1. What is a joint? The Joints
A site where two or more bones come together, whether or not movement occurs between them, is called a Joint

2. pertaining to the joint
Articulation
Means
pertaining to the joint
e.g. articular surface of the bone, articular artery, articular nerve etc.

3. Classification of the Joints
Joints are classified according to the tissues that lie between the bones
They are
Fibrous
Synovial
Cartilaginous

4. Sutures of the skull
1- Fibrous Joint
The articulating surfaces of the bones are joined by fibrous tissue, and thus very little movement is possible. The sutures of the vault of the skull and the inferior tibiofibular joints are examples of fibrous joints.

5. There are 3 subtypes of fibrous joints:
1.Suture:
Bones are held together by a thin layer of dense fibrous tissue and also by interlocking projections of the bones. The connecting fibers holding bones together are short. This type of joint occurs only in the skull: cranial sutures

6. 2. Syndesmoses:
Bones are held together by a cord or sheet of dense fibrous connective tissue. The connecting fibers holding bones together are long. The tibia/fibula joint and the interosseous membrane connecting the radius and ulna along their length, are syndesmosis.

7. 3.Gomphosis:
It is a peg-in-socket fibrous joint. The only examples are the articulations of teeth (the peg) with their alveolar sockets in the mandible or the maxillae. The thin fibrous membrane that hold teeth inside their alveolar sockets is called the periodontal ligament.

8. 2- Cartilaginous Joint
In cartilaginous joints the bones are united with each other by cartilage.
There is NO JOINT CAVITY.

9. There are two subtypes of cartilaginous joints:
Primary cartilaginous joints (synchondroses):
A plate of hyaline cartilage connects the bones at the joint. Only hyaline cartilage is involved, not moveable. An example is the cartilaginous epiphyseal plate which separates the epiphysis from the diaphysis in long bones during growth. These joints are immoveable (synarthroses) and are replaced by bone in the adult.

10. 2. Secondary cartilaginous joints (symphyses)
It involves both hyaline and fibrocartilage. The articular surface of each bone is covered with a thin layer of hyaline cartilage, and fibrocartilage unites these two layers. Limited movement is permitted at such joints, depending on the thickness of the fibrocartilage pad which can be compressed or stretched.
Two important examples are the pubic symphysis and the intervertebral discs.

11. 3-Synovial Joint Characterized by:
The articular surfaces of the bones are covered by a thin layer of hyaline cartilage separated by a joint cavity
This arrangement permits a great degree of freedom of movement
Synovial membrane lines the joint cavity that produces the synovial fluid
Joint cavity is enclosed by a double layered membrane: the articular capsule
Synovial joints are reinforced by a number of ligaments

12. Synovial joints are classified according to the shape of the articulating surfaces which, in turn, determines the range of movement permitted
They can be classified into 7 major categories:
1. Plane (gliding)
In plane joints, the apposed articular surfaces are flat or almost flat, and this permits the bones to slide on one another. Examples of these joints are the sternoclavicular and acromioclavicular joints
the joints are nonaxial

14. 2. Hinge
Hinge joints resemble the hinge on a door, so that flexion and extension movements are possible.
Examples of these joints are the elbow, knee, and ankle joints

15. 3. Pivot
In pivot joints, a central bony pivot is surrounded by a bony–ligamentous ring, and rotation is the only movement possible. The atlantoaxial and superior radioulnar joints are good examples.
Since the only rotation is allowed, the Joints are uniaxial.

16. 4. Condyloid
Condyloid joints have two distinct convex surfaces that articulate with two concave surfaces. The movements of flexion, extension, abduction, and adduction are possible together with a small amount of rotation. The metacarpophalangeal joints or knuckle joints are good examples

17. 5. Saddle
In saddle joints, the articular surfaces are reciprocally concavoconvex and resemble a saddle on a horse's back. These joints permit flexion, extension, abduction, adduction, and rotation. The best example of this type of joint is the carpometacarpal joint of the thumb

18. 6- Ellipsoid joints
In ellipsoid joints, an elliptical convex articular surface fits into an elliptical concave articular surface. The movements of flexion, extension, abduction, and adduction can take place, but rotation is impossible. The wrist joint is a good example.

19. 7. Ball and socket
In ball-and-socket joints, a ball-shaped head of one bone fits into a socketlike concavity of another. This arrangement permits free movements, including flexion, extension, abduction, adduction, medial rotation, lateral rotation, and circumduction.
The shoulder and hip joints are good examples of this type of joint

20. 12 pairs of Cranial nerves
Introduction to the nervous system
Classification
Nervous System (NS)
Functional Division
Structural Division
Central NS
Autonomic NS
Somatic NS
Brain
Spinal Cord
Peripheral NS
Sympathetic NS
Parasympathetic NS
12 pairs of Cranial nerves
&
31 pairs of spinal nerves

21. Nervous system consists of two main cell type
a. Neurons
b. Neuroglia (Non neuronal cells)
Neurones
Neurons are the functional structural units of nervous system

22. CNS NERVE Bundle of axons NUCLEUS
Collection of nerve cell bodies in the CNS
TRACT
Bundle of nerve fibers connecting nuclei

23. PNS GANGLION Collection of nerve cell bodies in the PNS CRANIAL NERVES
Exit the cranial cavity through foramina
12 pairs of cranial nerves.   Olfactory I   Optic II   Oculomotor III   Trochlear IV   Trigeminal V   Abducens VI   Facial VII   Auditory (vestibulocochlear) VIII   Glossopharyngeal IX   Vagus X   Spinal Accessory XI   Hypoglossal XII

24. SPINAL NERVES
31 Pair
Exit the vertebral column through intervertebral foramina

26. Autonomic NS Sympathetic Thoracolumber Division
Parasympathetic Craniosacral Division