Mower G D, Caplan C J, Christen W G, Duffy F H
J Comp Neurol. 1985 May 22;235(4):448-66. doi: 10.1002/cne.902350404.
Recent studies (Cynader and Mitchell, '80; Mower et al., '81) have shown that total dark rearing prolongs susceptibility to the physiological effects of monocular deprivation (MD) in visual cortex beyond the normal age limits. The present study addressed whether this delayed physiological plasticity is accompanied by delayed anatomical plasticity in the geniculocortical pathway. Ocular dominance (OD) columns as defined by transsynaptic autoradiography following injection of 3H proline into one eye were studied both qualitatively and quantitatively in 17 cats. Compared to normal rearing (N-3), both binocular eyelid suture (N-2) and total dark rearing (N-3) resulted in incomplete segregation of OD columns in area 17. This apparent immaturity after binocular deprivation, however, did not reflect a delayed capacity for development and plasticity. Visual experience after dark rearing produced no marked changes. In cats who experienced MD after dark rearing, injection of either the nondeprived (N-2) or deprived eye (N-3) resulted in a nearly uniform distribution of label throughout layer IV of area 17. The same result occurred with binocular vision after dark rearing (N-1). MD from birth, however, produced expansion of columns from the nondeprived eye (N-1) and contraction of columns from the deprived eye (N-1). MD imposed after 4 months of normal vision resulted in normal OD columns (N-1). Electrophysiological studies revealed a high proportion of binocular cells within layer IV in cats who experienced monocular or binocular vision after dark rearing. Outside of layer IV there were clear environmental effects on OD of single cells in these cats. Measurements of cell sizes in the clateral geniculate nucleus showed shrinkage of cells innervated by the deprived eye when MD was initiated at birth (N-3). MD after dark rearing (N-4) produced no differences in cell sizes. It is concluded that visual input is necessary for the formation of normal OD columns, the critical period for formation and environmental modification of OD columns is limited to early life, and the physiological effects of visual experience after dark rearing reflect changes occurring beyond the geniculocortical pathway.
近期研究(辛纳德和米切尔,1980年;莫尔等人,1981年)表明,完全黑暗饲养会使视觉皮层对单眼剥夺(MD)生理效应的易感性延长至超出正常年龄限制。本研究探讨了这种延迟的生理可塑性是否伴随着膝状体皮质通路中延迟的解剖可塑性。在17只猫中,通过向一只眼睛注射³H脯氨酸后经跨突触放射自显影定义的眼优势(OD)柱进行了定性和定量研究。与正常饲养(N-3)相比,双眼睑缝合(N-2)和完全黑暗饲养(N-3)均导致17区OD柱的不完全分离。然而,双眼剥夺后的这种明显不成熟并不反映发育和可塑性能力的延迟。黑暗饲养后的视觉经验没有产生明显变化。在黑暗饲养后经历MD的猫中,注射未剥夺眼(N-2)或剥夺眼(N-3)均导致17区IV层整个区域标记几乎均匀分布。黑暗饲养后的双眼视觉(N-1)也出现了相同结果。然而,从出生就开始MD会导致未剥夺眼(N-1)的柱扩张和剥夺眼(N-1)的柱收缩。在正常视觉4个月后施加MD会产生正常的OD柱(N-1)。电生理研究显示,在黑暗饲养后经历单眼或双眼视觉的猫的IV层内,双眼细胞比例很高。在这些猫中,IV层之外的单细胞OD受到明显的环境影响。对外侧膝状体核中细胞大小的测量显示,当在出生时开始MD(N-3)时,被剥夺眼支配的细胞会缩小。黑暗饲养后(N-4)进行MD对细胞大小没有差异。结论是,视觉输入对于正常OD柱的形成是必要的,OD柱形成和环境修饰的关键期仅限于生命早期,黑暗饲养后的视觉经验的生理效应反映了膝状体皮质通路之外发生的变化。
