[Myelination, demyelination and re-myelination in the central nervous system]

Effects of aging on the myelination of the optic nerve in rats

AIM OF THE STUDY

Cognitive decline due to aging is most probably the result of changes in the white matter in the central nervous system (CNS) and/or demyelination.

MATERIAL AND METHODS

We used electron microscopic analysis of the morphological changes in aging rats' optic nerves as an easily accessible part of the CNS.

RESULTS

Several age changes were observed in aging rats (36 months) vs. young adult rats (6 months), namely degeneration of axons, decreased packing density and morphological alterations of myelination, including the ballooning of some myelin sheaths, separation of myelin lamellae and degenerative changes in the oligodendrocytes population.

CONCLUSION

Cognitive decline related to aging may occur in part due to the disturbed myelination of axons in CNS white matter.

Preclinical Explorative Assessment of Dimethyl Fumarate-Based Biocompatible Nanolipoidal Carriers for the Management of Multiple Sclerosis

Multiple sclerosis (MS) is a neurodegenerative disease in which myelin sheath damage occurs due to internal and external factors. MS especially affects the young population. Dimethyl fumarate (DMF) is a promising agent for MS treatment, although it is associated with concerns such as poor brain permeation, multiple dosing, and gastrointestinal flushing. The present study attempts to evaluate the preclinical performance of specially designed DMF-based lipoidal nanoparticles in a cuprizone-induced demyelination model in rodents. The studies proved the efficacy of lipid-based nanoparticles containing DMF in a once-a-day dosage regimen over that of thrice-a-day plain DMF administration on crucial parameters like motor coordination, grip strength, mortality, body weight, and locomotor activity. However, neither blank lipid nor blank neuroprotective (vitamins A, D, and E) loaded nanoparticles were able to elicit any desirable behavioral response. Histopathological studies showed that the designed once-a-day DMF nanomedicines were well tolerated and rejuvenated the myelin sheath vis-à-vis the plain DMF thrice-a-day regimen. These findings provide proof of concept for a biocompatible nanomedicine for MS with tremendous promise for effective brain delivery and patient compliance on the grounds of a reduction in the dosage frequency.

Marcação imuno-histoquímica da resposta macrofágica e astrocitária no tronco encefálico de ratos Wistar submetidos ao modelo gliotóxico do brometo de etídio e tratados com ciclofosfamida

O gliotóxico brometo de etídio (BE) foi utilizado para o estudo da resposta macrofágica e astrocitária sob imunossupressão com ciclofosfamida (CY). Investigou-se a imunorreatividade astrocitária à proteína glial fibrilar ácida (GFAP) e à vimentina (VIM), e a imunorreatividade macrofágica ao ED1 após injeção do BE. Foram utilizados ratos Wistar adultos injetados na cisterna basal com salina a 0,9% (grupo I), BE a 0,1% (grupo II) e BE a 0,1%, imunossuprimidos com CY (grupo III). Fragmentos do tronco encefálico foram colhidos do 1º ao 21º dia pós-injeção para estudo imuno-histoquímico da GFAP, VIM e ED1. Nos grupos II e III, observou-se imunorreatividade aumentada para GFAP e re-expressão de VIM. No grupo II, células ED1-positivas foram observadas a partir do 2º dia e no grupo III, a partir do 3º dia. Aos 14 dias pós-injeção, havia mais células ED1-positivas no grupo III. A CY aparentemente não alterou a resposta astrocitária.

Ethidium bromide-induced demyelination of the sciatic nerve of adult Wistar rats

Peripheral nerve ultrastructure was assessed after single or multiple local injections of the intercalating dye ethidium bromide. Thirty-four adult Wistar rats of both sexes were divided into five groups and maintained in a controlled environment with rat chow and water ad libitum throughout the experiment. The experimental animals were injected with 1 microl of 0.1% ethidium bromide in 0.9% saline into the central third of the left sciatic nerve 1 (group 1), 2 (group 2), 4 (group 3), 6 (group 4) or 8 (group 5) times. In groups 2 to 5 the injections were made at 28-day intervals. Control animals received the same amount of 0.9% saline. The animals were killed at different times after injection: group 1 at 7 days (2 rats) and 15 days (2 rats); for groups 2, 3, 4 and 5, all rats were killed 10 days after the last injection and the lesions were investigated by light and transmission electron microscopy. In the acute lesions, intoxicated Schwann cells showed a vacuolated cytoplasm and separation of the sheaths from the axon. Myelin sheaths underwent progressive vesiculation and subsequent segmental demyelination. Myelin debris were withdrawn by macrophages and remyelination by Schwann cells was prominent. With the increase in the number of injections collagen fibers also increased in number and progressively enveloped smaller numbers of remyelinated axons composing new fascicles. Wallerian degeneration of fibers apparently not affected by ethidium bromide was more intense in the nerves from groups 4 and 5. The peripheral nerve repairs itself after demyelinating challenges with a profusion of collagen fibers and new fasciculations. This experimental model is valid to mimic recurrent demyelinating neuropathies.

Behaviour of oligodendrocytes and Schwann cells in an experimental model of toxic demyelination of the central nervous system

Oligodendrocytes and Schwann cells are engaged in myelin production, maintenance and repairing respectively in the central nervous system (CNS) and the peripheral nervous system (PNS). Whereas oligodendrocytes act only within the CNS, Schwann cells are able to invade the CNS in order to make new myelin sheaths around demyelinated axons. Both cells have some limitations in their activities, i.e. oligodendrocytes are post-mitotic cells and Schwann cells only get into the CNS in the absence of astrocytes. Ethidium bromide (EB) is a gliotoxic chemical that when injected locally within the CNS, induce demyelination. In the EB model of demyelination, glial cells are destroyed early after intoxication and Schwann cells are free to approach the naked central axons. In normal Wistar rats, regeneration of lost myelin sheaths can be achieved as early as thirteen days after intoxication; in Wistar rats immunosuppressed with cyclophosphamide the process is delayed and in rats administered cyclosporine it may be accelerated. Aiming the enlightening of those complex processes, all events concerning the myelinating cells in an experimental model are herein presented and discussed.

[Demyelination and remyelination after multiple intramedullary injections of ethidium bromide in Wistar rats]

The ethidium bromide model of demyelination has been employed to study the central nervous system response to several episodes of demyelination. Twenty-seven Wistar rats received 2 to 4 intraspinal injections of 1 microliter of either 0.1% ethidium bromide in normal saline (19 rats) or saline 0.9% (8 rats) in different anatomical locations. The intervals between the injections ranged from 28 to 42 days. Ten days after the last injection all the rats were perfused with 2.5% glutaraldehyde. The spinal sections were evaluated macroscopically and by light and transmission electron microscopy. The lesions were typical of focal primary demyelination with preserved vascular structures and followed by remyelinization and varied in size and histological aspects. After multiple sequential ethidium bromide injections, the central nervous system seems to modify its response capacity to an inflammatory challenge although there is no change in its pattern of remyelination.

Biology of the repair of central nervous system demyelinated lesions: an appraisal

The integrity of myelin sheaths is maintained by oligodendrocytes and Schwann cells respectively in the central nervous system (CNS) and in the peripheral nervous system. The process of demyelination consisting of the withdrawal of myelin sheaths from their axons is a characteristic feature of multiple sclerosis, the most common human demyelinating disease. Many experimental models have been designed to study the biology of demyelination and remyelination (repair of the lost myelin) in the CNS, due to the difficulties in studying human material. In the ethidium bromide (an intercalating gliotoxic drug) model of demyelination, CNS remyelination may be carried out by surviving oligodendrocytes and/or by cells differentiated from the primitive cell lines or either by Schwann cells that invade the CNS. However, some factors such as the age of the experimental animals, intensity and time of exposure to the intercalating chemical and the topography of the lesions have marked influence on the repair of the tissue.

Desmielinização tóxica do sistema nervoso central: I. Ação de uma droga intercalante gliotóxica na medula espinhal de ratos Wistar

Pequenos volumes de brometo de etídio foram injetados nas colunas dorsais da medula lombar de ratos Wistar. Foi assim induzido processo desmielinizante que variou em natureza e velocidade de reparação de acordo com a dose empregada. As lesões produzidas foram classificadas em três tipos (I, rápidas; II, lentas; III, intermediárias), de acordo com as características histológicas e a extensão da remielinização. Em algumas lesões ou em áreas dentro da mesma lesão, os restos de mielina e de células gliais eram rapidamente processados por macrófagos e os axônios rapidamente remielinizados por células de Schwann, enquanto em outras lesões de duração similar, ou em áreas dentro da mesma lesão, a mielina se transformava em emaranhados de membranas que persistiam ao redor do axônio por longos períodos de tempo. Nas lesões que continham tais membranas derivadas da mielina, os macrófagos eram escassos e a remielinização, feita pelas células de Schwann, era demorada e trabalhosa. Concluiu-se que a resolução lenta de algumas lesões resultara do lapso transcorrido entre a intoxicação e o desaparecimento das células relacionadas à mielina, significando que as respostas celulares à desmielinização tiveram lugar em área livre de células gliais. Esta não podia sustentar, portanto, a movimentação celular necessária para a remoção dos restos de mielina e a posterior remielinização. Esta investigação indica que o desenvolvimento e o desfecho da desmielinização podem ser alterados pelos eventos celulares que acompanham a degeneração dos oligodendrócitos.