Clinical Review

Management of prolonged decelerations

OBG Manag. 2006 November;18(11):30-45

Gary A. Dildy III, MD

Some are benign, some are pathologic but reversible, and others are the most feared complications in obstetrics

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IN THIS ARTICLE

3 FHR patterns: What would you do?

6 pearls for managing prolonged decelerations

References

1. Cetrulo CL, Schifrin BS. Fetal heart rate patterns preceding death in utero. Obstet Gynecol. 1976;48:521-527.

2. Cunningham FG, Leveno KJ, Bloom SL, et al. Williams Obstetrics. 22nd ed. New York: McGraw-Hill; 2005.

3. Electronic fetal heart rate monitoring: research guidelines for interpretation. National Institute of Child Health and Human Development Research Planning Workshop. Am J Obstet Gynecol. 1997;177:1385-1390.

4. Intrapartum fetal heart rate monitoring. ACOG Practice Bulletin #70. American College of Obstetricians and Gynecologists. Obstet Gynecol. 2005;106:1453-1461.

5. Young BK, Weinstein HM. Moderate fetal bradycardia. Am J Obstet Gynecol. 1976;126:271-275.

6. Young BK, Katz M, et al. Fetal blood and tissue pH with moderate bradycardia. Am J Obstet Gynecol. 1979;135:45-47.

7. Reynolds SR. Bradycardia in the lamb fetus in response to circulatory distress. Am J Physiol. 1954;176:169-174.

8. Langer O, Sonnendecker EW. Characteristics and management of intrapartum prolonged fetal bradycardia. Br J Obstet Gynaecol. 1982;89:904-912.

9. Williams KP, Galerneau F. Fetal heart rate parameters predictive of neonatal outcome in the presence of a prolonged deceleration. Obstet Gynecol. 2002;100:951-954.

10. Zilianti M, Segura CL, et al. Studies on fetal bradycardia during birth process. II. Obstet Gynecol. 1973;42:840-843.

11. Leung AS, Leung EK, Paul RH. Uterine rupture after previous cesarean delivery: maternal and fetal consequences. Am J Obstet Gynecol. 1993;169:945-950.

12. Freeman RK, Garite TG, Nageotte MP. Fetal Heart Rate Monitoring. Philadelphia: Lippincott Williams & Wilkins; 2003.

13. Miyazaki FS, Taylor NA. Saline amnioinfusion for relief of variable or prolonged decelerations. A preliminary report. Am J Obstet Gynecol. 1983;146:670-678.

14. Hofmeyr GJ. Amnioinfusion for umbilical cord compression in labour. Cochrane Database Syst Rev. 2000;CD000013.-

15. Gabbe SG, Nelson LM, Paul RH. Fetal heart rate response to acute hemorrhage. Obstet Gynecol. 1977;49:247-251.

16. Paul RH, Koh KS, Bernstein SG. Changes in fetal heart rateuterine contraction patterns associated with eclampsia. Am J Obstet Gynecol. 1978;130:165-169.

17. Clark SL, Hankins GD, Dudley DA, Dildy GA, Porter TF. Amniotic fluid embolism: analysis of the national registry. Am J Obstet Gynecol. 1995;172:1158-1167;discussion 1167-1169.

18. Clark SL, Gimovsky ML, Miller FC. The scalp stimulation test: a clinical alternative to fetal scalp blood sampling. Am J Obstet Gynecol. 1984;148:274-277.

19. Dildy GA, Loucks CA, Clark SL. Intrapartum fetal pulse oximetry in the presence of fetal cardiac arrhythmia. Am J Obstet Gynecol. 1993;169:1609-1611.

20. van den Berg PP, Nijland R, van den Brand SF, Jongsma HW, Nijhuis JG. Intrapartum fetal surveillance of congenital heart block with pulse oximetry. Obstet Gynecol. 1994;84:683-686.

21. Garite TJ, Dildy GA, McNamara H, et al. A multicenter controlled trial of fetal pulse oximetry in the intrapartum management of nonreassuring fetal heart rate patterns. Am J Obstet Gynecol. 2000;183:1049-1058.

22. Gull I, Jaffa AJ, Oren M, Grisaru D, Peyser MR, Lessing JB. Acid accumulation during end-stage bradycardia in term fetuses: how long is too long? Br J Obstet Gynaecol. 1996;103:1096-1101.

Fast Track

Fetal bradycardias and prolonged decelerations are 2 distinct entities; the first usually does not warrant immediate intervention

Amnioinfusion for cord compression reduces variable FHR decelerations and the need for cesarean section

Fetal scalp stimulation to assess fetal status should be done during periods of FHR baseline

A prolonged deceleration may signal danger—or reflect a perfectly normal fetal response to maternal pelvic examination. Because of the wide range of possibilities, this fetal heart rate pattern justifies close attention. For example, repetitive prolonged decelerations may indicate cord compression from oligohydramnios. Even more troubling, a prolonged deceleration may occur for the first time during the evolution of a profound catastrophe, such as amniotic fluid embolism or uterine rupture during vaginal birth after cesarean delivery (VBAC). In some circumstances, a prolonged deceleration may be the terminus of a progression of nonreassuring fetal heart rate (FHR) changes, and becomes the immediate precursor to fetal death (TABLE 1).¹

When FHR patterns exhibit these aberrations, we rightly worry about fetal well-being and the possible need for operative intervention. Unfortunately, the degree of fetal compromise is difficult to predict and depends on preexisting fetal condition, physiologic reserve, degree and duration of the insult, and other variables.

TABLE 1

Some causes of prolonged decelerations and bradycardias

PROLONGED DECELERATION	BRADYCARDIA
Cord compression Oligohydramnios Cord prolapse Uteroplacental insufficiency Anesthesia (paracervical, spinal, epidural) Maternal valsalva Maternal supine hypotension Hypertonic or prolonged contractions Abruptio placentae Uterine rupture Cocaine ingestion Maternal hypoxia Maternal seizures, eclampsia Respiratory depression from medications Cardiopulmonary arrest Amniotic fluid embolism Fetal hemorrhage Vasa previa Traumatic amniocentesis Fetal vagal reaction Rapid descent, impending birth Cervical examination Fetal scalp electrode placement Fetal blood sampling Fetal central nervous system anomalies Idiopathic (cord compression?)	Congenital conduction abnormalities Complete heart block Long QT syndrome Congenital heart defects Tachyarrhythmia (Fetal tachyarrhythmia may produce an EFM tracing that appears to be a bradycardia and can only be distinguished by ultrasound) Medications Beta blockers Hypothermia Infection Chorioamnionitis Endotoxemia

PROLONGED DECELERATION

BRADYCARDIA

Cord compression
Oligohydramnios
Cord prolapse Uteroplacental insufficiency
Anesthesia (paracervical, spinal, epidural)
Maternal valsalva
Maternal supine hypotension
Hypertonic or prolonged contractions
Abruptio placentae
Uterine rupture
Cocaine ingestion Maternal hypoxia
Maternal seizures, eclampsia
Respiratory depression from medications
Cardiopulmonary arrest
Amniotic fluid embolism Fetal hemorrhage
Vasa previa
Traumatic amniocentesis Fetal vagal reaction
Rapid descent, impending birth
Cervical examination
Fetal scalp electrode placement
Fetal blood sampling Fetal central nervous system anomalies Idiopathic (cord compression?)

Congenital conduction abnormalities
Complete heart block
Long QT syndrome
Congenital heart defects
Tachyarrhythmia (Fetal tachyarrhythmia may produce an EFM tracing that appears to be a bradycardia and can only be distinguished by ultrasound) Medications
Beta blockers Hypothermia Infection
Chorioamnionitis
Endotoxemia

Ultimately, a judgment call

The 22nd edition of Williams Obstetrics² summarizes the clinical challenges involved in the management of prolonged decelerations during labor: “Management of isolated prolonged decelerations is based on bedside clinical judgment, which inevitably will sometimes be imperfect given the unpredictability of these decelerations.”

“Fetal bradycardia” and “prolonged deceleration” are distinct entities

In general parlance, we often use the terms “fetal bradycardia” and “prolonged deceleration” loosely. In practice, we must differentiate these entities because underlying pathophysiologic mechanisms and clinical management may differ substantially.

The problem: Since the introduction of electronic fetal monitoring (EFM) in the 1960s, numerous descriptions of FHR patterns have been published, each slightly different from the others. The result: confusing nomenclature, miscommunication among clinicians, and stymied research efforts.

To standardize definitions of intrapartum FHR patterns so that the effectiveness of EFM could be better assessed in observational studies and clinical trials, the National Institute of Child Health and Human Development organized a workshop.³ Its recommendations were subsequently adopted by the American College of Obstetricians and Gynecologists (ACOG).⁴ Among the definitions:

Differentiation between the 2 entities is critical because, in many cases, bradycardias are chronic patterns that may not be associated with immediate fetal compromise and do not require immediate intervention. For example, a fetal bradycardia due to congenital heart block would not benefit from immediate delivery, especially prior to term.

“Moderate fetal bradycardia,” defined as a baseline of 100 to 119 bpm, was reported in 1.8% of 1,386 continuously monitored patients and is attributed to relative cephalopelvic disproportion, resolving after rotation of the fetal vertex and associated with normal neonatal outcome.^5,6

Similar decelerations can reflect different events

The exact depth and duration of a prolonged deceleration leading to fetal compromise and requiring prompt delivery is difficult to define, although some observations warrant consideration. Experiments with fetal lambs show that the deceleration in response to umbilical vein occlusion is associated with a fall in fetal blood pressure, whereas deceleration in response to umbilical artery occlusion is associated with a rise in fetal blood pressure. This reflex can be abolished by vagotomy, but will eventually recur due to anoxia.⁷

Vital clue: What happened before the prolonged deceleration?

In clinical practice, it is important to appreciate characteristics of the FHR pattern preceding the prolonged deceleration.⁸ Williams and Galerneau⁹ correlated baseline FHR variability and duration of prolonged decelerations with neonatal acid–base status in 186 term gestations with an identified prolonged deceleration within 30 minutes of delivery. Patients were divided into 4 groups, based on FHR variability and recovery of the FHR baseline (TABLE 2).