To Determine the Effects of Labor Induction on Maternal and Fetal Outcome in Postterm Pregnancies (41 Weeks Plus) ()
1. Introduction
There is an increased risk of fetal and neonatal morbidity and mortality in postterm pregnancies [1] as well as an increased maternal morbidity [2] . Stillbirths occurring at and beyond term (37 - 42 weeks gestation) are a major public health problem contributing more to perinatal mortality than either deaths from complications of prematurity or the sudden infant death syndrome [3] . Induction of labour at term is used to prevent this high fetal mortality from postterm pregnancies; however, both clinicians and patients alike are concerned about the its risks, which include uterine hyper-stimulation, failed induction and increased Caesarean section rates. Postterm pregnancies are also associated with increased costs which arise from antenatal monitoring of the foetus and the cost of inducing labour [4] , in addition to being a source of significant anxiety for the pregnant woman [5] . Optimization of these conflicting pressures still poses a clinical challenge.
A normal term pregnancy is between 37 and 42 weeks of gestation with a progressive increase in the perinatal morbidity and mortality rates during this period. In clinical practice, it is important, yet very difficult to define an “ideal” time when the benefits of a medical intervention (induction of labor) outweigh the benefits of the natural evolution of pregnancy. Both preterm (defined as delivery before 37 completed weeks of gestation) and postterm (delivery at or beyond 41 week of gestation) births are associated with increased neonatal morbidity and mortality. Postterm pregnancy constantly remains a difficult and controversial problem in modern obstetrics. Postterm pregnancy, by definition, refers to a pregnancy that has extended to or beyond 41 weeks of gestation (294 days, or estimated date of delivery (EDD) + 14 days), and it complicates 10% of all gestations [6] [7] . Accurate dating of the pregnancy is critical to the diagnosis [6] . The most frequent cause of an apparently postterm pregnancy is an error in dating. When postterm pregnancy truly exists, the cause is usually unknown [6] . Postterm antenatal fetal surveillance traditionally begins at 42 completed weeks of gestation; however, recent data have shown that a significant percentage of cases of perinatal asphyxia occur between 40 and 42 weeks of gestation. Some studies [8] [9] mentioned that the pregnancy risks start increasing from gestational week 41. In this paper, we have reviewed the literature data about the diagnosis of postterm pregnancy, prenatal indicators, and maternal fetal outcomes of prolonged pregnancy, and the timing to start the antepartum fetal tests.
The aim of the study was to determine the effects of labor induction on maternal and fetal outcome in postterm pregnancies (41 weeks plus) of patients attending the obstetrics department of Aljamhoria Hospital, Benghazi and to evaluate the outcome of mother and fetus.
2. Subjects and Methods
2.1. Subjects
A total of 150 women who reached 41 weeks + gestation between June 1, 2012 and Dec 31, 2012 at the Department of Obstetrics & Gynecology, Faculty of Medicine, Benghazi university and who were scheduled for induction of labor after a normal CTG and USS and a favourable Bishop’s score were included in this prospective observational study.
Caesarean delivery rates were calculated for those who underwent induction.
2.2. Exclusion Criteria
Women with any medical or obstetric risk factors were excluded, e.g. previous CS, women aged more than 35 years, multipara (>4 delivery), multiple pregnancy, any medical disease (hypertension or diabetes) and unreactive CTG or biophysical profile (BPP).
3. Methods
Women assigned to both arms of the study had the same baseline assessment: an ultrasound scan (with emphasis on estimated fetal weight and amniotic fluid volume), a cardiotocogram, and a clinical vaginal examination. For women assigned to continued antenatal assessment, induction of labor was arranged if the cardiotocogram recordings were abnormal, the estimated fetal weight was less than 2 standard deviations, or oligohydramnios (amniotic fluid index less than 5 cm or single deepest pocket less than 2 cm) was found. If these investigations are normal, they were reassessed every third day until spontaneous delivery occurred, or until labor was induced on day 300.
Women who had a favorable cervix (Bishop score of 6 or more) were induced by amniotomy followed by oxytocin Syntocinon, infusion. Women with an unfavorable cervix (Bishop score less than 6) had cervical priming using misoprostol (prostaglandin E1 50 mcg pessary encased in a gelatin capsule) at 6-hour intervals in the posterior fornix. A maximum of four doses were given in a 24-hour period, and cervical priming was continued for a maximum of 2 days. Once the cervix was favorable, amniotomy and oxytocin infusion were used. Women with a uterine scar were induced with 0.5 mg dinoprostone (prostaglandin E2, Minprostin endocervical gel) given intracervically every 12 hours.
Women being induced, or being assessed on admission in labor, had a cardiotocogram. If this was abnormal, or if meconium was seen after rupture of membranes, then a continuous electronic fetal monitoring was recommended. Antenatal, intrapartum, and postnatal data were collected on a single chart that accompanied the patient through this period and was completed by the staff contemporaneously. The charts were designed to allow automatic optical recognition and transmission to a computer database based in the University Clinical Trials Office. The process of data transmission was checked for error by two of the authors (R.H. and E.S.).
3.1. The Outcome of the Neonate Was Recorded
Meconium aspiration, Birth asphyxia, neonatal (NN) death, Still birth.
Neonatal morbidity was primarily defined by assessing a series of relevant outcomes. Information about the presence of meconium, birth weight, crown- heel length, Apgar scores, umbilical cord pH, and base excess and the need for resuscitation were recorded immediately after delivery. Supplementary medical information was obtained from the routine pediatric examination on the first or second day, and if admitted, from the neonatal intensive care unit (NICU).
Neonatal morbidity was scored by evaluating the degree of deviation from the potential of a perfect outcome for each newborn. We defined a perfect outcome as being an infant with a birth weight of 3.8 kg and a Ponderal Index of 2.88 (a measure of weight relative to length obtained from 180 healthy newborns with gestational age 287 days or more acting as controls in a study of preeclampsia). Other optimal features for outcome were considered to be 1- and 5-minute Apgar scores of 10, umbilical cord pH of 7.40 with base excess equal to 0 (zero), and no medical complications or need for treatment. To compare the study groups, we assigned a priori weights to the outcome variables based on clinical judgment and consensus among the researchers. The sum in each neonate constitutes a Neonatal Morbidity score, which increases with increasing morbidity. One Neonatal Morbidity unit corresponds to, for example, the presence of meconium, a one-point decrease in the 5-minute Apgar score, or a pH decrease of 0.1. We further calculated the Canadian Multicenter postterm Pregnancy neonatal morbidity index developed by Hannah et al. [9] , in which morbidity was defined when the upper 2 percentile was exceeded.
Severe perineal lacerations were defined as third and fourth-degree perineal lacerations during delivery. Maternal hemorrhage was defined as blood loss more than 500 ml at delivery. Uterine contraction abnormalities were defined as prolonged first stage of labor (less than 1 cm cervical dilatation per 1.5 hours), prolonged active second stage of labor (longer than 1 hour) and short active second stage of labor (less than 15 minutes). Precipitate labor was defined as a total length of labor less than 3 hours.
3.2. Ethical Considerations
Approval was taken from the ethics committee.
Each participant was informed about the aim and procedures of the study and consent to participate in the study was obtained.
4. Results
This study was carried out on 150 pregnant women who reached more than 41 weeks’ gestation between Jun 1, 2012 and Dec 1, 2012 and who were scheduled for induction of labor after a normal CTG and USS and a favourable Bishop’s score, to determine the effects of labor induction on maternal and fetal outcome in postterm pregnancies (41 weeks plus).
Table 1 shows the incidence of caesarean section and fetal distress among the studied group, it was found that a caesarean section was done in 17 cases (11.3%) and fetal distress was found in 16 cases (10.7%).
Table 2 shows the relationship between nationality and fetal distress. It was found that there was no significant association between nationality and fetal distress (p > 0.05).
Table 1. Distribution of the studied patients regarding the caesarean delivery and fetal distress.
Table 2. Nationality in relation to fetal distress.
Table 3 shows the relationship between blood group and fetal distress. It was found that there was a significant relationship between blood group B and O RH- and the incidence of fetal distress (p < 0.05).
Table 4 shows the relationship between booking status and fetal distress. It was found that there was no significant relationship between booking status and fetal distress.
Table 5 shows the relationship between H/O postdatism and some other variables. It demonstrates that there was no significant relationship between H/O of postdatism and fetal distress (p > 0.05). All the patients that had H/O macrosomia had fetal distress, showing a significant relationship between the two (p < 0.05). The majority of fetal distress cases were from caesarean section delivery, indicating a significant relationship between CS and fetal distress (p < 0.01).
Table 3. Blood group and RH group in relation to fetal distress.
Table 4. Booking of the pregnancy in relation to fetal distress.
Table 5. Relationship between relevant history and other variables.
The relationship between type of CS and fetal distress found that the emergency CS showed a high percentage of fetal distress, (p < 0.05).
The relationship between the indication for CS and fetal distress found that the majority of the fetal distress cases had an indication for CS (FD, and FDM) more than the non-fetal distress indication (p < 0.01).
It was found that all fetuses that had Apgar scores of 8 were distressed, showing a significant relationship between Apgar score at 10 min and fetal distress (p < 0.001).
There was no significant relationship between fetal distress and sex of the fetus.
There was a significant association between the respiratory distress syndrome and fetal distress (p < 0.01).
Table 6 shows the relationship between fetal distress and different risk factors. Regarding duration of hospital stay, it was found that there was a significant increase in hospital stay period in fetal distress cases than the others. Gestational age was found not to have any significant effect on the inncidence of fetal distress. The number of props given did not show any association to fetal distress neither did the duration from start of induction to transfer to labour room.
There was a significant increase in the amount of oxytocin in unit in distressed cases than the non-distressed cases (p < 0.05), and the total duration of induction, also showed a significant increase in stressed fetuses than the non- stressed (p < 0.05).
The level of haemoglobin (Hb) before and after delivery showed no significant relationship to fetal distress (p > 0.05). There was a significant increase in the weight of distressed fetuses than the non-distressed ones (p < 0.01).
5. Discussion
In our study, it was found that there was a significant relationship between blood group B and O RH- and the incidence of fetal distress.
In agreement with our study, Denomme et al., (2004) showed that there was a significant positive correlation between maternal ABO-mismatched blood and fetal distress [10] .
Table 6. Relationship between fetal distress and different risk factors.
In our study, it was found that there was no significant relationship between booking status and fetal distress. In disagreement to our study, however, Jaspinder and Kawaljit (2012) demonstrated that a higher incidence of fetal distress was seen in unbooked mothers (61.12%) when compared to booked mothers (38.89%) [11] .
A recent study conducted by Khatoon et al. showed that one of the most common reasons for referral among unbooked women was fetal distress, evidenced by meconium stained liquor. The high incidence rate of birth asphyxia due to Fetal Distress prior to birth in unbooked mothers has been reported by various authors in their research works. It reveals that young age and an unbooked status might had withdrawn them from taking antenatal care at an early gestational age or till the development of obstetric complications which had led to the development of antepartum or intrapartum fetal hypoxia and distress [12] .
In this study, it was found that there was a significant relationship between H/O macrosomia and CS with fetal distress. Jaspinder and Kawaljit (2012) found that emergency Caesarean section occurred in 79.17% of mothers with Fetal Distress [11] .
In our study, we found that all fetuses that had an Apgar score of 8 were distressed indicating a significant relationship between Apgar score at 10 min and fetal distress. Mojbian et al. (2013) found that there were statistically significant differences between APGAR score and fetal distress [13] .
In our study, there was no significant relationship between fetal distress and sex of the fetus.
In this study, all the fetuses that had meconium aspiration had fetal distress, showing a significant association between the respiratory distress syndrome and fetal distress. There was a significant increase in hospital stay period in fetal distress cases than the others. It was found that there was no significant difference between the two studied groups regarding gestational age.
There was a significant increase in the amount of oxytocin in unit in distressed cases than the non-distressed. The total duration of induction also shows a significant increase in stressed fetuses than the non-stressed.
There was no significant relationship between Hb level and fetal distress. Jaspinder and Kawaljit (2012) showed that anemia was associated with the highest incidence of Fetal Distress (34.73%). Oligohydraminos, Pregnancy Induced Hypertension and Intrauterine Growth Retardation were responsible for Fetal Distress in 19.45%, 18.06% and 18.06% of cases, respectively. The various other obstetric conditions implicated in a decreasing order were: Meconium Stained Amniotic Fluid (16.67%), Preterm Labor with Scar tenderness (16.67%), Preterm Premature Rupture of Membrane (12.50%), Postdatism (12.50%), Placenta Previa (09.73%), Uteroplacental Insufficiency (06.95%), True Nuchal Knot (06.95%), Failed Labour (05.56%) and Gestational Diabetes mellitus (02.78%) [11] .
In this study, the weight of the baby was directly proportional to the incidence of fetal distress.
This study shows that policies of immediate induction of labor or serial antenatal monitoring while awaiting spontaneous labor produce no significant differences in the neonatal outcome or mode of delivery of postterm pregnancies. Women who were induced were more likely to have a precipitate labor with a shorter active second stage, although these factors did not alter neonatal outcome.
The study of postterm pregnancies is complicated by the fact that both the normal duration of pregnancy and the best method to define the estimated delivery of pregnancy remain controversial. In Norway, the normal duration of pregnancy is defined as 282 days, in line with several studies examining the mean and mode of pregnancy duration. Similarly, ultrasonography has been shown to be the method of choice for defining the estimated date of delivery (where equipment and trained personnel are available) and is found to reduce the number of pregnancies defined as being postterm [14] [15] . In Norway, pregnancies are routinely dated by ultrasonography at 18 weeks and we defined the point for investigating the postmature pregnancy as being one complete week beyond the normal duration of pregnancy, i.e., 289 days.
Several studies have demonstrated that the risks of stillbirth and perinatal mortality increase beyond 41 weeks of gestation [16] [17] . Despite this, the absolute mortality rate remains quite low, and it would take at least 500 inductions at 41 weeks to prevent one neonatal death [5] . Consequently, the maternal and fetal morbidity related to induction of labor are potentially important issues and were the subject of investigation here. This study was not designed to examine differences in mortality. Indeed, there were no fetal deaths in the study, and the only neonatal death related to birth asphyxia was secondary to a true knot in the cord. This death would probably not have been avoided by induction a few days earlier [17] .
In the process of designing this study we reviewed the methodology used by other investigators to define neonatal morbidity. We found most scoring systems unsuitable for a quantitative comparison of the study groups [18] , among other things because they focus on premature infants, NICU admission, and mortality. The Neonatal Morbidity score was based on suboptimal outcomes which have been described as being associated with postterm delivery. This scoring system was tested in two pilot studies before the randomized trial. To quantify neonatal outcome, we constructed the “perfect infant” and defined multiple criteria to assess the deviation from this. The weight ascribed to various criteria could be debated, but the fundamental design of the trial―including randomization and a priori definitions―ensures a valid group comparison. The morbidity index used by Hannah et al. [19] was also calculated, but the index is difficult to interpret clinically and provided no further information on neonatal morbidity.
Mothers who had Preterm Premature Rupture of Membrane (PPROM) further experienced Fetal heart rate abnormalities (12.05%). Moberg et al. [20] suggested an increased incidence of fetal distress in patients with PPROM due to the loss of protection of umbilical cord that amniotic fluid normally provides. Postdated pregnancy (>40 weeks gestation) led to non-reassuring fetal heart rate (12.50%) as concluded by James et al. [21] in their study. Fetal distress was found in mothers with an abnormal location of placenta (placenta previa) (9.73%) in our study [22] . Fetuses with a true nuchal cord (06.95%) experienced in-utero hypoxia and distress. Begum et al. [23] concluded that a true nuchal cord is a sign of fetal distress in their study but did not consider it as an indication for operative delivery. The study done in 2010 by Geidam et al. [24] found no significant differences between cases and controls of fetal distress in terms of age, parity, booking status, presence of obstetric conditions, duration of operation and birth weight of babies.
Fetal distress was diagnosed by fetal heart rate (FHR) and presence of meconium. However, an accurate method for establishment of fetal distress is to perform a fetal scalp blood pH estimation which is considered the gold standard for assessment of fetal wellbeing but is not done in our setup. Cardiotocography monitoring is known to overestimate fetal distress [13] . This shows that the method of screening used for making the diagnosis of fetal distress has its own limitations [25] ; however, the first response when fetal distress is detected or suspected is that of intrauterine resuscitation which will improve the condition of the fetus and may help to avoid an unnecessary intervention. An alteration of maternal position, Hydration, Oxygen, Intravenous hypertonic dextrose, Amnioinfusion, Tocolysis, etc. [17] are some of the measures which can be used for resuscitation. However, in some cases of fetal distress, an immediate operative delivery may be the only option to ensure a healthy neonate.
Various factors like young age, lack of awareness regarding provision of antenatal care, lack of health education, negligence, financial constraints, environmental & cultural prejudices, male involvement in maternal health care, poor nutritional status of young women (anemia), lack of transport facility, and absence of patient counseling prior to planning of mode of delivery might be responsible for the late booking status with decompensated obstetrics condition resulting in fetal hypoxia, asphyxia and distress [25] .