BlotW. J.MillerR. W. (1972). Small head size following in utero exposure to atomic radiation, Hiroshima and Nagasaki. Atomic Bomb Casualty Commission Technical Report 35–72.
2.
BrizzeeK. R.BrannonR. B. (1972). Cell recovery in foetal brain after ionizing radiation. Int. J. Radiat. Biol. 21, 375–388.
3.
BrockT. O.O'CallaghanJ. P. (1987). Quantitative changes in the synaptic vessel proteins synapsin I and p38 and the astrocyte-specific protein glial fibrillary acidic protein are associated with chemical-induced injury to the rat central nervous system. J. Neurosci. 7, 931–942.
4.
D'AmatoC. J.HicksS. P. (1965). Effects of low levels of ionizing radiation on the developing cerebral cortex of the rat. Neurology15, 1104–1116.
5.
DunnK.YoshimaruH.OtakeM.AnnegersJ. F.SchullW. J. (1988). Prenatal exposure to ionizing radiation and subsequent development of seizures. Radiation Effects Research Foundation Technical Report 5–88.
6.
EvartsE. E. (1984). Hierarchies and emergent features in motor control. In: Dynamic Aspects of Neocortical Function, pp. 557–580 (EdelmanG. M.GallW. E.CowanW. M., eds). John Wiley and Sons, New York.
7.
GoldsteinL.MurphyD. P. (1929). Etiology of the ill-health in children born after maternal pelvic irradiation. Part 2. Defective children born after post-conception pelvic irradiation. Am. J. Roentgenol. 22, 322–331.
8.
GranrothG. (1979). Defects of the central nervous system in Finland. IV. Associations with diagnostic X-ray examinations. Am. J. Obstet. Gynecol. 133, 191–194.
9.
HashizumeT.MaruyamaT.NishizawaK.NishimuraA. (1973). Dose estimation of human fetus exposed in utero to radiations from atomic bombs in Hiroshima and Nagasaki. J. Radiat. Res. 14, 346–362.
10.
HoshinoK.KameyamaY. (1988). Development stage-dependent radiosensitivity of neural cells in the ventricular zone of the telencephalon in mouse and rat fetuses. Teratology37, 257–262.
11.
ICRP (1984). Statement from the 1983 Washington Meeting of the ICRP. In: Annals of the ICRP14(1). Pergamon Press, Oxford.
12.
ICRP (1986). Developmental Effects of Irradiation on the Brain of the Embryo and Fetus, ICRP Publication 49. Annals of the ICRP16(4), 1–43.
13.
JacobsL. A.BrizzeeK. R. (1966). Effects of total-body X-irradiation in single and fractionated doses on developing cerebral cortex in rat foetus. Nature210, 31–33.
14.
KameyamaY.HoshinoK.HayashiY. (1978). Effects of low-dose X-radiation on the matrix cells in the telencephalon of mouse embryos. In: Developmental Toxicology of Energy-Related Pollutants, pp. 182–200 (MahlumD. D.SikovM. R.HachettP. L.AndrewF. D., eds). U.S. DOE Technical Information Center, Oak Ridge.
15.
KerrG. D. (1979). Organ dose estimates for the Japanese atomic bomb survivors. Health Phys. 37, 487–508.
16.
KogaY. (1937). Two intelligence test methods viewed in relation to evaluated intelligence. Collection of Reports in Commemoration of Dr. Matsumoto, Studies in Psychology and Arts, pp. 923–988 (in Japanese).
17.
KonermannG. (1987). Postimplantation defects in development following ionizing radiation. Adv. Radiat. Biol. 13, 91–167.
18.
LaytonD. D. (1962). Heterotopic cerebral gray matter as an epileptogenic focus. J. Neuropath. 1(21), 244–249.
19.
MeyerM. B.TonasciaJ. A.MerzT. (1976). Long-term effects of prenatal X ray on development and fertility of human females. In: Biological and Environmental Effects of Low-Level Radiation. II, pp. 273–277. IAEA, Vienna.
20.
MillerR. W. (1956). Delayed effects occurring within the first decade after exposure of young individuals to the Hiroshima atomic bomb. Pediatrics18, 1–18.
21.
MillerR. W.BlotW. J. (1972). Small head size after in utero exposure to atomic radiation. Lancetii, 784–787.
22.
MillerR. W.MulvihillJ. J. (1976). Small head size after atomic irradiation. Teratology14, 355–358.
23.
MoleR. H. (1982). Consequences of prenatal radiation exposure for postnatal development: A review. Int. J. Radiat. Biol. 42, 1–12.
24.
MoleR. H. (1990a). Severe mental retardation after large prenatal exposures to bomb radiation. Reduction in oxygen transport to fetal brain: a possible abscopal mechanism. Int. J. Radiat. Biol. 58, 705–711.
25.
MoleR. H. (1990b). The effect of prenatal radiation exposure on the developing human brain. Int. J. Radiat. Biol. 57, 647–663.
26.
MooreK. L. (1980). Clinically Oriented Anatomy, p. 196. Williams and Wilkins, Baltimore.
27.
MounteastleV. B. (1979). An organizing principle for cerebral function: the unit module and the distributed system. In: The Neurosciences: Fourth Study Program, pp. 21–42 (SchmittF. O.WordenF. G., eds). MIT Press, Cambridge, MA.
28.
MullerF.O'RahillyR. (1984). Cerebral dysraphia (future anencephaly) in a human twin embryo at stage 13. Teratology30, 167–177.
29.
MurphyD. P. (1947). Maternal pelvic irradiation. In: Congenital Malformations. Second Edition (MurphyD. P., ed.). Lippincott, Philadelphia.
30.
NeumeisterK. (1978). Findings in children after radiation exposure in utero from X-ray examination of mothers. In: Late Biological Effects of Ionizing Radiation, Vol. 1, pp. 119–134. IAEA, Vienna.
31.
NokkentvedK. (1968). Effects of Diagnostic Radiation Upon the Human Fetus. Munksgaard, Copenhagen.
32.
OppenheimB. E.GriemM. L.MeierP. (1976). An investigation of effects of prenatal exposure to diagnostic X rays. In: Biological and Environmental Effects of Low-level Radiation. II, pp. 249–260. IAEA, Vienna.
33.
OtakeM.YoshimaruH.SchullW. J. (1987). Severe mental retardation among the prenatally exposed survivors of the atomic bombing of Hiroshima and Nagasaki: A comparison of the T65DR and DS86 dosimetry systems. Radiation Effects Research Foundation Technical Report TR 16–87.
34.
OtakeM.SchullW. J.FujikoshiY.YoshimaruH. (1988). Effect on school performance of prenatal exposure to ionizing radiation in Hiroshima: A comparison of the T65DR and DS86 dosimetry systems. Radiation Effects Research Foundation Technical Report 2–88.
35.
PierceD. A.StramD. O.VaethM. (1989). Allowing for random errors in radiation exposure estimates for atomic bomb survivors data. Radiation Effects Research Foundation Technical Report 2–89.
36.
PlummerG. (1952). Anomalies occurring in children in utero, Hiroshima. Atomic Bomb Casualty Commission Technical Report 29-C-59.
37.
RakicP. (1988). Specification of cerebral cortical areas. Science241, 170–241.
38.
RakieP. (1988). Defects of neuronal migration and the pathogenesis of cortical malformations. Prog. Brain Res. 73, 15–37.
39.
RERF TR 2–88 (1988). See Otake (1988).
40.
RERF TR 16–87 (1987). See Otake (1987).
41.
RERF TR 3–88 (1988). See Schull (1988).
42.
RoeschW. C. (ed.) (1987). Reassessment of Atomic Bomb Radiation Dosimetry in Hiroshima and Nagasaki: Final Report. Radiation Effects Research Foundation, Hiroshima.
43.
RoseK. S. B. (1989). Epidemiological surveys on the effects of low-level radiation dose: a comparative assessment. Volume B. Intra-uterine irradiation effects. Atomic Energy Authority Document AEA-EE-0001 (AERE R 12045 Volume B), Harwell.
44.
SchullW. J.OtakeM.YoshimaruH. (1988). Effect on intelligence test score of prenatal exposure to ionizing radiation in Hiroshima and Nagasaki: A comparison of the T65DR and DS86 dosimetry systems. Radiation Effects Research Foundation Technical Report 3–88.
45.
SchullW. J.OtakeM.YoshimaruH. (1989). Radiation-related damage to the developing human brain. In: Low Dose Radiation: Biological Bases of Risk Assessment (BaverstockK. F.StatherJ. A., eds). Taylor and Francis, London.
46.
SeverL. E.GilbertE. S.HessolN. A.McIntyreJ. M. (1988a). A case-control study of congenital malformations and occupational exposure to low-level ionizing radiation. Am. J. Epidemiol. 127, 226–242.
47.
SeverL. E.HessolN. A.GilbertE. S.McIntyreJ. M. (1988b). The prevalence at birth of congenital malformations near the Hanford site. Am. J. Epidemiol. 127, 243–254.
48.
TabuchiA.HiraiT.NakagawaS.ShimadaK.FujitaJ. (1967). Clinical findings on in utero exposed microcephalic children. Atomic Bomb Casualty Commission Technical Report 28–67.
49.
TanebashiM. (1972). Intelligence and intelligence tests. In: Outline of Educational Psychology, 20th Edition, pp. 128–158 (KogaY., ed.) Kyoda Shuppansha, Tokyo (in Japanese).
50.
UNSCEAR (1977). United Nations Scientific Committee on the Effects of Atomic Radiation. Annex J. Developmental Effects of Irradiation In Utero, pp. 655–725. United Nations, New York.
51.
UNSCEAR (1986). United Nations Scientific Committee on the Effects of Atomic Radiation. Genetic and Somatic Effects of Ionising Radiation. Annex C. Biological Effects of Pre-Natal Irradiation. United Nations, New York.
52.
United States Nuclear Regulatory Commission (1989). Health Effects Models for Nuclear Power Plant Accident Consequence Analysis. Parts I and II. Division of Regulatory Applications, Office of Nuclear Regulatory Research, U.S. Nuclear Regulatory Commission, Washington, D.C..
53.
WoodJ. W.JohnsonK. G.OmoriY. (1965). In utero exposure to the Hiroshima atomic bomb: Follow-up at twenty years. Atomic Bomb Casualty Commission Technical Report 9–65.
54.
WoodJ. W.JohnsonK. G.OmoriY.KawamotoS.KeehnR. J. (1966). Mental retardation in children exposed in utero, Hiroshima-Nagasaki. Atomic Bomb Casualty Commission Technical Report 10–66.
55.
YamazakiJ. N. (1966). A review of the literature on the radiation dosage required to cause manifest central nervous system disturbances from in utero and postnatal exposure. Pediatrics37, 877–903.
56.
YoshimaruH.OtakeM.SchullW. J. (1989). Further observations on damage to the developing brain following prenatal exposure to ionizing radiation. Radiation Effects Research Foundation Technical Report (in press).
