Lecture Exam Review: Biology - Lymphatic/Immune System PDF

Summary

This document is a list of things to review for a lecture exam on the lymphatic system and the immune system. It includes information about the structures of the lymphatic system and their functions.

Full Transcript

Things to know/review for Lecture Exam #3

Chapter 22: Lymphatic/Immune Systems
List the parts of the lymphatic system.

Lymph (fluid portion)

Lymphatic vessels

Lymphatic nodules

Lymph nodes

Tonsils

Spleen

Thymus

Red Bone Marrow
Describe the structure of lymphatic vessels.
Lymphatic Capillaries
o More PERMEABLE than blood capillaries
o Epithelium functions as series of ONE-WAY VALVES
o Found in ALL-PARTS of the body EXCEPT …
▪ NERVOUS SYSTEM
▪ BONE MARROW
▪ TISSUES without BLOOD VESSELS(cartilage,
cornea, epidermis)
Lymphatic vessels
o Have valves that ensure one-way flow
o Structure like small veins
o Route used by pathogens/cancer cells
Explain how lymph transported through lymphatic vessels.
Capillaries

Trunks

Thoracic duct
Right lymphatic duct: Drains part of body that is
not drained by the right
Drains right
lymphatic duct
side of
o Head Cisterna chyli
o Upper o Enlarged sac in
limb abdominal area
o Thorax which collects
lymph
 Junction of Jugular
and Subclavian veins

Distinguish between lymphatic tissue and a lymphatic organ - primary and secondary

(where is it found and what is the function)

Lymphatic ORGANS contain Lymphatic TISSUE
(lymphocytes, macrophages, dendritic cells, reticular
cells, and other cell types)
Primary
Where immune cells mature and become
immunocompetent
Red bone marrow
thymus

Secondary
Mature lymphocytes encounter ANTIGENS and are
activated
Nodes
Spleen
Nodules (tonsils, Peyer’s patch, appendix)
Lymphatic tissue DOES NOT have a Connective tissue
capsule; organs are encapsulated
Describe the structure and function of lymphatic tissue and a lymphatic organ.
Lymphatic Organ
o Primary
▪ Thymus
bilobed gland in superior mediastinum.
Lobes surrounded by capsule with
Trabeculae extend into gland dividing it
into lobules.
Internal framework of epithelial cells

▪ Cortex
densely packed and rapidly dividing
lymphocytes
macrophages and dendritic cells
▪ Medulla
fewer lymphocytes but has thymic
corpuscles involved in development of
regulatory T (Treg ) cells
Treg cells
o prevent autoimmunity
▪ Thymus secrets thymosin
Important in T cell development
o Secondary
▪ naïve lymphocyte encounter antigens
(pathogen) and are activated
▪ Common structures
Reticular fibers
o Associated with fixed
macrophages
germinal centers
o Sites of formation of lymphocytes
o Cells are rapidly dividing
Specialized post-capillary vessels
o allow cells from the blood to
directly enter these tissues
▪ Organs
Lymph nodes
o Principal secondary lymphoid
organs
o Filters lymph and activates
immune cells
o Prominent clusters:
o Round/bean-shaped structures 1
to 25 mm long
o responsible for filtering lymph with
external fibrous capsule
▪ Large lymphatic capillaries
crisscrossing reticular
fibers (Macrophages
reside on fibers)
o Capsules extend inward as
trabeculae
o Substances removed by
phagocytosis or stimulate
lymphocytes to proliferate in
germinal centers
o Two histologically distinct
regions of node
▪ Cortex
▪ Medulla
o Circulation
o Lymph enters afferent
lymphatic vessels
o Through cortex which has
germinal center and then to
medulla which has cords of
B cells and plasma cells
o Exits at hilum via efferent
lymphatic vessels
o Homeostatic imbalance
o Buboes:
▪ Swollen “glands”
▪ Sometimes pus-filled
▪ Bubonic plague
o Lymph nodes
 ▪ secondary cancer
sites
▪ Cancer cells often
migrate to lymph
nodes
Trapped and
proliferate
▪ Can move from
lymphatic system to
circulatory system
spreading cancer
through body.
Spleen
o Blood-rich organ about the size of
fist
o Located lateral on left side of
stomach
o Largest lymphoid organ
o Served by splenic artery and vein,
enter/ exit at hilum
o Encased by fibrous capsule and
has trabecula
o Function
▪ Destroys defective RBCs.
▪ Detects and responds to
foreign substances.
▪ Limited reservoir for blood.
o Blood flows through 3 different
rates
o Slow flow is via open
circulation
o White pulp
▪ mainly immune
function
▪ Surrounds central
arteriole
▪ Location of B cells &
T cells
o Red pulp
▪ old blood cell+
bloodborne
pathogens destroyed
▪ Reticular fibers
▪ Macrophages engulf
RBC
o
o Slow flow is via open circulation

Nodules
o denser aggregations.
o Numerous in loose connective
tissue of digestive (Peyer’s
 patches), respiratory, urinary,
o Found in areas routinely exposed
to environmental pathogens
▪ M.A.L.T (Mucosa-
associated lymphoid
tissue)
Lymphoid tissues
associated with
mucous membranes
Tonsils
Peyer’s Patch
Appendix
▪ B.A.L.T (Bronchus-
associated lymphoid
tissue)
effective against
inhaled pathogens

Lymphatic Tissue
o MALT
▪ Tonsils
Large groups of lymphatic nodules in
nasopharynx and oral cavity.
Simplest of lymphoid organs
Epithelium form tonsillar crypts
Major function - Help children’s bodies
recognize, destroy pathogens and
develop immunity
Form a ring around the border between
the oral cavity and the pharynx.
Groups
o Palatine (the “tonsils”),
posterior oral cavity - largest,
most often infected
o Pharyngeal (the “adenoids”),
posterior wall of nasopharynx
o Lingual, base of tongue
▪ Peyer’s Patch
Dome-shaped structures of dense
cluster of lymphocytes
found underlying the mucosa
found in the ileum
o functions of Location
▪ Destroy bacteria,
preventing intestinal wall
breach
▪ Generate “memory”
lymphocytes in adaptive
immunit
▪ Appendix
offshoot of cecum
 Function not really known but believe to
play role as secondary immune organ

Storage for good bacteria and
repopulates the digestive system after
bouts of diarrhea
o BALT
▪ Lymphoid follicular structures with an overlying
epithelial layer found along the bifurcations of
the bronchi
▪ Less-organized structure than other lymphoid
nodules but still are dense cluster of
lymphocytes
▪ Effective against inhaled pathogens
Define the concepts of specificity and memory as they apply to immunity.
Specificity
o Related to the adaptive immune system
o Recognizes and targets specific antigens
Memory
o Stronger attack to known antigens on second and subsequent
Distinguish between general characteristics of innate immunity and adaptive immunity.
Adaptive immunity
o Third line of defense
o Two main branches
▪ Cellular (cell-mediated) immunity
Lymphocytes -T-Cells
o Directly
o Indirectly
Cellular targets
▪ Humoral (antibody- mediated) immunity
Antibodies produced by B-cells
Bind to target cell
Extracellular targets
o Specific defensive system
▪ Eliminates almost any pathogen or abnormal cell
o Must be primed to initial exposure
o Characteristics
▪ Specific: recognizes and targets specific antigens
▪ Memory: stronger attack to “known” antigens on second
subsequent exposures
o Stimulates
▪ Antigens – large molecules
Foreign
o Not produced by the body
o Introduced from the outside
o Bacteria, viruses, other microorganisms that
cause disease
o Pollen, animal dander, feces of mites, foods,
drug cause overreaction of immune system
(ALLERGIC REACTION)
▪ Self-antigens: produced by body
 Innate immunity
o First line of defense+ Second line of defense
▪ Includes physical barriers (ex: skin, mucous membranes) and
internal defenses (ex: phagocytosis, natural killer cells
o Broad response
▪ Targets wide range of pathogens using generalized
mechanisms such as inflammation and phagocytosis
o Limited specificity
o Uses pattern recognition receptors (ex: toll-like receptors) to detect
common pathogen-associated molecular patterns (PAMPS)
Difference between innate and adaptive immunity
Innate immunity
o Rapid and general (non- specific) response
Adaptive immunity
o Very specific but takes longer to establish
Describe the components of innate immunity.
Surface barriers (1st Line of Defense)
o Physical barriers
▪ Prevent microbes and chemicals from entering the body
▪ Skin, mucous membrane
Keratin
o Resistant to
▪ Acid/bases
▪ Bacterial enzymes
▪ Toxins
▪ Tears, saliva, urine
Lysozyme
o Enzyme that destroys bacteria by digesting cell wall
▪ Cilla in respiratory tract
▪ Coughing and sneezing
▪ Protective chemicals that inhibit or destroy microorganisms
Sweat
Saliva
Tears
Acid
 Mucus

Internal defenses (2nd Line of Defense)
o Triggered by the surface barriers breached by nicks or cuts
o Internal group of cells and molecules activated ONLY if deep tissues are
invaded
o Phagocytes
▪ Important and effective mechanism of swallowing and destroying
pathogens during innate immune response
Phagosome joins lysosome
Digestive enzymes, effectively killing many pathogens
▪ White blood cells that ingest foreign invaders(pathogen)
Neutrophils
Macrophages (differentiate from monocytes)

▪Some pathogens not killed with acidified lysosomal enzymes (eg:
tuberculosis bacteria)
▪ Helper T cells trigger respiratory
Rapid release of free radicals or reactive oxygen species
Increasing pH and osmolarity + kills bacteria
▪ Macrophages
Develop form monocytes that leave blood -> enter tissue
Longer-lived than neutrophils
Can ingest larger particles (Can become Dendritic cells)
Chief phagocytic cells
Free macrophages: wander
Fixed macrophages: permanent residents in some organs
Go by many names:
o Kupffer cells in liver
o Histiocytes in connective tissues
o Alveolar macrophages in lungs
o Microglia in CNS
▪ Neutrophils
Attracted via chemotaxis
Granules contain mediator proteins (such as histamine)
Most abundant WBC but become phagocytic on exposure to
infectious material
o NK cells
▪ Main function is immunological surveillance or policing blood and
lymph
▪ Attack cells that lack “self” cell- surface receptors (MHC1)
▪ Kill by inducing apoptosis (cell death) in cancer cells and virus-
infected cells
▪ Attaches to cells via activation receptor (Fas ligand) then sends
apoptotic signals
▪ Secrete chemicals
Perforin
o Forms pores in membranes of infected cells
Granzyme
o Protein-digesting enzyme
o Soluble Mediators
▪ Proteins that play a role in the regulation (control) of an immune
 reaction
▪ Can be initiating, perpetuating, or aggravating
▪ Messengers
Cytokine: molecule that allows cells to communicate with
each other over short distances

Chemokine: similar to cytokine but function to attract
WBC (chemotaxis) from longer distances towards the
source (ie injured tissue)

▪ Most important antimicrobial proteins
Interferons
o Induced proteins
o Travel to adjacent cells and gives notice of viral
infection
Complement proteins
o Bind to membrane of the pathogen labeling it for
phagocytosis (opsonization)
o Act as chemokine to attract phagocytes
o Form damaging pores in membrane of pathogen
o Inflammation
▪ Sign that innate response has been triggered
▪ Triggered by body tissues injured or infection
▪ Benefits
Prevents spread of damaging agents
Disposes of cell debris and pathogens
Alerts adaptive immune system
Sets the stage for repair
▪ Acute
Short term inflammatory response
Can become chronic
▪ Chronic
Ongoing inflammation
Caused by foreign bodies
Persistent pathogens and auto immune disease
▪ Stages of inflammation
o Tissue injury
▪ Inflammatory chemical release
▪ Chemicals released
Histamine
Leukotrienes
Prostaglandins
Causing
o Vasodilation
o leaky capillaries
o attract leukocytes to area
o Vasodilation and increased permeability
▪ Blood flow to area increases
▪ Fluid containing clotting factors and antibodies flood
area (edema)
▪ Fluid sweeps foreign material into lymphatic vessels
▪ Clotting factors form fibrin mesh, begins repair
 ▪ Pressure on nerve endings = pain
o Phagocyte mobilization
▪ Leukotrienes attract NEUTROPHILS
▪ Neutrophils flood area first
▪ macrophages follow
▪ phagocyte and pathogen subsequently die
▪ accumulated is visible as pus
▪ Complement proteins activated if pathogen involved
▪ Adaptive immunity elements arrive
▪
o Fever
▪ Abnormally high body temperature
▪ Systemic response
▪ Leukocytes and macrophages secrete pyrogens
▪ Pyrogens:
Hypothalamus raises temperature
Liver and spleen sequester iron/zinc
Increases metabolic rate increases rate of repair

Describe how chemical mediators are involved with immunity.
Cytokines
o Act as signaling proteins released by immune cells (e.g.,
macrophages, T cells) to regulate inflammation, immune cell
activity, and communication.
Chemokines
o A subset of cytokines that guide the movement of immune cells
toward areas of infection or injury.
o
Histamine
o Released by mast cells and basophils during allergic reactions and
in response to injury.
Prostaglandins and Leukotrienes
o Lipid-based mediators produced at infection or injury sites.
o Enhance inflammation
o Increase pain sensitivity
o Cause for fever by stimulating blood flow to the area
o Assisting in immune cell treatetment

Antibodies
o Produced by B cells in response to specific antigens.
Complement Proteins
o A group of blood proteins that enhance immune defense when
activated.
List the types of white blood cells involved in innate immunity.
Neutrophil
o Attracted via chemotaxis
o Granules contain mediator proteins (such as histamine)
o Most abundant WBC but become phagocytic on exposure to
infectious material
Monocytes
o Develop form monocytes that leave blood -> enter tissue
o Longer-lived than neutrophils
 o Can ingest larger particles (Can become Dendritic cells)
o Chief phagocytic cells
o Free macrophages: wander
o Fixed macrophages: permanent residents in some organs

Dendritic Cells
o Found in tissues that are in contact with the external environment,
like the skin and mucous membranes.
o Antigen presenting cell
o Present antigens to T cells in lymph nodes
o Most effective presenter (links innate and adaptive immunity)
NK Cells
▪ Main function is immunological surveillance or policing
blood and lymph
▪ Attack cells that lack “self” cell- surface receptors
(MHC1)
▪ Kill by inducing apoptosis (cell death) in cancer cells and
virus-infected cells
▪ Attaches to cells via activation receptor (Fas ligand) then
sends apoptotic signals
▪ Secrete chemicals
Perforin
o Forms pores in membranes of infected cells
Granzyme
o Protein-digesting enzyme

Eosinophils
o attracted to site by T cell cytokines.
o Mast cell degranulation (inflammation)
o fluid leakage
o caused by the increase in local vascular permeability thought to
have a flushing action
List the events of the inflammatory response and explain their significance.
▪ Stages of inflammation
o Tissue injury
▪ Inflammatory chemical release
▪ Chemicals released
Histamine
Leukotrienes
Prostaglandins
Causing
o Vasodilation
o leaky capillaries
o attract leukocytes to area
o Vasodilation and increased permeability
▪ Blood flow to area increases
▪ Fluid containing clotting factors and antibodies flood
area (edema)
▪ Fluid sweeps foreign material into lymphatic vessels
▪ Clotting factors form fibrin mesh, b’egins repair
▪ Pressure on nerve endings = pain
o Phagocyte mobilization
▪ Leukotrienes attract NEUTROPHILS
 ▪ Neutrophils flood area first
▪ macrophages follow
▪ phagocyte and pathogen subsequently die
▪ accumulated is visible as pus
▪ Complement proteins activated if pathogen involved
▪ Adaptive immunity elements arrive

What is the respiratory burst?
Triggered by Helper T cells
Rapid release of free radicals or reactive oxygen (ROS)
Increasing pH and osmolarity and kills bacteria
Define antigen.
Any substance that causes the body to make an immune response against that substance

Describe the two groups of antigens…foreign and self
Foreign
o Not produced by the body
o Introduced from the outside
o Bacteria, viruses, other microorganisms that cause disease
o Pollen, animal dander, feces of mites, foods, drug cause overreaction
of immune system (ALLERGIC REACTION)
Self
o produced by body
Describe the origin, development, activation, and proliferation of lymphocytes (T and B
cells)
Origins
Develop

Which cells recognized them (CD4/CD8)

CD4
o Helper function T-cells
o Recognized antigens from MHC class II
CD8
o Cytotoxic function T- cells
o Recognized antigens from MHC class I
Describe the function of major histocompatibility complex (MHC) molecules.
Group of self-proteins
Unique to everyone
Groove holds self-antigen or foreign antigen
o Association of antigen and MHC occurs inside cell
o T cell recognize antigens presented on MHC proteins
Distinguish between MHC class I molecules and MHC class II molecules.
MHC class I
o Displayed by all cells except RBCs
o Endogenous antigen (virus, parasites, bacterias that replicate inside the
cell)
o Activate CD8 T cells
MHC class II
o displayed by APCs (dendritic cells, macrophages, & B cells)
▪ Exogenous antigen (pathogens found outside cells
▪ Activate CD4 T cells
Define antibody-mediated immunity and name the cells involved.
 Humoral (antibody- mediated) immunity
o Antibodies produced by B-cells
o Bind to target cell
o Extracellular targets
Cells involved
o B cells
o Plasma cells
o Memory B cells
o Helper T cells (CD4)
o Dendritic Cells
o Macrophages
Define cell-mediated immunity and name the cells involved.
Cellular (cell-mediated) immunity
o Lymphocytes -T-Cells
o Directly
o Indirectly
o Cellular targets
Cells involved
o CD8+ T Cells (Cytotoxic T Cells):
o D4+ T Cells (Helper T Cells, specifically Th1 subset):
o Macrophages
o Natural Killer (NK) Cells
o Dendritic cells
o Memory T cell
Know the 5 difference types of antibodies and their function
IgM
o Receptor on surface of B-cells
o LARGEST Antibodies
o very effective
o Main in primary response
o Activates complement protein cascade
IgD
o Receptor on surface of B cells
IgG
o Most common antibody
o Main in secondary response
o Crosses placenta to protect fetus
IgA
o Secreted in mucus, saliva, and tears
o ONLY antibody to LEAVE interior to protect body surfaces
IgE
o Cause release of histamine
o Associated with allergies
Describe the functions of the ssddifferent antibodies.
IgM
o Receptor on surface of B-cells
o LARGEST Antibodies
o very effective
o Main in primary response
o Activates complement protein cascade
IgD
o Receptor on surface of B cells
IgG
 o Most common antibody
o Main in secondary response
o Crosses placenta to protect fetus
IgA
o Secreted in mucus, saliva, and tears
o ONLY antibody to LEAVE interior to protect body surfaces
IgE
o Cause release of histamine
o Associated with allergies

Discuss the primary and secondary responses to an antigen and explain the basis for
long-lasting immunity.
Primary immune response
o First time exposure
▪ Lag period: 3 to 6 days
▪ Levels peak in 10 days
Secondary immune response
o Re-exposure
o Faster, more prolonged, more effective
o Respond within hours, not days
o Antibodies bind with greater affinity
o Antibody level can remain high for week to months
Describe the types and functions of T cells.

Explain the ways that adaptive immunity can be acquired (active and passive)
Active
o Contact
o Naturally acquired
▪ Infection; contact with pathogen
o Artificially acquired
▪ Vaccine; dead or attenuated pathogens
Passive
o No contact
o Naturally acquired
▪ Antibodies passed from mother to fetus
o Artificially acquired
▪ Antibodies injected

What is edema?
Swelling caused by too much fluid trapped in the body tissues
Immune system disorders
Immunodeficiencies
o Congenital (genetic) or acquired conditions that impair function or
production of immune cells
o Severe combined immunodeficiency (SCID) syndrome:
▪ A combination of genetic defects affecting B and T cells
o Treatment: bone marrow transplant
AIDS (acquired immunodeficiency syndrome)
o Infection by the human immunodeficiency virus (HIV)
o HIV interferes with helper T cells
o Virus uses CD4 receptor to enter cell
 o High mutation rate of virus results in resistance to drugs
o Initial immune response produces anti bodies with flu-like symptoms in first
1-2wk
o Seroconversion defers AIDS until immune system collapses
o Four known individuals have been cured due to stem cell transfusion
which contained cells with genetic mutation of the CCR5 gene
Hypersensitivities
o immune responses to harmless threat causing tissue damage
o Different types:
▪ Type I
Immediate
happens rapidly and can be systemic (anaphylactic shock)
treated with anti-histamine or epinephrine
▪ Type II + III
Slow onset: 1-3 hours
blood transfer
▪ TYPE IV
Delayed
Slow onset 1–3 days
i.e. tuberculosis, poison ivy
Auto immune diseases
o when immune system loses ability to distinguish self from foreign
o Examples
▪ Rheumatoid arthritis: immune system attacks
▪ Multiple sclerosis: destroys white matter myelin
▪ Graves’ disease: causes hyperthyroidism
▪ Type 1 diabetes: attack pancreatic beta cells
▪ Glomerulonephritis: damages kidney
o Treatment: suppress immune system
Chapter 23: Respiratory System

List the structures that comprise the respiratory system.

External nose – for air inspiration

Nasal cavity

o Clean +warm

o Humidify air

Pharynx

o Common passageway for food + air

Larynx

o VOICE BOX

o Keeps airway patent

o Division of upper and lower respiratory system
 Trachea

o Air cleaning tube into lungs

Bronchi

o TUBE

o Directs air into lungs

Lungs

o Network of aveoli
Describe the structural and function anatomy of the respiratory system.

Pulmonary ventilation
o Aka breathing
o Moving air IN and OUT of lungs
Gas Exchange
o Diffusion of gases across plasma membranes
o Two types:
▪ Pulmonary
External gas exchange
Gas exchange between air in LUNG (specifically in ALVEOLI)
+ BLOOD
▪ Tissue
Internal gas exchange
Gas exchange between BLOOD and TISSUES

Transport
o Oxygen and Carbon Dioxide moving through the bloodstream
Regulation of blood pH
o Regulation of hydrogen(H)
Production of chemical T issue
o ACE = enzyme involved in blood pressure regulation
Voice production
o Movement of air past vocal folds
Olfaction
o Airborne molecules drawn into nasal cavity
Protection
o Against microorganisms by
▪ Preventing entry
▪ Removing them from respiratory surfaces
Upper and lower respiratory tracts further divided into conducting zone and
respiratory zone
o Conducting zone
▪ Conduits that transport gases (nose -> small air tubes in lungs strictly
for pulmonary ventilation)
▪ Includes ALL respiratory structures EXCEPT the alveoli sac
o Respiratory zone
▪ Site of gas exchange
▪ Alveoli sac
 Know the structure of the larynx and role of epiglottis and vocal chords
Larynx
o The voice box
o Attached to HYOID BONE
o Composed of 8 hyaline, 1 elastic cartilage (EPIGLOTTIS)
o Home of the vocal cords
o Epithelium
o Continuous with trachea
Thyroid cartilage
o Part of larynx
o Large, shield-shaped cartilage
o Laryngeal prominence (ADAM’S APPLE)
Epiglottis
o Part of larynx
o Attached to thyroid cartilage
o Covers larynx inlet

Describe the anatomy of the respiratory passages, beginning at the nose and ending
with the alveoli.

Nose and Paranasal Sinuses
o Nose = ONLY external portion
o Functions of nose
▪ Provides an airway
▪ Moistens/warms air
▪ Filters/cleans air
▪ Resonating chamber of speech
▪ Houses olfactory receptors
o Structures of nose
▪ Root (Area between eyebrows)
▪ Bridge + Dorsum nasi (Anterior margin)
▪ Apex (tip of nose)
▪ Alae (Lateral boundary)
Nasal Cavity
o Formed by nasal and frontal bones superiorly
o Formed by Maxillary bones laterally
o Plates of hyaline cartilage
o Divided nasal septum
▪ Anteriorly – septal cartilage
▪ Posteriorly – vomer bone and perpendicular plate
o Posterior nasal opening
▪ Where nasal cavity turns into nasopharynx
o Nasal vestibule
▪ Superior to nostrils
▪ Lined with hairs that filter coarse particles
o Mucous membranes
▪ Contain lysozyme and defensins
▪ Ciliated cells sweep mucus towards throat
▪ Inhaled air warmed by capillaries
▪ Mucosa contains sensory nerve endings that
triggers sneezing reflex

o Nasal conchae
 ▪ Mucosa -covered projections
▪ Superior, middle, and inferior conchae
▪ Shape helps
Increase mucosal area
Enhance air turbulance
▪ Function
Filter Heat, and moisten air going in
Reclaim heat and moisture
Paranasal Sinuses
o Cavities surrounding nasal cavity
▪ Frontal, sphenoid, ethmoid, and
maxillary bones
▪ Functions
Lighten skull
Secrete mucus
Help to warm and moisten air
The Pharynx
o Muscular tube “throat”
▪ Connects nasal cavity and mouth to larynx and
esophagus
▪ Composed of skeletal muscle
o Three regions
▪ Nasopharynx
▪ Oropharynx
▪ Laryngopharynx
o Common opening for digestive and respiratory systems
o Nasopharynx
▪ Lies posterior to nasal cavity
▪ Pseudostratified columnar epithelium with
goblet cells
▪ Mucous debris is allowed
▪ Uvula close nasopharynx during swallowing
▪ Pharyngeal tonsils(adenoids) – located on
posterior wall
▪ Auditory(eustachian) tubes
Drain and equalize pressure from
middle ear + open into lateral walls
How pathogen from cold causes
ear infection
o Oropharynx
▪ Shared with digestive system
▪ Lined with most stratified squamous
epithelium
▪ Passageway for food and air
▪ Stratified squamous epithelium
▪ Fauces opening that connect oral cavity
and pharynx
▪ Palatine tonsils on lateral walls of fauces
▪ Lingual tonsil on posterior surface of
tongue
o Laryngopharynx
▪ Passageway for food and air
 ▪ Stratified squamous epithelium
▪ Posterior to epiglottis
▪ Extends to larynx (anteriorly) +
esophagus(posteriorly)
The Larynx
o The voice box
o Attached to HYOID BONE
o Composed of 8 hyaline, 1 elastic cartilage (EPIGLOTTIS)
o Home of the vocal cords
o Epithelium
o Continuous with trachea
o Thyroid cartilage
▪ Large, shield -shaped cartilage
▪ Laryngeal prominence (Adam’s apple)
o Epiglottis
▪ Attached to Thyroid cartilage
▪ Covers larynx inlet during swallowing
▪ Covered in taste bud- containing mucosa
o Functions of larynx
▪ Provides patent (open and unobstructed) airway
▪ Routes air and food into proper vessel
▪ Voice production
o Vocal folds
▪ Glottis
Folds and opening between vocal folds
▪ True vocal cords
Elastic fiber that fold to form
Folds vibrate to produce sound
▪ Vestibular folds
False vocal cords
Close glottis during swallowing

The Trachea
o Trachealis
▪ Smooth muscle fibers, connect posterior parts of
cartilage rings
▪ Contracts during coughing
o Crania
▪ Last tracheal cartilage that branches into two main
bronchi
▪ Mucosa of carina highly sensitive
Violent coughing if foreign objects makes
contact
The Bronchi and Subdivisions
o Bronchial tree
▪ Collective term used for multiple-branched bronchi
▪ Trachea divides into right and left primary bronchi
(bronchus singular)
▪ Branches into lobar: 3 on right, 2 on left
o Bronchi and bronchioles capable of changing diameter:
▪ Bronchodilation: smooth muscle relaxes
decreased resistance so airflow increases.
 Bronchoconstriction: smooth muscle contracts
▪
Increased resistance so airflow decreases.
o Branches into segmental bronchi
o Branches become smaller and smaller until becoming
terminal bronchioles - 1000 each lung
o Asthma attack
Respiratory Zone
o Alveolus (alveolar sac = cluster)
▪ Walls w/ 2 type of cells
Type I pneumocytes
o Thin squamous epithelial cells
o 90% of surface of alveolus.
o Gas exchange
Type II pneumocytes
o Round or cube shaped secretory
cells
o Produce surfactant and
antimicrobial proteins

▪ Alveolar pores connect adjacent alveoli, equalize
pressure
▪ Alveolar macrophages keep alveolar surfaces
sterile

State the parts of the respiratory membrane
Respiratory membrane
o Alveoli + Capillary
o 0.1-0.5 um thick
o Blood air barrier
o Gas exchange

Explain the role of the thoracic wall in respiration.
Protects lungs and heart
Supports chest expansion/contraction
Attachment for respiratory muscles
Moves ribs (pump-handle & bucket-handle)
Changes thoracic cavity volume
Enables air pressure regulation for breathing

Describe the structure of the lungs

Root
Coastal Surface
Apex
Base
Right lung Left lung
Superior, middle, and inferior Superior and inferior lobes
lobes Oblique fissure
Horizontal fissure Smaller than right
Oblique fissure

Lobes divided into bronchopulmonary segments
 o 10 on right
o 8–10 on left
o Separated by connective tissue septa
o Each segment has own artery, vein, and bronchus
Muscles of respiration.
Change volume of the thoracic cavity
Allowing air to flow in and out of the lungs
Muscle of inspiration
o INCREASE volume of cavity
o Diaphragm
o External Intercostals
o Pectoralis minor
o Scalene muscles
Muscle of expiration
o DECREASE volume of cavity
o Internal intercostals
o transverse thoracic
o assistance from
o abdominal muscles.
Mechanics of inspiration & expiration (quite and forced)
Inspiration
o Eupnea=quiet breathing
o Involving diaphragm and external intercostals
1. Diaphragm contracts
Increase thoracic volume
2. External intercoastal muscle contracts
Rib cage lifted and out
Increase in thoracic volume
o Steps
1. Inspiratory muscles contract
2. Thoracic cavity volume increases
3. Lungs are stretched
4. Intrapulmonary volume increases
5. Intrapulmonary pressure drops
6. Air flows into lungs down its pressure gradient until
intrapulmonary pressure is ATM
o Forced
o Hyperpnea
o Accessory muscles activated
▪ Scalene
▪ Sternocleidomastoid
▪ Pectoralis minor
▪ Erector spinae
Muscle straighten thoracic
▪ Increase thoracic cage size further than normal, creates
a larger pressure gradient, more air drawn in
Expiration
o Passive process
1. inspiratory muscles relax
2. Thoracic cavity volume decreases
3. Volume decrease
4. Lung’s recoil
o Steps
 1.
Inspiratory muscles relax
2.
Thoracic cavity volume decreases
3.
Elastic lungs recoil passively
4.
Intrapulmonary volume decreases
5.
Intrapulmonary pressure rises
6.Air (gases) flows out of lungs until intrapulmonary
pressure equals ATM
o Force expiration
▪ Active process that uses oblique and transverse
abdominal muscles

Explain partial pressure and its relationship to the concentration of gases in the body.

Partial pressure
o Proportional to its percentage in mixture
o Greater partial pressure difference between 2 areas = more rapid
movement of gas
 Understand how changes in alveolar pressure is responsible for the movement of air
into and out of the lungs.

Intra-alveolar pressure
pressure within alveoli, changes during phases of breathing

Explain how surfactant prevents the collapse of the lungs.

Describe the partial pressure gradients for O2 and CO2. in external respiration and
internal respiration
Contrast fetal hemoglobin with adult hemoglobin.
Adult
o Alpha-beta
Fetal
o Alpha-gamma
Explain how O2 and CO2 are transported in the blood.
Oxygen
o 1.5% dissolved in plasma
o 98.5% bound to Fe of hemoglobin
(Hb)
Carbon Dioxide
▪ Three forms
7-10% dissolved in plasma
20% bound to hemoglobin
Binds specific amino acids on
hemoglobin to form carbaminohemoglobin
70% transported as bicarbonate ions (HCO3–) in
plasma

Explain the O2/CO2 exchange in the lungs and at the tissues.
Describe the respiratory areas of the brainstem and how they produce a rhythmic pattern
of ventilation.
Pulmonary ventilation
o Can be under voluntary control
o When sleep or focused on other tasks = regulated involuntary
Respiratory rate
Neural controls involve reticular formation of medulla and pons
Medullary respiratory centers
o Ventral respiratory group
▪ produces the normal, involuntary rhythm of breathing called
eupnea
o Dorsal respiratory group
▪ modifies the respiratory rhythm.
o Excite inspiratory muscles via phrenic(diaphragm)
o intercostal nerves (external intercostals)
Explain how blood pH, CO2 and O2 levels affect ventilation.
Know is Henry’s Law, Bohr Effect, Dalton’s law
 Henry’s Law
o Concentration of a gas in a liquid is determined by its partial pressure
and its solubility coefficient at a given temperature.

o Each gas will dissolve in the liquid in proportion to its solubility (ability
to dissolve) and partial pressure

▪ solubility decreases inversely with temperature
▪ greater partial pressure = more soluble
▪ At equilibrium partial pressures in the two phases will be
equal

Bohr Effect
o effect of pH on oxygen-hemoglobin dissociation curve
▪ pH of blood declines = amount of oxygen bound to
hemoglobin at any partial oxygen declines

Dalton’s Law of partial pressures
o Mixture of gases = sum of pressures exerted by each gas
Relationship of pressure to volume
Discuss the Hering‒Breuer reflex and its importance.
LIMITS the depth of inspiration and prevents overinflation of the lungs
Explain how the cerebral cortex and limbic system can affect ventilation.
Hypothalamic controls
o Modifies rate and depth of respiration through limbic system
o Ex: breath holding in anger or gasping with pain

Cortical controls
o direct signals from cerebral motor cortex
o bypass medullary controls
o Ex: voluntary breath holding

Know the carbon dioxide/carbonic acid/bicarbonate equation... what does do?

Regulates Blood pH
o The equation acts as a buffer system that helps maintain blood pH
within a narrow range (around 7.35–7.45).
CO₂ Control
o Increased CO₂
▪ shifts the reaction right, producing more H⁺, which lowers pH
(more acidic)
▪ Ex: during exercise
o Decreased CO₂
▪ shifts the reaction left, using up H⁺ and raising pH (more
basic).
 ▪ Ex: Hyperventilation

Two different circulations associated with the lungs: pulmonary and bronchial

Fetal respiration
help tone muscles in preparation for breathing once born
Birth
o Through birth canal thoracic cavity compressed, expelling fluid
from lungs
o Preterm birth frequently results in severe respiratory distress
o Prior to 26 weeks, sufficient pulmonary surfactant NOT
produced
Chemicals monitored for respiration

Chapter 27: Fluids, Electrolytes and Acid/Base

List the dominant cations and anions in the major fluid compartments.
Cations
o Sodium (Na+)
o Potassium(K+)
Anions
o Bicarbonate (HPO4 ^-2)
o Chloride

Describe the causes of edema.
Edema
o Interstitial fluid accumulation
o Causes
▪ Hypernatremia
High plasma sodium levels
Leads to confusion, seizures, and coma
▪ Glucocorticoids (cortisol = stress)
Increase Na+ (Sodium reabsorption
Discuss what body fluid osmolality is and how it effects water movement
Body fluid osmolarity
o Change in the concentration leads to change in osmolarity leads to water
flow
o ECF osmolality -> water leaves cell, more salt
o ECF osmolality -> water enters cell, less salt
o Maintained around 280-300mOsm = Healthy
o Rise in osmolality
▪ Stimulates thirst
▪ Cause ADH release
o Decrease in osmolality
▪ Inhibits thirst
▪ Cause ADH inhibition
Understand fluid intake vs fluid loss
Fluid intake
o Intake must equal output
o Food and Beverages (90%)
o Cellular respiration (10%) (Metabolic water)
o About 2.5L-3.0L of water per day
 o Output:
▪ Kidney -Most fluid as urine
▪ Evaporation- 1/3 lost through the skin and respiratory passageways
▪ Feces- 4% loss from the digestive system tract
Fluid loss
o Obligatory water losses
▪ Why we CANNOT live without water very long
▪ Insensible water loss
Lungs, skin, and feces
▪ Sensible water loss
Urine to excrete wastes
Minimum daily loss of 500ml
Volume of urine also depend on
o Fluid intake
o Diet
o Water loss
Demonstrate an understanding ion homeostasis.
Sodium
o most abundant cation outside the cell
o Major contributor to osmotic pressure
o Changes affect
▪ plasma volume
▪ blood pressure
▪ ECF/IF volumes
▪ Nervous and muscle function
o water balance linked to blood pressure/volume control mechanisms
o Changes in pressure/volume trigger neural and hormonal controls
▪ Renin-angiotensin-aldosterone mechanism
▪ Atrial natriuretic peptide (ANP)
▪ Other hormones
o Regulation
o Aldosterone plays biggest role
o High Aldosterone = Sodium actively reabsorbed
o Low aldosterone = Sodium not absorbed
o Elevated K+ can also triggers aldosterone production
o Water follows SALT
o Renin-angiotensin-aldosterone mechanism
▪ Kidneys release renin
▪ Renin catalyzes production of angiotensin II which targets
adrenal gland
▪ Adrenal cortex releases aldosterone which targets kidney
(DCF)
▪ Increased Na reabsorption and K secretion

o Other hormones
o Estrogens
▪ increase NaCl reabsorption
▪ LEADS to water retention
o Progesterone
▪ decreases Na+ reabsorption
▪ Promotes salt/water LOSS
o Glucocorticoids
▪ Cortisol =stress
 ▪ Increase Na+ reabsorption and promote edema

Calcium + Phosphate
o Function
▪ Important for exocytosis, including neurotransmitters
▪ Needed for muscle contraction
▪ Regulates action potential in cardiac muscle
o Regulation
▪ Regulated by the kidneys, digestive tract, and bones.
▪ Balance between deposition and reabsorption from bone.
▪ Balance between absorption from intestines and excretion by
kidneys

Know the role of: the renin-angiotensin-aldosterone system, atrial natriuretic hormone
and antidiuretic hormone (ADH).

ADH
o Made by hypothalamus
o Released by posterior pituitary gland
o Release proportional to WATER REASORBTION
o Decreased ADH = DILUTED URINE
o Increased ADH = CONCENTRATED URINE
o Osmoreceptors sense solute
o Decreased blood pressure
▪ Triggers ADH release
▪ Caused by large changes quickly
Intense sweating
Vomiting
Diarrhea
Severe blood loss

Renin-angiotensin-aldosterone
o INCREASES blood pressure and fluid retention through RENIN,
ANGIOTENSIN II, and ALDOSTERONE.
o Kidneys release RENIN
o Renin catalyzes (cause a reaction) of ANGIOTENSIN II
o ANGIOTENSIN = targets adrenal gland
o ADRENAL CORTEX RELEASES ALDOSTERONE
o Increased Na (Sodium) reabsorption
o Increased K secretion
atrial natriuretic hormone
o DECREASES blood pressure + fluid volume through natriuresis
and vasodilation
o Atrial cells RESPOND to stretch by increased blood pressure
o Targets
▪ Kidney
▪ Hypothalamus
▪ Adrenal gland
o Works to decrease blood pressure/volume
o Inhibits ADH, renin, and aldosterone production
 o Loss of Na (Sodium) and water
o Promotes vasodilation
Explain the actions of the different types of buffer systems of the body.
Chemical Buffer Systems
o System that acts to resist drastic pH changes
o Mechanisms for regulation of concentration
o Work immediately
o Three major chemical buffering system:
▪ Bicarbonate
▪ Phosphate
▪ Protein
o Psychological buffer systems
▪ Respiratory system
Short term
Rapid response through breathing
▪ Renal system
Long term
Slower response
Taking hours to days

Bicarbonate
o Buffers ICF and ECF
o Primary Buffer

o pH decreases = HCOɜ-(BICARBONATE) ties up H+ and
forms H2CO3(Carbonic Acid)

o pH INcreases = H2CO3(Carbonic Acid) dissociate and
DONATE H+ to form water

o Bicarbonate [HCOɜ-] closely regulated by KIDNEYS
o Carbonic Acid [H2CO3] supply is ALMOST limitless
Phosphate
o Second line of defense
o Action nearly identical to bicarbonate buffer
o Effective mostly in urine
Protein
o Intracellular proteins are plentiful
o Amphoteric
▪ Function as weak acid and weak base
▪ pH rises, carboxyl groups release H+

▪ pH falls, NH group bind H+

▪ Hemoglobin functions as an Intracellular buffer
Explain the causes and effects of acid-base imbalances.
 Respiratory system causes acid-base imbalances
o Hypoventilation causes RESPIRATORY ACIDOSIS
o Hyperventilation causes RESPIRATORY ALKALOSIS
Respiratory acidosis/alkalosis
o Failure of respiratory system to perform pH- balancing role
o Most important indicator is Pco2(partial pressure of Carbon dioxide)
Metabolic acidosis/ alkalosis
o Failure of kidney to maintain pH
o Abnormal HCO3- levels
Understand how the hypothalamic thirst center function
Osmoreceptors – detect INCREASES of 1-2%
Baroreceptors sense – DECREASED of blood volume/pressure
Signal sent to HYPOTHALAMIC THIRST CENTERS in the medulla oblongata
Resulting in dry mouth (reduced saliva)

Define hyponatremia, hypernatremia, hypokalemia, hyperkalemia, hyperphosphatemia,
hypophosphatemia.
Hyponatremia
o Low plasma sodium levels
o Can lead to confusion, seizures, coma
Hypernatremia
o High plasma sodium levels
o Lead to pulmonary edema muscle convulsions
Hypokalemia
o Abnormally LOW levels of POTASSIUM in extracellular
fluid
Hyperkalemia
o Abnormally HIGH levels of POTASSIUM in extracellular
fluid
Hyperphosphatemia
o High phosphate levels
o Due to RENAL FAILURE, CHEMOTHERAPY,
HYPERPARATHYROIDISM (secondary to elevated plasma
calcium levels)
Hypophosphatemia
o Low phosphate levels
o Due to reduced absorption from intestine from VITAMIN D
DEFICIENCY or ALCHOL ABUSE

Know difference between metabolic acidosis/alkalosis and respiratory acidosis/alkalosis
and compensation.
Respiratory acidosis/alkalosis
o Failure of respiratory system to perform pH- balancing role
o Most important indicator is Pco2(partial pressure of Carbon dioxide)
Metabolic acidosis/ alkalosis
o Failure of kidney to maintain pH
o Abnormal HCO3- levels
Respiratory compensation
o Lungs compensate for metabolic pH problems
o Metabolic acidosis
▪ INCREASING rate/depth of breathing
o Metabolic alkalosis
▪ DECREASING breathing, CO2 accumulates
 Renal compensation
o Kidneys compensate for pH problems cause by lungs
o Respiratory acidosis
▪ Kidneys compensate for HCO3-, create new HCO3- and
secrete more H+
o Respiratory acidosis
▪ Kidney
Reabsorb more HCO3-(Bicarbonate)
Create new HCO3-(Bicarbonate)
Secrete more H+
o Respiratory alkalosis
Kidney excrete more HCO3-(Bicarbonate)

Know the carbon dioxide/carbonic acid/bicarbonate equation.

Explain the effect an acidic environment has on oxygen transport