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About WaterBirth

Water birth is a method of giving birth, which involves immersion in warm water, providing many benefits for both mother and infant, including pain relief and a less traumatic birth experience for the baby.

WaterBirth History


Waterbirth portable birthing poolThe use of warm-water pools for labor and childbirth is a relatively recent phenomenon in Western societies. During the 1960s, Russian researcher Igor Charkovsky undertook considerable research into the safety and possible benefits of water birth in the Soviet Union. In the late 1960s, French obstetrician Frederick Leboyer developed the practice of immersing newly-born infants in warm water to help ease the transition from the womb to the outside world, and to mitigate the effects of any possible birth trauma.

 

 

Another French obstetrician, Michel Odent, took Leboyer's work further, using the warm-water birth pool for pain relief for the mother, and as a way to normalize the birth process. When some women refused to get out of the water to finish giving birth, Odent started researching the possible benefits for the baby of being born under water, as well as the potential problems in such births. By the late 1990s, thousands of women had given birth at Odent's birthing center at Pithiviers, and the notion of water birth had spread to many other Western countries.

Water birth first came to the United States through couples giving birth at home, but soon was introduced into the medical environment of hospitals and free-standing birth centers by obstetricians and certified nurse midwives. In 1991, Monadnock Community Hospital in Peterborough, New Hampshire became the first hospital to create a protocol for giving birth in water. By 2005, there were over 300 hospitals in the US that had adopted such protocols. More than three-quarters of all National Health Service hospitals in the UK provide this option for laboring women.


Research


Considerable research has been undertaken into the safety of water birth. Two of the most prolific researchers have been Michel Odent and the American obstetrician Michael Rosenthal. Dianne Garland, a midwife in the UK, has focused on gathering research through the National Health Service system, and has published a book called, Waterbirth: An Attitude to Care.

Benefits

For the baby Childbirth can be a strenuous experience for the baby. Properly heated water helps to ease the transition from the birth canal to the outside world because the warm liquid resembles the familiar intra-uterine environment, and softens light, colors and noises.

To the mother

Pain Management


Reports that water birth is an effective form of pain management during labor and delivery. Water birth is a form of hydrotherapy which, in studies, has been shown to be an effective form of pain management for a variety of conditions especially lower back pain (a common complaint of women in labor)[citation needed]. In an appraisal of 17 randomized trials, two controlled studies, 12 cohort studies, and two case reports, it was concluded that there was a definite "benefit from hydrotherapy in pain, function, self-efficacy and affect, joint mobility, strength, and balance, particularly among older adults, subjects with rheumatic conditions and chronic low back pain," (Geytenbeek 2002). When compared with conventional pain management techniques for labor and delivery (e.g. anaesthesia and narcotics) hydrotherapy is also possibly a safer alternative. In studies, epidural anaesthesia (EDA), is correlated with an increased rate of instrumental (e.g. forceps in childbirth) delivery rates and also cesarean section rates (Ros et al. 2007). Full immersion in water promotes physiological responses in the mother that reduce pain including a redistribution of blood volume, which stimulates the release of oxytocin and vasopressin (Katz 1990), the latter which also increases oxytocin blood levels (Odent 1998). The Cochrane Database of Systematic Reviews has found that "the statistically significant reduction in maternal perception of pain and in the rate of epidural analgesia suggest that water immersion during the first stage of labour is beneficial for some women. No evidence was found that this benefit was associated with poorer outcomes for babies or longer labours."

Intact perineum/Decreased Episiotomy


Support from the water slows crowning of the infant's head and offers perineal support (Garland 2000), which decreases the risk of tearing and reduces the need for episiotomies. Indeed, there is a zero episiotomy rate in the waterbirth literature. Moroever, "perineal trauma is reported to be generally less severe, with more intact perineums for multips, but in some literature about the same frequency of tears for pimips in or out of the water," (see Burn 1993 and Garland 1997).

 

Risks and Concerns


A large-scale study of waterbirth in the UK (1994-1996) showed a decrease in perinatal mortality (1.2 per 1,000 for waterbirth vs. 4 per 1,000 for conventional birth during the same period) (Harper 2000; Gilbert 1999; London: Office for National Statistics 2005). While of the 150,000 recorded waterbirths worldwide between 1985 and 1999, problems comparable to non-water births did arise, "there are no valid reports of infants deaths due to water aspiration or inhalation," .

A review of the literature on water birth suggests that any controversy in the medical community stems from OBGYN and pre-natal care providers who generally support water birth, on the one hand, and pediatric specialists who criticize water birth, on the other (see Schuman 2006). While this is by no means a universal divide, it appears to correlate with the "do no harm" credo. The American Academy of Pediatrics 2005 statement on water birth explains that because to date there is no adequate randomized controlled study to demonstrate any benefit to the newborn (only concern over possible complications), when parents are informed about water birth, risks (rather than benefits) should be stressed (Schuman 2006). However, on the other hand, studies have shown that labouring in water does offer significant benefits to the mother (as cited above). While as of 2006 the American College of Obstetricians and Gynecologists had not taken an official position on water birth (Schuman 2006), the Royal College of Obstetricians and Gynaecologists and the Royal College of Midwives explicitly support, "Immersion in water during labour and birth," (Royal College of Midwives 2006). Studies that are critical of water birth generally object to or cite evidence from "poorly managed" or un-monitored water birth by inexperience care providers (e.g. Zimmermann et al. 1993).

Infant Aspiration of Water


Infants receive oxygen through the umbilical cord until the time that the cord is cut or the placenta dislodges from the uterine wall, an average of 2-10 minutes after birth (sometimes up to 30 minutes). In addition, from about 10 weeks gestation, the lungs of the fetus produce fluids which conributes to amniotic fluid. When carried out under prescribed conditions, the water in which the baby is birthed is maintained as close to body temperature as possible, thus contributing to a minimal sensation of transition for the infant from womb to tub. However, water is not the same as amniotic fluid which is taken up by the baby's lungs as part of normal in-utero respiratory movements. Aspiration of water has profound detrimental physiological effects.

In a normal infant (determined by monitoring of fetal heart rate during labor) several physiological factors are put forward for preventing the infant from inhaling water at birth. These supposed inhibitory factors include the following: the natural slowing or stopping altogether of fetal breathing movements (FBM) from 24 to 48 hours prior to birth (Johnson 1996); It should be remembered that this does not relate to the actual moment of birth 2. pre-birth hypoxia - all infants are born experiencing acute hypoxia or lack of oxygen, which causes apnea or swallowing, not breathing or gasping. [This is not the case. While the PO2 is probably in the order of 20, much less than an adult or child, Foetal haemoglobin is very efficient in extracting oxygen from the maternal circulation and providing to the baby. While babies are often peripherally cyanosed [blue] at delivery, they are centrally pink.] So they are not Hypoxic in practical terms. However, any interruption to that supply of oxygen (eg. birth, placental separation) will aggravate the hypoxia. It is said by some that if a fetus does experience prolonged oxygen deprivation during labor, which would lead to gasping at the time of birth (Fewell 1983), variabilities would be noted in the fetal heart rate, usually resulting in prolonged bradycardia and the mother would be instructed to leave the tub immediately; This is an assumption that management in all situations is of a particular standard.[Prolonged hypoxia leads to a depressed baby that does not move and does not make respiratory efforts (Apgar score). A vigorous baby always breathes at birth and is required to do so by the sudden changes in its circlatory system, which now shunts blood through the lungs in increased amounts. Oxygen is no longer supplied through the cord and so the lungs must be used immediately for this purpose. This requires a baby to breathe immediately. 3. In the event that water were to pass the larynx, "it could not pass into the lungs because water is a hypotonic solution and lung fluids present in the fetus before and at the time of birth are hypertonic, which are denser and prevent hypotonic solutions from merging or coming into their presence"; [Breathing requires creation of a negative intra-thoracic pressure and the first few breaths create very large negative pressure in order to open the alveoli [air sacs]. These high negative pressures can suck the thick tenacious meconium into the lungs with ease, bath water is easy to inhale] 4. the dive reflex (Mammalian diving reflex), which is associated with the larynx and present in infants until 6 to 8 months of age, causes the glottis to close when the taste buds come into contact non-breastmilk substances, thus the solution is swallowed, not inhaled (Harding, Johnson, and McClelland 1978). Unfortunately the dive reflex in humans is poorly developed and is easily overcome by any degree of oxygen deprivation.

The infant's first breath is not triggered by the absence of the water over the face which is supposed to trigger the mammalian diving reflex. It is triggered by changes in temperature and pressure on the baby. For the first breath to take place the baby switches over from fetal circulation to newborn circulation, closing the shunts in the heart, creating pulmonary circulation, changing the pressures in the lungs, pushing out fluids that are already present in lung spaces and allowing for the exchange of oxygen and carbon dioxide. This process is rapid for most babies but can take a few minutes to completely initiate. Supply of Oxygen through the umbilical cord is unreliable as the placenta can separate at any time and always partially separates once the baby is delivered and the uterus contracts down. There is always a threat that the newborn will inhale water during the water birth process.

Infection


Another concern is that the water could increase the risk of infection. In a randomized controlled trial of the effects of water labor in Canada, no difference was noted in the low rates of maternal and newborn signs of infection in women with ruptured membranes (Rush 1996). Due to the rigorous protocols for cleaning birthing tubs between labors (especially in hospitals), there is little (if any) risk of transferring bacteria from infant to infant or mother to mother. In a 1999 study of bacterial cultures carried out at the Oregon Health Sciences University Hospital, there were no instances of bacteria cultured from the birth pool itself. While Pseudomonas bacteria (common in tap water) were present, even those infants that tested positive for the bacteria needed no treatment for infections. These findings confirm those of a British study conducted over a 3-year period (Brown 1998).

Slowed Labor


Due to the documented relaxing effects of water, laboring in water is sometimes associated with a decrease in the intensity of contractions, and is thus thought to slow labor. While water birth experts argue that this must be evaluated on a case-by-case bases, some hospitals have adopted a "5 centimeter" rule, allowing women to enter the tub only once the cervix has already expanded to 5 centimeters.

Maternal Blood Loss


For care providers who are inexperienced delivery in water, it may be difficult to assess the amount of maternal blood loss. While well-developed methods of determining maternal blood loss in water do exist , many providers prefer to deliver the placenta "on land" for this reason (e.g. the University of Michigan hospital).

Acceptance


Water birth is accepted and practiced in many parts of the United States, Canada, Australia, and New Zealand, as well as many European countries, including the United Kingdom and Germany, where many[specify] maternity clinics have birthing tubs. Many[specify] independent birthing centers and many home birth midwives offer water birth services. At present, water birth is often practiced by those who choose to have a home birth, because the majority of hospitals have not yet installed proper birth pools in their maternity wards. In 2006 more than 300 U.S. hospitals offered such facilities. At least two such hospitals were listed in the 2006 U.S. News and World Report "Honor Roll" of best U.S. hospitals: Barnes-Jewish Hospital in St. Louis, Missouri and the University of Michigan hospital in Ann Arbor, MI.

References


^ Water Birth and Infection in Babies - British Medical Journal
Flade, Ines: Rundbrief Nummer 2. Einiges über die Wassergeburt.
Geburtsberichte, Geburtshaus und mehr e. V. Jena, Jena 1999.
Schroeter, Ken. "Water Births: A Naked Emperor" Pediatrics, Vol. 114 No. 3, September 2004, pp. 855-858 (critical commentary in a mainstream medical journal)
Garland, Dianne. Waterbirth: An Attitude to Care, Books for Midwives PR, UK, 2000 1 5947 7067 0
Geytenbeek, Jenny. "Evidence of effective hydrotherapy". In Physiotherapy. V. 88(9):514-529, 2002.
Ros, Andrea, Ricardo Felberbaum, Iris Jahnke, Klaus Diedrich, Peter Schmucker, and Michael Huppe. 2007 "Epidural anaethesia for labour: does it influence the mode of delivery?" In Archives of Gynecology and Obstetrics. V. 275(4):269-274(6).
Katz, V., et al. (1990, Feb.). A comparison of bed rest and immersion for treating the edema of pregnancy. Obstet and Gynecol 75 (2): 147-51
Odent, M. (1998, March). Use of water during labor—updated recommendations. MIDIRS 8 (1): 68-9
Burn, E., Greenish, K. (1993). Water Birth. Pooling information. Nursing Times 89 (8): 47-9.
Garland, D., Jones, K. (1997, June). Ibid.
Gilbert, R., Tookey, P. (1999, Aug. 21). Perinatal mortality and morbidity among babies delivered in water:surveillance study and postal survey. BMJ 319(7208): 483-7.
Office of National Statistics. 2007. "Mortality Stastics: Childhood, infant and perinatal - Review of the Registrar General on deaths in England and Wales, 2005." Series DH3 No. 38. London.
Schuman, Andrew. 2006. "When parents-to-be ask about water birth." In Modern Medicine.
Royal College of Midwives. 2006. "Immersion in water during labour and birth." Joint Position Paper no. 1. London, Royal College of Obstetricians and Gynecologists and Royal College of Midwives.
Zimmerman R, Huch A, Huch R. 1993. "Water birth—Is it safe?" In the Journal of Perinatal Medicine 21:5.
Johnson, Paul. (1996). Birth under water – to breathe or not to breathe. B J of Obstet Gynecol 103 (3): 202-8.
Fewell, J.E., Johnson, P. (1983). Upper airway dynamics during breathing and during apnea in fetal lambs. J of Physiol 339: 495-504.
Harding, R., Johnson, P., McClelland, M. (1978) Liquid sensitive laryngeal receptors in the developing sheep, cat, and monkey. J of Physiol 277: 409-22.
Eriksson, M., et al. (1996, Aug.). Warm tub bath during labor. A study of 1385 women with prelabor rupture of the membranes after 34 weeks of gestation. Acta Obstet et Gynecol Scand 75 (7): 642-644.
Garland, D., Jones, K. (1997, June). Ibid.
Siegel, P. (1960). Does bath water enter the vagina? Journal of Obstet and Gynecol 15: 660-1.
Rush, J., et al. (1996, Sept.). The effects of whirlpool baths in labor: a randomized, controlled trial. Birth 23 (3):136-43.
Brown, L. (1998, April). The tide of waterbirth has turned: audit of water birth. British Journal of Midwifery 6(4): 236-43.

 

Resources
Books

New Active Birth — A Concise Guide to Natural Childbirth,' Janet Balaskas, HarperCollins, UK, 1995 ISBN 0-7225-2566-4
Having a Great Birth in Australia, David Vernon, Australian College of Midwives, Canberra, 2005 ISBN 0-9751674-3-X

Films

Water Baby: Experiences of Waterbirth an award-winning documentary by filmmaker Karil Daniels

Water birth. (2007, September 7). In Wikipedia, The Free Encyclopedia . Retrieved 21:33, September 7, 2007, from http://en.wikipedia.org/w/index.php?title=Water_birth&oldid=156194358