Doppler fetal monitor

(Redirected from Doppler velocimetry)

A Doppler fetal monitor, informally known as sonicaid (generic trademark), is a hand-held ultrasound transducer used to detect the fetal heartbeat for prenatal care. It uses the Doppler effect to provide an audible simulation of the heart beat. Some models also display the heart rate in beats per minute (BPM). Use of this monitor is sometimes known as Doppler auscultation. The Doppler fetal monitor is commonly referred to simply as a Doppler or fetal Doppler. It may be classified as a form of Doppler ultrasonography (although usually not technically -graphy but rather sound-generating).

Doppler fetal monitor
Purposehear fetal heartbeat
Photo of a genuine Sonicaid®, the original Doppler fetal monitor

Doppler fetal monitors provide information about the fetus similar to that provided by a fetal stethoscope. One advantage of the Doppler fetal monitor over a (purely acoustic) fetal stethoscope is the electronic audio output, which allows people other than the user to hear the heartbeat. One disadvantage is the greater complexity and cost and the lower reliability of an electronic device.[citation needed]

The device was invented in 1958 by Dr. Edward H. Hon,[1] Originally intended for use by health care professionals, this device is becoming popular for personal use.

Types

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Fetal Heart Rate and Activity Monitor - Baby Doppler

Dopplers for home or hospital use differ in the following ways:

  • Manufacturer: popular manufacturers Baby Doppler, Sonoline, Ultrasound Technologies, Newman Medical, Nicolet (purchased by Natus), Arjo-Huntleigh, and Summit Doppler (now Cooper Surgical).
  • Probe type: waterproof or not. Waterproof probes are used for water births.
  • Probe frequency: 2-MHz or 3-MHz probes. Most practitioners can find the heart rate with either probe. A 3-MHz probe is recommended to detect a heart rate in early pregnancy (8–10 weeks gestation). A 2-MHz probe is recommended for pregnant women who are overweight. The newer EchoHeart 5-MHz transvaginal probes aids in the detection of fetal heart tones (FHT) early in pregnancy (6–8 weeks) and for patients who have a retroverted uterus or throughout pregnancy for FHT detection for women who are obese.
  • Heart rate display: some Dopplers automatically display the heart rate on a built-in LCD; for others the fetal heart rate must be counted and timed by the practitioner.

A major advantage of being able to record and share the recording is that it can be emailed to a healthcare professional to be checked if there are any concerns about whether or not it is the fetus's heart rate and whether or not is normal. Typically, they work from about 12 weeks.[2]

In response to increasing home usage of clinical fetal doppler systems, the FDA issued a formal statement recommending against at-home use.[3] Fetal dopplers using 2-3MHz ultrasound are prescription devices designed and developed for use by licensed and trained health care professionals. System misuse (duration, angulation) and systems operating outside of intended range can produce thermal and non-thermal effects on fetal tissue, including the possibility for over-heating fetal tissue and introducing mechanical stress on the fetus due to cavitation, radiation force, and acoustic streaming.[4][5]

See also

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References

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  1. ^ Roger K. Freeman, Thomas J. Garite, Michael P. Nageotte, Fetal Heart Rate Monitoring Third Edition, 2003, p. 3. "The earliest preliminary report of FHR monitoring came in 1958 from Edward Hon, MD,... via fetal ECG monitor on the maternal abdomen." Google Books citation
  2. ^ Dawes, G. S. (September 1981). "Numerical analysis of the human fetal heart rate: The quality of ultrasound records". American Journal of Obstetrics and Gynecology. 141 (1): 43–52. doi:10.1016/0002-9378(81)90673-6. PMID 7270621 – via AJOG.
  3. ^ Vaezy, Shahram (December 2014). "Avoid Fetal "Keepsake" Images, Heartbeat Monitors". U.S. Food & Drug Administration. Retrieved September 12, 2018.
  4. ^ Church, Charles (April 2007). "Quantification of risk from fetal exposure to diagnostic ultrasound". Progress in Biophysics and Molecular Biology. 93 (1–3): 331–353. doi:10.1016/j.pbiomolbio.2006.07.015. PMID 16949653.
  5. ^ Edwards, M.J. (July 2009). "Effects of heat on embryos and foetuses". International Journal of Hyperthermia. 19 (3): 295–324. doi:10.1080/0265673021000039628. PMID 12745973. S2CID 23521342.