Examples of appendicular skeleton in the following topics:
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- In the human body, the appendicular skeleton is unfused (unlike the axial skeleton), which allows for a much greater range of motion.
- The appendicular skeleton is composed of 126 bones.
- Note that these areas may include other bones that are not a part of the appendicular skeleton; they are instead a part of the axial skeleton.
- The femur, tibia, patella, and fibula are all a part of the appendicular skeleton.
- The appendicular skeleton is composed of the six major regions shown here.
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- The appendicular skeleton includes the skeletal elements
within the limbs, as well as supporting pectoral
and pelvic
girdles.
- The appendicular skeleton
of vertebrates, including humans, consists of the bones that support and compose the appendages
(for example, the arms and legs of humans).
- The appendicular skeleton includes the skeletal elements
within the limbs, as well as supporting the pectoral
and pelvic
girdles.
- The
appendicular skeleton comprises 126 bones and is involved in locomotion and
manipulation of objects in the environment.
- Image depicting the human skeleton with the appendicular skeleton colored red.
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- The skeletal system is divided into two distinct divisions: the axial skeleton and the appendicular system.
- As a result, an average adult skeleton consists of 206 bones .
- It is a complex structure with two distinct divisions: the axial and the appendicular skeletons.
- The appendicular skeleton is composed of 126 bones in the human body.
- Differentiate the purpose and the number of bones of the axial and appendicular skeletons
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- The axial skeleton functions to support and protect the organs of
the dorsal and ventral cavities and serves as a surface for the attachment
of muscles and parts of the appendicular skeleton.
- The axial skeleton is the part of the skeleton
that consists of the bones of
the head and trunk of
a vertebrate
animal, including humans.
- It also serves as a surface for the attachment
of muscles and parts of the appendicular skeleton.
- The human’s axial skeleton is composed of 80
bones and is the central core of the body.
- The primary divisions of the
skeleton system are:
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- The axial skeleton consists of the 80 bones along the central axis of the human body.
- The axial skeleton consists of the 80 bones along the central axis of the human body.
- The axial skeleton and the appendicular skeleton together form the complete skeleton.
- The human rib cage, also known as the thoracic cage, is a bony and cartilaginous structure which surrounds the thoracic cavity and supports the pectoral girdle, forming a core portion of the human skeleton.
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- The cardiac skeleton, also known the heart's fibrous skeleton, consists of dense connective tissue in the heart that separates the atria from the ventricles.
- The cardiac skeleton, or fibrous skeleton of the heart, is the structure of dense connective tissue that separates the atria from the ventricles.
- The fibrous skeleton provides critical support for the heart and separates the flow of electrical impulses through the heart.
- The fibrous skeleton of the heart acts as an insulator for the flow of electrical current across the heart.
- The fibrous skeleton of the heart also protects against cardiac arrhythmias.
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- The Appendicular Region makes up the parts of the human body that connect to the axial region.
- These are the two basic categories of regional terms; however, many other terms are used to describe smaller regions within the axial and appendicular regions.
- For example, the brachial region consists of the arm as a part of the appendicular region, while the abdominal region consists of the abdomen as a smaller part of the axial region.
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- Early in gestation, a fetus has a cartilaginous skeleton that becomes skeletal bones in the gradual process of endochondral ossification.
- Early in gestation, a fetus has a cartilaginous skeleton from which the long bones and most other bones gradually form throughout the remaining gestation period and for years after birth in a process called endochondral ossification.