The Body in Motion PDF

Summary

This document provides an overview of the skeletal system, including major bones, anatomical terms, types of bones (long, short, flat, irregular, sesamoid), and the five key functions of bones (support, protection, movement, mineral storage, and blood cell production). The document also covers different types of joints and their functions.

Full Transcript

Core 2: the body in motion

Skeletal system:

Major bones involved in movement:
About bones
Humans are born with 300 bones but at maturity the human skeleton has 206 bones as the
bones fuse together by cartilage after being born e.g. the skull

Anatomical terms
Superior - towards the head, e.g. the chest is superior to the hips
Inferior - towards the feet, e.g. the foot is inferior to the leg
Anterior - towards the front, e.g. the breast is on the anterior chest wall
Posterior - towards the back, e.g. the backbone is posterior to the heart
Medial - towards the midline of the body, e.g. the big toe is on the medial side of the foot
Lateral - towards the side of the body, e.g. the little toe is on the lateral side of the foot
Proximal - towards the bodies mass, e.g. the shoulder is proximal to the elbow
Distal - away from the bodies mass, e.g. the elbow is distal to the shoulder
Supine - lying face down
Prone - lying face up

Major skeletal bones

Structure of bones
The outer part of the bone consists of dense, strong compact bone tissue and forms the actual shaft of
long bones, spongy bone (cancellous bone) is strong and light able to withstand stress and meets with
adjacent bones forming joints. The centre cavity and the spaces between spongy bone is filled with
bone marrow containing blood vessels, fat and blood forming tissue. The articular surface is soft and
resilient, preventing jarring and allowing bones to move freely on each other.

Types of bones
Long bones - long in length consisting of two ends and a shart, made up of hard shell casing
(compact bone) and spongy bone on the inside e.g. femur, humerus, radius, ulna
Short bones - cube-like and made up of spongy bone with a thin layer of compact bone
providing the shape e.g. carpals, tarsals, metacarpals, metatarsals
Flat bones - flat thing bones that usually protect organs e.g. skull, sternum
Irregular bones - do not fall into above categories and usually complicated in shape e.g.
vertebrae, pelvis
Sesamoid bones - usually small, round and flat, found where tendons pass over a joint e.g.
patella. They aim to protect the tendon and increase movement

Five main functions of bones
1. Support - bones provide the framework of the body; they support it and give the body shape,
e.g. the vertebrae supports the ribs to enable us to stand
2. Protection - bones protect vital organs within the body, e.g. the pelvis surrounds the
reproduction organ
3. Movement - in conjunction with muscles, bones act as levers to allow the body to move, e.g.
the flexion of the knee joint allows us to kick a ball
4. Storage of minerals - bones store minerals needed for the functioning of the body e.g. calcium
5. Blood cell production - the formation of blood cells occurs in the cavities of certain bones

The skeleton
Axial skeleton
Includes the skull, ribs and vertebral column
Is the central main structure of the overall skeleton with the stability allowing bones of the
appendicular system to move more efficiently
Many of these bones do not move or have minimal movements

Appendicular skeleton
Includes the pelvic girdle, the limbs and shoulder (clavicle and scapular)
Key long bones directly involved in effecting moving
Structure and function of synovial joints

Types of synovial joints
Plane (intertarsal joints) – allows limited gliding movements
Hinge (elbow and knee) – allows movements along one axis for flexion or extension
Pivot (C1 to C2 vertebral joint - top of the neck) – allows rotational movements and some
bending
Ellipsoid/Condyloid (radius to carpal joint – wrist) – allows movement in two planes,
allowing flexion, extension, adduction, abduction, and circumduction
Saddle (base of the thumb) – allows the same movements as the condyloid but with no axial
rotation
Ball-and-socket (pelvis and shoulder) – allows movement through three planes (flexion,
extension; abduction, adduction; rotation) and is the most mobile of the synovial joints

Cartilaginous joints - a joint joined by cartilage (strong and flexible connective tissue) that is slightly
moveable e.g. joints between the vertebrae
Fibrous joints - A joint where no movement is possible and the bones are joined by fibre (connective
tissue, collagen fibres connect periosteum to bone)

Ligaments - well defined fibrous bands that connect articulating bones. They are designed to
assist the joint capsule to maintain stability in the joint by restraining excessive movement,
controlling the degree and direction of movement that occurs
Tendons - tough inelastic cords of tissue that attach muscle to bone
Synovial fluid - acts as a lubricant keeping the joint oiled and the moving surfaces apart. It
forms a fluid cushioning between joints providing nutrition for the cartilage and carrying
 away waste. When the articular cartilage is under pressure (during movement), fluid is
‘pumped’ into the joint space with the viscosity (stickiness) varying. The fluid becomes more
viscous in cooler temperature potentially causing joint stiffness in cold weather
Synovial membrane - The tissue that lines the non-contact parts of the joint capsule. It
secretes synovial fluid
Hyaline cartilage - a smooth shiny cartilage that allows the bones to move freely over each
other. It receives nourishment through the synovial fluid and is thicker where greater weight
bearing

Joint actions

Muscular system:

Major muscles involved in movement:
About muscles
There are more than 600 muscles, all attached to bones
Muscles can only pull

Types of muscle tissue
Cardiac - involuntary, striated in appearance, occurs in the wall of the heart
Smooth - involuntary, non striated in appearance, occurs in walls of internal organs and blood vessels
Skeletal - voluntary, striated in appearance, attached to the skeleton to provide movement

Muscle fibres
Slow twitch - contracts slowly especially during sustained physical activity requiring
endurance
Fast twitch - contracts quickly especially during brief high-intensity and explosive movements

Origins and insertions
When a muscle contracts, one bone moves while another stays stationary
Origin - stable stationary bone
Insertion - attachment at moveable end

Muscle relationships (agonist + antagonist):
Agonist - the working/contracting muscle (primary mover) that shortens
Antagonist - relaxing muscle that lengthens
Stabiliser - gives the muscle a fixed base, acting as a joint, so agonist can work more efficiently

Isotonic - Contractions which cause the muscle to change length as it contracts and causes movement
of a body joint
Concentric - the muscle shortens
Eccentric - the muscle lengthens
Isometric - contraction occurs when the muscle fibres are activated and develop force, but the
muscle length does not change; that is, movement does not occur
Respiratory system:

Structure and function:

Structure Function

Nose Nostrils bring air into the nose where it is filtered, warmed and moistened

Nasal Cavity Tiny hairs called cilia protect the nasal passageways, filtering out dust and other particles that
enter through the breathed air

Pharynx The pharynx carries food and air, used for digestion and respiration. The oesophagus is for food
leading to the stomach. The trachea is for air, with a small flap called the epiglottis, stopping food
and liquid from going into the lungs

Larynx The larynx (voicebox) is at the top of the trachea, this is where our vocal cords are

Trachea The trachea (windpipe) is a 2-3 cm tube that extends downwards from the bottom of the larynx
for about 12 cm. The walls of the trachea are made strong by stiff rings of cartilage that keep it
open. It is also lined with tiny hairs that sweep foreign particles and fluids out of the airway. It
divides into two branches

Lungs The lungs and respiratory system allow us to breathe

Bronchi The trachea divides into two branches, the left and right bronchi, with each entering one lung.
The branches resemble the limbs of a tree, dividing into smaller and finer branches called
bronchioles which end in alveoli.
 Alveoli The bronchioles end in tiny air sacs called alveoli. The alveoli structure enables fresh air to get to
the air sacs which are surrounded by tiny blood vessels, capillaries. It has a permeable membrane
and this is where gaseous exchange occurs.

Function - delivers oxygen to the cardiovascular system for distribution to the body and removes
carbon dioxide

Lung function (inspiration, expiration):
Inspiration - breathing in; diaphragm contracts, and thoracic cavity expands whilst the pressure within
it decreases, as a result the lungs expand and air is taken in
Expiration - the diaphragm relaxes, the volume of the thoracic cavity decreases and the pressure
within it increases, the lungs contract and air is forced out
Lung ventilation - movement of air in and out of the lungs
Around 6L of air is ventilated each minute, and during moderate exercise, that increases to approx
90L/min
Tidal volume - amount of air inhaled and exhaled during one breath
Respiratory frequency - amount of breaths taken in a minute

VO2 max - maximal oxygen uptake that can be used by the body in one minute during max exercise
ranging from 20-40 ml/kg/min (unit and ordinary) up to 8-90 ml/kg/min (elite endurance athletes)

Formulas
Increase in ventilation - measured by determining tidal volume and respiratory frequency
Minute ventilation (amount of air inhaled and exhaled each minute) = tidal volume x resp frequency

Exchange of gases (internal, external):
Internal gas exchange
Refers to exchange of gases between the cells of the
body and the blood
Oxygenated blood is brought to the cell, oxygen is taken
out of the blood and transferred to the cell whilst carbon dioxide
travels from the cell to the blood through capillaries
Carbon dioxide then taken to the lungs through the heart
to remove carbon and receive oxygen (external respiration)
Blood flows from the left side to the right side of the
heart (systemic circulation)

External gas exchange
Exchange of gases across the respiratory membrane in
the lungs
Deoxygenated blood travels to the capillaries that cover
alveoli, carbon dioxide diffuses out of blood and into the alveoli
where it is expired
 At the same time oxygen that has been breathed in diffuses across the alveoli, membrane and
into capillaries where it is taken away from the lungs, back to the heart to be pumped around
the body and used by cells
Blood flows from the right side to the left side of the heart (pulmonary circulation)

Diffusion - movement of substance from a high to low concentration of that substance e.g. exchange
of gas across the membranes of the capillary and cell

Circulatory system:

Components of blood:
Blood accounts for about 7-8% of our total body weight
Healthy adults have 5-6L of blood
A person can donate blood every 90 days

Blood recovery
Plasma recovers within 24 - 48 hours
Red blood cells recover in about 3 weeks
Platelets and white blood cells recover within minutes

Functions of blood
To transport: nutrients, oxygen, carbon dioxide, waste products and hormones to cells and
organs around the body
To protect us from diseases (white blood cells)
To regulate the bodies temperature

Components of blood

Red blood cells or RBC (erythrocytes)
- Make up more than 99% of formed elements in blood
- Contain oxygen carrying pigment called haemoglobin, giving blood cells its red colour
- Live for around 120 days, replaced at a rate of 2 million per second
- Formed in red bone marrow
- About 44%

White blood cells (leucocytes)
- Combat infection and inflammation in a process called phagocytosis
- Live from a few hours to a few days
- Formed in thymus, spleen and bone marrow
Platelets (thrombocytes)
- Involved in clotting and help to repair slightly damaged vessels
- Lifespan of 5-9 days
- Formed in bone marrow
White blood cells and platelets are about 1%
Plasma
- fluid/liquid component of blood
- Largest component of human blood (about 55%)
- Contains water, salts, enzymes, antibodies and other proteins

Structure and function of the heart:

1. Deoxygenated blood enters right atrium from superior and inferior vena cava, right atrium
contracts
2. Blood in right atrium flows through right AV valve (tricuspid) into right ventricle
3. Contraction of right ventricle forces pulmonary valve open
4. Blood flows through pulmonary valve into pulmonary trunk
5. Blood is distributed by right and left pulmonary arteries to the lungs where it unloads CO2
and loads O2
6. Oxygenated blood returns from lungs via pulmonary veins to left atrium that contracts
7. Blood in left atrium flows through left AV valve (mitral) into left ventricle
8. Contraction of left ventricle (simultaneous with step 3) forces aortic valve open
9. Blood flows through aortic valve into ascending aorta
10. Blood in aorta is distributed to every organ in the body where it unloads O2 and loads CO2
In muscles and body organs, the blood releases oxygen and nutrients, absorbs food and water from
intestines. The liver processes nutrients and, together with kidneys, purifies the blood.
11. Deoxygenated blood returns to heart via vena cava
Arteries + veins + capillaries:
Arteries - carry away from the heart to the tissue, thick elastic walls
Veins - carry from tissues back to the heart, thinner and less elastic walls, have valves to prevent blood
flowing back the wrong way
Capillaries - very small networks of vessels where nutrients and gases are exchanged between blood
and cells, lie between arterioles and venules connecting both systems
Oxygenated blood - appears bright red
Deoxygenated blood - appears dark red
Valves - prevent backflow of blood

Pulmonary and systemic circulation:
Pulmonary circulation - circulates deoxygenated blood from the right side of the heart to the lungs,
then back to the heart (step 1-6)
Systemic circulation - pumps oxygenated blood from left side of the heart out to all body tissues, then
back to the right side of the heart (step 7-11)

Blood pressure:
The force that blood exerts on the walls of blood vessels, expressed in millimetres of mercury
(mmHg)
Sphygmomanometer - instrument for measuring blood pressure

Systolic blood pressure - amount of pressure in your arteries during the contraction of your heart (top
number)
Diastolic blood pressure - blood pressure when your heart is between beats (in relaxation) (bottom
number)
Therefore, blood pressure peaks when the heart muscle contracts and pumps blood (a cycle
called systole), and falls when the heart relaxes and refills with blood (a cycle called diastole)
E.g. 120/80 mmHg is a normal reading, 140/90 is a high reading
Health components of fitness:
Related closely to improvements in health outcomes and make up the base work of fitness. They
provide general conditioning for most sports performances.

Cardiorespiratory endurance:
The ability of the working muscles to take up and use the oxygen that has been breathed in during
exercise and transferred to muscle
Commonly referred to as aerobic power (with oxygen)
Cycling, triathlons, marathons
Tests - beep test

Muscular strength:
The ability to exert force against a resistance in a single maximal effort
Muscle hypertrophy - w\increase in the size of the muscle from an increase in the cross
sectional area of the individual muscle fibres
Weightlifting, wrestling, rugby league, gymnastics
Tests - grip strength dynamometer or 1RM

Muscular endurance:
Ability of the muscles to endure for physical work for extended periods of time without undue fatigue
Cycling, cross country, rowing
Tests - push up or sit up test

Flexibility:
Ability to move joints and use muscles through their full range of motion
Heavy influence on avoiding injury
Increases mobility
Improves posture
Improves blood circulation
Gymnastics, dancing
Tests - sit and reach test, goniometer

Body composition:
The percentage of fat opposed to lean body mass in a human being
Heavy influence on what sport individual suited to
All people need essential fat (15-20% for men, 20-25% for women) that surrounds vital
organs including the kidneys, heart and liver for protection, insulation and shock absorption
Absence of fat would lead to chronic health problems
Tests - BMI, body composition scan, skinfold test
Skill components of fitness:
Related specifically to skills that are used in sport. Not essential for health but help athletes perform at
a high level in their sport.

Power:
The ability to combine strength and speed in an explosive action calculated by strength x speed
Speed dominated power - greater emphasis on speed e.g. track events, throwing
Strength dominated power - greater emphasis on strength e.g. weightlifting, field events
Includes accelerating, jumping and throwing implements
Tests - standing broad jump, vertical jump

Speed:
Ability to perform body movements quickly
Body weight and air resistance reduce speed
Largely determined by fibre type
Footy, track, touch, cricket
Tests - 10-50m sprint

Agility:
Ability to change direction with speed and precision
Multi directional sport requires athlete to dodge and weave, quickly changing direction and
ac/decelerating
Agile player responds quickly to stimuli (opponent)
Skiing, soccer, basketball, netball
Tests - illinois agility test

Coordination:
The ability to harmonise messages from senses with body parts to produce smooth, skillful, controlled
movements
Interaction between brain and muscle
Less prone to injuries or accidents
Throwing and catching e.g. netball, gymnastics, table tennis
Tests - hand wall toss

Balance:
Ability to maintain equilibrium while either stationary or moving
Static - when stationary
Dynamic - when moving
Improved by practise
Reduces chance of injury
Walking on bar in gymnastics, landing on one foot in netball
Tests - stork stand (static), Y balance test (dynamic)
Reaction time:
Time taken to respond to a stimuli
Time between realising presence of stimulus and appropriate response
Sprinting, running, shooting
Tests - ruler test

Aerobic and anaerobic training:

Aerobic - Exercise dependent on oxygen utilisation by the body at a low to moderate intensity, for 90s
or more, and can continue for an extended period of time, e.g. marathon, 1500m swim. 60-85% max
HR

Anaerobic - Exercise in absence of oxygen relying on stored energy (glucose and fat) in the body that
can be metabolised, at a higher intensity but for a shorter period of time, 90s or less, e.g. sprinting,
high jump, long jump, weightlifting. Above 85% max HR

FITT principle:
Frequency
How often and should be at least 3-5 times per week
Training session frequency should sufficiently stress body so an adaptation can occur
Rest days essential for muscle fibres to regenerate and to reduce risk of injury

Intensity
Amount of effort required by an individual to achieve a fitness benefit
Measured by heart rate
Moderate (60-70% of max heart rate), vigorous (70-85% of max heart rate)

Time
20-30 min for people in good health, increasing to 50 if possible
Longer than 60 min will lead to exhaustion with risk of overtraining and developing injuries
Expectation for elite athletes who should be able to train for longer
6 weeks in minimum for realisation of training effects

Type
Best type - continuous and using large muscle groups (running, swimming, cycling)
Practise should incorporate movements at competition speed or skill level
Many different sessions and exercises to maximise variety and reduce boredom

Immediate psychological responses to training:

Heart rate:
Rises at start of training to meet increased oxygen demand
 Heart rate plateaus as intensity remains constant as the body can supply sufficient oxygen to
working muscles
Only returns to normal after waste products (CO2 and lactic acid are removed)

Ventilation rate:
Total volume of oxygen breathed into the lungs per minute
Will plateau after a period of time if exercise intensity remains constant
Remains elevated after exercise until waste products removed

Stroke volume:
The amount of blood pumped out of left ventricle during a single contraction
Increases gradually as heart rate increases
Increases as the body required more oxygen
High stroke volume and low heart rate indicated better general health (same result, less effort)

Cardiac output:
Total amount of blood pumped out of the heart each minute
Increases as heart rate increases
Untrained people can increase to approx 21 L per min, elite endurance athletes can increase to
approx 35 L per min

Lactate levels:
Amount of lactate acid found in muscles and blood stream during intense aerobic activity
When anaerobic energy (energy without oxygen above 85% intensity) is when lactic acid is
produced
Oxygen is required to remove lactic acid from body, and will lead to fatigue, muscle soreness
and cramps when insufficient oxygen to remove it

Motion:
Types of motion:
Linear motion - movement in a straight line, all body parts moving in the same direction at the same
speed e.g. a swimmer gliding off the wall after tumble turn, a downhill skier holding a body position
as they move down in a straight line

Angular motion - occurs around an axis that can be internal (a joint in the body around which a body
rotates), or external e.g. swing of baseball bat, gymnast around high bar, figure skater doing axle jump

General motion - combination of linear and angular motion e.g. running in a 100m sprint caused by
angular motion of the arms and legs, freestyle swimmer uses angular motion of their arms to propel
the body forward in a linear motion
Velocity + speed:

Velocity:
Describes both magnitude and direction (displacement/time)
Displacement - the change in position of an object from point A to point B

Speed
Describes only the magnitude (how quickly the body is moving) (distance/time)
Distance - full length travelled to get from point A to point B

Speed and velocity only equal if movement occurs in straight line, thus speed and velocity of
a cricket batter running the same but speed and velocity of 400m sprinter around oval shaped
track is different

Acceleration:
The rate at which an object increases its velocity (velocity/change in time)
Can be uniform (constant change in velocity) or varied (because of fatigue or opponents e.g.
in rugby player comes to tackle so direction change)
Length and frequency of an individual's stride affects acceleration
Faster acceleration helps to reach top speed faster
Relates directly to agility - faster acceleration allows for better agility
A baseballer runner needs to increase velocity quickly to get to the next base fast and decrease
quickly to ensure they stay on the base

Momentum:
The measure of an object’s motion with magnitude and direction (mass x velocity)
A players mass stays the same so to increase momentum they need to increase velocity and
the greater the momentum, the greater the effect upon collision
E.g. triple long jump, long distance running, hitting or throwing sports
Linear momentum - describes translating motion
Angular momentum - describes rotating motion
Balance and stability:
Static balance - person remains stable over relatively fixed base e.g. handstand on a beam
Dynamic balance - when performer is in motion e.g. during flips on floor routine
Stability - degree to which a body resists being upset or moved

Centre + line of gravity:
Centre of gravity - point at which all weight is evenly distributed and about which the object is
balanced e.g. when standing for a human is about 55-60% of height depending on leg length, upper
body development etc.

Line of gravity - imaginary line drawn vertically downward from centre of gravity, where it touches
the ground affects stability

Base of support:
The area enclosed by the outline of the support on the ground, whether hands or feet, and as the base
of support increases (e.g. feet move further apart), stability increases
- For a person to maintain a stable position, the line of gravity must pass through the base of
support e.g. through lowering body
- Increased mass increases stability as tends to remain steadier as requires more force to be
accelerated

(in image unstable as line of gravity falls outside base of support)

Fluid mechanics:

Flotation + centre of buoyancy:
Flotation - any change in the density of the surrounding water affects the level at which an object
floats, fresh water is denser and thinner then salt so a boat floats lower

Buoyancy - loss in weight an object seems to undergo when places in liquid as compared to its weight
in the air
- Centre of buoyancy is the centre of gravity of the volume of water which the person or object
displaces
- Stable when centre of gravity and centre of buoyancy on same vertical line
Archimedes principle:
“An object fully or partially immersed in a liquid is buoyed upward by a force equal to the weight of
the liquid displaced by that object”
- Means a floating object displaces an amount of water equal to its own weight

Drag, lift, stabilising:
Fluid resistance
force applied by a gas or liquid resisting the motion of a body through it
Shaving, proper form, tight swimwear reduces resistance

Drag
Pressure drag - comes from frontal area exposed to water, a swimmer must streamline their body to
reduce it
Skin drag - resistance due to new water rubbing against swimmers body, fastskin tight swimsuits
mimic the skin of a shark to reduce skin drag
Wave drag - waves created by swimmer moving in water, less splashes and smoother strokes reduce
waves, lane roped stop wave drag affecting swimmers in other lanes

Lift
Arm stroke produces most drive in lifting the body
Optimum efficiency - pushing a large amount of water a small distance

Stabilising
Kick stabilises with propulsive force

Force:

How the body applies force:
The body generates force by manipulating the gravitational force and using its muscles and arm
momentum e.g. in vertical jump
“For every action there is an equal and opposite reaction”

How the body absorbs force:
Bones, body tissue and muscles absorb force by transferring the force to our muscles where
contractions in the opposite direction absorb the force
The body increases time of absorption, movement length or area to more safely absorb force
E.g. gymnastics position after doing flips finishing off bar routine
Applying force to an object:
Movement of the limb or body that makes contact with the external object is where the force
is transferred to an object
Body uses largest muscle groups to generate maximum force
E.g. twisting their body in shot put before final push with arms, or run before power shot in
NFL