Cardiotocography

Cardiotocography (CTG) is a technical means of recording the fetal heartbeat and the uterine contractions during pregnancy. The machine used to perform the monitoring is called a cardiotocograph, more commonly known as an electronic fetal monitor (EFM).

Fetal monitoring was invented by Doctors Alan Bradfield, Orvan Hess and Edward Hon. A refined (antepartal, non-invasive, beat-to-beat) version (cardiotocograph) was later developed for Hewlett Packard by Konrad Hammacher.

CTG monitoring is widely used to assess fetal wellbeing. A review found that in the antenatal period (before labour) there is no evidence to suggest that monitoring women with high-risk pregnancies benefits the mother or baby although research around this is old and should be interpreted with caution. The same review found that computerized CTG machines resulted in lower numbers of baby deaths than the traditional CTG machines (as shown in picture). More up-to-date research is needed to provide more information around this practice. CTG monitoring can sometimes lead to medical interventions which are not necessarily needed. Fetal vibroacoustic stimulation (sound played to the unborn baby through the mother’s abdomen) has been used to provoke the baby into being more active. This can improve their CTG monitoring so that the mother does not have to be monitored for as long, however the safety of this technique has not been fully assessed; hearing impairment, stress reactions and other effects should be investigated before this technique is used widely.

External cardiotocography can be used for continuous or intermittent monitoring. The fetal heart rate and the activity of the uterine muscle are detected by two transducers placed on the mother’s abdomen (one above the fetal heart, to monitor heart rate and the other at the funds of the uterus to measure frequency of contractions). Doppler ultrasound provides the information which is recorded on a paper strip known as a cardiotocograph (CTG). External tachometry is useful in showing the beginning and end of contractions, as well as frequency, but not the strength of contractions. The absolute values of pressure readings on an external tachometer are dependent on position, and are not sensitive in people who are obese. In cases where information on the strength, or precise timing, of contractions is needed, an internal tachometer is more appropriate.

Internal cardiotocography uses an electronic transducer connected directly to the fetal scalp. A wire electrode is attached to the fetal scalp through the cervical opening and is connected to the monitor. This type of electrode is sometimes called a spiral or scalp electrode. Internal monitoring provides a more accurate and consistent transmission of the fetal heart rate than external monitoring because factors such as movement do not affect it. Internal monitoring may be used when external monitoring of the fetal heart rate is inadequate, or closer surveillance is needed. Internal tachometry can only be used if membranes (fore-waters) have ruptured either spontaneously or artificially, and the cervix is open. To gauge the strength of contractions, a small catheter (Intrauterine pressure catheter or IUPC) is passed into the uterus, past the fetus. Combined with an internal fetal monitor, an IUPC may give a more precise reading of the baby’s heart rate and the strength of contractions.

A typical CTG reading is printed on paper and/or stored on a computer for later reference. A variety of systems for centralized viewing of CTG have been installed in a large number of maternity hospitals in industrialized countries, allowing simultaneous monitoring of multiple tracings in one or more locations. Display of maternal vital signs, ST signals and an electronic partogram are available in the majority of these systems. A few of them have incorporated computer analysis of cardiotocographic signals or combined cardiotocographic and ST data analysis.

A typical CTG output for a woman not in labour. A: Fetal heartbeat; B: Indicator showing movements felt by mother (caused by pressing a button); C: Fetal movement; D: Uterine contractions

 

Sonography

sonographer, or ultrasonographer, is a healthcare professional, who specialise in the use of ultrasonic imaging devices to produce diagnostic images, scans, videos, or 3D volumes of anatomy and diagnostic data, frequently a radiographer but may be any healthcare professional with the appropriate training. The requirements for clinical practice vary greatly by country. Sonography requires specialized education and skills to view, analyze and modify the scan to optimize the information in the image. Because of the high levels of decisional latitude and diagnostic input, sonographers have a high degree of responsibility in the diagnostic process. Many countries require that medical sonographers have professional certification. Sonographers must understand ultrasound physics, cross sectional anatomy, physiology and pathology.

Why sonography is done?

An abdominal sonogram can help to diagnose a variety of conditions and to assess damage caused by illness. Doctors can also use abdominal sonography to guide them as they perform needle biopsies on abdominal organs. Abdominal sonography specifically focuses on structures in the upper abdomen.

What is sonography used for?

The many uses of ultrasound technology – Diagnostic Medical Sonography. Sonography, also known as ultrasound scanning or imaging, is a non-invasive diagnostic procedure where high-frequency sound waves are applied to parts of the body to produce images of otherwise obscured internal organs and blood flow.

What Is the Difference Between Sonography and Ultrasound?

Sonography is a medical field in which ultrasound devices are used. You may work as a sonographer, using ultrasound equipment to create images of internal body structures for medical analysis. Read on to learn more about a career as a diagnostic medical sonographer.

Sonography and Ultrasound Defined

Sonography – sometimes called ultrasonography – is the practice of using high-frequency waves to produce an image for medical analysis. These high frequency waves are called ultrasound waves. Ultrasound waves are a useful method to produce a needed medical image without the use of radiation. You might be most familiar with sonography’s role in the field of obstetrics to produce an ultrasound image of an unborn baby. Sonography is also used to analyze tissues and organs of the body, such as the heart, eyes and abdomen.