Gross anatomical and biometrical parameters of hippocampus in Surti buffalo (Bubalus bubalis)

2018 ◽  
Author(s):  
Harishbhai P. Gori ◽  
Subhash C. Dubal ◽  
Shabir Ahmad Malik ◽  
Sawan D. Rathwa
Keyword(s):  
White Matter ◽  
Thin Layer ◽  
Medial Temporal Lobe ◽  
Bubalus Bubalis ◽  
Caudal Part ◽  
Hippocampal Commissure ◽  
Deep Groove ◽  
Medial Surfaces ◽  
The Brain ◽  
Surti Buffalo

The present study was conducted on hippocampus of six adult Surti buffalo. Hippocampus was a small organ located within the medial temporal lobe of the brain. The hippocampus made a curve from the deep face of the piriform lobe around the thalamus and formed the caudal part of the floor of the lateral ventricle. It was separated deeply by the hippocampal fissure from the dentate gyrus. The two hippocampi were connected at their highest parts by transvers fibers which constituted the hippocampal commissure. The hippocampus was as long “C” or small “Y”shaped structure. The ventro-medial hippocampal surface had a deep groove, the hippocampal sulcus, which divided this surface into a lateral and medial surfaces. The ventricular surface of the hippocampus was covered with a thin layer of white matter, the alveus, which arises from the crus of the fornix, and was therefore continuous with the fimbria. Moreover, the uncus was not observed. Several equations showed significant (P less than 0.5) and positive co-relationship between the weight of hippocampus and the weight of brain. The ratio of weight of the hippocampus and weight of the brain was about 1: 37.

scholarly journals The angular gyrus model of consciousness

2013 ◽  
Author(s):  
Graeme E Smith
Keyword(s):  
White Matter ◽  
Temporal Lobe ◽  
Medial Temporal Lobe ◽  
Declarative Memory ◽  
Angular Gyrus ◽  
Memory Model ◽  
White Matter Tracts ◽  
Parietal Lobes ◽  
Intersection Area ◽  
The Brain

The Angular Gyrus sits at the point where the Temporal and Parietal Lobes join. It is a point where integrative processes link together the Where and What pathways through the brain and link them to time. It is also the most likely location for at least two centers of consciousness. In this article the location is discussed and it's potential for a model of consciousness that replaces the Declarative Memory Model of Consciousness previously put forward. It's main benefit over the Declarative Memory Model of Consciousness is that it allows for the preservation of consciousness despite the loss of declarative memory in the cases of Medial Temporal Lobe injury/disease. However Connectome studies might support this model in that the TemporoParietal Fiber Intersection Area provides 7 different white matter tracts that intersect in this area.

scholarly journals The angular gyrus model of consciousness

2013 ◽  
Author(s):  
Graeme E Smith
Keyword(s):  
White Matter ◽  
Temporal Lobe ◽  
Medial Temporal Lobe ◽  
Declarative Memory ◽  
Angular Gyrus ◽  
Memory Model ◽  
White Matter Tracts ◽  
Parietal Lobes ◽  
Intersection Area ◽  
The Brain

The Angular Gyrus sits at the point where the Temporal and Parietal Lobes join. It is a point where integrative processes link together the Where and What pathways through the brain and link them to time. It is also the most likely location for at least two centers of consciousness. In this article the location is discussed and it's potential for a model of consciousness that replaces the Declarative Memory Model of Consciousness previously put forward. It's main benefit over the Declarative Memory Model of Consciousness is that it allows for the preservation of consciousness despite the loss of declarative memory in the cases of Medial Temporal Lobe injury/disease. However Connectome studies might support this model in that the TemporoParietal Fiber Intersection Area provides 7 different white matter tracts that intersect in this area.

scholarly journals The angular gyrus model of consciousness

2013 ◽  
Author(s):  
Graeme E Smith
Keyword(s):  
White Matter ◽  
Temporal Lobe ◽  
Medial Temporal Lobe ◽  
Declarative Memory ◽  
Angular Gyrus ◽  
Memory Model ◽  
White Matter Tracts ◽  
Parietal Lobes ◽  
Intersection Area ◽  
The Brain

The Angular Gyrus sits at the point where the Temporal and Parietal Lobes join. It is a point where integrative processes link together the Where and What pathways through the brain and link them to time. It is also the most likely location for at least two centers of consciousness. In this article the location is discussed and it's potential for a model of consciousness that replaces the Declarative Memory Model of Consciousness previously put forward. It's main benefit over the Declarative Memory Model of Consciousness is that it allows for the preservation of consciousness despite the loss of declarative memory in the cases of Medial Temporal Lobe injury/disease. However Connectome studies might support this model in that the TemporoParietal Fiber Intersection Area provides 7 different white matter tracts that intersect in this area.

scholarly journals Gyrification Index and Encephalizaton Quotient of Brain of Surti Buffalo (Bubalus bubalis)

2018 ◽  
Vol 14 (1) ◽  
Author(s):  
Alka Suman ◽  
Sweta Pandya
Keyword(s):  
Cerebral Cortex ◽  
Bubalus Bubalis ◽  
Mean Value ◽  
Cerebral Hemispheres ◽  
Exposed Surface ◽  
Brain Mass ◽  
Encephalization Quotient ◽  
Gyrification Index ◽  
The Brain ◽  
Surti Buffalo

The brain of Surti buffaloes presents many cortical foldings. These are called gyrification. In the present study on brain of 12 Surti buffaloes, the folded cerebral hemispheres presented various sulci and gyri of different sizes. Gyrification Index (GI) was measured by the sum of the complete exposed surface and superficially exposed surface of cerebral cortex. The overall mean value of gyrification index of both of cerebral hemispheres was 2.52±0.02. The Encephalization Quotient (EQ) is the ratio of brain mass to body mass, which gives rough estimate of the intelligence of the Surti buffaloes. The overall mean value of encephalization quotient of Surti buffaloes was found to be 0.74.

Characterization of Ischemic Stroke in CT Images using Image Processing

2017 ◽  
Vol 7 (9) ◽  
pp. 18
Author(s):  
Amal Alzain ◽  
Suhaib Alameen ◽  
Rani Elmaki ◽  
Mohamed E. M. Gar-Elnabi
Keyword(s):  
Ischemic Stroke ◽  
White Matter ◽  
Classification Accuracy ◽  
Ct Images ◽  
Gray Level ◽  
Level Variation ◽  
Interactive Data ◽  
The Brain ◽  
Brain Tissues

This study concern to characterize the brain tissues to ischemic stroke, gray matter, white matter and CSF using texture analysisto extract classification features from CT images. The First Order Statistic techniques included sevenfeatures. To find the gray level variation in CT images it complements the FOS features extracted from CT images withgray level in pixels and estimate the variation of thesubpatterns. analyzing the image with Interactive Data Language IDL software to measure the grey level of images. The results show that the Gray Level variation and   features give classification accuracy of ischemic stroke 97.6%, gray matter95.2%, white matter 97.3% and the CSF classification accuracy 98.0%. The overall classification accuracy of brain tissues 97.0%.These relationships are stored in a Texture Dictionary that can be later used to automatically annotate new CT images with the appropriate brain tissues names.

What Has Direct Cortical and Subcortical Electrostimulation Taught Us about Neurolinguistics?

2019 ◽  
pp. 185-211
Author(s):  
Hugues Duffau
Keyword(s):  
White Matter ◽  
Large Scale ◽  
Functional Neuroimaging ◽  
Great Accuracy ◽  
Subcortical White Matter ◽  
Cerebral Lesions ◽  
Physiological Basis ◽  
Postoperative Mri ◽  
The Brain

Investigating the neural and physiological basis of language is one of the most important challenges in neurosciences. Direct electrical stimulation (DES), usually performed in awake patients during surgery for cerebral lesions, is a reliable tool for detecting both cortical and subcortical (white matter and deep grey nuclei) regions crucial for cognitive functions, especially language. DES transiently interacts locally with a small cortical or axonal site, but also nonlocally, as the focal perturbation will disrupt the entire subnetwork sustaining a given function. Thus, in contrast to functional neuroimaging, DES represents a unique opportunity to identify with great accuracy and reproducibility, in vivo in humans, the structures that are actually indispensable to the function, by inducing a transient virtual lesion based on the inhibition of a subcircuit lasting a few seconds. Currently, this is the sole technique that is able to directly investigate the functional role of white matter tracts in humans. Thus, combining transient disturbances elicited by DES with the anatomical data provided by pre- and postoperative MRI enables to achieve reliable anatomo-functional correlations, supporting a network organization of the brain, and leading to the reappraisal of models of language representation. Finally, combining serial peri-operative functional neuroimaging and online intraoperative DES allows the study of mechanisms underlying neuroplasticity. This chapter critically reviews the basic principles of DES, its advantages and limitations, and what DES can reveal about the neural foundations of language, that is, the large-scale distribution of language areas in the brain, their connectivity, and their ability to reorganize.

THE METABOLISM OF NORMAL BRAIN AND HUMAN GLIOMAS IN RELATION TO CELL TYPE AND DENSITY

1955 ◽  
Vol 33 (3) ◽  
pp. 395-403 ◽  
Author(s):  
Irving H. Heller ◽  
K. A. C. Elliott
Keyword(s):  
Cerebral Cortex ◽  
White Matter ◽  
Brain Tumors ◽  
Corpus Callosum ◽  
Oxygen Uptake ◽  
Glial Cells ◽  
Cerebellar Cortex ◽  
Unit Weight ◽  
Uptake Rates ◽  
The Brain

Per unit weight, cerebral and cerebellar cortex respire much more actively than corpus callosum. The rate per cell nucleus is highest in cerebral cortex, lower in corpus callosum, and still lower in cerebellar cortex. The oxygen uptake rates of the brain tumors studied, with the exception of an oligodendroglioma, were about the same as that of white matter on the weight basis but lower than that of cerebral cortex or white matter on the cell basis. In agreement with previous work, an oligodendroglioma respired much more actively than the other tumors. The rates of glycolysis of the brain tumors per unit weight were low but, relative to their respiration rate, glycolysis was higher than in normal gray or white matter. Consideration of the figures obtained leads to the following tentative conclusions: Glial cells of corpus callosum respire more actively than the neurons of the cerebellar cortex. Neurons of the cerebral cortex respire on the average much more actively than neurons of the cerebellar cortex or glial cells. Considerably more than 70% of the oxygen uptake by cerebral cortex is due to neurons. The oxygen uptake rates of normal oligodendroglia and astrocytes are probably about the same as the rates found per nucleus in an oligodendroglioma and in astrocytomas; oligodendroglia respire much more actively than astrocytes.

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