Obstetric ultrasonography of twins at a gestational age of almost 9 weeks. The mother’s and the twins’ bodies have a higher echogenicity than the amniotic fluid around them. The standard representation is brighter color for higher echogenicity, giving the almost anechoic fluid an almost black appearance.

Echogenicity (misspelled sometimes as echogenecity) or echogeneity is the ability to bounce an echo, e.g. return the signal in medical ultrasound examinations. In other words, echogenicity is higher when the surface bouncing the sound echo reflects increased sound waves. Tissues that have higher echogenicity are called "hyperechogenic" and are usually represented with lighter colors on images in medical ultrasonography. In contrast, tissues with lower echogenicity are called "hypoechogenic" and are usually represented with darker colors. Areas that lack echogenicity are called "anechogenic" and are usually displayed as completely dark.[1]

Microbubbles

Echogenicity can be increased by intravenously administering gas-filled microbubble contrast agent to the systemic circulation, with the procedure being called contrast-enhanced ultrasound. This is because microbubbles have a high degree of echogenicity. When gas bubbles are caught in an ultrasonic frequency field, they compress, oscillate, and reflect a characteristic echo- this generates the strong and unique sonogram in contrast-enhanced ultrasound. Gas cores can be composed of air, or heavy gases like perfluorocarbon, or nitrogen.[2] Heavy gases are less water-soluble so they are less likely to leak out from the microbubble to impair echogenicity (McCulloch et al., 2000). Therefore, microbubbles with heavy gas cores are likely to last longer in circulation.

Reasons for higher echogenicity

During ultrasound examinations, sometimes echogenicity is higher in certain parts of body. Fatty liver could cause increased echogenicity in the liver, especially if the liver transaminases are elevated.[3]

Women with polycystic ovary syndrome may also show an increase in stromal echogenicity.

See also

References

  1. Ihnatsenka, Barys; Boezaart, André Pierre (2010). "Ultrasound: Basic understanding and learning the language". International Journal of Shoulder Surgery. 4 (3): 55–62. doi:10.4103/0973-6042.76960. PMC 3063344. PMID 21472065.
  2. Lindner, JR (2004). "Microbubbles in medical imaging: current applications and future directions". Nature Reviews. Drug Discovery. 3 (6): 527–32. doi:10.1038/nrd1417. PMID 15173842. S2CID 29807146.
  3. Mathiesen, UL; Franzén, LE (2002). "Increased liver echogenicity at ultrasound examination reflects degree of steatosis but not of fibrosis in asymptomatic patients with mild/moderate abnormalities of liver transaminases". Scandinavian Journal of Gastroenterology. Department of Internal Medicine, County Hospital, Oskarshamn, Sweden. 34 (7): 516–22. doi:10.1016/s1590-8658(02)80111-6. PMID 12236486.
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