Several studies have demonstrated that the accurate visualization and quantification of pathological lesions in neurodegenerative disorders depend on the reliability of staining methods. In an attempt to gain a better assessment of the density and distribution of the neuropathological markers of Alzheimer's disease, we compared the staining efficiency of a modified thioflavine S protocol for neurofibrillary tangles (NFT) and senile plaques (SP) to different argentic impregnation techniques (Bielchowsky, Gallyas, Globus, Campbell-Switzer-Martin) and to immunohistochemical stainings obtained with two different antibodies against the amyloid beta protein A4 and the microtubule-associated tau protein. The modified thioflavine S technique (MTST) detects up to 60% more SP and up to 50% more NFT than the Bielschowsky and Globus methods, respectively. The results obtained with the specific antibodies are comparable to those obtained with the MTST, but these immunotechniques are more expensive and time consuming for routine neuropathological evaluation, and the appropriate antibodies are not always commercially available. Furthermore, the morphological appearance of NFT and SP with MTST is greatly improved when compared to the classical thioflavine S and the increased signal-to-noise ratio between specifically stained structures and background permits an accurate semi-automatic quantification.
Large differences are usually observed when standard staining methods for a number of pathological lesions in neurodegenerative disorders are compared. With the modified thioflavine S method presented here (easy and cheap to perform), the morphological appearance of the stained neurofibrillary tangles (NFT) and senile plaques (SP) is greatly improved. Furthermore, the intense contrast between stained lesions and background obtained with this technique permits an accurate automatic quantification of NFT and SP using a computer-assisted image analysis system.
Floating sections from human brains immersed for more than forty years in formalin, or from brains freshly fixed for a short time are treated by KMnO4-Pal's modified solutions to suppress the endogenous peroxidase activity before using the peroxidase-antiperoxidase method (PAP), or to remove the autofluorescence of lipofuscin, which is very intense in brains from old patients, before using the immunofluorescence method. Following this, immersion of sections in NaOH and H2O2 allows for the demasking of antigenic sites. These treatments enhance the immunolabelling considerably, with results comparable to those obtained with freshly fixed tissues, and facilitate the discrimination between specifically and unspecifically stained structures.
The distribution of delta sleep inducing peptide (DSIP) in the rabbit brain has been studied with immunohistochemical techniques. DSIP-like immunoreactivity was predominantly detected in the basal forebrain, hypothalamus and hypophysis. Even in colchicine-pretreated animals, immunolabeled cell bodies were relatively few. They were mostly scattered through the ventrolateral septum, the diagonal band of Broca and preoptic areas. Clusters of positive cell bodies were also found in the arcuate nucleus and adjacent lateral hypothalamic areas. Large populations of varicose fibers and terminal-like structures were observed in the juxtaventricular zone of the ventrolateral septum, in the preoptic areas and lamina terminalis especially around the preoptic recess of the third ventricle and more caudally, in the ventromedial nucleus of the hypothalamus. Dense networks of immunolabeled fibers were visualized in the median eminence and pituitary stalk where many fibers could be seen in close apposition to the capillaries. Many DSIP-immunoreactive fibers were observed in the subfornical organ. Other extra-hypothalamic regions displaying a low-to-moderate density of immunoreactive fibers were the indusium griseum, the hippocampus, the fimbria of the fornix, the subcommissural organ, the medial habenula and, occasionally, the medial periaqueductal gray. Most cells of the pars intermedia and a few cells of the pars distalis of the anterior pituitary were DSIP-immunoreactive. Taken together these results in the rabbit brain emphasize the predominant localization of DSIP-like immunoreactivity in areas related to the hypothalamic neurosecretory systems.
The authors have developed a method which makes it possible, for the first time, to visualize the delta sleep-inducing peptide in histological preparations and study it under the light and fluorescence microscope. Their research builds on Monnier’s discovery, in 1963, of a humoral hypnogenic factor in rabbits which was subsequently isolated and identified as a nonapeptide. Dubbed delta sleep-inducing peptide (DSIP), this factor was later detected in rat brain by radioimmunoassay but has eluded histological visualization until recently. In their work, the authors used an anti-DSIP antiserum suitable for immunohistological purposes. Two indirect immunohistological methods (PAP and immunofluorescence) allowed them to visualize, for the first time, structures containing specific DSIP-like immunoreactivity in some areas of the rat brain: indusium griseum, nucleus septi lateralis, hippocampus, striae longitudinales of Lancisi, bandeletta diagonalis of Broca, pallidum, hypothalamus, hypophysis and neocortex. Some DSIP pathways seem likely: (1) indusium griseum – striae longitudinales – hippocampus; (2) nucleus septi lateralis – striae longitudinales, bandeletta diagonalis – hippocampus; (3) neurons of the pyramidal layer of the hippocampus – gyms dentatus; (4) pallidum – commissura of Ganser – hypothalamus. The possible correlations between DSIP neurons and neurons with other neurotransmitters are discussed. In preliminary clinical trials, DSIP has shown promise for the treatment of insomnia and the opiate and alcohol withdrawal syndromes. Apart from the influence of DSIP on sleep and its possible role in addiction, the authors discuss the part which may be played by the limbic DSIP systems in instinctive-affective and memory mechanisms, and their possible involvement in psychosis and Alzheimer’s disease. Studies on DSIP have opened up new perspectives for research on the mechanisms of sleep, memory, drug addiction"(and possibly even of psychosis and Alzheimer’s disease) and their treatment.
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