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No.  Why is there a question?  Even if you suspect you are pregnant, you should not use a violet wand, or any electrical toys that apply current to the body.  I’ve been saying this for many years, and available research shows that higher voltage electricity can be even more harmful to a fetus than household current. High voltage is considered any voltage above 500v.  Information from 2 research abstracts appears below, the 2nd abstract cites the first.

 

Fetal Death in Early Pregnancy Due to Electric Current

  1. Dr. Richard Jaffe M.D.*,
  2. Moshe Fejgin,
  3. Noah Ben Aderet

Article first published online: 11 JAN 2011

DOI: 10.3109/00016348609155186

Acta Obstetricia et Gynecologica Scandinavica

Volume 65, Issue 3, page 283, January 1986

Electric shock injuries in pregnant women are rare events. The uterus and amniotic fluid are thought to be excellent conductors of electric current which reaches the fetus causing cardiac arrest and fetal death. All cases except one reported in the literature occurred in the third trimester, and ended with the death of the fetus. We report a case of a woman struck by a high voltage electric current in the 13th week of her pregnancy, causing fetal death and abortion.

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ABSTRACT:

There are conflicting reports on how harmful electric shock is to a fetus. The clinical spectrum of electrical injury ranges from a transient unpleasant sensation felt by a mother and no effect on her fetus to fetal death either immediately or few days later. Several factors, such as the magnitude of the current and the duration of contact, are thought to affect outcome. In this case, it appears the current did not travel through her abdomen. Recommendations for fetal monitoring after electrocution have been published.

Injuries from electric shock account for about 1000 deaths annually in the United States and comprise about 5% of admissions to burn centres. Electrocution is the fifth leading cause of fatal occupational injuries in the United States; 1% of household accidental deaths are caused by electrical injuries. More than 60% of reported electrical injuries are due to electrocution with 110- or 220-V current and most commonly result from failure to ground tools or appliances properly or from using electrical devices near water.1

The spectrum of clinical injury from accidental electrical shock ranges from a transient unpleasant sensation after exposure to low-intensity current to sudden death due to cardiac arrest. Clinical manifestations are sometimes seen immediately after contact, but might not become apparent until several hours after injury.1

Several case reports2-9 and small case series10-12 of serious complications, including fetal death, following electric shock have been published. Due to publication bias, reports of adverse outcomes are more often published than reports of normal outcomes. Hence, the literature does not reflect the usual outcome of contact with low-voltage current.

Rees10 reviewed the cases of four women who experienced electric shock during pregnancy. All four fetuses died: one due to spontaneous abortion in the first trimester; two ceased moving immediately after the injury and were aborted, and one died 3 days after delivery with burn marks on his body. Fatovich11 reviewed a series of 15 victims of electric shock during pregnancy published in the English literature. The fetuses died in 73% of cases, and there was only one normal pregnancy outcome. Leiberman et al12 reported on six pregnant women who suffered electric shock at home. In all cases, the current went from the hand to the foot, probably through the uterus, and all of the women felt fine after the incident. Three fetuses were stillborn, two within a week of the electric shock and one after 12 weeks. All had severe intrauterine growth retardation.

One prospective cohort study of pregnant women who experienced electric shock was published by the Motherisk Program.13 Our results somewhat contradict previous findings. Of 31 pregnant women who called us, 28 were exposed to electric shock while using home appliances. Twenty-eight of these women delivered healthy newborns. One baby had a ventricular septal defect that closed spontaneously during early childhood, and two women had spontaneous abortions, one temporally related to the accidental injury, the other probably not associated with it. We found no differences in mean birth weight, gestational age at delivery, rates of cesarean section, or neonatal distress between electric-shock and control groups.

Risk factors

Some risk factors for unfavourable outcomes of pregnancy can be gathered from the cases in the literature. The magnitude of the current causing the electrocution is clearly a risk factor. High-voltage electric shock (eg, from an electrified fence) that passed through the uterus resulted in fetal death.8 Lower voltages, such as the 110-V systems used in North America and the 220-V systems used mainly in Europe, caused fewer problems.13

The pathway along which the current traveled probably has the greatest effect on the outcome of pregnancy.13 The passage of current from hand to foot through the uterus could cause sudden contraction of the uterus. Amniotic fluid transmits current effectively,8 and this could increase risk of spontaneous abortions and fetal burns or death. Another confirmation of this is the relatively benign effects on fetuses of the electroconvulsive therapy (ECT) used to treat depression and psychosis during all three trimesters of pregnancy.14 During ECT, the current does not travel through the uterus.

Possible blunt trauma to the uterus after loss of consciousness and a fall is also of concern and illustrates the need to monitor both mother and fetus. Duration of current flow in the body, body weight,12 and being wet during the electrical injury13 are also risk factors for more severe adverse outcomes.

Surveillance

Although fetal11,12,15 and obstetric11 surveillance are recommended following electrical injury, there is no evidence that any form of monitoring or treatment has a direct effect on outcome. Recommendations for fetal monitoring after electric shock have been published.16 Before 20 weeks’ gestation, no monitoring is needed. During the second half of pregnancy, fetal echocardiography is recommended if not performed earlier, and maternal electrocardiography (ECG) and fetal heart rate and uterine activity monitoring are recommended for 24 hours if the injury involved loss of consciousness, abnormal maternal ECG results, or known maternal cardiovascular illness. Any mechanical injury to the mother (ie, a fall) is an indication for 4 hours’ fetal and uterine monitoring.

Pregnant women suffering electric shock from low-voltage current, especially the 110-V current used in North America, which did not pass through the uterus and had no or minor adverse effects on the mother, would likely have no immediate effect on a fetus. Nonetheless, the effect of electrical injury on the outcome of pregnancy is still controversial, and only larger prospective observational studies could give us a better understanding of expected outcomes and requirements for monitoring.

References

1. Fish R. Electric shock. Part I: physics and pathophysiology. J Emerg Med 1993;11:309-12.
2. Toongsuwan S. Post mortem caesarean section following death by electrocution. Aust N Z J Obstet Gynaecol 1972;12:265-6.
3. Hrozek OJ. Intrauterine death of the fetus in a mother shocked by electric current. Zentralbl Gynakol 1963;85:203-4.
4. Esteve H. Avortement et électrocution: un accident de travail exceptionel. Arch Mal Prof Med Trav Sec Soc 1971;32:559-62.
5. Steer RG. Delayed fetal death following electrical injury in the first trimester. Aust N Z J Obstet Gynaecol 1992;32:377-8.
6. Mehl LE. Electrical injury from tasering and miscarriage. Acta Obstet Gynecol Scand 1992;71:118-23.
7. Peppler RD, Labranche FJ Jr, Comeaux JJ. Intrauterine death of a fetus in a mother shocked by an electrical current: a case report. J La State Med Soc 1973;124(2):37-8.
8. Jaffe R, Fejgin M, Ben Aderet N. Fetal death in early pregnancy due to electric current. Acta Obstet Gynecol Scand 1986;65:283.
9. Yoong AF. Electrical shock sustained in pregnancy followed by placental abruption. Postgrad Med J 1990;66(777):563-4.
10. Rees WD. Pregnant women struck by lightning. BMJ 1965;1:103-4.
11. Fatovich DM. Electric shock in pregnancy. J Emerg Med 1993;11:175-7.
12. Leiberman JR, Mazor M, Molcho J, Haiam E, Maor E, Insler V. Electrical accidents during pregnancy. Obstet Gynecol 1986;67(6):861-3.
13. Einarson A, Bailey B, Inocencion G, Ormond K, Koren G. Accidental electric shock in pregnancy: a prospective cohort study. Am J Obstet Gynecol 1997;176(3):678-81.
14. Consensus Conference on Electroconvulsive Therapy. Report of the Consensus Conference on Electroconvulsive Therapy. JAMA 1985;254(15):2103-8.
15. Strong TH Jr, Gocke SE, Levy AV, Newel GJ. Electrical shock in pregnancy: a case report. J Emerg Med 1987;5:381-3.
16. Fish RM. Electric injury. Part III: cardiac monitoring indications, the pregnant patient, and lightning. J Emerg Med 2000;18:181-7.

 

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