Astrocytic reactions in spinal gray matter following sciatic axotomy.

Astrocytic responses following unilateral sciatic nerve axotomy were examined in the spinal gray matter. Using an antiserum to glial fibrillary acidic protein (GFAP), immunoreactive astrocytes were studied in both dorsal and ventral gray matter at intervals from 2 days through 34 days post-axotomy. In all axotomized animals, increased numbers of strongly immunoreactive astrocytes were present in the gray matter ipsilateral to the surgery. Such astrocytes were absent from the contralateral intact side and from gray matter bilaterally in adjacent spinal segments not involved in formation of the sciatic nerve. These GFAP-positive astrocytes occurred not only in association with large motor neurons in the ventral gray matter but also in association with central processes of dorsal root ganglion neurons in the dorsal gray matter. The response was quite rapid, being discernible both dorsally and ventrally as early as the second post-operative day. This increased GFAP immunoreactivity persisted throughout the entire observation period, with the perikarya of large ventral motor neurons appearing to become surrounded or encapsulated by the immunoreactive processes. A further alteration noted at the longest post-operative intervals was the presence in the ventral gray matter of astrocytes appearing to be binucleate. The data obtained indicate that the astrocytic response is not related solely to reactions in motor neurons and, furthermore, the rapidity with which it develops in the dorsal gray matter suggests that its induction is not dependent upon transganglionic degeneration, which others have reported to occur weeks after peripheral nerve injury.

Central canal area in the early postnatal rat: normal development and radiation-induced changes.

The spinal central canal area in the early postnatal rat differs markedly in appearance from that in the adult. Dorsally and ventrally, the walls of the canal lack nuclei and appear to be composed of processes from cell bodies at some distance from the lumen. Additionally, a densely packed cluster of cells similar to those in the lateral walls is situated ventral to the canal area. Preliminary data indicated that the cells in this cluster were extremely susceptible to ionizing radiation; the present study: (1) characterizes these cells ultrastructurally in the normal animal; and (2) examines radiation-induced changes. Ultrastructurally, the cells forming this cluster in the normal 3-day-old rat were tightly packed, and their outlines followed the contours of adjacent cells. The cytoplasm, which contained an abundance of organelles, including distinct, wide-bore endoplasmic reticulum with darkly stained cisternae, occasionally surrounded bundles of axons. Synapses and junctional complexes were absent. Both nuclear and cytoplasmic characteristics are those of immature astrocytes. By 6 h following irradiation of the 3-day-old, many cells in this cluster were pyknotic, and by 24 h the cluster had essentially disappeared. The number of cells surrounding the lumen decreased less rapidly than in the cluster. By 10 days post-irradiation (P-I) this number was approximately 39% less than in the control. These changes indicated a differential sensitivity to ionizing radiation between the cells of the ventral cluster and those elsewhere in the central canal area.

Patterns of x-radiation-induced Schwann cell development in spinal cords of immature rats.

Schwann cells, Schwann cell myelin, and connective tissue components develop in the spinal cord of the immature rat following exposure to x-rays. For the purposes of this paper, these intraspinal peripheral nervous tissue constituents are referred to as IPNT. A series of investigations are in progress to elucidate factors related to the development of IPNT, and the present study is a light microscopic evaluation of the relationship between the amount of radiation administered (1,000-3,000R) to the lumbosacral spinal cord in 3-day-old rats and the incidence and distribution of IPNT at intervals up to 60 days postirradiation (P-I). The results showed that IPNT was present in only 33% of the rats exposed to 1,000R, whereas its presence was observed in 86% or more of those in the 2,000-, 2,500-, and 3,000R groups. The distribution of IPNT was quite limited in the 1,000R group, where it was restricted to the spinal cord-dorsal root junction and was found in only a few sections within the irradiated area. The distribution was more widespread with increasing amounts of radiation, and IPNT occupied substantial portions of the dorsal funiculi and extended into the dorsal gray matter in the 3,000R group. In all aR mals developing IPNT in the groups receiving 2,000R or more, the IPNT was present in essentially all sections from the irradiated area. Further studies will compare in detail spinal cords exposed to 1,000R in which IPNT is an infrequent, limited occurrence with those exposed to higher doses where IPNT occurs in a more widespread fashion in essentially all animals.

Changes in the central canal area of immature rats following spinal cord injury.

A small, unilateral, penetrating wound was placed in the dorsolateral portion of the lumbosacral spinal cord in immature rats. Although this wound did not extend into the central canal area, some cells forming the walls of this canal underwent proliferative activity as demonstrated by [3H]thymidine autoradiography. The uniform, regular cellular arrangement of these walls was lost and portions of the walls thickened and became multilayered in appearance.