Anatomy 2 PDF

Summary

This document provides a detailed overview of the anatomy various joints, including the wrist, elbow, and shoulder. It includes descriptions and diagrams.

Full Transcript

**[TABLE OF CONTENTS]**

- Specific joints

- Cartilage

- Tendons and ligaments

**[WRIST JOINT]**

The wrist joint is formed by

Distally -- the proximal row of carpal bones (except the pisiform)

Proximally -- the distal end of the radius, and the articular disk


The ulna is not part of the wrist joint, it articulates with the radius,
just proximal to the wrist joint, at the distal radioulnar joint.

Together, the carpal bones form a concave surface with articulates with
the convex surface of the radius and the articular disk.

The wrist is an ellipsoidal (condyloid) type synovial joint allowing for
movement along the two axes,

flexion / extension and adduction / abduction

the movements of the wrist are performed by the muscles of the forearm

**[ELBOW JOINT]**

The elbow joint is where the long bone at the top of your arm (humerus)
meets the 2 bones in the forearm (radius and ulna)

It is classified as a synovial hinge joint, and it allows you to bend
your arm.

The upper part of the radius can rotate so you are able to twist your
forearm.

The ulnohumeral joint or trochlear joint is composed of the 2 bones
(humerus and ulna) and is the junction between the trochlea notch of the
ulna and the trochlea of humerus.

It is classified as a hinge joint which allows for movements of flexion,
extension and circumduction.

The radioulnar joints are 2 locations in witch the radius and ulna
articulate in the forearm

- Proximal radioulnar joint -- located near the elbow. It is and
articulation between the head of the radius and the radial notch of
the ulna.

- Distal radioulnar joint -- located near the wrist. It is an
articulation between the ulnar notch of the radius and the ulnar
head

Both joints are classified as pivot joints, responsible for the
pronation and supination of the forearm.

**[SHOUDLER JOINT]**

The shoulder joint (Glenohumeral joint) is a ball and socket joint
between the scapula and the humerus.

It is the major joint connecting the upper limbs to the trunk.

It is one of the most mobile joint sin the human body, but this makes
the joint less stable.

The shoulder joint is formed by the articulation of the head of the
humorous with the glenoid cavity (fossa) of the scapula.

Like most synovial joints the articulating surfaces are covered with
hyaline (articular) cartilage

The head of the humerus is much larger than the glenoid fossa, giving
the joint a wide range of movement at the cost of inherent instability.


To reduce the disproportion in surfaces the glenoid fossa is deepened by
a fibrocartilage rim called the glenoid labrum (lips)

GLENOID LABRUM -- a fibrocartilaginous ridge surrounding the glenoid
cavity. It deepens the cavity and creates a seal with the head of the
humorous reducing the risk of dislocation.

**[SHOUDLER MOVMENTS]**

- #### **EXTENSION - arm moves backwards in sagittal plane**

- #### **FLEXION - arm moves forwards in sagittal plane**

- #### **ABDUCTION - arm moves away from midline in frontal plane**

- #### **ADDUCTION - arm moves towards midline in frontal plane**

- #### **INTERNAL ROTATION - rotation towards the midline, so that the thumb is pointing medially.**

- #### **EXTERNAL ROTATION - rotation away from the midline, so that the thumb is pointing laterally.**

**[SPINE ]**

There are 2 types of joints in the spine

The vertebral bodies are joined by inter-vertebral discs made of
fibrocartilage and thereby structurally form a symphysis type of
cartilaginous joints

Each vertebra also has 4 articular processes (2 above and 2 below) which
join the vertebrae above and below via synovial joints (facet joints)

All vertebrae also protect the delicate spinal cord and nerves within
their vertebral canal

**[SPINE INTER-VERTEBRAL JOINTS]**

**[CERVICAL]**

The cervical spine has 7 stacked bones called vertebrae labelled C1 to
C7


The top of the cervical spine connects to the skull and the bottom
connects to the thoracic vertebrae at the about shoulder level

The cervical spine forms a lordotic curve by gently curving towards the
front of the body and the back

Roles of the cervical spine

- Protecting the spinal cord

- Supporting the head and its movements

- Facilitating and protecting flow of blood to the brain

**[THORACIC]**

The thoracic spine is the second segment of the vertebral column located
between the cervical and lumbar vertebral segments.

Is consists of 12 vertebrae which are separated by intervertebral discs

Along with the sternum and the ribs the thoracis spine forms part of the
thoracic cage

The bony structure helps protect the internal organs

**[CHARACTERISTIC FEATURES]**


Vertebra body is heart shaped

Presence of demi-facets on the sides of each vertebral body these
articulate with the heads of the ribs

Presence of costal facets on the transverse processes these articulate
with the tubercles of the ribs

The spinous processes are long and slant inferiorly this offers
increased protection to the spinal cord

Thoracic spine is considered to have a restricted range of motion (ROM)
compared with that of the cervical and lumbar spine

The ROM of the thoracis spine is restricted by the rib cage

**[LUMBAR]**


The lumbar vertebrae consist of 5 individual cylindrical bones that form
the spine in the lower back

These vertebrae carry all of the upper body's weight while providing
flexibility and movement to the trunk region

As in other regions of the spine the movements of the lumbar spine are

- Flexion / extension

- Lateral bending

- Rotation

While lumbar motion is potentially greater than that of the thoracic
spine because of the lack of rib restriction, facet facing and heavy
ligaments check the range of rotatory motion

**[SPECIFIC JOINTS ]**

**[THE PELVIS JOINTS]**

The joints of the pelvis include

- Sacrococcygeal

- Lumbosacral

- Pubic symphysis

- Sacroiliac

The lumbosacral joints forms from the 5^th^ lumbar vertebrae and the
sacrum

In between the articular processes this joint has an intervertebral disc

The sacrococcygeal joint is a fusion of the bone between the sacrum and
coccyx

It also consists of an intervertebral disc between the 2 vertebrae and
several accessory ligaments

The sacroiliac joints are synovial articulations between the surfaces of
the ilium and sacrum on either side

The sacroiliac joints surface is smooth and flat and has posterior
strengthening by dorsal sacroiliac and interosseous ligaments

When a person is upright the body weight usually transmits to the sacrum
and iliac

When sitting or supine the persons body weight transmits to the ischial
tuberosity

The pubic symphysis is a cartilaginous joint located between the main
body of the pubic bone in the anterior midline. This joint is covered
with hyaline cartilage and the ligaments around it are flexible and
relax during pregnancy

**[HIP JOINT]**

A cartilaginous labrum expands the size of the bony socket

It can be distorted and damaged at extreme ranges of hip motion

**[KNEE JOINT]**

The knee joint is a hinge type synovial joint which mainly allows for

- Flexion / extension

- Small degree of medial and lateral rotation

It is formed by articulations between the patella, femur and tibia


**[KNEE LIGAMENTS]**

Ligaments are bands of strong tissue that connect bone to bone

The knee has 4 major ligaments that connect the femur to the tibia

- Anterior cruciate ligament (ACL)

- Posterior cruciate ligament (PCL)

- Medial collateral ligament (MCL)

- Lateral collateral ligament (LCL)

The ACL and PCL prevent the femur and tibia from sliding too far
forwards and backwards

The MCL and LCL prevent side to side movement

A knee meniscus is a thick pad of cartilage located between the femur
and tibia

There are 2 menisci in each knee

- Medial meniscus (located on the inside of the knee)

- Lateral meniscus (located on the outside of the knee)

The menisci reduce shock and absorb impact when moving or bearing weight


Also helps stabilize the knee and facilitate smooth motion between the
surface of the knee

**[THE ANKLE JOINT]**

Ankle joint is formed by 3 bones

- Tibia

- Fibula

- Talus (in foot)

The tibia and fibula are bound together by strong tibiofibular ligaments

Together they form a bracket shaped socket, covered in hyaline
cartilage. This socket is known as mortise

The body of the talus fits snugly into the mortise formed by the bones
of the leg. The articulating part of the talus is wedge shaped -- it is
broad anteriorly and narrow posteriorly

DORSIFLEXION -- the anterior part of the talus is
held in the mortise and the joint is more stable

PLANTARFLEXION -- the posterior part of the talus is held in the mortise
and the joint is less stable

The ankle joint is a hinge type joint with movement permitted in one
plane

The plantarflexion and dorsiflexion are the main movements that occur at
the ankle joint

Eversion and inversion are produced at the other joints of the foot,
such as the subtalar joint

PLANTARFLEXION is produced by the muscles in the posterior compartment
of the leg (gastrocnemius, soleus plantaris and posterior tibial)

DORSIFLEXION is produced by the muscles in the anterior compartment of
the leg

(tibialis anterior, extensor hallucis longus and extensor digitorum
longus)

The medial ligament is attached to the medial
malleolus (a bony prominence projecting from the medial aspect of the
distal tibia)

Is consists of four ligaments, which fan out from the malleolus,
attaching to the talus, calcaneus and navicular bones

The primary action of the medial ligaments is to resist over eversion of
the foot

The lateral ligament originates from the lateral malleolus (a bony
projecting from the lateral distal fibula)

It resists over inversion of the foot and is comprised of 3 distinct and
separate ligaments

- Anterior talofibular

- Posterior talofibular

- Calcaneofibular


**[TYPES OF CARTILAGE]**

- Articular cartilage

- Growth cartilage

- Fibrocartilage

**[ARTICULAR, GROWTH AND FIBROCARTILAGE]**

**[ARTICULAR (HYALINE) CARTILAGE]**

Is a connective tissue covering the end of bones that functions as a
load bearing, low-friction, and wear-resistant surface to facilitate
joint movement 

Provides** **smooth** **articular surfaces for movable (synovial)
joints.

It** **protects** **through shock absorbing.

Has** **poor regenerative** **(healing) capacity. Damage can lead to
degeneration of tissue.**\
**

Mainly subjected to compression forces.


**[GROWTH CARTILAGE (PHYSIS OR GROWTH PLATE)]**

Responsible for growth in height.**\
** **\
**Fuses** **(ossifies)** **in** **late teens resulting in cessation of
growth.** **

bumps (tubercles) on bones for tendon attachment** **also have growth
plates.

**[FIBROCARTILAGE]**

Provides articular pad for some movable joints

Provides tough union between structures

Examples of fibrocartilage pads in joints

- Between ulna and metacarpals

- Between vertebrae

- Lateral and medial meniscus cartilage

**[LIGAMENTS]**


Strong rope like tissue joins bone to bone

Ligamentous joint capsule surrounds (encapsulates) movable (synovial)
joints

Capsule is also reinforced with ligaments

There are some ligaments within joints (eg knee and hip)

In joints between long bones of the limbs there are often thick
ligaments on each side of the joint (collateral ligaments)

**[TENDONS]**

Strong rope like tissue that joins muscle to bone

Inverts into the periosteum of bone with some fibbers actually
interwoven into bone matrix


Sometimes in sheets called fascia

Some tendons also serve as joint stabilizers (rotator cuff of the
shoulder)

**[COMMON INJURIES AND DISEASES IN MAG]**

- Osgood-Schlatter disease

- Servers disease

- Injuries to knee ligaments during under rotation on longitudinal
axis

- Injuries to ankles during under rotation on transversal axis

**[FOREARM SPLITS]**

Forearm splints are painful and frustrating injuries that occur most
often in athletes, gymnasts, and weight trainers.

This injury is due to tendons that are unable to stand the stress that
is being placed on them.

These tissues tear away from the bone or bones that they are attached
to.

This is very similar to shin splints, and generally take about the same
amount time to heal.

Interosseous membrane between radius & ulna (forearm).

**[SHIN SPLINTS]**

The term "shin splints" describes pain felt along
the front of your leg and shinbone.

You'll notice the pain in the front area of the leg between your knee
and ankle.

Shin splints are a common overuse injury.

They can occur from running or doing other high-impact activities for
extended periods of time or without adequate stretching.

**[GYMNAST WRIST ]**

Gymnast wrist is an overuse injury that can occur in adolescent
gymnasts.

It is a combination of injuries to the bone and the ligaments of the
wrist.

Gymnast wrist occurs because of the repetitive compressive forces
applied across the wrist during the weight bearing activities of
gymnastics.

Gymnast wrist is commonly shown as a chronic stress fracture of the
distal radius, and in these skeletally immature gymnasts, this is near
the growth plate of the wrist.

**[SHOULDER INJURIES -- IMPINGEMENT]**

Shoulder impingement - when the tendons of the rotator cuff (RTC) become
trapped and compressed under the bones (humerus and acromion) during
shoulder movements.

The shoulder is unusual because unlike most areas
of the body, the bone covers the muscle.

The rotator cuff muscle is sandwiched between the humerus (arm bone) and
the acromion (top of the shoulder) in an area called the subacromial
space.

The rotator cuff (RTC) can become pinched between these bones leading to
injury and inflammation (tendonitis and bursitis).