Animal Body Systems

About This Presentation

Title:

Animal Body Systems

Description:

Animal Body Systems Skin Protects the Body Integument comes from the Latin word integumentum , meaning – PowerPoint PPT presentation

Number of Views:1452

Avg rating:3.0/5.0

Slides: 139

Provided by: TamiPa

Category:

more less

Transcript and Presenter's Notes

Title: Animal Body Systems

1
Animal Body Systems
2
Skin Protects the Body

Integument comes from the Latin word integumentum
, meaning "cover" or "enclosure."
In animals an integument is any natural outer
covering, such as skin, shell, or membrane.

The skin makes up 12-15 of body weight and has a
surface area of 1-2 meters

3
Skin Protects the Body

The human integumentary system is an external
body covering, but also much more. It protects,
nourishes, insulates, and cushions. It is
absolutely essential to life. Without it, an
individual would be attacked immediately by
bacteria and die from heat or freezing and water
loss.

The integumentary system is composed primarily of
the skin and accessory structures including hair,
nails, and certain exocrine glands (glands that
have ducts or tubes that carry their secretions
to the surface of the skin or into body cavities
for elimination).

4
Skin Layers

A flexible and responsive organ
An organ is any part of the body formed of two or
more tissues that performs a specialized
function. As an organ, the skin is the largest
and heaviest in the body

Composed of 2 principal layers
Epidermis outer most layer
Dermis inner thicker layer
Beneath the dermis lies the subcutaneous layer or
hypodermis, composed of adipose or fatty tissue.
Although not technically part of the skin, it
does anchor the skin to the underlying muscles
and contains the major blood vessels that supply
the dermis and houses many white blood cells,
which destroy foreign invaders that have entered
the body through breaks in the skin.

5
Functions of the Skin

Just think about the differences in the skin of a
fish, a lizard, a frog, a bird, and a mammal.
Scales, slime, feathers, and hair are all parts
of the integumentary systems for animals.
The skin protects the underlying organs. The fur
helps insulate against heat loss. Dogs and cats
do not sweat through their skin. They only sweat
from their footpads and nose. They lose water by
panting rather than sweating.

Fish
Snake
Bird
6
Epidermis

Outer most layer made up of an interior and an
exterior part
Exterior consists of 25 30 layers of dead,
flattened cells that are continually shed
These dead cells contain keratin, a protein fiber
that protect the underneath layers from exposure
to bacteria, heat and chemicals.

7
Epidermis

The epidermis consists of stratified squamous
epithelial tissue.
Epithelial tissue covers the internal and
external surfaces of the body and also forms
glandular organs.
Squamous cells are thin and flat like fish
scales.
Stratified simply means having two or more
layers.

In short, the epidermis is composed of many
layers of thin, flattened cells that fit closely
together and are able to withstand a good deal of
abuse or friction. It is also waterproof because
keratin, a protein is produced.

9
Epidermis

The epidermis can be divided into four or
five layers. Most important of
these are the inner and outer
layers.
The inner or deepest cell layer is the only layer
of the epidermis that receives nutrients (from
the underlying dermis). The cells of this layer,
called basal cells, are constantly dividing and
creating new cells daily, which push the older
cells toward the surface. Basal cells produce
keratin, an extremely durable and water-resistant
fibrous protein.

10
Epidermis

Another type of cell found in the lower epidermis
is the melanocyte.
Melanocytes produce melanin, a protein pigment
that ranges in color from yellow to brown to
black.
The amount of melanin produced determines skin
color, which is a hereditary characteristic.
The melanocytes of dark-skinned individuals
continuously produce large amounts of melanin.
Those of light-skinned individuals produce less.
Freckles are the result of melanin clumping in
one spot.

11
Epidermis

The outermost layer of the epidermis
consists of about twenty to thirty rows
of tightly joined flat dead cells.
All that is left in these cells is their
keratin, which makes this outer layer waterproof.
It takes roughly fourteen days for cells to move
from the inner layer of the epidermis to the
outer layer. Once part of the outer layer, the
dead cells remain for another fourteen days or so
before flaking off slowly and steadily. Therefore
every 28 days all of the cells of the epidermis
are replaced by new cells.

12
Dermis

The dermis, the second layer of
skin, lies between the epidermis
and the subcutaneous layer.
Thicker than the epidermis, the dermis
contains the accessory skin structures.
Hair, sweat glands, and
sebaceous (oil) glands are all rooted in the
dermis. This layer also contains blood vessels
and nerve fibers. Nourished by the blood and
oxygen provided by these blood vessels, the cells
of the dermis are alive.
Connective tissue forms the dermis. Bundles of
elastic and collagen (tough fibrous protein)
fibers blend into the connective tissue. These
fibers provide the dermis strength and
flexibility.

13
Dermis

Thickness of the epidermis varies in different
parts of the body depending upon the function
Thickest on your palms and soles of your feet

14
Hair Follicles

Hair grows out of narrow cavities of the dermis
called hair follicles that are supplied with
blood vessels and nerves and are attached to
muscle tissue
Many hair follicles have an oil gland associated
with them and if the gland is blocked by oil and
dead cells a pimple forms

15
Dermis

The upper layer of the dermis has
fingerlike projections that extend
into the epidermis. Called dermal
papillae, they contain blood
capillaries that provide nutrients for
the basal cells in the epidermis. On the skin
surface of the hands and feet, especially on the
tips of the fingers, thumbs, and toes, the dermal
papillae form looped and whorled ridges. These
print patterns, known as fingerprints or
toeprints, increase the gripping ability of the
hands and feet. Genetically determined, the
patterns are unique to every individual.

16
Dermis

Within the dermis are sensory receptors for the
senses of touch, pressure, heat, cold, and pain.
A specific type of receptor exists for each
sensation. For pain, the receptors are free nerve
endings. For the other sensations, the receptors
are encapsulated nerve endings. The number and
type of sensory receptors present in a particular
area of skin determines how sensitive that area
is to a particular sensation. For example,
fingertips have many touch receptors and are
quite sensitive. The skin of the upper arm is
less sensitive because it has very few touch
receptors.

17
Functions of the Integumentary System

Helps maintain homeostasis by regulating internal
body temperature
Temperature rises, capillaries dilate and blood
flow increases allowing more heat to be lost by
radiation
Cold makes capillaries constrict and heat is
conserved
Sweat is produced as a response to increased body
temperature heat lost in evaporation body
cools
Sense organ nerve cells receive relay
information
Vitamin production UV light exposure produces
Vitamin D
Protective layer shields chemicals and physical
damage
Cuts allow bacteria to enter - skin repairs
itself quickly

18
Skin Diseases and Problems
Cowpox Lesion

Dermoid cyst, dog
Malignant melanoma, hamster
19
Pityriasis rosea lesion on pigs hind limb. Note
the small ring-like early stage lesions the
older expanding larger rings healing centrally as
they expand.
Squamous cell carcinomas
20
Vocabulary Words

Melanocytes
Melanin
Sebaceous glands
Collagen
Hair follicles
Keratin
Basal cells

Integument
Epidermis
Dermis
Subcutaneous layer /hypodermis
Stratified squamous epithelial tissue

21
Musculoskeletal System

The musculoskeletal system consists of the bones,
cartilage, muscles, ligaments, and tendons.
All vertebrates have a Musculoskeletal System
Primary functions of the musculoskeletal system
include support, motion, protection of vital
organs, and production of blood cells.
The skeletal system serves as the main storage
system for calcium and phosphorus and contains
critical components of the hematopoietic system.

22
Bones
23
Bones
24
Bones

Human skeleton has 206 bones (22 bones in human
skull)
Skeleton has two main parts
Axial skeleton includes the skull and bones that
support it (skull, hyoid bone, vertebral column,
ribs, sternum, etc)
Appendicular skeleton (hangs) includes bones of
the extremities and structures associated with
them such as the shoulder and hip bones, pelvic
girdle, wrists, ankles, fingers and toes
Bone is a connective tissue and one of the
hardest tissues in the body
Common name of bones differ from medical names

25
Bone Structure

Most bones made of 6 kinds of tissue
Spongy bone
Compact bone (solid bone)
Cartilage
Ligament
Marrow
Outer Membrane

26
Bone Structure

27
Compact and Spongy Bone

Bones are composed of two types of tissue
Compact strong, hard outer layer surrounding
every bone
Stores calcium
Spongy contains many holes and spaces
Found towards the end of bones
Strong and gives bone strength
Stores calcium too
Birds have more bone than other vertebrates
(lightens skeleton)

28
Haversian Canal

Haversian canal or osteon are tubular structures
that run the length of the bone
Osteocytes are live bone cells that receive
oxygen and nutrients from small blood vessels

29
Cartilage

Form of connective tissue that is more elastic
and softer than bone
Articular cartilage covers the joint surfaces of
bone
Meniscus is a curved fibrous cartilage found in
some joints that serves as a cushion to forces
applied to the joint

30
Ligaments and Tendons

Ligaments are bands of tough, fibrous connective
tissue connecting two bones
Usually found at bone joints where bones connect
Tendons are thick bands of fibrous connective
tissue that connects muscles to bones

31
Marrow

Produce blood cells in the bone marrow (the soft
center of the bone)
Red marrow hematopoietic (blood forming) -
found in the humerus, femur, sternum, ribs,
vertebrae pelvis - produces red blood cells,
white blood cells, and cell fragments for blood
clotting
Yellow marrow consists of stored fat cells

32
Outer Membrane

Thin sheet of tissue that covers bone
Periosteum
Growth area for bone
Many nerves and blood vessels supply the bone
through the membrane
This is the part that hurts when the bone is
bumped or bruised

33
Joints

Joint articulation (join together allowing
motion)
A joint is found where 2 or more bones meet
Facilitate movement

34
Joints

Joints held in place by ligaments tough bands
of connective tissue
Movable joints bone ends covered in cartilage
makes movement smooth
Bursae are fluid filled sacs that act like a
cushion in areas with friction. They are found on
the outside of the joint decreasing friction and
keeping bones and tendons from rubbing against
each other

35
Joint Types

Joints are classified based on the degree of
movement they allow
The ball-and-socket joint is found in hip-bones
and shoulders allows the most movement of all
the joints. One bone (like the femur) has a
ball-like knob at the end of it, the knob fits
into a cup-like space on the other side. The
ball-and-socket joint is what allows baseball
pitchers to throw a ball with tremendous speed.
The sliding joint is found in the vertebral
column and allows small sliding movements. The
vertebrae have pads of cartilage between them,
and the bones slide over these pads. This is what
makes the backbone so flexible.

36
Joint Types

The pivot joint allows movement turning from side
to side, and your head is attached to your
vertebral column with this joint. A hole in one
bone fits over a pointed part of the other bone,
so that one bone can turn on top of the other.
The hinge joint allows bones to move back and
forth, and is found in your elbow and knee. It
allows bones to move like a hinge in a door.

1. fixed joint 2. pivot joint 3. ball-and-socket
joint
4. sliding joint 5. hinge joint

38
Formation of Bone

Ossification is the formation of bone from
fibrous tissue
Vertebrate skeletons are made of cartilage when
they are born

39
Formation of Bone

Humans begin to replace the cartilage with bone
by the 9th week
Blood vessels penetrate the membrane covering the
cartilage and stimulate its cells to become bone
cells called osteoblasts

40
Formation of Bone

Osteoblasts are immature bone cells that produce
bony tissue
Osteoblasts secrete collagen to which minerals
(calcium salts, etc) are deposited turning the
osteoblasts into osteocytes
Adult skeleton almost all bone except for where
flexibility is needed (nose tip, external ears,
discs between vertebrae and movable joint linings)

41
Bone Growth

Bone tissue is alive and made of cells
Growth occurs in length and diameter
Length at ends of bones in cartilage plates
Diameter at outer surface
Increased production of sex hormones during teen
years causes rapid osteoblasts cell division
resulting in a growth spurt
After growth stops, bone-forming cells
responsible for repair and maintenance of bone
Bone Growth Movie

42
Functions of the Skeletal System

Provides a framework for body tissues
Protection of internal organs(heart, lungs,
brain)
Skeleton provides attachment points for muscles

43
Bones Store Minerals

Store calcium and phosphate among other minerals
Calcium responsible for bone strength
Sources milk, yogurt, cheese, lettuce, spinach
and dark leafy vegetables

Bone Minerals
44
Injury Diseases of Bones

Forcible twisting of a joint is a sprain and the
injury occurs at the bursae, ligaments, or
tendons
Arthritis is an inflammation of the joints caused
by infections, aging or injury
Bone spurs are outgrowths of bone (form of
arthritis)
Osteoporosis loss of bone volume and mineral
content causing bones to become more porous and
brittle
Broken bones bones are realigned and
immobilized until bone tissue regrows

45
Diseases and Injuries of the Musculoskeletal
System

Because many body systems, including the nervous,
vascular, and integumentary systems, are
interrelated, disorders of one of these systems
may also affect the musculoskeletal system and
complicate diagnosis.
Diseases of the musculoskeletal system most often
involve motion deficits or functional disorders.
The degree of impairment depends on the specific
problem and its severity. Skeletal and articular
disorders are by far the most common.

Tendons act as bridging and attachment structures
for the muscles
Some bridge long gaps between the muscles and
target bone and, therefore, are prone to injury
themselves.
An example is the superficial flexor tendon of
horses, which is frequently injured by partial
tearing that leads to tendinitis.
Another acquired tendon injury involves traumatic
disruptions. Due to the relatively poor blood
supply of both tendons and ligaments, healing is
delayed and frequently poor.
Management of injuries to ligaments and
tendons requires patience and long-term
rehabilitation.

Bone diseases are generally congenital or
hereditary, nutritional, or traumatic.
Congenital disorders include in utero
malformations and atavisms, such as polydactyly
or persistent ulnae or fibulae in foals
Genetic defect examples are atlanto-occipital
malformations in Arabian horses or certain cases
of spinal ataxia, canine hip dysplasia, and
abnormal bone formation such as that caused by
parathyroid hypoplasia.

48
Bilateral hip dysplasia in a dog
Normal hips in a dog
49

Nutritional diseases are caused primarily by
imbalances or deficiencies in minerals
particularly copper, zinc, and magnesium.
Calcium and phosphorus concentrations must also
be present in the correct ratio.
Osteomalacia is an example of imbalanced or
deficient calcium and phosphorus intake.
Other nutritional disorders are caused by
excessive protein intake of growing animals.
Either deficiency or excess intake of some
vitamins (vitamins A and D) may influence growth
and development of bone (Rickets)
Aseptic physitis or special osteochondrotic
conditions may be caused by zinc toxicity or
copper deficiency.

Osteoporosis
ossification of the cartilage
50
Symptoms Of Rickets
Osteomalacia
51

Traumatic causes of bone disorders represent the
vast majority of cases and including fractures,
fissures.
Lack of weight bearing, reduced motion,
instability, pain, heat, or swelling usually
accompany these disorders.
Diagnostic procedures include inspection, manual
palpation, diagnostic imaging (such as
radiography, ultrasonography, or thermography,
and increasingly scintigraphy, computed
tomography, or MRI), and diagnostic anesthesia to
determine the specific anatomic structure or
region involved in the problem.

PET Scan (top) and Thermography of a cat are
branches of Nuclear Medicine that uses
radioactive isotopes
52

Chronic inflammation of joints and surrounding
structures is most common in articulations
associated with locomotion, although other joints
may occasionally be affected.
Normal synovial fluid lubricates the synovial
tissues in a joint by lubrication and the
articular cartilage.

53
Vocabulary Words

Cartilage
Axial Skeleton
Appendicular skeleton
Joint
Ligament
Bursa
Tendon
Compact bone
Osteoblast
Red marrow
Yellow marrow

Osteocyte
Spongy bone
Compact bone

54
Muscles

Half of your body mass is muscle
Humans have more than 600 muscles
Muscular system is all the muscles in your body
Muscles are groups of fibers or cells that are
fused together in a bundle
They can change their shape and length to cause
movement

55
Muscle Types

Three types of muscle fibers
Smooth muscle
Cardiac muscle
Skeletal muscle
Each has a different structure and pattern that
make it different from the others

56
Smooth Muscle

Found in walls of your internal organs and blood
vessels, digestive and reproductive tracts
Made of sheets of cells that are elongated and
spindly
Not connected to bone
Most common function involuntary muscle
movement - squeeze so that pressure is exerted on
the inside of the tube or organ it surrounds to
move material through it (peristalsis, movement
of gametes)
Spindle shaped with one nucleus per cell

57
Cardiac Muscle

Involuntary muscle (you cant control your
brain controls) that makes up your heart
Tightly interconnected and form a network that
allows the heart to contract efficiently
Not connected to bone
Conducts electrical impulses necessary for
rhythmic contraction
Bundles of fibers striated (striped from 2 kinds
of proteins that make it up)

58
Skeletal Muscle

Attached to bones for movement
Majority of muscle in body is skeletal muscle
Voluntary muscle movement is under your control
Striated two kinds of proteins make it up
Most meats that you eat are skeletal muscle

59
Skeletal MuscleFilaments
60
Skeletal Muscle Contraction

Most work in opposing pairs
Muscles can only shorten
Takes a pair of muscles to move bones back and
forth
One muscle contracts the other in the pair
relaxes
Muscles made of muscle fibers that are long fused
muscle cells
Involuntary muscles must be stimulated by a nerve
impulse
Muscles only move when a muscle is contracted
Contraction shortens the muscle

61
Fast and Slow Twitch

Fast Twitch (Type II) uses anaerobic metabolism
to create fuel good for short bursts of
strength fire more rapidly Two types (Olympic
Sprinters have 80 fast twitch fibers)
Type IIa intermediate fast twitch use aerobic
and anaerobic metabolism and are a combination of
Fast and Slow Twitch muscle fibers
Type IIb Uses anaerobic metabolism to produce
powerful, quick bursts of speed but fatigues fast
Slow Twitch (Type I) fire more slowly muscles
more efficient at using O2 to generate more ATP
for constant muscle contractions can go a long
time before they fatigue (marathon runners)

Fast
Slow
62
Myofibrils

Myofibrils are smaller units of muscle fiber that
is composed of thick myosin protein filaments and
thin actin protein filaments
Myofibrils can be divided into sections called
sarcomeres (functional unit of muscle)

63
Muscle Contractions

Connected to bone by tendons
Tendons cause the bone to be pulled when the
muscle contracts
When you flex your muscles you are contracting
them they bulge through the skin

64
Sliding Filament Theory

Explanation of how muscle contraction occurs
When signaled, the actin filaments within each
sarcomere slide toward one another, shortening
the sarcomeres in a fiber and causing the muscle
to contract
Myosin filaments do not move

65
Muscle Strength and Exercise

The number of muscle fibers in a muscle are fixed
when you are born
Strength depends upon the thickness of the fibers
on how many contract at one time
Regular exercise stresses muscle fibers slightly
and to compensate for this added workload, the
fibers increase in diameter by adding myofibrils
Regular exercise improves muscle performance

66
Lactic Acid

Muscle cells continuously supplied with ATP from
aerobic and anaerobic processes
Anaerobic processes form lactic acid that builds
up in muscle cells.
Acid moves into the blood increasing respiration
rate blood becomes more acidic
Lactic acid broken down when excess oxygen is
produced

67
Fatigued Muscles
68
Vocabulary

Actin
Cardiac Muscle
Skeletal Muscle
Smooth Muscle
Involuntary Muscle
Voluntary Muscle
Myofibril
Myosin
Sarcomere
Sliding Filament Theory

69
Cardiovascular System

AKA Circulatory System
Pertains to the heart and blood vessels
Includes the heart, blood vessels and blood
Essential to support life of each of the millions
of cells that makes up an animal
Blood has a wide range of functions to maintain
the animals health
Heart and blood provide an access path to all the
body tissues

70
Blood Components

Centrifuged blood separates into cellular portion
(erythrocytes, thrombocytes, and leukocytes) and
plasma (water and protein)
Cellular portion of the blood makes up 30 45
depending upon animal age and species

71
Blood Proteins

Three types
Albumin major blood protein water maintenance
Draws water into blood stream by osmosis
Produced in the liver
Globulins
Antibodies produced by immune system
Fibrinogen
Aids in clotting blood

72
Cellular Component

Three types
Erythrocytes or Red blood cells
Leukocytes or White blood cells
Thromboctyes or Platelets

73
Erythrocytes

Carry oxygen
Biconcave disk
Produced in bone marrow erythropoiesis
Lifespan varies Dog 100-110 days Cat 66-78 days
Erythrocytes low in blood - kidney releases
erythropoietin stimulating bone marrow to produce
more RBC
Contain Hemoglobin iron containing molecule
that gives blood the red color

74
Hemoglobin

Efficient at binding oxygen
carrying 97 of the oxygen
Highest oxygen content in the lungs and it gets
lower as it is pumped through tissues organs
Higher CO2 concentrations in tissues lower pH
(lactic acid) increases amount of O2 released
Carries 20 of CO2 that is converted to
bicarbonate and transported to the lungs
Absorbs many free H ions lowering pH

75
Leukocytes

Help fight infection
5 major types each with different functions
Neutrophils, lymphocytes, eosinophils, monocytes,
and basophils
Produced in bone marrow
Found in the blood or in tissues to fight
infection
A normal dog has 6000-7000 WBCs/microliter

76
Neutrophils

Phagocytize and destroy microorganisms in tissues
and usually not in the blood
Nucleus appears segmented or divided

77
Monocyte

Phagocytize microbes
Produced in the marrow then move to the blood and
into tissues
Mature into macrophages that establish in the
liver or lungs
Remove microorganisms, dead cells and
foreign particles

78
Eosinophils

Look similar to neutrophils with segmented
nucleus
Have a large number of visible granules in the
cytoplasm
Roles in fighting parasites and in allergic
reactions
Granules help to control inflammation

79
Basophils

Many granules with a segmented nucleus
Involved in allergic reactions
Some granules contain histamine
Histamine causes inflammation in the linings of
the nasal passages and respiratory tract
producing sneezing and runny noses

80
Lymphocytes

Have a single nucleus
Produce antibodies to help fight disease
Make up a portion of globulin found in plasma
Found in all organs and tissues involved in
fighting infection (tonsils, lymph nodes, spleen,
thymus)
Neutrophils and lymphocytes make up the largest
number of WBCs in the circulation blood

81
Platelets

Produced in bone marrow
Aid in normal clotting of the blood
Only damaged vessel stimulates a clot
Very complicated process involving platelets and
numerous proteins and factors in the blood
Blood vessel is cut?vessel constricts?platelets
begin to attach to the edges of the damaged
vessel?clotting factors convert fibrinogen to
fibrin completing the plug?over time fibrin is
replaced with repaired blood vessel

82
Blood

Useful in diagnosing disease
Numerous blood tests available
Hypo value below normal
Hyper value above normal
Anemia low red blood cell count
Less oxygen supplied to tissues
Fatigue during exercise usually first symptom
3 common causes
excessive blood loss
Shortened RBC life span
Decreased RBC production
Body attempts to correct anemia by releasing as
many RBCs as possible some immature without
nucleus

83
Blood Clotting in Animals

Quite impressive
Farm cat with leg amputated by farm machinery can
stop bleeding without intervention

84
Blood Functions

2 major functions
Transport substances throughout the body
Oxygen, carbon dioxide, nutrients, wastes,
electrolytes and hormones
Protect the body from infection and diseases

85
Mammalian Heart Structures

Heart is located inside the thoracic cavity
4 chambered heart making 2 separate circulatory
paths
Pulmonary side pumps blood to the lungs
Exchanges oxygen and carbon dioxide
Systemic circulation delivers blood to the body
Delivers oxygen rich blood and nutrients to the
organs

86
Structures of the Heart

Located low in the chest between two lungs
Surrounded by the pericardium -thin membrane
Pericardium filled with pericardial fluid to
prevent friction between the heart and the
pericardium when the heart beats
Hollow organ divided into 4 chambers
Valves keep blood flowing in one direction
Present in all major vessels leaving the heart
Muscular septum separates right and left sides

87
Heart Walls

Heart is made of 3 walls
Epicardium external layer of the heart
Myocardium middle and thickest layer of the
heart this is the actual heart muscle
Endocardium inner layer of the heart lines
the heart chambers and valves

88
Coronary Arteries

Called coronary arteries because they look like a
crown
Supply blood and nutrients to the myocardium
Coronary veins remove wastes from the myocardium
Disruption of blood flow may be coronary
occlusion (blocked)
Ischemia is a deficiency of blood supply to an
area
Ischemia can lead to necrosis (death of tissue)
the area is called an infarct (infarction)

89
Blood Vessels and Blood Flow

Opening within a vessel is the lumen
Diameter affected by constriction or dilation
Vasoconstrictors and vasodilators contract or
dilate the vessels
Blood returns to the heart from the systemic
circulation via large vessels called vena cava
In front of heart blood returns by cranial vena
cava
Behind heart through caudal vena cava
Human anatomy
Superior vena cava cranial vena cava
Inferior vena cava caudal vena cava

90
Blood Circulation

Vena cava?right atrium?right ventricle (via right
atrioventricular valve)?lungs (via pulmonary
artery through pulmonary semilunar valve)?left
atrium (via pulmonary vein)?left ventricle (via
left atrioentricular valve)?aorta (via aortic
semilunar valve)?arteries? arterioles?capillaries?
veinules?veins?Vena cava

91
Heart Facts

Blood returning through the vena cava is low in
oxygen, high in wastes and CO2
Valves in the heart and in major arteries leaving
the heart keep blood from flowing backwards
The left ventricle is the thickest wall of the
heart

Veins have thinner walls than arteries
A muscular septum divides the left and right side
of the heart
Major branches off aorta carotid (head and
brain), mesenteric (gastrointestinal tract),
renal (kidneys), iliac (hind legs)

92
Heart Rate

Rate of heartbeat is partially controlled by the
nervous system through electrical stimulation of
the myocardium
Beat begins within the heart by pace maker cells
without input from the nervous system

93
Pacemaker System

Pacemaker system keeps heartbeat and contractions
regular and organized
Atrial contraction followed by ventricular
contraction
Mammals pacemaker called sinoatrial (SA)
node that is found in the wall of the right
atrium near the entrance of the
superior vena cava
Purkinje fibers - specialized cells in
right atrium signal SA node to spread
electrical signal to surrounding muscle
cells
Atria contract blood pushed into the two
ventricles
Signal picked up by the atrioventricular (AV)
node
Conducting fibers carry electrical stimulus to
the ventricles and ventricles contract

94
Cardiac Cycle

A cardiac cycle is one complete contraction and
relaxation period
Rate varies by species
Pulse the rhythmic expansion and contraction of
an artery produced by pressure created as blood
surges through veins
Atria fills with blood during
relaxation or diastole phase
Systole phase is during the
contraction

2 complete cycles
95
Blood Pressure

Tension exerted by blood on the arterial walls
Blood pressure is taken during both phases of
cardiac cycle and is measured by a
sphygmomanometer
Hypertension high blood pressure/hypotension
low pressure
Higher (first) number is during systole phase the
second (lower) number is diastole phase

96
Blood Pressure

Measured in mm Hg
Human typical blood pressure is 120/80
Blood pressure varies for each species and for
fitness levels
Blood pressure increases heart rate decreases
(impulse from vagus nerve)
Blood pressure decreases heart rate increases
(impulse from vagus nerve)
Pressure much higher in arteries than in veins

97
Electrocardiograms

Flow of ions that incites cardiac muscle
contraction causes a small electrical current
Electrocardiograph is an instrument that measures
these electrical currents
Electrocardiogram (ECG) is a tracing made of the
currents
ECG identifies problems associated with the
contraction of the heart
Changes in the size of the heart or damaged
portions can be detected by changes in the sizes
or shapes of the peaks on the ECG

98
Heart Rhythms

Sinus rhythm normal consistent rate rhythm
Arrhythmia change in rate, rhythm/conduction in
the heart
Sinus tachycardia is a faster than normal rate
Sinus bradycardia is a slower than normal rate
Sinus arrhythmia heart rate increases w/inhale
and decreases w/exhale
Atrial fibrillation SA node not acting as
pacemaker atria quivers instead of contracting
correctly
Ventricular fibrillation Site in ventricle
fires very rapidly making the ventricle quiver
instead of contracting. Most serious arrhythmia
requires defibrillation
Asystole Heart no longer contracting cardiac
arrest

99
Heart Rate

Several factors influence heart rate
Disease
Fear
Nervousness
Shock

100
Heart Murmurs

Sound made by a defective valve
or abnormal blood flow
A swishing noise caused by a leak in a
valve
Results from the inability of the valve to
perform or close properly
AV valve leak systolic murmur (occurs during
contraction of ventricles) lub-swish-dub
Aortic valve leak diastolic murmur (blood
leaking back into ventricle as it relaxes)
lub-dub-swish

101
Cardiac Output

Amount of blood pumped in one minute
Capable of increasing dramatically when needed
(ex horse running a race)
Heart rate increases
Amount of blood increases

Cardiac Output in mL/min heart rate (beats/min)
X stroke volume (mL/beat)
An average person has a resting heart rate of 70
beats/minute and a resting stroke volume of 70
mL/beat. The cardiac output for this person at
rest is
Cardiac Output 70 (beats/min) X 70 (mL/beat)
4900 mL/minute.
The total volume of blood in the circulatory
system of an average person is about 5 liters
(5000 mL) and it is pumped through the heart
about once a minute in a healthy adult.

102
Shock

Inadequate tissue perfusion not enough blood
pumped to the vital organs
Animals are weak and depressed
Heart rate is rapid and weak
Low capillary refill time (press on gums and pink
color should return in 1 second)

103
Heart Failure

Commonly affects elderly pets specially if they
have a heart murmur
Heart enlarges and beats rapidly
Cough develops from enlarged heart putting
pressure on the airway
Fluid accumulates in the lungs or abdomen
Condition eventually fatal

104
Pathologic Conditions

Artherosclerosis hardening and narrowing of the
arteries
Congestive heart failure retention of fluid and
edema (fluid in intercellular spaces) as a result
of insufficient cardiac output
Carditis inflammation of heart
Pericarditis inflammation of pericardium
Myocarditis inflammation of myocardium
Endocarditis inflammation of endocardium and
sometimes heart valves
Vasculitis inflammation of blood vessel
Aneurysm balloon-like enlargement of artery
Hemangioma benign tumor of newly formed blood
vessels

105
Pathologic Conditions

Thrombus blood clot attached to artery or vein
Embolus foreign object circulating in blood
embolism blockage of blood vessel
Cardiomyopathy disease of heart muscle
Hypoxia below normal oxygen levels
Dirofilariasis heart worm infection
Congenital present at birth
Anomaly deviation from normal
Idiopathic unknown cause
Iatrogenic produced by treatment

106
Vocabulary

Platelets
Pericardium
Arteries
Veins
Vasoconstrictor
Vasodilator
Hypertension
Electrocardiogram
Ventricles
Atria
Aorta
Myocardium
Epicardium

Erythrocytes
Thrombocytes
Leukocytes
Albumin
Globulins
Fibrinogen
Hemeoglobin
Neutrophils
Monocyte
Eosinophils
Basophils
Lymphocytes
Endocardium

107
Respiratory System

Brings O2 into the body and blood delivers it to
cells
Respiration exchange of gases between the
atmosphere and body cells
Ventilation breathing fresh air

108
Respiratory Tract

The respiratory tract is divided into upper and
lower tracts
Upper nose, mouth, pharynx, epiglottis and
larynx
Lower trachea, bronchial tree and lungs

109
Upper Respiratory Tract

Air enters and exits the body through the nose
Nose consists of nostrils or nares that are
paired and is divided by cartilage called the
nasal septum
Endotherms have nasal turbinatesscroll-like
bones covered with vascular mucous membranes that
warm, moisturize and filter inhaled air

110
Upper Respiratory Tract

Lined with mucous membrane
Mucous from glandular secretions and cilia help
filter the air to remove debris
Olfactory receptors, responsible for smell are
nerve endings in the mucosal lining

111
Upper Respiratory Tract

Sinus is a fluid or air filled sac in the bone
that produce mucous, make bone lighter and aid
formation of sounds
Air passes through the nasal cavity to the
pharynx carrying air food pharynx throat
Pharynx connects nasal passages to larynx and
mouth to esophagus

112
Divisions of the Pharynx

Nasopharynx passageway of air entering through
the nose located posterior throat to the nasal
cavity above the soft palate
Oropharyns - throat between the soft palate
epiglottis air passageway
Laryngopharynx throat below epiglottis that
opens into the voice box and esophagus food
entering mouths passageway

113
Other Upper Respiratory Tract Structures

Soft Palate closes off the nasopharynx to
prevent food from going up the nose during
swallowing
Epiglottis acts like a lid covering the larynx
during swallowing to keep food from entering
trachea and going into the lungs

114
Larynx

Larynx is a firm cartilage structure between the
pharynx and the trachea is called the voice box
Opening to the major airways (you can feel yours
at the top of your neck)
Contains the vocal folds (cords) paired
membranous bands in the larynx that help produce
sound

115
Glottis

The vocal apparatus consisting of vocal cords and
the space between them
Air passes through glottis causing a vibration
that produces sound
In avian species the syrinx is the vocal
apparatus and it is located between the trachea
and bronchi

116
Respiratory System

Epithelium covered with mucus that filters the
air by trapping particles that are eventually
swallowed
Mucus is moist and it keeps the lungs from
loosing moisture
Increases the surface area allowing air to
contact a large amount of epithelium and the air
warms up close to body temperature before it
enters the lungs

117
Trachea

Larynx leads to the trachea also called the
windpipe
Passes into the thorax
Trachea is ventral to the esophagus and held open
by a series of C-shaped cartilage rings
Open part of C is adjacent to esophagus makes
swallowing easier Cs joined by connective
tissue
Cartilage allow neck to move without pinching off
the air flow
Lined with smooth epithelium and mucous coated
cilia for catching tiny particles
Mucus with particles is worked back up to the
larynx then swallowed

Tracheal collapse During inspiration, the
trachea in the neck tends to collapse
118
Bronchi

Trachea enters the chest and branches into two
major bronchi that each lead to a lung
Bronchi divide into smaller and smaller airways
forming the bronchioles
divisions of Bronchi
resemble tree branches and is
called the bronchial tree
Bronchioles have smooth muscle in
their walls allowing
airway to dilate or
constrict

119
Bronchioles

Bronchioles lead to smallest openings the alveoli
Contain no cartilage or glands
Gas exchange occurs between alveoli and blood
Branch terminate into alveoli
1. Trachea 2. Mainstem bronchus 3. Lobar
bronchus4. Segmental bronchus5. Bronchiole 6.
Alveolar duct7. Alveolus

120
Alveoli

Alveoli coated in surfactant that keeps them from
collapsing and lowering the amount of pressure
required to inflate
Thin flexible membrane wall surrounded by
capillaries
Prematurely born animals may lack surfactant
(fatal)

121
Lungs

Thoracic cavity is contained within the ribs
The main organ of respiration is the lungs
Lungs are divided into lobes (well defined
portion) and the number of lobes differs between
species
Area between the lungs is
the mediastinum and is where you would
find the heart, aorta, lymph
nodes, esophagus, trachea, bronchial
tubes, nerves thoracic duct
thymus

122
Lungs

Lungs contain an enormous collection of
alveoli, bronchioles and bronchi
Lungs look and feel spongy with
air trapped and elastic connective tissue that
holds airways together
Lungs covered with smooth epithelial membrane
called pleura (also lines the thorax)
Fluid between the pleural layers provides
lubrication to prevent friction
In healthy animals lungs will touch the chest
wall during inhalation

123
Diaphragm

Muscle separating thoracic peritoneal cavities
Causes air pressure in lungs to drop below
atmospheric pressure producing a vacuum in
thoracic cavity to draw in air
Diaphragm relaxes air is forced out
Innervated by phrenic nerve

124
Breathing

Inhalation (Inspiration) air taken into lungs
chest cavity volume increases
Exhalation (expiration) air forced out of lungs
chest cavity volume decreases
Difficulty in breathing dyspnea

125
Inhalation

Intercoastal Muscles between the ribs raise the
ribs and expand the chest
Diaphragm contracts moves towards the abdomen
Pressure in the lungs is lowered allowing air to
flow into the lungs

126
Expiration

Intercoastal Muscles relax ribs lower
Diaphragm relaxes arching forward toward chest
Elastic tissue in lungs recoils driving air out

127
Respiration Rate

Respiration Rate breaths per minute
Brain controls the normal rate of respiration
Factors influencing respiration rates
Heat (hot day)
Nervousness (trip to the vet)
Activity level
Panting (for cooling) Cools blood in
pharynx blood vessels that lowers the
body temp as cooler blood circulates
Oxygen plays a small part in respiration rate
levels must fall very low before they stimulate
respiration but CO2 levels quickly stimulate
respiration

128
Normal Respiration Rates Normal Respiration Rates
Animal Respiration Rate
Dog 22
Cat 26
Cow 30
Horse 12
Human 12
Sheep 19
Guinea Pig 90
Hamster 74
129
Exercise Respiration

Muscles produce more CO2 when animal is active
stimulating faster respiration
Special receptors in major arteries detect the
increase of CO2 in the blood and send signals to
the brain
Bronchioles are stimulated to dilate opening
airways and improving air delivery to alveoli

130
Breathing

Breathing is an involuntary process but it can be
controlled consciously (ex holding your breath)

Pulmonary
air-sac system of a Common Teal (Anas crecca)
with blue highlighting the location of air sacs
.b, Main components of the avian flow-through
system. Abd, abdominal air sac Cdth, caudal
thoracic air sac Cl, clavicular air sac Crth,
cranial thoracic air sac Cv, cervical air sac
Fu, furcula Hu, humerus Lu, lung Lvd, lateral
vertebral diverticula Pv, pelvis and Tr,
trachea (From O'Connor and Claessens 2005)
131
Sneezing

A protective reflex action usually caused by the
irritation of sensitive nerve endings in the
mucous membrane that lines the nose
Large amount of air forced through nose and mouth
forcing trapped particles out
Nasal discharge categorized by character serous
(clear), mucoid (cloudy), blood tinged, bloody
(epistaxis) or a combination of these.
It is also categorized by location unilateral
(one nostril vs. bilateral (both nostrils)
chronicity (acute vs. chronic) and associated
signs of disease. For example, nasal bleeding
could suggest injury, a tumor, bleeding disorder
or a tick-borne infection.

132
Coughing

When foreign particles enter the larynx and
trachea and they initiate the coughing reflex
Air is first inhaled, then the epiglottis and
vocal folds close and the animal begins to exhale
forcefully opening the epiglottis and vocal folds
allowing air to rush out with great force
Kennel Cough - The most common cause in dogs is
the bacteria Bordetella bronchiseptica. The
bacteria becomes airborne when an infected dog
breathes, barks and coughs, then the bacteria is
inhaled by another animal, resulting in kennel
cough transmission
Phlegm thick mucus secreted by respiratory
lining that is ejected through the mouth it is
called sputum (can be used for cytologic
examination/testing)

133
Clinical Practice

Cyanosis blood has a darker bluish color when
oxygen levels are too low indicated inadequate
oxygen being delivered to tissues
Pneumonia inflammation in the lungs usually
caused by an infection (viral or bacterial)
White blood cells try to fight infection cells
and tissue fluid accumulate in alveoli decrease
in lung capacity and effectiveness of gas
exchange
Bubbling sound of popping bubbles suggesting
fluid accumulation
Pleural friction rub - pleural noise indicating
lungs and chest are inflamed and irritated
Crackles and Wheezes noises that indicate
inflammation, fluid or both in the lungs

134
Clinical Practice

Hypoxia inadequate O2 supply to body tissues
Hypercapnia excessive CO2 in blood (Hypocapnia
decrease in CO2 levels in blood)
Respiratory acidosis excessive CO2 in blood
lowering blood pH (respiratory alkalosis
abnormally low CO2 levels raising pH)
Hyperventilation - abnormal increase in
respiration rate
Indotracheal intubation passage of a tube
through the oral cavity, pharynx and larynx into
the trachea
Chest tube tube inserted into thoracic cavity
to remove gases or fluids

135
Clinical Practice

Cats/kittens with runny eyes, nasal discharge,
sore throat, fever, coughing and sneezing not
unusual for all cats in house to develop the
symptoms since disease causing organisms are
highly contagious
Horses have much larger lungs than cattle of the
same size
Roaring one vocal fold fails to open air has ½
opening to enter/exit
Heaves coughing, nasal discharge, labored
breathing and easily tire from exposure to dust
and mold bronchodialators are given to open
airway and decrease inflammation

136
A smoker's dissected heart and lungs show black
spots from tar.
137
Cross section of a human lung. The white area in
the upper lobe is cancer the black areas are
discoloration due to smoking
138
Vocabulary