Neurotrophic and behavioral effects of occipital cortex transplants in newborn rats

Haun, Forrest; Tj, Cunningham; La, Rothblat

doi:10.1017/s0952523800012049

Vis Neurosci

1989

DOI: 10.1017/s0952523800012049

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Neurotrophic and behavioral effects of occipital cortex transplants in newborn rats

Forrest Haun

Cunningham Tj²,

Rothblat La³

Abstract: Cell suspensions of embryonic occipital cortex were transplanted into newborn rats with large unilateral visual cortex lesions. When the animals were adults, they were tested on a difficult visual discrimination, and subsequently their brains were analyzed for possible neurotrophic effects of the transplants on nonvisual cortical areas which normally form connections with the occipital cortex. Behaviorally, animals with lesions and transplants learn to discriminate between columns and rows of squares at a rate… Show more

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Cited by 8 publications

References 70 publications

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Isochronic transplantation of neonatal grafts in the visual cortex of cats: responsiveness, ocular dominance and specificity of cortical cells to visual stimulation

Yinon

Gelerstein

1991

Exp Brain Res

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The visual cortex of adult cats was studied physiologically following neonatal isochronic transplantation of grafts from areas 17,18, which were placed homotopically, in order to reveal their functional integration and thus possible repairing of damaged cortical neuronal circuits. Three homograft cats, in which transplantation was carried out between siblings (228 cortical cells) were compared to 4 animals receiving reimplanted autografts of the equivalent size (131 cells) as well as 3 animals with analogous sectioning of the visual cortex (162 cells) (pseudograft controls). The location of the boundaries between the transplant region and the host were determined using the Nissl's method for staining histological cross sections. Extracellular unit recording revealed typical waveform of the action potentials in the transplanted region and in the surrounding host tissue of all groups of cats. Visual responsiveness in the homograft cats was 17.5% in the transplanted region and 80.4% in the unoperated hemisphere; the corresponding results were 40.3% for the transplanted region and 82.2% for the unoperated hemisphere in the autografts and 23.1% and 73.4% in the pseudografts. The specificity of the cells to visual stimulation as expressed by their orientation and direction specificity, indicated preservation of these properties in the transplanted cats. While all responsive cells in the transplanted region of the homografts were orientation specific, their proportion was 60% in the autografts and 55.5% in the analogous region in the pseudograft controls. As to the direction specific cells, their performance in the grafted region of the grafted cats was even much higher than that of the pseudograft controls. The ocular dominance distribution of the cells showed preservation of binocularity in the transplanted region (90.0% binocular cells) of the homografts; it was however smaller in the equivalent region of the autografts (65.0%) and remarkably reduced (20.0%) in the pseudografts. It was concluded that despite the deafferentation induced during the transplantation procedure, a remarkable visual responsiveness was found in the transplanted region, indicating postoperative recovery. However, the cells there were mainly affected in their activity and less in their specificity to visual stimulation.

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Isochronic transplantation of neonatal grafts in the visual cortex of cats: responsiveness, ocular dominance and specificity of cortical cells to visual stimulation

Yinon

Gelerstein

1991

Exp Brain Res

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Spinal cord transplants enhance the recovery of locomotor function after spinal cord injury at birth

1990

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Fetal spinal cord transplants placed into the site of a neonatal spinal cord lesion after the response of immature CNS neurons to injury. The transplants prevent the retrograde cell death of immature axotomized neurons and support the growth of axons into and through the site of injury. In the present experiments we used a battery of locomotor tasks to determine if these transplants are also capable of promoting the recovery of motor function after spinal cord injury at birth. Embryonic (E14) spinal cord transplants were placed into the site of a spinal cord "over-hemisection" in rat pups. Three groups of animals were used: 1) normal control animals, 2) animals with a spinal cord hemisection only, and 3) animals with a spinal cord transplant at the site of the hemisection. Eight to twelve weeks later, the animals were trained and videotaped while crossing runways requiring accurate foot placement and footprinted while walking on a treadmill. The videotapes and footprints were analyzed to obtain quantitative measures of locomotor function. Footprint analysis revealed that the animals' base of support during locomotion was increased by a neonatal hemisection. The base of support in animals with transplants was similar to control values. Animals with a hemisection rotated their hindlimbs further laterally than did control animals during locomotion. A transplant at the site of injury modified this response. Normal animals were able to cross a grid runway quickly with only a few errors. In contrast, animals with a hemisection took a longer time and made more errors while crossing. The presence of a transplant at the site of injury enabled the animals to cross the grid more quickly and to make fewer errors than the animals with a hemisection only. Animals that received the transplants demonstrated qualitative and quantitative improvements in several parameters of locomotion. Spinal cord transplants at the site of neonatal spinal cord injury result in enhanced sparing or recovery of motor function. We suggest that this transplant induced recovery of function is a consequence of the anatomical plasticity elicited by the transplants.

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System-wide repercussions of damage to the immature visual cortex

Payne

Cornwell

1994

Trends in Neurosciences

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Neurotrophic and behavioral effects of occipital cortex transplants in newborn rats

Cited by 8 publications

References 70 publications

Isochronic transplantation of neonatal grafts in the visual cortex of cats: responsiveness, ocular dominance and specificity of cortical cells to visual stimulation

Isochronic transplantation of neonatal grafts in the visual cortex of cats: responsiveness, ocular dominance and specificity of cortical cells to visual stimulation

Spinal cord transplants enhance the recovery of locomotor function after spinal cord injury at birth

System-wide repercussions of damage to the immature visual cortex

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