Cranial ultrasound

Cranial ultrasound
Purposetechnique to scan brain

Cranial ultrasound is a technique for scanning the brain using high-frequency sound waves. It is used almost exclusively in babies because their fontanelle (the soft spot on the skull) provides an "acoustic window". A different form of ultrasound-based brain scanning, transcranial Doppler, can be used in any age group. This uses Doppler ultrasound to assess blood flow through the major arteries in the brain, and can scan through bone. It is not usual for this technique to be referred to simply as "cranial ultrasound". Additionally, cranial ultrasound can be used for intra-operative imaging in adults undergoing neurosurgery once the skull has been opened, for example to help identify the margins of a tumour.[1]

Uses

Premature babies are especially vulnerable to certain conditions involving the brain. These include intraventricular hemorrhage (IVH), which often occurs during the first few days,[2] and periventricular leukomalacia (PVL), which tends to occur later on.[3] One of the main purposes of routine cranial ultrasound scanning in neonatal units is to identify these problems as they develop. If severe intraventricular haemorrhage is noted then the baby will need to be scanned more frequently in case post-hemorrhagic hydrocephalus (swelling of the ventricles as the natural flow of the cerebrospinal fluid is blocked by blood-clots) develops.[4]

Other indications include babies that requires ventilatory support, neonatal encephalopathy, and signs and symptoms that suggests central nervous system disorder such as seizures, microcephaly, macrocephaly, hypotonia, and unexplained poor feeding at term.[5]

Most neonatal units in the developed world routinely perform serial cranial ultrasound scans on babies who are born significantly premature. A typical regimen might involve performing a scan on the first, third and seventh day of a premature baby's life, and then at regular intervals until the baby reaches term.[6]

Technique

Coronal anterior section through anterior fontanelle of a one-year-old girl.

A 5 to 7.5 MHz probe is used to scan deeper structures in the brain. A 7 to 12 MHz probe is used for scanning superficial structures for detecting lesions between the brain and the skull, superior sagittal sinus thrombosis, cerebral oedema, and evaluating the structures of sulci and gyri.[4]

Mid sagittal section through anterior fontanelle of a one-year-old girl.

A water-based gel is applied to the infant's head, over the anterior fontanelle, to aid conduction of ultrasound waves. Ideally scans are performed during sleep or when the infant is calm. The operator then uses an ultrasound probe to examine the baby's brain, viewing the images on a computer screen and recording them as necessary.[citation needed]

A standard cranial ultrasound examination usually involves recording of approximately 11 views of the brain from different angles, six in the coronal plane and five in the sagittal and parasaggital planes.[7] This allows all parts of the ventricles and most of the rest of the brain to be visualised.[citation needed]

Who performs the scans varies between different health systems. In many hospitals in the United Kingdom paediatricians or neonatologists usually perform cranial ultrasound; in other systems advanced nurse practitioners, radiologists or sonographers may perform most scans.[citation needed]

While the anterior fontanelle is the most commonly used acoustic window for cranial ultrasounds, more advanced operators may gain additional views, especially of posterior fossa structures, by using the mastoid fontanelle, the posterior fontanelle and/or the temporal window.[8]

Other refinements of cranial ultrasound technique include serial measurement of the width of the lateral ventricles ("ventricular index") to monitor suspected ventricular dilatation and colour Doppler to assess blood flow.[citation needed]

Limitations

Cranial ultrasound is a very safe technique as it is non-invasive and does not involve any kind of ionising radiation. However, it is subject to certain limitations.

  • Operator dependency: the quality of images obtained relies on the skill of the person performing sonography.
  • Some brain structures are poorly visualised, notably posterior fossa structures such as the cerebellum if only the anterior fontanelle is used.[9]
  • If the fontanelle is very small, for example is post-mature infants, scanning may be technically difficult.
  • Damage to the brain soft tissue (parenchyma), for example resulting from ischaemia or abnormal myelination, may be hard to see.[10]

Therefore, many neonatal services prefer to perform an MRI scan when the infant is near term, as well as routine cranial ultrasound, to avoid missing more subtle abnormalities.

References

  1. ^ Dumain T (4 February 2022). Melinosky C (ed.). "What Is a Cranial Ultrasound?". WedMD.
  2. ^ MedlinePlus Encyclopedia: Intraventricular hemorrhage of the newborn
  3. ^ Pediatric Periventricular Leukomalacia at eMedicine
  4. ^ a b Gupta P, Sodhi KS, Saxena AK, Khandelwal N, Singhi P (2016). "Neonatal cranial sonography: A concise review for clinicians". Journal of Pediatric Neurosciences. 11 (1): 7–13. doi:10.4103/1817-1745.181261. PMC 4862295. PMID 27195026.
  5. ^ James, Anitha C. (September 2018). "Practical guide to neonatal cranial ultrasound (CrUS): basics". Paediatrics and Child Health. 28 (9): 424–430. doi:10.1016/j.paed.2018.07.003. S2CID 56987166.
  6. ^ "Cranial Ultrasound guideline". NHS Forth Valley. 12 February 2016.
  7. ^ James, Anitha C. (September 2018). "Practical guide to neonatal cranial ultrasound (CrUS): basics". Paediatrics and Child Health. 28 (9): 424–430. doi:10.1016/j.paed.2018.07.003. S2CID 56987166.
  8. ^ Lissauer T, Fanaroff AA, Miall L, Fanaroff J (2015). Neonatology at a Glance. John Wiley & Sons. p. 187.
  9. ^ van Wezel-Meijler, G, "Neonatal Cranial Ultrasonography" pp85-90, Springer Berlin Heidelberg, 2007
  10. ^ van Wezel-Meijler G, Steggerda SJ, Leijser LM (February 2010). "Cranial ultrasonography in neonates: role and limitations". Seminars in Perinatology. 34 (1): 28–38. doi:10.1053/j.semperi.2009.10.002. PMID 20109970.