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    Obstetric Imaging

    Fetal Cerebellum: US Appearance with Advancing Gestational Age

    Published Online:Oct 1 2001https://doi.org/10.1148/radiol.2211001583

    Abstract

    PURPOSE: To evaluate the change in ultrasonographic (US) appearance of the fetal cerebellum with advancing gestation.

    MATERIALS AND METHODS: A total of 291 normal fetuses of uncomplicated pregnancies were evaluated at gestational ages (GAs) between 15 and 41 weeks with a 3.75-MHz transabdominal curvilinear probe. After the transcerebellar view was obtained, the transverse cerebellar diameter (TCD) was measured and the images were stored. On hard-copy US images, cerebella were assigned three grades of appearance. These grades were analyzed in relation to GA and TCD. Inter- and intraobserver variations were assessed in 91 randomly selected cases.

    RESULTS: Cerebella in 137 (47.1%), 71 (24.4%), and 83 (28.5%) of 291 subjects were classified as grade I (hypoechoic, “eyeglass” shape), grade II (intermediate echogenicity, “dumbbell” outline), and grade III (hyperechoic, “fan” shape), respectively. With advancing gestation, the dominant grade changed from I to III gradually and progressively. The median GA and TCD, respectively, were 22 weeks and 22 mm for grade I, 29 weeks and 35 mm for grade II, and 36 weeks and 46 mm for grade III. These differences were statistically significant (P < .001). The agreements within inter- and intraobserver estimations were 96% (87 of 91) and 95% (86 of 91), respectively.

    CONCLUSION: A gradual change in US appearance of the fetal cerebellum is seen with advancing gestation.

    References

    • 1 American College of Obstetricians and Gynecologists. ACOG technical bulletin: ultrasonography in pregnancy No. 187. Washington, DC: American College of Obstetricians and Gynecologists, 1993. Google Scholar
    • 2 McLeary RD, Kuhns LR, Barr M, Jr. Ultrasonography of the fetal cerebellum. Radiology 1984; 151:439-442. LinkGoogle Scholar
    • 3 Reece EA, Goldstein I, Pilu G, Hobbins JC. Fetal cerebellar growth unaffected by intrauterine growth retardation: a new parameter for prenatal diagnosis. Am J Obstet Gynecol 1987; 157:632-638. Crossref, MedlineGoogle Scholar
    • 4 Lee W, Barton S, Comstock CH, Bajorek S, Batton D, Kirk JS. Transverse cerebellar diameter: a useful predictor of gestational age for fetuses with asymmetric growth retardation. Am J Obstet Gynecol 1991; 165:1044-1050. Crossref, MedlineGoogle Scholar
    • 5 Rakic P, Sidman RL. Histogenesis of cortical layers in human cerebellum, particularly the lamina dissecans. J Comp Neurol 1970; 139:473-500. Crossref, MedlineGoogle Scholar
    • 6 Zecevic N, Rakic P. Differentiation of Purkinje cells and their relationship to other components of developing cerebellar cortex in man. J Comp Neurol 1976; 167:27-47. Crossref, MedlineGoogle Scholar
    • 7 Selzer ME, Myers RE, Holstein SB. Maturational changes in brain water and electrolytes in rhesus monkey with some implications for electrogenesis. Brain Res 1972; 45:193-204. Crossref, MedlineGoogle Scholar
    • 8 Hill LM, Martin JG, Fries J, Hixson J. The role of the transcerebellar view in the detection of fetal central nervous system anomaly. Am J Obstet Gynecol 1991; 164:1220-1224. Crossref, MedlineGoogle Scholar
    • 9 Rakic P, Sidman RL. Organization of cerebellar cortex secondary to deficit of granule cells in weaver mutant mice. J Comp Neurol 1973; 152:133-161. Crossref, MedlineGoogle Scholar
    • 10 Rakic P, Sidman RL. Sequence of developmental abnormalities leading to granule cell deficit in cerebellar cortex of weaver mutant mice. J Comp Neurol 1973; 152:103-132. Crossref, MedlineGoogle Scholar
    • 11 Altman J. Postnatal development of the cerebellar cortex in the rat. II. Phases in the maturation of Purkinje cells and of the molecular layer. J Comp Neurol 1972; 145:399-463. Google Scholar
    • 12 Kornguth SE, Anderson JW, Scott G. The development of synaptic contacts in the cerebellum of Macaca mulatta. J Comp Neurol 1968; 132:531-546. Crossref, MedlineGoogle Scholar
    • 13 Rakic P. Neuron-glia relationship during granule cell migration in developing cerebellar cortex: a Golgi and electronmicroscopic study in Macacus rhesus. J Comp Neurol 1971; 141:283-312. Crossref, MedlineGoogle Scholar
    • 14 Rakic P, Stensas LJ, Sayre E, Sidman RL. Computer-aided three-dimensional reconstruction and quantitative analysis of cells from serial electron microscopic montages of foetal monkey brain. Nature 1974; 250:31-34. Crossref, MedlineGoogle Scholar
    • 15 Rees S, Harding R. The effects of intrauterine growth retardation on the development of the Purkinje cell dendritic tree in the cerebellar cortex of fetal sheep: a note on the ontogeny of the Purkinje cell. Int J Dev Neurosci 1988; 6:461-469. Crossref, MedlineGoogle Scholar
    • 16 Wisniewski KE, Laure-Kamionowska M, Wisniewski HM. Evidence of arrest of neurogenesis and synaptogenesis in brains of patients with Down’s syndrome. N Engl J Med 1984; 311:1187-1188. CrossrefGoogle Scholar
    • 17 Petit TL, LeBoutillier JC, Alfano DP, Becker LE. Synaptic development in the human fetus: a morphometric analysis of normal and Down’s syndrome neocortex. Exp Neurol 1984; 83:13-23. Crossref, MedlineGoogle Scholar
    • 18 Schmidt-Sidor B, Wisniewski KE, Shepard TH, Sersen EA. Brain growth in Down syndrome subjects 15 to 22 weeks of gestational age and birth to 60 months. Clin Neuropathol 1990; 9:181-190. MedlineGoogle Scholar
    • 19 Golden JA, Hyman BT. Development of the superior temporal neocortex is anomalous in trisomy 21. J Neuropathol Exp Neurol 1994; 53:513-520. Crossref, MedlineGoogle Scholar
    • 20 de la Monte SM, Hedley-Whyte ET. Small cerebral hemispheres in adults with Down’s syndrome: contributions of developmental arrest and lesions of Alzheimer’s disease. J Neuropathol Exp Neurol 1990; 49:509-520. Crossref, MedlineGoogle Scholar
    • 21 Hill LM, Marchese S, Peterson C, Fries J. The effect of trisomy 18 on transverse cerebellar diameter. Am J Obstet Gynecol 1991; 165:72-75. Crossref, MedlineGoogle Scholar
    • 22 Rotmensch S, Goldstein I, Liberati M, Shalev J, Ben-Rafael Z, Copel JA. Fetal transcerebellar diameter in Down syndrome. Obstet Gynecol 1997; 89:534-537. Crossref, MedlineGoogle Scholar
    • 23 Velazquez PN, Romano MC. Corticosterone therapy during gestation: effects on the development of rat cerebellum. Int J Dev Neurosci 1987; 5:189-194. Crossref, MedlineGoogle Scholar
    • 24 Huang WL, Beazley LD, Quinlivan JA, Evans SF, Newnham JP, Dunlop SA. Effect of corticosteroids on brain growth in fetal sheep. Obstet Gynecol 1999; 94:213-218. Crossref, MedlineGoogle Scholar
    • 25 French NP, Hagan R, Evans SF, Godfrey M, Newnham JP. Repeated antenatal corticosteroids: size at birth and subsequent development. Am J Obstet Gynecol 1999; 180:114-121. Crossref, MedlineGoogle Scholar
    • 26 Saintonge J, Cote R. Fetal brain development in diabetic guinea pigs. Pediatr Res 1984; 18:650-653. Crossref, MedlineGoogle Scholar
    • 27 Saintonge J, Cote R. Brain development in relation to fetal weight and maternal glucose tolerance during normal gestation. Brain Dev 1987; 9:26-32. Crossref, MedlineGoogle Scholar

    Article History

    Published in print: Oct 2001