Synapses Collection (#2)

Neural network, artwork C013 / 4636
Neural network. Computer artwork of nerve cells (neurons) connected by processes (filaments), known as dendrites and axons, to form a neural network

Neuromuscular synapse, light micrograph
Neuromuscular junction. Fluorescent confocal light micrograph of the junction between a nerve cell and a muscle (not seen). The axon of the nerve cell (neuron) has been tagged with a blue dye

Brain nerve cells
Nerve cells in the brain. Artwork showing the different types of nerve cells in the grey matter of the brain. Neurons (yellow, for example at lower right) relay nerve signals around the brain

Vomiting, artwork
Vomiting. Computer artwork of synapses, or junctions, (cones) between nerve cells and the exterior wall of the stomach. During the vomit reflex, nerve impulses are sent from the brain to the stomach

Nerve cell synapses, computer artwork
Nerve cell synapses. Computer artwork of the chemical synapses between two nerve cells, or neurons, (one red and one blue)

Synapse, computer artwork
Synapses. Computer artwork of synapses, the junctions between the ends (blue, swollen) of two nerve cells (neurons). Nerve cells are responsible for passing information around the central nervous

Brain activity, computer artwork
Brain activity, conceptual artwork. The brain activity is represented by firing chemical synapses (green). Chemical synapses are junctions through which the cells of the nervous system signal to each

Neurological drug treatment, artwork
Neurological drug treatment, conceptual image. Computer artwork representing the use of drugs that affect neural networks by altering the transmission of neurotransmitters across synapses (blue)

Muscle motor neurones, light micrograph
Muscle motor neurones. Light micrograph of dendrites (axons, black) from motor nerve cells (motor neurones) in muscle tissue (pink-purple strands)

Nerve synapse, artwork
Nerve synapse. Computer artwork of of a junction, or synapse, between two nerve cells (neurons). As the electrical signal reaches the presynaptic end of a neuron it triggers the release of

Neural network. Artwork of nerve cells (neurons, green) connected by nerve processes (dendrites and axons) to form a neural network

Nerve cell synapse, computer artwork. Nerve cells, or neurons, are responsible for passing information around the central nervous system (CNS) and from the CNS to the rest of the body

Neuromuscular junctions, artwork
Neuromuscular junctions. Computer artwork of junctions between nerves (thread-like objects) and a muscle (purple surface)

Synapses, artwork
Synapses. Computer artwork of synapses, the junctions between the ends (green, swollen) of two nerve cells (neurons). Signals are passed along nerve cells in the form of an electrical impulse

Nerve cells and synapses. Computer artwork of nerve cells, or neurons with synapses

Neural network, abstract artwork
Neural network. Abstract computer artwork representing nerve cells, or neurons. Neurons are responsible for passing information around the central nervous system (CNS)

Brain activity, artwork
Brain activity. Computer artwork showing activity (red) in the frontal (left) and temporal (centre) lobes of a human brain. The front of the brain is at left

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"Unraveling the Intricacies of Synapses: A Window into Schizophrenia and Beyond" In the vast realm of neuroscience, synapses stand as the fundamental building blocks that enable communication between nerve cells. Like intricate bridges connecting one neuron to another, these synapses play a pivotal role in shaping our thoughts, emotions, and actions. Through mesmerizing computer artwork depicting cross-section biomedical illustrations, we delve into the captivating world of synapses. One such illustration showcases how these synaptic connections can shed light on schizophrenia—a complex mental disorder characterized by distorted perceptions and impaired cognition. As scientists unravel the mysteries surrounding this condition, understanding aberrant synaptic functioning emerges as a key focus for potential breakthroughs. Beyond psychiatric disorders lies another intriguing facet—how ecstasy affects brain function. Exploring this topic reveals an astonishing interplay between synthetic substances and delicate neural networks. Computer-generated images offer glimpses into how ecstasy alters synaptic transmission, providing valuable insights into its short-term euphoric effects and long-term consequences on cognitive abilities. Venturing further within these artistic renderings, we encounter a stunning cross-section biomedical illustration illustrating how nerve cells in the retina respond to light stimuli through specialized structures called rods and cones. This visual masterpiece unravels nature's ingenious design behind vision perception—an intricate dance orchestrated by countless synapses working harmoniously to transform light signals into vivid sensory experiences. As our journey continues through this gallery of scientific artistry, various artworks showcasing nerve cell synapses captivate our attention—their vibrant hues capturing both their beauty and complexity. These masterpieces serve as reminders that beneath their aesthetic allure lie profound mechanisms governing human existence. From schizophrenia research to exploring drug-induced alterations in brain function or unveiling the intricacies of visual perception—the study remains at the forefront of cutting-edge neuroscience. With each stroke of an artist's brush or pixel meticulously placed on a screen, we inch closer towards comprehending these microscopic marvels that shape our very being.