Network science and the human brain: Using graph theory to understand the brain and one of its hubs, the amygdala, in health and disease

Picolinic Acid is an endogenous metabolite of L-tryptophan (TRP) that has been reported to possess a wide range of neuroprotective, immunological, and anti-proliferative affects within the body. However the salient physiological function of this molecule is yet to be established. The synthesis of picolinic acid as a product of the kynurenine pathway (KP) suggests that, similar to other KP metabolites, picolinic acid may play a role in the pathogenesis of inflammatory disorders within the CNS and possibly other organs. In this paper we review the limited body of literature dealing with the physiological actions of picolinic acid in the CNS and its associated synthesis via the kynurenine pathway in health and disease. Discrepancies and gaps in our current knowledge of picolinic acid are identified highlighting areas of research to promote a more complete understanding of its endogenous function in the brain.

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Role of Graph Theory in Computational Neuroscience

10.4018/978-1-7998-7433-1.ch005 ◽

2022 ◽

pp. 86-97

Author(s):

Hitesh Marwaha ◽

Anurag Sharma ◽

Vikrant Sharma

Keyword(s):

Graph Theory ◽

Human Brain ◽

Computational Neuroscience ◽

Cognitive Functions ◽

Special Focus ◽

Meaningful Information ◽

Different Types ◽

The Brain ◽

Vertex Centrality

Neuroscience is the study of the brain and its impact on behavior and cognitive functions. Computational neuroscience is the subfield that deals with the study of the ability of the brain to think and compute. It also analyzes various electrical and chemical signals that take place in the brain to represent and process the information. In this chapter, a special focus will be given on the processing of signals by the brain to solve the problems. In the second section of the chapter, the role of graph theory is discussed to analyze the pattern of neurons. Graph-based analysis reveals meaningful information about the topological architecture of human brain networks. The graph-based analysis also discloses the networks in which most nodes are not neighbors of each other but can be reached from every other node by a small number of steps. In the end, it is concluded that by using the various operations of graph theory, the vertex centrality, betweenness, etc. can be computed to identify the dominant neurons for solving different types of computational problems.

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Human brain atlasing: past, present and future

The Neuroradiology Journal ◽

10.1177/1971400917739274 ◽

2017 ◽

Vol 30 (6) ◽

pp. 504-519 ◽

Cited By ~ 8

Author(s):

Wieslaw L Nowinski

Keyword(s):

Human Brain ◽

Large Scale ◽

State Of The Art ◽

The State ◽

Brain Atlas ◽

Future Directions ◽

Human Connectome Project ◽

Health And Disease ◽

The Brain ◽

Brain Atlases

We have recently witnessed an explosion of large-scale initiatives and projects addressing mapping, modeling, simulation and atlasing of the human brain, including the BRAIN Initiative, the Human Brain Project, the Human Connectome Project (HCP), the Big Brain, the Blue Brain Project, the Allen Brain Atlas, the Brainnetome, among others. Besides these large and international initiatives, there are numerous mid-size and small brain atlas-related projects. My contribution to these global efforts has been to create adult human brain atlases in health and disease, and to develop atlas-based applications. For over two decades with my R&D lab I developed 35 brain atlases, licensed to 67 companies and made available in about 100 countries. This paper has two objectives. First, it provides an overview of the state of the art in brain atlasing. Second, as it is already 20 years from the release of our first brain atlas, I summarise my past and present efforts, share my experience in atlas creation, validation and commercialisation, compare with the state of the art, and propose future directions.

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Frontier concept of rabi chip for intelligent humanoid

Journal of Analytical Chromatography and Spectroscopy ◽

10.24294/jacs.v1i2.908 ◽

2018 ◽

Vol 1 (2) ◽

Author(s):

Preecha Yupapin ◽

Amiri I. S. ◽

Ali J. ◽

Ponsuwancharoen N. ◽

Youplao P.

Keyword(s):

Human Brain ◽

Brain Function ◽

Rabi Oscillation ◽

Liquid Core ◽

Brain Surface ◽

Dipole Oscillation ◽

On Chip ◽

The Brain ◽

Robotic Applications ◽

Atom System

The sequence of the human brain can be configured by the originated strongly coupling fields to a pair of the ionic substances(bio-cells) within the microtubules. From which the dipole oscillation begins and transports by the strong trapped force, which is known as a tweezer. The tweezers are the trapped polaritons, which are the electrical charges with information. They will be collected on the brain surface and transport via the liquid core guide wave, which is the mixture of blood content and water. The oscillation frequency is called the Rabi frequency, is formed by the two-level atom system. Our aim will manipulate the Rabi oscillation by an on-chip device, where the quantum outputs may help to form the realistic human brain function for humanoid robotic applications.

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TIMELESS BUILDINGS AND THE HUMAN BRAIN: The Effect of Spiritual Spaces on Human Brain Waves

International Journal of Architectural Research Archnet-IJAR ◽

10.26687/archnet-ijar.v8i1.329 ◽

2014 ◽

Vol 8 (1) ◽

pp. 133

Author(s):

Sally M. Essawy ◽

Basil Kamel ◽

Mohamed S. Elsawy

Keyword(s):

Human Brain ◽

Case Studies ◽

Spiritual Experience ◽

Brain Wave ◽

Human Comfort ◽

Beliefs And Practices ◽

Brain Waves ◽

Space Design ◽

State Of Mind ◽

The Brain

Some buildings hold certain qualities of space design similar to those originated from nature in harmony with its surroundings. These buildings, mostly associated with religious beliefs and practices, allow for human comfort and a unique state of mind. This paper aims to verify such effect on the human brain. It concentrates on measuring brain waves when the user is located in several spots (coordinates) in some of these buildings. Several experiments are conducted on selected case studies to identify whether certain buildings affect the brain wave frequencies of their users or not. These are measured in terms of Brain Wave Frequency Charts through EEG Device. The changes identified on the brain were then translated into a brain diagram that reflects the spiritual experience all through the trip inside the selected buildings. This could then be used in architecture to enhance such unique quality.

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Art and the Brain’s Reward System

10.1093/oso/9780190927929.003.0008 ◽

2018 ◽

Author(s):

Henrik Hogh-Olesen

Keyword(s):

Human Brain ◽

Reward System ◽

Human Existence ◽

Brain Scans ◽

System P ◽

The Aesthetic ◽

The Brain ◽

Reward Circuit

Chapter 7 takes the investigation of the aesthetic impulse into the human brain to understand, first, why only we—and not our closest relatives among the primates—express ourselves aesthetically; and second, how the brain reacts when presented with aesthetic material. Brain scans are less useful when you are interested in the Why of aesthetic behavior rather than the How. Nevertheless, some brain studies have been ground-breaking, and neuroaesthetics offers a pivotal argument for the key function of the aesthetic impulse in human lives; it shows us that the brain’s reward circuit is activated when we are presented with aesthetic objects and stimuli. For why reward a perception or an activity that is evolutionarily useless and worthless in relation to human existence?

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Is There a Brain Microbiome?

Neuroscience Insights ◽

10.1177/26331055211018709 ◽

2021 ◽

Vol 16 ◽

pp. 263310552110187

Author(s):

Christopher D Link

Keyword(s):

Animal Models ◽

Human Brain ◽

Neurodegenerative Diseases ◽

Ground Truth ◽

Healthy Human ◽

Strong Motivation ◽

The Many ◽

The Brain

Numerous studies have identified microbial sequences or epitopes in pathological and non-pathological human brain samples. It has not been resolved if these observations are artifactual, or truly represent population of the brain by microbes. Given the tempting speculation that resident microbes could play a role in the many neuropsychiatric and neurodegenerative diseases that currently lack clear etiologies, there is a strong motivation to determine the “ground truth” of microbial existence in living brains. Here I argue that the evidence for the presence of microbes in diseased brains is quite strong, but a compelling demonstration of resident microbes in the healthy human brain remains to be done. Dedicated animal models studies may be required to determine if there is indeed a “brain microbiome.”

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DNA Methylation Profiles of Tph1A and BDNF in Gut and Brain of L. Rhamnosus-Treated Zebrafish

Biomolecules ◽

10.3390/biom11020142 ◽

2021 ◽

Vol 11 (2) ◽

pp. 142

Author(s):

Mariella Cuomo ◽

Luca Borrelli ◽

Rosa Della Monica ◽

Lorena Coretti ◽

Giulia De Riso ◽

...

Keyword(s):

Dna Methylation ◽

Molecular Mechanisms ◽

The Past ◽

Targeted Analysis ◽

Lack Of Information ◽

High Resolution Power ◽

Resolution Level ◽

Health And Disease ◽

High Doses ◽

The Brain

The bidirectional microbiota–gut–brain axis has raised increasing interest over the past years in the context of health and disease, but there is a lack of information on molecular mechanisms underlying this connection. We hypothesized that change in microbiota composition may affect brain epigenetics leading to long-lasting effects on specific brain gene regulation. To test this hypothesis, we used Zebrafish (Danio Rerio) as a model system. As previously shown, treatment with high doses of probiotics can modulate behavior in Zebrafish, causing significant changes in the expression of some brain-relevant genes, such as BDNF and Tph1A. Using an ultra-deep targeted analysis, we investigated the methylation state of the BDNF and Tph1A promoter region in the brain and gut of probiotic-treated and untreated Zebrafishes. Thanks to the high resolution power of our analysis, we evaluated cell-to-cell methylation differences. At this resolution level, we found slight DNA methylation changes in probiotic-treated samples, likely related to a subgroup of brain and gut cells, and that specific DNA methylation signatures significantly correlated with specific behavioral scores.

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A bigger brain for a more complex environment

Reviews in the Neurosciences ◽

10.1515/revneuro-2020-0041 ◽

2020 ◽

Vol 31 (8) ◽

pp. 803-816

Author(s):

Umberto di Porzio

Keyword(s):

Human Brain ◽

Cognitive Abilities ◽

Molecular Genetic ◽

Adult Size ◽

Genetic Changes ◽

Cultural Challenges ◽

Birth Canal ◽

Newborn Brain ◽

Neuronal Interactions ◽

The Brain

AbstractThe environment increased complexity required more neural functions to develop in the hominin brains, and the hominins adapted to the complexity by developing a bigger brain with a greater interconnection between its parts. Thus, complex environments drove the growth of the brain. In about two million years during hominin evolution, the brain increased three folds in size, one of the largest and most complex amongst mammals, relative to body size. The size increase has led to anatomical reorganization and complex neuronal interactions in a relatively small skull. At birth, the human brain is only about 20% of its adult size. That facilitates the passage through the birth canal. Therefore, the human brain, especially cortex, develops postnatally in a rich stimulating environment with continuous brain wiring and rewiring and insertion of billions of new neurons. One of the consequence is that in the newborn brain, neuroplasticity is always turned “on” and it remains active throughout life, which gave humans the ability to adapt to complex and often hostile environments, integrate external experiences, solve problems, elaborate abstract ideas and innovative technologies, store a lot of information. Besides, hominins acquired unique abilities as music, language, and intense social cooperation. Overwhelming ecological, social, and cultural challenges have made the human brain so unique. From these events, as well as the molecular genetic changes that took place in those million years, under the pressure of natural selection, derive the distinctive cognitive abilities that have led us to complex social organizations and made our species successful.

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