March 2007 Vol 7 Isuue 1 FINAL without suicide .indd ABSTRACT Objective: In view of the large number of pregnancies complicated by neural tube defect (NTD) in Khuzestan, south west Iran, this study assesses the prevalence of NTD and its ecological and social factors. Methods: This is a retrospective study, based on medical documents using an analytic assessment of NTDs in pregnant women attending the Jundi Shapur University hospitals in Ahvaz from 2 March 2002 to 20 March 2004. Results: The total number of pregnant women was 3,262 and 56 pregnancies were complicated with NTD. A large number of the infants with NTDs were female (70%) and the most common anomaly was anencephaly. The prevalence was 4.2 in ,000 births. The percentage in primigravida was 42.6% and in multigravida 57.4%. The main risk factor for NTD was age of the mother, those between 2 and 30 being the most affected. Consanguinity is the second risk factor with 3% of cou- ples who were close relatives. Other socio-demographic factors were also significant. Conclusion: This retrospective study confirms clinical observation that pregnancies complicated by NTD in Khuzestan are common. There are various ecological and social factors that correlate with the prevalence of NTD. Keywords: Neural tube defect, Social and ecological factors, retrospective study, Khuzestan, Iran, Prevalence and Correlates of Neural Tube Defect in South West Iran Retrospective analysis *Ahmad Behrooz, Mohammad H Gorjizadeh SULTAN QABOOS UNIVERSITY MEDICAL JOURNAL APRIL 2007 VOL 7, NO. 1 SULTAN QABOOS UNIVERSITY© NEURAL TUBE DEFECTS (NTDS) ARE AMONG the most common defect of human con-genital malformations, affecting 0.6 per 1,000 live births in the United States, where there are approximately 4,000 NTD complicated pregnancies annually.1 Spina bifida and anencephaly are the most commonly reported NTDs, which affect 4,000 preg- nancies resulting in 2,500 to 3,000 births in the Unit- ed States each year.2, 3 Although its etiology remains a mystery, remarkable advances have been made in the understanding and prevention of NTDs over the past few decades. Department of Obstetrics and Gynecology, Jondishapur University of Medical Sciences, 54 West 1st Street Kianpars, Ahvaz, Iran 6155815111 *To whom correspondence should be addressed. Email: ahmadbehrooz@yahoo.com C L I N I C A L & B A S I C R E S E A R C H إيران غرب جنوب في به املرتبطة والعوامل األنبوب العصبي عيوب انتشار استعادي حتليل جورجيزادة ومحمد بهروز أحمد (جنوب غرب ــتان خوزس في العالقة ذات والبيئية االجتماعية والعوامل ، أثناء احلمل العصبي ــوب األنبوب عي ــار انتش مدى الهدف: تقييم ــص: امللخ عند العصبي عيوب األنبوب وتقييم حتليل في الطبية على الوثائق اعتمدت ــتعادية اس ــة دراس الطريقة: هذه ــارها. انتش لكثرة بالنظر إيران)، وذلك للحوامل الكلي العدد النتائج: كان .2004 20 مارس 2002 إلى 21 مارس من للفترة األهواز في شابور جندي جامعة املراجعات ملستشفى احلوامل ــارا انتش األكثر احلالة وكانت ،(70%) احلاالت أكثرية الرضع البنات ــكل ش العصبي. األنبوب في عيوبا لديهم أطفاال ولدن 56 حامال منهن ،13262 عمر هو خطورة األكثر 42.6 % . كان العامل (البكر) األولى للمرة احلوامل ــبة نس كانت .1000 4.2 لكل ــار االنتش وكان الدماغ، ــخ) (مس انعدام هي العوامل أن كما %31 منهم. في ظهر حيث زواج األقارب، الثاني اخلطورة عامل كان بينما ــنة، 30 س 21 و بني تقع تأثرا األكثر األعمار كانت أالم، حيث في العصبي عيوب األنبوب انتشار كثرة املالحظات السريرية حول االستعادية الدراسة هذه أيضا. اخلالصة: أثبتت مهمة والدميوغرافية االجتماعية العيوب. تلك بانتشار عالقة لها التي والبيئية االجتماعية العوامل مختلف خوزستان، وهناك االجتماعية والدميغرافية العوامل الفوليك، حامض العصبي، األنبوب الكلمات: عيب مفتاح A H M A D B E H R O O Z A N D M O H A M M A D H G O R J I Z A D E H 32 A number of risk factors are associated with NTDs. A previous pregnancy with an NTD has the strongest association, with a relative risk of 10. There are strong ethnic and geographical associations with NTDs.4 The most commonly cited causes for NTDs in- clude a deficiency in folate concentrations.5, 6 Genetic susceptibility, environmental factors, in utero drug exposure, and/or abnormal metabolic pathways that lead to a failure of neural tube closure during fetal de- velopment has also been linked with NTDS.7, 8 In view of the large number of pregnancies compli- cated by NTDs in Khuzestan and because of the many risk factors, such as socioeconomic status, nutritional deficiency, ethnicity, consanguinity, multiparity, ge- ography and mutagens like chemical bombing in this region, this study aims to explore retrospectively the rate and associate factors for NTDs in this particular region of Iran. M E T H O D S The medical records of all pregnant women, includ- ing those with documented NTDs, who attended the Jundishapur University Hospitals, in Ahvaz, from 21 March 2002 till 20 March 2004, were reviewed. Data regarding NTD variations, the gender of af- fected fetuses, maternal age, parity, any family rela- tionship of the couple, previous affected pregnancies or wastage, and mother’s blood group and Rhesus factor (Rh) were looked for and recorded. Moreover, the results were also analytically assessed. Data were compared using Chi square test: ρ-values < 0.05 were considered statistically significant. All analyses were performed using the Statistical Package for Social Science /PC+ software (version 7). The study was ap- proved by the Internal Review Board of the Obstetrics & Gynecology Department at Jundishapur University of Medical Sciences. R E S U L T S Among 13,262 medical records of live births, 56 wom- en had fetuses or newborns with NTDs (4.2 per 1,000 births): anencephaly (n=30, 53.6%), spina bifida (n=15, 26.8%), meningocele (n=5, 8.9%), encephalocele (n=3, 5.4%), anencephaly plus meningo-myelocele (n=3, 5.4%). As for the gender factor, among 56 pregnancies af- fected with NTD, 39 (70%) were female and 17 (30%) were male. This difference is statistically significant (p<0.05). Among the 56 women whose pregnancies were affected by NTDs, 7 (12.5%) were 10-20 years old, 39 (69.7%) 21-30 years, while 10 (17.8%) were 31- 40 years old. As far as the parity factor was concerned, among the mothers whose pregnancies were affected by NTDs, 24 (42.8%) women were primiparous and 32 (57.1%) were multiparous. There was no significant dif- ference between the two groups (p=0.07). As for the family relationship of the couple, 31% of women with pregnancies affected by NTDs were relat- ed to their husbands. Fifty three (94.6%) of women had NTDs for the first time in pregnancy, whereas only 3 (5.4%) women had a history of NTDs in previous preg- nancies. Among 56 women with pregnancies affected by NTDs, 10 (17.8%) had a history of one previous abortion and 6 (10.7%) had had more than one abor- tion. In terms of blood group and Rh compatibility, the blood group B was the most represented and the blood group AB was the least in women with NTD affected pregnancies. Most of the women were Rh positive. A final correlate of NTDs that was explored in this study is climatic condition. The data suggest that there is a temporal relationship between the frequency of NTD and prevailing hot weather. The present study unequivocally suggests that NTD is highest during the two seasons of spring and autumn and thus among births in late winter and early spring. D I S C U S S I O N NTDs are thought to have multifactor etiology with environmental and genetic susceptibility, maternal age, nutritional intake, exposure to drugs and harm- ful material, geographic region and socioeconomic status.9 In this study, we reviewed medical records of all pregnant women with documented NTDs, who at- tended our university hospitals between 21 March 2002 and 20 March 2004. Among 13,262 women, 56 fetuses had NTDs (4.2 per 1000 birth). This incidence is markedly higher (2 to 4 fold) than the prevalence reported elsewhere. Worldwide, prevalence of NTDs ranges from 1.4-2 per 1,000 live births.8-10 It is important to speculate on factors contribut- ing to the high incidence of NTD in this population. It is possible that eight years of war (1980-1987) that af- fected this region may have led to the area being con- taminated with mutagen substances. This issue would require more systematic study. P R E VA L E N C E A N D C O R R E L AT E S O F N E U R A L TU B E D E F E C T I N S O U T H - WE S T O F I R A N 33 In our study, the defect with highest frequency was anencephaly with 22.6 per 10,000 births, followed by myelomeningocele (11.3 per 10,000 births), menin- gocele (3.8 per 10,000 births) and encephaloceles (2.3 per 10,000 births). The rate is significantly higher than previously published studies. For example, Hendricks11 in his study of a western population found a rate of anencephaly of 6.4 per per 10,000 births, spina bifida: 7.1 per 10,000 births, encephalocele: 1.1 per 10,000 births In 1999, Leach et al12 reported 2.6 per 1,000 births, the prevalence of anencephaly in Poland. A study from Rosch et al. in 1999 reported 1.64 per 1000 births, the incidence of neural tube defects in Magdeburg, Germany.13 The incidence of NTDs in Oman is 1.25 per 1,000 births, according to study of Rajab et al.14 There is some evidence to suggest that the fe- male gender may be associated with a higher risk for NTDs.15 Two-thirds of newborns affected with NTDs are female.16 In our study, 70% of new borns affected with NTDs were female. The effect of maternal age on risk of NTDs is gen- erally considered to be small. When an association can be found, risk tends to be elevated in older or very young mothers.17 In our study, most women with pregnancies affected by NTDs were 21 to 30 years old. Although women aged 21-30 had more pregnancies af- fected by NTDs, this seems to be due to a bias in our study, because the vast majority of the cases studied were in that age group. The effect of maternal parity on the risk of NTD is probably stronger than maternal age. Studies have shown both a modest risk in mothers of parity three or more and an increased risk in primiparous mothers.18 We found no difference in occurrence rate of NTDs between primiparous and multiparous mothers (p=0.02). Most cases are the first affected child in their fami- lies, although inheritance of this trait is influenced by familial predisposition, which is due to its threshold hereditary patterns.16 In our study, most of the mal- formed fetuses were the first affected individuals in their big families. In about 30% of cases, parents of the child affected by NTDs had first cousin relationships, so predisposition to these defects is increased. Indeed, there is no clear inheritance pattern in a single fam- ily and the presence of more affected cases in a family shows a higher susceptibility in that particular family. Women with a previous history of NTD birth have a 10 times increased risk for another NTD birth. How- ever, the majority (95%) of NTD pregnancies occur in women without a previous history of NTD births.19 Thus the prevention of the first occurrence is of real public health importance.20 The frequency of NTD is the highest during the two seasons of spring and autumn,15 so the defects are mostly seen in individuals born late in winter and early in the spring.6 In our study, the season in which NTDs prevalence is highest was spring. With respect to neural tube development in the first trimester, in our analysis most affected fetuses born occurred with mothers who became pregnant early in the summer. Obviously, the environmental temperature during summer in Khuzestan is 50 degrees centigrade, which could affect the prevalence of NTDs. As in the study made by Rajab and colleagues in the Royal Hospital of Oman in 1999, an environmental temperature of more than 48 degree centigrade was suggested to be risk factor in development of neural tube defects.14 This corroborates an animal study experiment, where pregnant mice, when exposed to high temperatures, had a high rate of NTDs.21 C O N C L U S I O N Because of the high incidence of NTDs and especially anencephaly in Khuzestan, it is recommended to in- stitute a nationwide educational programme and to establish public health guidelines for the prevention of neural tube defects. Over the last few decades, there has clearly been a substantial body of literature that supports the association of maternal use of multivita- mins containing folic acid in early pregnancy and a re- duced risk for offspring with neural tube defects. The rationale for the folate deficiency hypothesis is that prenatal supplementation with antioxidant vitamins containing folic acid decreases the incidence of birth defects, especially neural tube defects. Other prevent- ative measures ought to be systematically explored. A C K N OW L E D G ME N T We express our appreciation to Mrs. Raana Ghomi Maibodi for her assistance in data collection. R E F E R E N C E S 1. Nakano KK. Anencephaly: A review. Dev Med Child Neurol 1973; 15:383-400. 2. Mulinare J, Erickson D. Prevention of neural tube de- fects. Teratology 1997; 56:17-18. 3. Honein MA, Paulozzi LJ, Mathews TJ, Erickson JD, A H M A D B E H R O O Z A N D M O H A M M A D H G O R J I Z A D E H 34 Wong LY. Impact of folic acid fortification of the US food supply on the occurrence of neural tube defects. JAMA 2001; 285:2981-2986. 4. Harris JA, Shaw GM. Neural tube defects—why are rates high among population of Mexican descent? En- viron Health Perspect 1995; 103:163-164. 5. Maclone TG. 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McGraw-Hill, 2001. p. 956-960. 11. Hendricks KA. Neural tube defects along the Texas Mexico border; 1993-1995; Am J Epidemiology 1999; 149:1119-1127. 12. Lech M. Prevention using folic Acid, a good method for reduction of neural tube defects in Poland. Przegl-Lek 1999; 55:334-336. 13. Rosch C. Incidence of neural tube defects in the Magde- burg administrative district. Gesundheitswesen 1998; 60:563-566. 14. Rajab A. Neural tube defects and congenital hydroceph- alus in the Sultanate of Oman. J Trop Pediatr 1998; 44: 300-303. 15. Haslam RH. Prenatal Diagnosis. In: Singer SAM, ed. Human genetics. WH Freeman, 1985: 122-124. 16. Gilman S. Genetics disorders with multifactorial inher- itance. In: Thompson MH, McInnes R, Willard H, eds. Genetics in Medicine. Philadelphia: WB Saunders Co, 1991. p. 349-357. 17. Frey L, Allen Hauser W. Epidemiology of neural tube defects. Epilepsia 2003; 44(supp 3): 4-13. 18. Elwood JM, Little J, Elwood JH. Fetal Loss. In: Elwood JM, Little J, Elwood JH, eds. Epidemiology and control of neural tube defects. Vol 20 Monographs in Epide- miology and Biostatistics. Oxford: Oxford University Press, 1992. p. 324-334. 19. Geisel J. Folic acid and neural tube defects in pregnancy. J Perinat & Neonat Nurs 2003; 17:268-279. 20. Birnbacher R, Messerschmidt AM, Pollak AP. Diagnosis and prevention of neural tube defects. Curr Opin Urol 2002; 12:461-464. 21. Shin JH, Shiota K. Folic acid supplementation of preg- nant mice suppresses heat-induced neural tube defects in the offspring. J Nutr 1999; 129:2070-2073.