexposed women (12·2 (se 0·6) kg). This finding is consistent with several studies( Reference Ziaee, Kihanidoost and Younesian 16 , Reference Kiziltan, Karabudak and Tuncay 22 , Reference Khoshdel, Kheiri and Hashemi-Dehkordi 23 , Reference Awwad, Usta and Succar 42 ) which reported significantly lower weight gain in women who fasted during pregnancy as compared with women who did not. Furthermore, women who were exposed to Ramadan and did not fast might have had the highest fat or sugar intake, through the consumption of seasonal meals during and shortly after Ramadan.

In conclusion, in Indonesian Muslim women lifestyle changes that occur with Ramadan are associated with lower reported energy intake. Ramadan overlap during pregnancy was not significantly associated with offspring birth weight while we cannot conclude on the effect of fasting on birth weight due to limited statistical power. Further studies with larger sample size focusing on other pregnancy outcomes and the offspring's long-term health are needed.

Acknowledgements

The authors have indicated they have no financial relationships relevant in this article to disclose.

A. I. S. and C. S. P. M. U. formulated the research question and designed the study; A. I. S. acquired the data; A. I. S. and C. S. P. M. U. analysed and interpreted the data and drafted the manuscript; D. A., R. C. P., M. B., T. J. R. and D. E. G. critically reviewed the manuscript for important intellectual content. All authors read and approved the final manuscript.

The authors declared no potential conflicts of interest with respect to the authorship and/or publication of this article.

References

1. Abu-Saad, K & Fraser, D (2010) Maternal nutrition and birth outcomes. Epidemiol Rev 32, 525.CrossRefGoogle ScholarPubMed
2. Rush, D (2001) Maternal nutrition and perinatal survival. Nutr Rev 59, 315326.CrossRefGoogle ScholarPubMed
3. Wu, G, Imhoff-Kunsch, B & Girard, AW (2012) Biological mechanisms for nutritional regulation of maternal health and fetal development. Paediatr Perinat Epidemiol 26, Suppl. 1, 426.CrossRefGoogle ScholarPubMed
4. Barker, DJP (2007) The origins of the developmental origins theory. J Intern Med 261, 412417.CrossRefGoogle ScholarPubMed
5. Barker, DJP, Lampl, M, Roseboom, T, et al. (2012) Resource allocation in utero and health in later life. Placenta 33, Suppl. 2, e30e34.CrossRefGoogle ScholarPubMed
6. Gluckman, PD, Hanson, M & Beedle, A (2007) Early life events and their consequences for later disease: a life history and evolutionary perspective. Am J Hum Biol 19, 119.CrossRefGoogle ScholarPubMed
7. Jaddoe, VW (2008) Fetal nutritional origins of adult diseases: challenges for epidemiological research. Eur J Epidemiol 23, 767771.CrossRefGoogle ScholarPubMed
8. Roseboom, TJ, Painter, RC, van Abeelen, AFM, et al. (2011) Hungry in the womb: what are the consequences? Lessons from the Dutch famine. Maturitas 70, 141145.CrossRefGoogle ScholarPubMed
9. Bakhotmah, BA (2011) The puzzle of self-reported weight gain in a month of fasting (Ramadan) among a cohort of Saudi families in Jeddah, Western Saudi Arabia. Nutr J 10, 84.CrossRefGoogle Scholar
10. Alkandari, JR, Maughan, RJ, Karli, U, et al. (2012) The implications of Ramadan fasting for human health and well-being. J Sports Sci 30, Suppl. 1, S9S19.CrossRefGoogle ScholarPubMed
11. Trepanowski, JF & Bloomer, RJ (2010) The impact of religious fasting on human health. Nutr J 9, 57.CrossRefGoogle ScholarPubMed
12. Roky, R, Chapotot, F, Hakkou, F, et al. (2001) Sleep during Ramadan intermittent fasting. J Sleep Res 10, 319327.CrossRefGoogle ScholarPubMed
13. Alwasel, SH, Harrath, A, Aljarallah, JS, et al. (2013) Intergenerational effects of in utero exposure to Ramadan in Tunisia. Am J Hum Biol 25, 341343.CrossRefGoogle Scholar
14. Leiper, JB, Molla, A & Molla, A (2003) Effects on health of fluid restriction during fasting in Ramadan. Eur J Clin Nutr 57, Suppl. 2, S30S38.CrossRefGoogle ScholarPubMed
15. Almond, D & Mazumder, B (2011) Health capital and the prenatal environment: the effect of Ramadan observance during pregnancy. Am Econ J 3, 5685.Google Scholar
16. Ziaee, V, Kihanidoost, Z, Younesian, M, et al. (2010) The effect of Ramadan fasting on outcome of pregnancy. Iran J Pediatr 20, 181186.Google ScholarPubMed
17. Kavehmanesh, Z & Abolghasemi, H (2004) Maternal Ramadan fasting and neonatal health. J Perinatol 24, 748750.CrossRefGoogle ScholarPubMed
18. Arab, M & Nasrollahi, S (2001) Interrelation of Ramadan fasting and birthweight. Med J Islam Acad Sci 14, 9195.Google Scholar
19. Ewijk RJG, V, Painter, RC & Roseboom, TJ (2013) Associations of prenatal exposure to Ramadan with small stature and thinness in adulthood: results from a large Indonesian population-based study. Am J Epidemiol 177, 729736.CrossRefGoogle ScholarPubMed
20. Makki, AM (2002) Impact of Ramadan fasting on birth weight in 4 hospitals in Sana'a city, Yemen. Saudi Med 23, 14191420.Google ScholarPubMed
21. Robinson, T & Raisler, J (2005) “Each one is a doctor for herself”: Ramadan fasting among pregnant Muslim women in The United States. Ethn Dis 15, 99103.Google ScholarPubMed
22. Kiziltan, G, Karabudak, E, Tuncay, G, et al. (2005) Dietary intake and nutritional status of Turkish pregnant women during Ramadan. Saudi Med J 26, 17821787.Google ScholarPubMed
23. Khoshdel, A, Kheiri, S, Hashemi-Dehkordi, E, et al. (2014) The effect of Ramadan fasting on LH, FSH, oestrogen, progesterone and leptin in pregnant women. J Obstet Gynaecol 34, 634638.CrossRefGoogle ScholarPubMed
24. Mirghani, HM, Weerasinghe, DS, Ezimokhai, M, et al. (2003) The effect of maternal fasting on the fetal biophysical profile. Int J Gynecol Obstet 81, 1721.CrossRefGoogle ScholarPubMed
25. Dikensoy, E, Balat, O, Cebesoy, B, et al. (2009) The effect of Ramadan fasting on maternal serum lipids, cortisol levels and fetal development. Arch Gynecol Obstet 279, 119123.CrossRefGoogle ScholarPubMed
26. Hızlı, D, Yılmaz, SS, Onaran, Y, et al. (2012) Impact of maternal fasting during Ramadan on fetal Doppler parameters, maternal lipid levels and neonatal outcomes. J Matern Neonatal Med 25, 975977.CrossRefGoogle ScholarPubMed
27. Cross, H, Eminson, J & Wharton, BA (1990) Ramadan and birth weight at full term in Asian Moslem pregnant women in Birmingham. Arch Dis Child 65, 10531056.CrossRefGoogle ScholarPubMed
28. Naderi, T & Kamyabi, Z (2004) Determinationof fundal height increase in fasting and non-fasting pregnant women during Ramadan. Saudi Med J 25, 809815.Google Scholar
29. Ozturk, E, Balat, O, Ugur, MG, et al. (2011) Effect of Ramadan fasting on maternal oxidative stress during the second trimester: a preliminary study. J Obstet Gynaecol Res 37, 729733.CrossRefGoogle ScholarPubMed
30. Shahgheibi, S, Ghadery, E, Pauladi, A, et al. (2005) Effects of fasting during the third trimester of pregnancy on neonatal growth indices. Ann Alquds Med 2, 5862.Google Scholar
31. Faris, MA-IE & Al-Holy, MA (2014) Implications of Ramadan intermittent fasting on maternal and fetal health and nutritional status: a review. Med J Nutr Metab 7, 107118.Google Scholar
32. Savitri, AI, Yadegari, N, Bakker, J, et al. (2014) Ramadan fasting and newborn's birth weight in pregnant Muslim women in The Netherlands. Br J Nutr 112, 15031509.CrossRefGoogle ScholarPubMed
33. Almond, D & Mazumder, B (2008) Health Capital and the Prenatal Environment: The Effect of Maternal Fasting during Pregnancy. http://www.nber.org/papers/w14428 (accessed December 2017).CrossRefGoogle Scholar
34. Joosoph, J, Abu, J & Yu, SL (2004) A survey of fasting during pregnancy. Singapore Med J 45, 583586.Google ScholarPubMed
35. Petherick, ES, Tuffnell, D & Wright, J (2014) Experiences and outcomes of maternal Ramadan fasting during pregnancy: results from a sub-cohort of the Born in Bradford birth cohort study. BMC Pregnancy Childbirth 14, 335.CrossRefGoogle ScholarPubMed
36. Alwasel, SH, Abotalib, Z, Aljarallah, JS, et al. (2010) Changes in placental size during Ramadan. Placenta 31, 607610.CrossRefGoogle ScholarPubMed
37. Al-Hourani, H & Atoum, M (2007) Body composition, nutrient intake and physical activity patterns in young women during Ramadan. Singapore Med J 48, 906910.Google ScholarPubMed
38. Muhilal (2002) Peran Gizi Dalam Meningkatkan Kualitas Sumber Daya Manusia: Telaah Dari Aspek Biokimia Gizi Hingga Pedoman Gizi Seimbang. Pidato Pengukuhan Jabatan Guru Besar Dalam Ilmu Gizi (The Role of Nutrition in Improving the Quality of Human Resources: A Study of the Nutritional Biochemical Aspect to a Balanced Nutrition Guideline. Inaugural Speech of Professorship in Nutrition Science). Bandung: Padjadjaran University.Google Scholar
39. Muhilal, Jalal F & Hardiansyah, (1998) Angka kecukupan yang dianjurkan (RDA). In Prosiding Widyakarya Nasional Pangan Dan Gizi VI, Serpong, 17–20 Februari 1998 (Proceedings of National Symposium on Food and Nutrition VI, Serpong, 17–20 February 1998). Jakarta: Lembaga Ilmu Pengetahuan Indonesia.Google Scholar
40. Aveyard, P, Begh, R, Sheikh, , et al. (2011) Promoting smoking cessation through smoking reduction during Ramadan. Addiction 106, 13791380.CrossRefGoogle ScholarPubMed
41. Ghouri, N, Atcha, M & Sheikh, A (2006) Influence of Islam on smoking among Muslims. BMJ 332, 291294.CrossRefGoogle ScholarPubMed
42. Awwad, J, Usta, IM, Succar, J, et al. (2012) The effect of maternal fasting during Ramadan on preterm delivery: a prospective cohort study. BJOG 119, 13791386.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Overview of the study population.

Figure 1

Table 1. Baseline characteristics of women based on Ramadan exposure and their fasting status(Numbers of subjects and percentages; mean values with their standard errors; medians and interquartile ranges)

Figure 2

Table 2. Total and trimester-specific associations between Ramadan exposure during pregnancy and the birth weight of newborns†(Regression coefficients and 95 % confidence intervals)

Figure 3

Table 3. Total and trimester-specific associations between maternal fasting during pregnancy and the birth weight of newborns*(Regression coefficients and 95 % confidence intervals)

Figure 4

Fig. 2. Boxplot showing the relationship between tertiles of fasting days and birth weight. Tertile 1 (n 33), tertile 2 (n 40) and tertile 3 (n 35). The horizontal lines represent medians, the boxes interquartile ranges, the whiskers are minima and maxima and the circles are outliers.

Figure 5

Table 4. Maternal dietary intake on one Ramadan day based on fasting status*(Mean values with their standard errors; medians and interquartile ranges)

Figure 6

Table 5. Maternal dietary intake on one Ramadan day as compared with 1 month after Ramadan within fasting women*(Mean values with their standard errors; medians and interquartile ranges)

Figure 7

Table 6. Maternal dietary intake on one Ramadan day as compared with 1 month later in women who were not fasting*(Mean values with their standard errors; medians and interquartile ranges)