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Revista de Saúde Pública

Print version ISSN 0034-8910

Rev. Saúde Pública vol.44 no.6 São Paulo Dec. 2010  Epub Oct 15, 2010

http://dx.doi.org/10.1590/S0034-89102010005000044 

ORIGINAL ARTICLES

 

Symphysis-fundal height curve in the diagnosis of fetal growth deviations

 

Curva de altura uterina por idade gestacional e diagnóstico de desvios do crescimento fetal

 

Curva de altura uterina por edad de gestación y diagnóstico de desvíos del crecimiento fetal

 

 

Djacyr Magna Cabral FreireI, II; Jose Guilherme CecattiI; Cláudio Sergio Medeiros PaivaII

IDepartamento de Tocoginecologia. Faculdade de Ciências Médicas. Universidade Estadual de Campinas. Campinas, SP, Brasil
IIUniversidade Federal da Paraíba. João Pessoa, PB, Brasil

Correspondence

 

 


ABSTRACT

OBJECTIVE: To validate a new symphysis-fundal curve for screening fetal growth deviations and to compare its performance with the standard curve adopted by the Brazilian Ministry of Health.
METHODS: Observational study including a total of 753 low-risk pregnant women with gestational age above 27 weeks between March to October 2006 in the city of João Pessoa, Northeastern Brazil. Symphisys-fundal was measured using a standard technique recommended by the Brazilian Ministry of Health. Estimated fetal weight assessed through ultrasound using the Brazilian fetal weight chart for gestational age was the gold standard. A subsample of 122 women with neonatal weight measurements was taken up to seven days after estimated fetal weight measurements and symphisys-fundal classification was compared with Lubchenco growth reference curve as gold standard. Sensitivity, specificity, positive and negative predictive values were calculated. The McNemar
χ2 test was used for comparing sensitivity of both symphisys-fundal curves studied.
RESULTS: The sensitivity of the new curve for detecting small for gestational age fetuses was 51.6% while that of the Brazilian Ministry of Health reference curve was significantly lower (12.5%). In the subsample using neonatal weight as gold standard, the sensitivity of the new reference curve was 85.7% while that of the Brazilian Ministry of Health was 42.9% for detecting small for gestational age.
CONCLUSIONS: The diagnostic performance of the new curve for detecting small for gestational age fetuses was significantly higher than that of the Brazilian Ministry of Health reference curve.

Descriptors: Embryonic and Fetal Development. Uterus, growth & development. Gestational Age. Ultrasonography, Prenatal. Prenatal Diagnosis. Validation Studie.


RESUMO

OBJETIVO: Validar curva de referência de altura uterina por idade gestacional para o rastreamento de desvios do crescimento fetal e comparar sua performance com a curva-padrão adotada pelo Ministério da Saúde do Brasil.
MÉTODOS: Estudo observacional que envolveu 753 gestantes de baixo risco de João Pessoa, PB, entre março e outubro de 2006, com idade gestacional acima de 27 semanas. A altura uterina foi medida de acordo com técnica preconizada pelo Ministério da Saúde. O padrão-ouro foi o peso fetal, estimado pelo ultrassom com base na curva de referência brasileira por idade gestacional. Uma subamostra de 122 casos com pesos neonatais obtidos até sete dias depois da estimativa do peso fetal, a classificação da altura uterina foi comparada com a curva de Lubchenco como padrão-ouro. A sensibilidade, a especificidade e os valores preditivos positivo e negativo foram calculados. Para comparar o desempenho da sensibilidade entre ambas as curvas de altura uterina, utilizou-se o teste
χ2 de McNemar.
RESULTADOS: A sensibilidade da nova curva para a detecção de fetos pequenos para a idade gestacional foi de 51,6%, enquanto a da curva do padrão-ouro foi significativamente menor (12,5%). Na subamostra que teve o peso neonatal como padrão-ouro, a sensibilidade da nova curva de referência foi de 85,7%, enquanto a do Ministério da Saúde exibiu 42,9% de sensibilidade para a detecção de fetos pequenos para a idade gestacional.
CONCLUSÕES: A capacidade diagnóstica da nova curva de referência para detectar fetos pequenos para a idade gestacional foi significativamente melhor do que a da curva recomendada pelo Ministério da Saúde.

Descritores: Desenvolvimento Embrionário e Fetal. Útero, crescimento & desenvolvimento. Idade Gestacional. Ultrassonografia Pré-Natal. Diagnóstico Pré-Natal. Estudos de Validação.


RESUMEN

OBJETIVO: Validar la curva de referencia de altura uterina por edad de gestación para el rastreo de desvíos del crecimiento fetal y comparar su performance con la curva estándar adoptada por el Ministerio de la Salud de Brasil.
MÉTODOS: Estudio observacional que envolvió 753 gestantes de bajo riesgo de Joao Pessoa, Noreste de Brasil, entre marzo y octubre de 2006, con edad de gestación por encima de 27 semanas. La altura uterina fue medida de acuerdo con técnica recomendada por el Ministerio de la Salud. El patrón-oro fue el peso fetal, estimado por el ultrasonido con base en la curva de referencia brasilera por edad de gestación. Una sub-muestra de 122 casos con pesos neonatales obtenidos hasta siete días después de la estimación del peso fetal, la clasificación de la altura uterina fue comparada con la curva de Lubchenco como estándar-oro. La sensibilidad, la especificidad y los valores predictivos positivo y negativo fueron calculados. Para comparar el desempeño de la sensibilidad entre ambas curvas de altura uterina, se utilizó la prueba chi-cuadrado de McNemar.
RESULTADOS: La sensibilidad de la nueva curva para la detección de fetos pequeños para la edad de gestación fue de 51,6%, mientras que la curva del patrón-oro fue significativamente menor (12,5%). En la sub-muestra que tuvo el peso neonatal como estándar-oro, la sensibilidad de la nueva curva de referencia fue de 87,7%, mientras que la del Ministerio de la Salud exhibió 42,9% de sensibilidad para la detección de fetos pequeños para la edad de gestación.
CONCLUSIONES: La capacidad diagnóstica de la nueva curva de referencia para detectar fetos pequeños para la edad de gestación fue significativamente mejor que la curva recomendada por el Ministerio de la Salud.

Descriptores: Desarrollo Embrionario y Fetal. Útero, crecimiento & desarrollo. Edad Gestacional. Ultrasonografía Prenatal. Diagnóstico Prenatal. Estudios de Validación.


 

 

INTRODUCTION

Serial measurement of symphysis-fundal height (SFH) during pregnancy is a major clinical tool to evaluate fetal growth as well as to identify other pregnancy complications.ª It is an easy-to-use low-cost tool, although it has not been widely confirmed as a reliable measurement in the prenatal care routine. Belizan et al4 showed these serial measurements greatly improve the predictive capacity of detecting fetal growth abnormalities. The Brazilian Ministry of Health (BMoH) recommends the use of a standard SFH curve developed by Fescina et al.9 Normal uterine growth is within the 10th and the 90th percentiles.b However, studies have reported different SFH patterns for Brazilian populations,10,18,21 and these differences could be explained not only by specific characteristics of ethnic groups but also by other factors such as different measurement techniques, risk level, socioeconomic and nutritional conditions, gestational age estimates and number of examiners.

The relationship between SFH and gestational age can provide clinical indications of fetal growth deviations. However, studies have found inconsistent performance results.4,9,11,19,21 Despite the lack of a single reliable method to identify fetal growth deviations, combined clinical and ultrasound methods improve diagnosis.5,6,15,18 As for the diagnosis of fetal growth restriction, newborn's weight is only a final measurement which does not allow any kind of intervention to manage fetal weight gain.5,6 On the other hand, fetal weight estimates using ultrasound provides data that enable to diagnose conditions that may be impairing fetal growth.5,6 However, the SFH curve is a non-invasive, easy-to-use, low-cost tool that may be used to support important clinical decisions for either diagnostic or therapeutic interventions in developing countries where access to sophisticated technological resources for the assessment of fetal growth is not always available. Although SFH curves are usually used to screen fetal growth restriction, there are concerns about their performance.

Freire et al10 have demonstrated that the UH growth curve developed with low risk pregnant women from Joao Pessoa (Northeastern Brazil), differs significantly from that adopted by the BMoH9 as the standard for the Brazilian population.

Differences between both curves, the one from Freire et al10 and that from Fescina et al9 used by the BMoH, raise the hypothesis that they perform differently when identifying normal fetal growth and any deviations. Therefore, since one of the main applications of SFH measurements in prenatal care is for screening fetal growth deviations,ª the standard curve may not be effective enough for this purpose, over or under diagnosing those conditions because it is based in a sample of women with a pattern of fetal growth different from that of the Brazilian population. The objective of the present study was to validate the SFH growth curve as a standard method for the screening of fetal growth deviations and to compare its performance with the pattern curve adopted by the Brazilian Ministry of Health.

 

METHODS

The validation of a SFH reference curve for gestational age was based on a curve developed by Freire et al.10 The present study was carried out in a university hospital and a public maternity hospital in the city of João Pessoa, Northeastern Brazil, from March to October 2006. These hospitals were selected as they are reference centers of prenatal care in the public health service and they have higher demand of pregnant women. Eligibility of pregnant women was assessed in the ultrasound department of these hospitals. The sample size was calculated based on an estimated prevalence of 12% intra-uterine growth restriction in this population.ª An 80% sensitivity for SFH measurements was assumed for detection of actual fetal growth restriction in the sample, with a sampling error of 9.2% and type I error of 0.05. The estimated sample size was 750 pregnant women. A sample of 753 pregnant women was selected according to free demand for each prenatal service.

The inclusion criteria included gestational age above 26 weeks, with a known last menstrual period or confirmed by ultrasound during the first half of pregnancy. Women who were pregnant with twins, fetal death or any fetal malformations that prevented the assessment of fetal weight and the amniotic fluid index by ultrasound were excluded. The following variables were studied: SFH, gestational age, ultrasound-derived estimated fetal weight (EFW), and fetal growth deviation (categorized by gestational age in small - lower than the 10th percentile; large - higher than the 90th percentile; and adequate - between the 10th and the 90th percentiles). Data was also collected for the following control variables: age; body mass index (BMI, classified by reference values for each gestational age according to Atalah et al1 as recommended by the BMoH); ethnic group/skin color; number of pregnancies; parity; previous caesarean sections; previous abortions and smoking habits.

SFH was measured with a flexible inelastic measuring tape from the pubic symphysis to the uterine fundus after correction of uterine dextrorotation, following the standard technique as recommended by the BMoH.10,ª Fetal weight was estimated by ultrasound using Hadlock et al formula13 as described elsewhere.5 The gold standard for classifying EFW was adapted from the curve developed by Cecatti et al5 with normal EFW percentiles established by ultrasound according to gestational age in a Brazilian population using third degree polynomial adjustments. We opted for this method due to high linear correlation previously found between EFW and neonatal weight.6

SFH measurements were taken in pregnant women attending prenatal care visits for routine ultrasound examination. Data was recorded in standard forms by the examiner. Ultrasound scans were performed with GE® Voluson 730 PRO and GE® Logic 500 equipment, both with multifrequency (2.5-5.0 MHz) convex probes.

For statistical analysis, SFH and EFW values for each pregnant woman in the study were plotted on their related charts as a function of gestational age and were compared to related standards. To validate Freire et al SFH growth curve,10 sensitivity, specificity, positive and negative predictive values were calculated for screening fetal growth deviation. The gold standard for diagnosing SGA and large for gestational age (LGA) fetuses was the classification of fetal weight using ultrasound-derived EFW reference curve developed by Cecatti et al.5 The same procedure was then performed with the BMoH SFH curve. For the comparison of sensitivity, the McNemar's χ2 test was used for non-independent samples with Yates' correction.

In a subsample of 122 women SFH measurements were taken up to seven days before delivery. Additionally, SFH classification was compared with neonatal weight classification based on Lubchenco et al's curve17 as the gold standard. SFH sensitivity for the diagnosis of fetal growth deviations was also compared with that of the BMoH standard SFH curve. A level of significance of 5% was set. For statistic analysis EpiInfo 2000 and Excel™ software were used.

The study protocol was approved by the Institutional Review Board of the Centro de Ciências da Saúde da Universidade Federal da Paraíba (3/23/2005) and the Instituto e Maternidade Cândida Vargas (3/11/2005).

 

RESULTS

The age of the 753 women studied ranged between 13 and 45 years old, with mean age of 26.5. The predominant ethnic group/skin color was white (46.6%); BMI ranged between 18.9 kg/m2 and 37.8 kg/m2 with mean BMI of 27 kg/m2. Most of them did not smoke (97.6%). Table 1 shows that 47.5% were primigravida, 50% had never had a delivery and 17.2% had previous cesarean sections. Gestational age ranged between 29 and 41 weeks, and most were over 32 weeks of pregnancy.

 

 

Figure 1 shows the distribution of SFH measurements against the 10th percentile and the 90th percentile in Freire et al SFH curve.10 The majority of cases were considered adequate (64.3%) and 10.5% were SGA. Compared to Cecatti et al curve,5 the proportion of adequate growth increased (70.1%) while the proportion of SGA (8.5%) and LGA (21.4%) decreased.

The sensitivity of SFH curve for the diagnosis of SGA and LGA, using the ultrasound-derived EFW curve as gold standard, is outlined in Table 2. Table 3 shows the sensitivity of SFH curve for the diagnosis of SGA and LGA using the neonatal weight curve as gold standard. The sensitivity of Freire et al11 curve for detecting SGA was 51.6% while that of the BMoH curve was only 12.5%, a statistically significant difference. When using actual neonatal weight, the sensitivity of the SFH curve was also higher for detecting SGA (85.7%) than that of the BMoH curve (42.9%).

 

DISCUSSION

This study validated the SFH curve developed by Freire et al10 and compared its performance with that of the BMoH curveª in a population of pregnant women under conditions similar to those seen in public health facilities in Brazil. This sample characteristic may be attributed to BMI distribution in the population as a significant association between BMI and SFH measurement was seen (data not shown). Almost half of pregnant women with fetal growth lying above the 90th percentile was classified as overweight or obese,ª higher proportion than those below the 90th percentile in the SFH curve (23.1%) (p<0.0001; data not shown). The BMI in the sample seems to reflect the behavior of ultrasound-derived EFW, which showed 8.5% of SGA and 21.4% of LGA. BMI was also significantly associated with EFW (p<0.001; data not shown) as the proportion of overweight or obese pregnant women was significantly higher in the LGA (41.0%) than in the non-LGA group (25.7%). This may explain the high prevalence of LGA in the sample, as well as reflect the so-called "obesity epidemics" as currently described in Western societies.

In general, studies on fetal growth curves among Brazilian women19 use Hadlock et al curve13 as a reference. However, a fetal growth curve created from a specific Brazilian population would be more appropriate, so the present study used the EFW curve, which was developed based on a sample of Brazilian women5,6 to assess SFH for diagnosing SGA and LGA. There is a wide variation in the performance of SFH measurements as a method for screening fetal growth deviation, especially when detecting SGA fetuses. It seems that the variation in the diagnostic performance between SFH reference curves is influenced not only by sociodemographic characteristics, but also by different methods used in the studies, the standardization of the technique used to measure SFH, the population under study (high- and low-risk pregnant women), and criteria used to define fetal growth restriction.

Belizan et al4 first reported 86% sensitivity and 90% specificity with 10% false positives, and concluded that SFH measurements can be used in the prenatal care to screen for fetal growth restrictions. Ghate et al12 assessed the performance of the SFH curve in predicting low-weight newborns and they found 87.5% sensitivity, 90% specificity and a positive predictive value of 77.8%. In the present study, the sensitivity of 51.6% of SFH in detecting SGA using EFW as gold standard is adequate to recommend its use for screening fetal growth deviation during prenatal care. The sensitivity of 85.7% of the SFH in detecting SGA in newborns of this study supports this recommendation as it shows a higher performance than that of the BMoH standard curve. Villar & Belizan23 and Engstrom & Sittler8 studies also indicated that SFH is an important and helpful measurement in the clinical diagnosis, not only in the screening of fetal growth deviation, but also to identify complications during pregnancy and errors in estimating gestational age. The charts may help identify low weight fetuses and allow appropriate interventions during prenatal care.

Fescina et al9 reported 50% sensitivity and 93% specificity and concluded that SFH measurement is an excellent method to identify fetuses with adequate weight for gestational age. This curve was accepted as a reference standard for Latin America and the Caribbean in 1984, and later by the BMoH.ª Since high sensitivity is a key characteristic of a good screening method, the use of this curve currently recommended by the BMoH in Brazil may be, at least, questionable. Even though a sensitivity of 51.6% is lower than that desired for an excellent screening method, Freire et al's curve10 has performed better than the BMoH curve in the clinical practice context. Other Brazilian studies also showed better performance of other curves19,21 in comparison to that of the BMoH curve, supporting the recommendation to validate curves directly derived from Brazilian populations. Maybe these curves would be more appropriate in Brazil, improving the probability of screening fetal growth deviations when used as a diagnostic resource in prenatal care. Ideally, all measurements of these different studies could be pooled in a common Brazilian reference SFH curve.

 

Figure 2

 

According to Freire et al,10 the SFH growth curve of pregnant women from public hospitals in the city of João Pessoa significantly differs from the standard curve recommended by the BMoH.9 Some other studies have investigated curves developed from a Brazilian population of pregnant women, however these curves differ methodologically from the present curve, especially in the SFH measurement technique and variation between examiners.18

Although Neilson20 claimed there is a lack of evidence indicating any real benefit of using SFH measurement in prenatal care, many countries have prenatal care protocols recommending its use along with reference curves designed for the population of interest.b Despite technological improvements, the real benefit of obstetric ultrasound, when used in the clinical routine as a screening method for fetal growth restriction in low-risk populations, is not yet supported by strong scientific evidence.2,14 Considering that even in developed countries it is estimated that approximately 50% of SGA fetuses are only identified at birth or death, and that this number is likely to be higher in developing countries, it is reasonable to accept the use of a low-cost method like the SFH measurement, even without excellent sensitivity. In a recent study Lindqvist & Molin16 showed that SGA fetuses that were not diagnosed during prenatal care have a four times greater risk of developing unfavorable outcomes than those diagnosed during prenatal care. This data emphasizes the need for assessing feasible screening methods that are appropriate to the reality of mother-infant health care.

One of the limitations of the present study is that we could not correlate neonatal outcome in the entire sample as only 122 cases (16.2%) had neonatal weight determined up to seven days after SFH and EFW measurements. However, a high linear correlation between EFW and neonatal weight (r = 0.94) was found in this subsample, which was considered to be more than enough to ascertain a strong association.11 Therefore, this finding supported the classification of EFW as the gold standard to diagnose fetal growth deviation in this study. Another limitation is regarding its cross-sectional design. As each pregnant woman had her SFH measurement assessed only once, it was not possible to evaluate the individual standard of SFH growth. Hypothetically, some undetected cases of SGA (false negatives) could have a reduction of SFH between two consecutive measurements. This hypothesis is consistent with new conceptual aspects of fetal growth restriction, which consider detecting a reduction in fetal weight a more important diagnostic criterion than the use of predetermined percentiles in fetal weight curves.3,7,22

Based on these results, important questions are posed in the area of public health. For instance, what would be the economic and perinatal impact of using a new and better SFH curve in the Brazilian population? A nationwide cohort study on maternal weight gain and fetal growth patterns would be the desirable for better understanding this relationship.

 

REFERENCES

1. Atalah E, Castillo C, Castro R, Aldea A. Propuesta de un nuevo estándar de evaluación nutricional en embarazadas. Rev Med Chil. 1997;125(12):1429-36.         [ Links ]

2. Bais JM, Eskes M, Pel M, Bonsel GJ, Bleker OP. Effectiveness of detection of intrauterine growth retardation by abdominal palpation as screening test in a low risk population: an observational study. Eur J Obstet Gynecol Reprod Biol. 2004;116(2):164-9. DOI:10.1016/j.ejogrb.2004.01.037        [ Links ]

3. Baschat AA, Hecher K. Fetal growth restriction due to placental disease. Semin Perinatol. 2004;28(1):67-80. DOI:10.1053/j.semperi.2003.10.014        [ Links ]

4. Belizán JM, Villar J, Nardin JC, Malamud J, De Vicurna LS. Diagnosis of intrauterine growth retardation by a simple clinical method: measurement of uterine height. Am J Obstet Gynecol. 1978;131(6):643-6.         [ Links ]

5. Cecatti JG, Machado MRM, Santos FFA, Marussi EF. Curva dos valores normais de peso fetal estimado por ultra-sonografia segundo a idade gestacional. Cad Saude Publica. 2000;16(4):1083-90. DOI:10.1590/S0102-311X2000000400026        [ Links ]

6. Cecatti JG, Machado MRM, Krupa FG, Figueiredo PG, Pires HMB. Validação da curva normal de peso fetal estimado pela ultra-sonografia para o diagnóstico do peso neonatal. Rev Bras Ginecol Obstet. 2003;25(1):35-40. DOI:10.1590/S0100-72032003000100006        [ Links ]

7. Cetin I, Foidart JM, Miozzo M, Raun T, Jansson T, Tsatsaris V, et al. Fetal growth restriction: a workshop report. Placenta. 2004;25(8-9):753-7. DOI:10.1016/j.placenta.2004.02.004        [ Links ]

8. Engstron JL, Sittler CP. Fundal height measurement. Part 5:The effect of clinician bias on fundal height measurement. J Nurse Midwif. 1994;39(3):130-41. DOI:10.1016/0091-2182(94)90095-7        [ Links ]

9. Fescina RH, Quevedo C, Martell M, Nieto F, Schwarcz R. Altura uterina como método para predecir el crecimiento fetal. Bol Oficina Sanit Panam. 1984;96(5):377-86.         [ Links ]

10. Freire DMC, Paiva CSM, Coelho EAC, Cecatti JG. Curva da altura uterina por idade gestacional em gestantes de baixo risco. Rev Bras Ginecol Obstet. 2006;28(1):3-9. DOI:10.1590/S0100-72032006000100002        [ Links ]

11. Freire DMC, Cecatti JG, Paiva CSM. Correlação entre peso fetal estimado por ultrassonografia e peso neonatal. Rev Brasil Ginecol Obstet. 2010;32(1):4-10. DOI:10.1590/S0100-72032010000100002        [ Links ]

12. Ghate M, Pratinidhi A, Gupte A. Risk prediction charts for low birth weight. Indian Pediatr. 1996;33(1):15-8.         [ Links ]

13. Hadlock FP, Harrist RB, Martinez-Poyer J. In utero analysis of fetal growth: a sonographic weight standard. Radiology. 1991;181(1):129-33.         [ Links ]

14. Jahn A, Razum O, Berle P. Routine screening for intrauterine growth retardation in Germany: Low sensitivity and questionable benefit for diagnosed cases. Acta Obstet Gynecol Scand. 1998;77(6):643-8. DOI:10.1034/j.1600-0412.1998.770611.x        [ Links ]

15. Kayem G, Grangé G, Bréart G, Goffinet F. Comparison of fundal height measurement and sonographically measured fetal abdominal circumference in the prediction of high and low birth weight at term. Ultrasound Obstet Gynecol. 2009; 34(5):566-71. DOI:10.1002/uog.6378        [ Links ]

16. Lindqvist PG, Molin J. Does antenatal identification of small-for-gestational age fetuses significantly improve their outcome? Ultrasound Obstet Gynecol. 2005;25(3):258-64. DOI:10.1002/uog.1806        [ Links ]

17. Lubchenco LO, Hansman C, Byd E, Dressler M. Intrauterine growth as estimated from liveborn birth weight data at 24 to 42 weeks of gestation. Pediatrics. 1963;32:793-800.         [ Links ]

18. Martinelli S, Bittar RE, Zugaib M. Proposta de nova curva de altura uterina para gestações entre a 20ª e a 42ª semana.. Rev Bras Ginecol Obstet. 2001;23(4):235-41. DOI:10.1590/S0100-72032001000400006        [ Links ]

19. Martinelli S, Bittar RE, Zugaib M. Predição da restrição do crescimento fetal pela medida da altura uterina. Rev Bras Ginecol Obstet. 2004;26(5):383-9. DOI: 10.1590/S0100-72032004000500007        [ Links ]

20. Neilson JP. Symphysis-fundal height measurement in pregnancy. Cochrane Database Syst Rev. 2000;(2):CD000944        [ Links ]

21. Oppermann MLR, Duncan BB, Mengue SS, Ramos JGL, Serruya SJ, Schmidt MI. Distribuição da altura uterina ao longo da gestação em uma coorte brasileira: comparação com a curva de referência do Centro Latino-Americano de Perinatologia. Rev Bras Ginecol Obstet. 2006;28(9):513-22. DOI:10.1590/S0100-72032006000900003        [ Links ]

22. Owen P, Farrell T, Hardwick JC, Khan KS. Relationship between customised birth weight centiles and neonatal anthropometric features of growth restriction. BJOG. 2002;109(6):658-62.         [ Links ]

23. Villar J, Belizan JM. The evolution of the methods used in the diagnosis of intrauterine growth retardation. Obstet Gynecol Survey. 1986;41(4):187-99. DOI:10.1097/00006254-198604000-00001        [ Links ]

 

 

Correspondence:
Jose Guilherme Cecatti
Unicamp
R. Alexander Fleming, 101
Cidade Universitária
13083-881 Campinas, SP, Brasil
E-mail: cecatti@unicamp.br

Received: 9/30/2009
Approved: 4/15/2010

 

 

The authors declare that there are no confl icts of interest.
a Ministério da Saúde. Pré-natal e puerpério: atenção qualificada e humanizada: manual Técnico. 2.ed. Brasília, DF; 2006.
b National Collaborating Center for Women's and Children's Health. Antenatal care: routine care for the healthy pregnant woman. Clinical Guideline. 2.ed. London: RCOG Press; 2009 [cited 2009 Sep 9]. Available from: http://www.nice.org.uk/nicemedia/pdf/CG62FullGuidelineCorrected June2008July2009.pdf

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