There are three types of muscles: skeletal, cardiac, and smooth muscle.
Each of them have distinct functions as well as structural characteristics that can be identified histologically.
These cells are often also called muscle fibers.
In this longitudinal section of skeletal muscle, the muscle fibers are the narrow strands that are all arranged in the same direction.
The muscle fibers are also arranged in parallel bundles called fascicles.
With longitudinal sections of skeletal muscle, the nuclei may not always look like they’re in the periphery, but with a transverse section, it’s much easier to visualize.
It’s also easier to identify the endomysium, which is the connective tissue that surrounds the polygonal muscle fibers.
The perimysium is also easier to identify, since it’s an even thicker layer of connective tissue that surrounds the fascicles.
Skeletal muscle has a rich network of capillaries, and if we zoom in further, we can see that the capillaries are typically seen at the corners of the polygonal muscle fibers.
Although it’s not always easy to see with H&E staining, the subtypes of skeletal muscle can sometimes be differentiated.
The muscle fibers contain many myofibrils that are made up of contractile proteins called myofilaments.
The myofilaments consist of thin actin filaments and thick myosin filaments that are arranged in parallel and also form the basic unit of the striated muscles called a sarcomere.
The myofilaments mainly consist of thin actin filaments and thick myosin filaments.
The alignment and structure of the sarcomeres result in perpendicular bands that can be seen in this image as striations that run vertically.
These striations can be seen in both skeletal and cardiac muscles.
If we take a closer look at this image, we can even identify some of the individual parts of the sarcomere that form the striations.
The A band is the thick and dark band in the middle of the sarcomere.
And the I band is the wide and light band which has a thin and dark Z disc that runs down the middle.
With electron microscopy, we’re able to obtain higher resolution images with more detail.