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Related Concept Videos

Anatomical Positions01:11

Anatomical Positions

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In anatomy, several standard anatomical positions are used as references for describing the position and orientation of different body parts. These positions help provide a common frame of reference when discussing anatomical structures. The anatomical position is the standard reference point for describing the body's position and orientation. In this position:
The body is upright, facing forward, and standing erect.
The feet are parallel and flat on the floor.
The arms are hanging by the...
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Anatomical Terminology01:20

Anatomical Terminology

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Knowledge of anatomy is essential to understand human biology and medicine. Anatomists and health care professionals use standard terminology to describe the human body with more precision and no ambiguity. Anatomical terms have mostly Greek and Latin-derived roots. Because these languages are rarely used in conversation, the meaning of words remains the same. Each term is made up of a root in between the prefixes and suffixes. The root of a term often refers to an organ, tissue, or condition,...
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Anatomical Movements00:51

Anatomical Movements

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Anatomical movements refer to the various actions or motions that can be performed by the body's joints and muscles. These movements are described using specific terms to provide a standardized way of discussing and understanding the range of motion at different joints.
Here are some common anatomical movements:
Flexion and extension motions are in the sagittal (anterior–posterior) plane of motion. These movements take place at the shoulder, hip, elbow, knee, wrist,...
16.1K
Cerebrum: Anatomical Overview II01:11

Cerebrum: Anatomical Overview II

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Each cerebral hemisphere can be divided into three main regions. The outermost region, the cerebral cortex, is a thin layer (2 to 4 millimeters thick) made up of gray matter, consisting of neuron cell bodies, dendrites, glial cells, and blood vessels. The middle region, or white matter, is primarily composed of myelinated nerve fibers organized into three types of large tracts: association fibers, commissures, and projection fibers. Association fibers connect different areas within the same...
5.0K
Diencephalon: Anatomical Regions01:30

Diencephalon: Anatomical Regions

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The diencephalon, etymologically translated as 'through brain,' plays an integral role as the conduit between the cerebrum and the vast extent of the nervous system. However, the olfactory system is an exception, as it interfaces directly with the cerebrum. The diencephalon, deeply ensconced beneath the cerebrum, primarily consists of three paired structures — the thalamus, hypothalamus, and epithelamus. It also includes accessory structures such as the subthalamus, which houses the...
5.4K
Cerebellum: Anatomical Regions01:17

Cerebellum: Anatomical Regions

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The cerebellum, also known as the "little brain," is located in the posterior cranial fossa, inferior to the tentorium cerebelli and dorsal to the brainstem. It plays a significant role in motor control, coordination, and proprioception.
Cerebellar Structure
Externally, the cerebellum features a highly convoluted surface with numerous folia (narrow ridges) separated by shallow sulci (grooves). The cerebellum is divided into two hemispheres by a thin median structure known as the vermis. The...
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Exploiting Anatomical Landmarks for Efficient In Vivo CLEM.

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Researchers developed a new, simpler method for 3D correlative light and electron microscopy in mouse brains. This label-free approach eliminates the need for artificial fiducials, streamlining the process.

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Area of Science:

  • Neuroscience
  • Microscopy
  • Cell Biology

Background:

  • Correlating light and electron microscopy is crucial for understanding cellular structures.
  • Existing methods often rely on artificial fiducials and anatomical landmarks, which are complex and cumbersome.
  • A need exists for more efficient and accessible correlative microscopy techniques.

Purpose of the Study:

  • To introduce a novel, label-free workflow for 3D correlative light and electron microscopy (CLEM).
  • To simplify the process of correlating high-resolution ultrastructural information with dynamic cellular processes observed in vivo.
  • To demonstrate the applicability of this new method in the mouse brain.

Main Methods:

  • Development of a new workflow integrating intravital microscopy with electron microscopy.
  • Utilizing label-free techniques, avoiding the need for artificial fiducials.
  • Application of the method to image mouse brain tissue.

Main Results:

  • Successful implementation of a label-free 3D correlative light and electron microscopy workflow.
  • Demonstration of a streamlined and less cumbersome correlation process compared to established protocols.
  • Acquisition of high-resolution 3D ultrastructural data correlated with live-cell imaging in the mouse brain.

Conclusions:

  • The new workflow significantly simplifies 3D correlative light and electron microscopy.
  • Label-free correlation offers a more efficient alternative to traditional methods relying on fiducials.
  • This advancement facilitates detailed ultrastructural analysis in conjunction with dynamic biological processes within the mouse brain.